Found 2 matching records:
Displaying record number 2124
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MAb ID |
PG9 |
HXB2 Location |
Env |
Env Epitope Map
|
Author Location |
gp120(126-196) |
Epitope |
(Discontinuous epitope)
|
Subtype |
A |
Ab Type |
gp120 V2 // V2 glycan(V2g) // V2 apex, quaternary structure |
Neutralizing |
P (tier 2) View neutralization details |
Contacts and Features |
View contacts and features |
Species
(Isotype)
|
human(IgG1) |
Patient |
Donor 24 |
Immunogen |
HIV-1 infection |
Keywords |
acute/early infection, anti-idiotype, antibody binding site, antibody gene transfer, antibody generation, antibody interactions, antibody lineage, antibody polyreactivity, antibody sequence, assay or method development, autoantibody or autoimmunity, autologous responses, binding affinity, broad neutralizer, CD4+ CTL, chimeric antibody, class I down-regulation by Nef, co-receptor, complement, computational prediction, contact residues, early treatment, effector function, elite controllers and/or long-term non-progressors, escape, genital and mucosal immunity, germline, glycosylation, HIV reservoir/latency/provirus, immunoprophylaxis, immunotherapy, junction or fusion peptide, memory cells, mimics, mother-to-infant transmission, mutation acquisition, neutralization, polyclonal antibodies, rate of progression, review, SIV, structure, subtype comparisons, therapeutic vaccine, transmission pair, vaccine antigen design, vaccine-induced immune responses, variant cross-reactivity, viral fitness and/or reversion |
Notes
Showing 207 of
207 notes.
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PG9: This review on antibody mediated cellular cytotoxicity (ADCC) effector functions of anti-HIV-1 antibodies discusses the association between the conformational state of HIV antigen, Env, and binding of either bnAbs or nnAbs (non-neutralizing antibodies) to it and their consequent Fc-mediated ADCC. While bnAbs tend to recognize the 'closed' trimeric State 1 conformation of Env, nnAbs and HIV+ sera bind States 2 and 3 of Env brought to its open conformation by interaction with the host CD4 molecule. Nef/Vpu-induced down regulation of membrane-bound CD4 (and also HLA, Env, BST-2, and NKG2DL) in HIV-infected cells therefore keeps Env in State 1 and these cells, reminiscent of the HIV latent reservoir, are susceptible to bnAb neutralization as well as ADCC. The use of CD4 mimetics (CD4mc), however, can mimic the interaction of CD4 with Env and bring it to its open, nnAb-binding state, after successive exposure of conserved epitopes in the coreceptor binding site (CoRBS) and anti cluster A to nnAbs. Therefore different ADCC-measuring assays are discussed with particular reference to the target cell being either HIV-infected and conducive to bnAb measurements or Env gp120 coated and a measure of nnAb ADCC. The inaccuracies introduced by bystander un-infected cells exposed to shed gp120 are also discussed. Antibodies A32, C11, N5i5 and 2.2c bind to the CD4-induced cluster A epitope on Env. While bnAbs VRC01, 3BNC117, PGT151, 8ANC195, PG9, PG16, PGT121, PGT126 have different binding regions all on closed State 1 of Env and elicit ADCC, the MPER set of 10E8, 4E10 and 2F5 recognize State 1 but do not result in potent ADCC. Studies have shown that some CD4BS bnAbs like b12 protect macaques from SHIV challenge, and 3BNC117 control HIV replication in humanized mice.
Richard2018
(CD4+ CTL, class I down-regulation by Nef, co-receptor, effector function, review)
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PG9: This article reviews how B cell receptor sequence analyses and repertoires can be used in vaccine stratagem. Overall, multiple immunogens and their interactions driving bnAb development to generate Abs with special genetic characteristics of V gene restriction, long CDRH3 (bnAbs like PG9 have twice the length of the average naive or memory B cell receptor CDRH3, at 30 aa) and high load SHM are the current effective strategy being used.
Kreer2020
(antibody generation, neutralization, therapeutic vaccine, review, antibody sequence)
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PG9: The study describes the generation, crystal structure, and immunogenic properties of a native-like Env SOSIP trimer based on a group M consensus (ConM) sequence. A crystal structure of ConM SOSIP.v7 trimer together with nAbs PGT124 and 35O22 revealed that ConM SOSIP.v7 is structurally similar to other Env trimers. In rabbits, the ConM SOSIP trimer induced serum nAbs that neutralized the autologous Tier 1A virus (ConM from 2004) and a related Tier 1B ConS virus (ConM from 2001). These responses target the trimer apex and were enhanced when the trimers were presented on ferritin nanoparticles. The neutralization of ConM and ConS pseudoviruses was tested against a large panel of nAbs and non-nAbs (2219, 2557, 3074, 3869, 447-52D, 830A, 654-30D, 1008-30D, 1570D, 729-30D, F105, 181D, 246D, 50-69D, sCD4, VRC01, 3BNC117, CH31, PG9, PG16, CH01, PGDM1400, PGT128, PGT121, 10-1074, PGT151, VRC43.01, 2G12, DH511.2_K3, 10E8, 2F5, 4E10); most nAbs were able to neutralize these pseudoviruses. Soluble ConM trimers were able to weakly activate B cells expressing PGT121 and PG16 BCRs but were inactive against those expressing VRC01 and PGT145. In contrast, at the same molar amount of trimers, the ConM SOSIP.v7-ferritin nanoparticles activated all 4 B cells efficiently. Binding of bnAbs 2G12 and PGT145 and non-nAbs F105 and 19b to ConM SOSIP.v7 trimer and SOSIP showed that the ferritin-bound trimer bound more avidly than the soluble trimer. This study shows that native-like HIV-1 Env trimers can be generated from consensus sequences, and such immunogens might be suitable vaccine components to prime and/or boost desirable nAb responses.
Sliepen2019
(neutralization, vaccine antigen design)
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PG9: Membrane-bound BG505-based ApexGT Env trimer vaccine candidates, which bind to inferred germline variants of bnAbs PCT64 and PG9, were developed through directed evolution and characterized. The antigenicity of the most promising immunogen, ApexGT5, was also assessed in variants designed for mRNA delivery. PCT64 and PG9/PG16 lineages were identified to have the highest and most consistent frequencies of precursors in 14 HIV-unexposed donors among 5 V2-apex-targeting bnAb classes which also included PGT141-145/PGDM1400-1414, CH01-CH04 and CAP256-VRC26 lineages. PG9/PG16 heavy chain (HC) precursors were found in 9/14 donors with a median frequency of 0.23 precursors per million BCRs. Of the assessed soluble trimers, PG9 had the greatest binding affinity for ApexGT3 (KD 0.2 nM). PG9 also had a KD value of 8.59 nM for binding to ApexGT5. Membrane-bound DNA-expressed BG505 SOSIP.MD39 (MD39, background for Apex constructs), ApexGT5, ApexGT5.Congly and ApexGT5.Gmax, as well as membrane-bound mRNA-encoded MD39, ApexGT5 and ApexGT5Congly, all had generally similar antigenic profiles and bound PG9 at moderate levels. A 4.75 Å resolution cryo-EM structure of PG9 Fab and ApexGT3.2MUT (PDB 7T77) confirmed 1:1 stoichiometry, angle of approach and extensive apex glycan interaction. The N130 and H185H glycans, present on ApexGT3.2MUT, do not make direct contacts with the PG9 Fab. The observed binding angle could cause structural clashes with an elongated loop2B, such as is found in wild-type BG505, but was similar between germline PG9 iGL and mature PG9. A trimeric interface was required for binding to PG9 iGL, but not mature PG9. Negative stain EM data suggested that an open conformation of an Env trimer would be required to accommodate 3 PG9 Fabs.
Willis2022
(antibody binding site, glycosylation, vaccine antigen design, binding affinity, antibody sequence, structure, antibody lineage, contact residues)
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PG9: A panel of 30 contemporary subtype B pseudoviruses (PSVs) was generated. Neutralization sensitivities of these PSVs were compared with subtype B strains from earlier in the pandemic using 31 nAbs (PG9, PG16, PGT145, PGDM1400, CH02, CH03, CH04, 830A, PGT121, PGT126, PGT128, PGT130, 10-1074, 2192, 2219, 3074, 3869, 447-52D, b12, NIH45-46, VRC01, VRC03, 3BNC117, HJ16, sCD4, 10E8, 4E10, 2F5, 7H6, 2G12, 35O22). A significant reduction in Env neutralization sensitivity was observed for 27 out of 31 nAbs for the contemporary, as compared to earlier-decade subtype B PSVs. A decline in neutralization sensitivity was observed across all Env domains; the nAbs that were most potent early in the pandemic suffered the greatest decline in potency over time. A metaanalysis demonstrated this trend across multiple subtypes. As HIV-1 Env diversification continues, changes in Env antigenicity and neutralization sensitivity should continue to be evaluated to inform the development of improved vaccine and antibody products to prevent and treat HIV-1.
Wieczorek2023
(neutralization, viral fitness and/or reversion)
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PG9: Pseudoviruses were made from 13 env sequences of subtypes A6 and CRF63_02A6, based on genetic variants of HIV-1 circulating in the Siberian Federal District. Neutralization of these viruses was tested for 8 bnAbs. Most of the pseudoviruses were sensitive to neutralization by VRC01, PGT126, and 10E8, moderately sensitive to PG9 and 4E10, and resistant to 2G12, PG16, and 2F5. All obtained variants of pseudoviruses were CCR5-tropic.
Rudometova2022
(co-receptor, neutralization, subtype comparisons)
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PG9: This study analyzed Env sequences of early HIV-1 clonal variants from 31 individuals from the Amsterdam Cohort Studies with diverse levels of heterologous neutralization at 2-4 years post-seroconversion. A number of Env signatures coincided with neutralization development. These included a statistically shorter variable region 1 and a lower probability of glycosylation. Induction of neutralization was associated with a lower probability of glycosylation at position 332, which is involved in the epitopes of many bnAbs. 2G12 and PGT126 were tested for their ability to block infectivity by patient viruses with predicted glycosylation at N332; the NLS glycosylation motif was associated with resistance to these mAbs more often than the NIS glycosylation motif. Sequence Harmony software identified amino acid changes associated with the development of heterologous neutralization. These residues mapped to various Env subdomains, but in particular to the first and fourth variable region, as well as the underlying α2 helix of the third constant region. These findings imply that the development of heterologous neutralization might depend on specific characteristics of early Env. Env signatures that correlate with the induction of neutralization might be relevant for the design of effective HIV-1 vaccines. Primary virus isolates from 21 of the patients were assayed for neutralization by 11 well-known nAbs (b12, VRC01, 447-52D, 2G12, PGT121, PGT126, PG9, PG16, PGT145, 2F5, 4E10).
vandenKerkhof2013
(glycosylation, neutralization, vaccine antigen design, polyclonal antibodies)
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PG9: The polyclonal response of human subjects VC20013 and VC10014 demonstrated increasing neutralization breadth against a panel of HIV-1 isolates over time. Full-length functional env genes were cloned longitudinally from these subjects from months after infection through 2.6 to 5.8 years of infection. Motifs associated with the development of breadth in published, cross-sectional studies were found in the viral sequences of both subjects. To test the immunogenicity of envelope vaccines derived from time points obtained during and after broadening of neutralization activity within these subjects, rabbits were coimmunized 4 times with selected multiple gp160 DNAs and gp140-trimeric envelope proteins. In an assay of rabbit polyclonal responses, the most rapid and persistent neutralization of multiclade tier 1 viruses was elicited by envelopes that were circulating in plasma at time points prior to the development of 50% neutralization breadth in both human subjects. The breadth elicited in rabbits was not improved by exposure to later envelope variants. Env immunogen sequences were tested for binding to a panel of well studied mAbs of various binding types (VRC01, HJ16, b12, b6, PG9, PGT121, 2G12, 2F5, F240); all gp140s bound to weak or non-neutralizing antibodies b6 and F240. MAb b6 also bound BG505 SOSIP, while F240 did not, suggesting that cluster I gp41 epitopes, which become exposed during gp120 shedding, are more easily accessed on these trimers than on BG505-SOSIP. These data have implications for vaccine development in describing a target time point to identify optimal env immunogens.
Malherbe2014
(vaccine antigen design, vaccine-induced immune responses, binding affinity, polyclonal antibodies)
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PG9: This study explored the basis of the neutralization resistance of tier 3 virus 253-11 (subtype CRF02_AG). Virus 253-11 was resistant to neutralization by 17b, b12, VRC03, F105, SCD4, CH12, Z13e1, PG16, PGT145, 2G12, PGT121, PGT126, PGT128, PGT130, 39F, F240, and 35O22; the virus was sensitive to 3BNC117, NIH45-46G54W, VRC01, 10E8, 2F5, 4E10, PG9, VRC26.26, 10-1074, and PGT151. Virus 253-11 was strikingly resistant to most tested antibodies that target V3/glycans, despite possessing key potential N-linked glycosylation sites, especially N301 and N332, needed for the recognition of this class of antibodies. The resistance of 253-11 was not associated with an unusually long V1/V2 loop, nor with polymorphisms in the V3 loop and N-linked glycosylation sites. The 253-11 MPER was rarely recognized by sera, but was more often recognized in a chimera consisting of a HIV-2 backbone with the 253-11 MPER, suggesting steric or kinetic hindrance of the MPER. Mutations in the 253-11 MPER previously reported to increase the lifetime of the prefusion Env conformation (Y681H, L669S), decreased the resistance of 253-11 to several mAbs, presumably destabilizing its otherwise stable, closed trimer structure. A crystal structure of a recombinant 253-11 SOSIP trimer revealed that the heptad repeat helices in gp41 are drawn in close proximity to the trimer axis and that gp120 protomers also showed a relatively compact form around the trimer axis.
Moyo2018
(neutralization, structure)
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PG9: This study assessed the ability of single bNAbs and triple bNAb combinations to mediate polyfunctional antiviral activity against a panel of cross-clade simian-human immunodeficiency viruses (SHIVs), which are commonly used as tools for validation of therapeutic strategies in nonhuman primate models. Most bnAbs assayed were capable of mediating both neutralizing and nonneutralizing effector functions (ADCC and ADCP) against cross-clade SHIVs, although the susceptibility to V3 glycan-specific bNAbs was highly strain dependent. Several triple bNAb combinations were identified comprising of CD4 binding site-, V2-glycan-, and gp120-gp41 interface-targeting bNAbs that are capable of mediating synergistic polyfunctional antiviral activities against multiple clade A, B, C, and D SHIVs. In assays using the transmitted/founder SHIV.C.CH505, there was a correlation between the neutralization potencies and nonneutralizing effector functions of bnAbs: PG9 was positive for neutralization and binding to infected cells, but negative for ADCC.
Berendam2021
(effector function, neutralization, binding affinity, broad neutralizer)
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PG9: This study used directed evolution to overcome the instability and heterogeneity of a primary Env isolate (ADA) in order to design better immunogens. HIV-1 virions were subjected to iterative cycles of destabilization and replication to select for Envs with enhanced stability. Several mutations in Env were associated with increased trimer stability, primarily in the heptad repeat regions of gp41 and V1 of gp120. Mutations from the most stable Envs were combined into a variant Env, termed "comb-mut", with superior homogeneity and stability. Comb-mut had greater binding affinity for PGT128, PG9, PG16, 2G12, VRC01, b12, and CD4-IgG2, but decreased binding to 4E10, 2F5, b6, 19b, 17b, 7B2, and D50. Comb-mut was more sensitive to neutralization by PG9. One specific mutation (K574) was shown to decrease the neutralization IC50 of mAbs b12, 2F5, 4E10, b6, 2G12, 8K8 and inhibitors sCD4, T-20, and PF-68742. Several of the Env substitutions were shown to stabilize Env spikes from HIV-1 clades A, B, and C. Spike stabilizing mutations may be useful in the development of Env immunogens that stably retain native, trimeric structure.
Leaman2013
(mimics, vaccine antigen design, binding affinity)
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PG9: Reduction in exposure of non-neutralizing Ab (nnAb) epitopes on native-like Env trimer immunogens results in bnAbs being elicited that have autologous tier 2 neutralization instead of tier 1. The design of trimer modifications to silence nnAb reactivity were directed towards (1) the V3 loop (2) epitopes exposed through CD4-induced conformational changes (CD4i epitopes) and (3) the exposed SOSIP trimer base that is usually buried within virus membrane. (1) In Steichen2016 2 Env variants of BG505 SOSIP.664 with reduced V3 nnAb-generating activity were created, one using mammalian display screens, BG505 MD39, and the other with an engineered disulfide bond, BG505 SOSIP.DS21. MD39's trimer design was improved by using the Rosetta Design platform and inserting 6 buried mutations to form BG505 Olio6, and both this trimer as well as the DS21 were shown to have reduced antigenicity for nnAb generation in a rabbit vaccine model. (2) To reduce CD4i epitope elicitation of nnAbs, saturation mutagenesis of Olio6 was performed, in search of the trimer that binds VRC01-class bnAbs but not CD4. BG505 Olio6.CD4KO containing the G473T mutation was identified. In addition, for the purposes of nucleic acid-based vaccine platform designs, the natural furin cleavage site between gp120 and gp41 was removed to abolish protease cleavage, by swapping the order of gp14 and gp120 in the gp160 gene, giving the trimer BG505 MD39.CP (circular permutation). (3) The exposed trimer base was masked with glycan in 3 under-glycosylated regions in order to direct bnAb responses to the distal regions (CD4bs, V2 apex, N332 superset) of the trimer instead, generating the GRSF (glycan resurfaced) MD39 and GRSF MD39.CP variants. Furthermore, variants with improved thermostability over MD39 were created, MD37 and MD64. All of these stabilizing mutations were transferred to diverse HIV isolates from different subtypes. Finally 3 subtype C (isolate 327c) trimers were assessed for binding to bnAbs, VRC01, PGT121, PGT151, PGT145, PG9 and to nnAbs, F105 and 17b - PG9 does bind all three.
Kulp2017
(antibody binding site, antibody generation, antibody interactions, assay or method development, autologous responses, vaccine antigen design, structure)
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PG9: Using subtype A BG505 Env structural information, improved variants of subtype B JRFL and subtype C 16055 Env native flexibly linked (NFL) trimers were generated. The trimer-derived (TD) residues that increased well-ordered, homogeneous, stable, and soluble trimers did not require positive or negative selection as previously needed [Guenaga2015, PLoS Pathos. 11(1):e1004570]. In JRFL trimer-derived Env immunogens, binding to PG9 was restored by the E168K mutation.
Guenaga2015a
(antibody interactions, assay or method development, vaccine antigen design, structure)
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PG9: Most published structures of bnAbs, yet none of non- or poorly-neutralizing mAbs, were structurally compatible with a newly generated crystal structure of a mature ligand-free endoglycosidase H-treated BG505 SOSIP.664 Env trimer. Robust binding of the structurally incompatible V3- and CD4-bs targeting nAbs could be induced with CD4. A “DS” variant of BG505 SOSIP.664, containing a stabilizing disulfide bond between 201C and 433C mutations, was developed and appeared to represent an obligate intermediate in that it bound only a single CD4 and remained in a prefusion closed conformation. BnAb PG9 was structurally compatible with BG505 SOSIP.664 and had a breadth of 78% (IC50 < 50 μg/ml) in a panel of 170 diverse HIV-1 pseudoviruses.
Kwon2015
(neutralization, vaccine antigen design, structure)
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PG9: Primary HIV-1 Envs were expressed as SHIVs, and responses from infected rhesus macaques showed patterns of Env-antibody coevolution similar to those in humans. This included conserved immunogenetic, structural, and chemical solutions to epitope recognition and precise Env-amino acid substitutions, insertions, and deletions leading to virus persistence. One macaque mAb (RHA1.V2.01), neutralized 49% of a 208-strain panel, and structural analysis revealed a V2-apex mode of recognition that resembles human bnAbs PGT145 or PCT64-35S. Signature sites were analyzed for RHA1.V2.01 and 7 V2 bnAbs (PCT64-34M, PGDM1400, PG9, CH01, PGT145, VRC26.08, VRC26.25).
Roark2021
(mutation acquisition, neutralization, vaccine antigen design, escape)
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PG9: This paper comprehensively defined the effect of every viable single aa mutation in the ectodomain and transmembrane domain of BG505.T332N Env on binding by 9 individual bnAbs targeting 5 epitope classes (VRC01, 3BNC117, PGT121, 10-1074, PG9, PGT145, PGT151, VRC34.01, and 10E8), as well as by a mixture of 3BNC117 and 10-1074. Escape mutations mostly occurred in a small subset of structurally-defined contacts within <4 Å and at sites within 5-10 Å of the Ab. Escape from both V2-apex-targeting bnAbs, PG9 and PGT145, occurred through the elimination of the N160 glycan and/or positive charges from the epitope. Mutations in trimer apex contact sites also facilitated escape. Env sites with the largest cumulative mutational impact on PG9 binding were N160, K171, K169, and T162. See LANL Features and Contacts database for more details.
Dingens2019
(antibody binding site, escape, contact residues)
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PG9: This study aimed to define properties shared by transmitted viruses by comparing antigenic and functional properties of envelope glycoproteins of viral variants isolated during primary infection in 27 patients belonging to 8 transmission clusters. The neutralization of the 27 pseudotyped viruses was assayed with 8 human bnAbs targeting various regions of the virus. The infectious properties of the viruses was assessed by measuring their infectivity and sensitivity to entry inhibitors. Transmitted viruses from the same transmission chain shared many properties, including similar neutralization profiles, sensitivity to inhibitors, and infectivity. All transmitted viruses were CCR5-tropic, sensitive to maraviroc, and resistant to soluble forms of CD4, irrespective of cluster. They were also generally sensitive to bnAbs that target V3 (10-1074, PGT121), CD4bs (3BNC117, NIH45-46G54W), and MPER region (10E8), suggesting that the loss of these epitopes may affect a virus’s capacity to be transmitted. The viruses were somewhat less sensitive to bnAbs targeting the V1V2 region (PG9, PGT145) and gp120/gp41 interface (8ANC195). These data suggest that the transmission bottleneck is governed by selective forces.
Beretta2018
(neutralization, acute/early infection)
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PG9: This study examined whether HIV-1-specific bnAbs are capable of cross-neutralizing simian immunodeficiency viruses (SIVs) from chimpanzees (n=11) or western gorillas (n=1). BnAbs directed against the epitopes at the CD4 binding site (VRC01, VRC03, VRC-PG04, VRC-CH03, VRC-CH31, F105, b13, NIH45-46G54W, 45-46m2, 45-46m7), V3 (10-1074, PGT121, PGT128, PGT135, and 2G12), and gp41-gp120 interface (8ANC195, 35O22, PGT151, PGT152, PGT158) failed to neutralize SIVcpz and SIVgor strains. V2-directed bNabs (PG9, PG16, PGT145) as well as llama-derived heavy-chain only antibodies recognizing the CD4 binding site or gp41 epitopes (JM4, J3, 3E3, 2E7, 11F1F, Bi-2H10) were either completely inactive or neutralized only a fraction of SIVcpz strains. In contrast, neutralization of SIVcpz and SIVgor strains was achieved with low-nanomolar potency by one antibody targeting the MPER region of gp41 (10E8), as well as functional CD4 and CCR5 receptor mimetics (eCD4-Ig, eCD4-Igmim2, CD4-218.3-E51, CD4-218.3-E51-mim2), mono- and bispecific anti-human CD4 mAbs (iMab, PG9-iMab, PG16-iMab, LM52, LM52-PGT128), and CCR5 receptor mAbs (PRO140, PRO140-10E8). Importantly, the latter antibodies blocked virus entry not only in TZM-bl cells but also in Cf2Th cells expressing chimpanzee CD4 and CCR5, and neutralized SIVcpz in chimpanzee CD4+ T cells. These findings provide new insight into the protective capacity of anti-HIV-1 bnAbs and identify candidates for further development to combat SIV infection.
Barbian2015
(neutralization, SIV, binding affinity)
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PG9: A recombinant native-like Env SOSIP trimer, AMC009, was developed based on viral founder sequences of elite neutralizer H18877. The subtype B AMC009 Env was defined as a Tier 2 virus based on a neutralization assay against well known nAbs (VRC01, 3BNC117, CH31, CH01, PG9, PG16, PGDM1400, 10-1074, PGT128, PGT121, PGT151, VRC34.01, 2G12, 2F5, 4E10, DH511.2.K3_4, 10E8, and the mAb mixture CH01-31).The AMC009 SOSIP protein formed stable native-like trimers that displayed multiple bnAb epitopes. Its overall structure was similar to that of BG505 SOSIP.664, and it resembled one from another elite neutralizer, AMC011, in having a dense and complete glycan shield. When tested as immunogens in rabbits, AMC009 trimers did not induce autologous neutralizing antibody responses efficiently, while the AMC011 trimers did so very weakly, outcomes that may reflect the completeness of their glycan shields. The AMC011 trimer induced antibodies that occasionally cross-neutralized heterologous tier 2 viruses, sometimes at high titer. Cross-neutralizing antibodies were more frequently elicited by a trivalent combination of AMC008, AMC009, and AMC011 trimers, all derived from subtype B viruses. Each of these three individual trimers could deplete the nAb activity from rabbit sera. Mapping the polyclonal sera by electron microscopy revealed that antibodies of multiple specificities could bind to sites on both autologous and heterologous trimers.
Schorcht2020
(neutralization, vaccine-induced immune responses, structure)
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PG9: HIV-1 and its SIV precursors share a bnAb epitope in Env V2 at the trimer apex. This study tested the immunogenicity of a chimpanzee SIV (SIVcpz) Env trimer. In mice expressing a human V2-apex bnAb heavy-chain precursor, trimer immunization induced V2-directed nAbs. Infection of macaques with chimeric simian-chimpanzee immunodeficiency viruses (SCIVs) elicited high-titer viremia, potent autologous neutralizing antibodies, rapid sequence escape in the canonical V2-apex epitope, and in some cases, low-titer heterologous plasma breadth mapping to the V2-apex. Antibody cloning from 2 macaques (T925 and T927) identified 7 lineages (53 mAbs) with long CDRH3 regions that cross-neutralize some primary HIV-1 strains with low potency. Electron microscopy of members of the two most cross-reactive lineages confirmed V2 targeting with an angle of approach distinct from prototypical V2-apex bNAbs; antibody binding either required or induced an occluded-open trimer. Probing with conformation-sensitive, nonneutralizing antibodies revealed that SCIV-expressed, but not wild-type SIVcpz Envs, as well as a subset of primary HIV-1 Envs, preferentially adopted a more open trimeric state. These results reveal the existence of a cryptic V2 epitope that is exposed in occluded-open SIVcpz and HIV-1 Env trimers and elicits cross-neutralizing responses of limited breadth and potency. This cryptic epitope, which in some Env backgrounds is immunodominant, needs to be considered in immunogen design. As part of the study, binding and neutralization assays used panels of nAbs (PG9, PG16, PGT145, PGDM1400, VRC26.25, CH01, BG1, VRC38.01), non-nAbs (697-D, 1393A, CH58, CAP228-3D, 3074, 447-52D, 17b, A32), and unmutated ancestors (PG9-RUA, PG16-RUA, VRC26-UCA, CH01-RUA).
Bibollet-Ruche2023
(neutralization, vaccine antigen design, vaccine-induced immune responses)
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PG9: A macaque sequential immunization protocol with increasingly native-like V3-glycan-targeting Env trimers multimerized onto virus-like particles elicited multiple on-target mAbs with heterologous, yet generally weak, neutralization activity and minimal protection in a subsequent intrarectal heterologous challenge with SHIVDH12-V3AD8. The priming immunogen was RC1-4fill (clade A/E, RC1 with 4 additional glycans), a low affinity Env trimer with additional glycans to facilitate V3-glycan targeting and mask BG505 glycan hole, while the boosting immunogens were 11MUTB-4fill (clade A/E), B41-5MUT or B41 wildtype (clade B), AMC011/Du422 (clade B/C), and consensus group M/consensus clade C Env trimers. In a RC1 binding assay, PG9 Fab competed moderately with isolated macaque mAbs (Ab1456 and Ab1461) and itself and modestly with isolated macaque mAb Ab1573.
Escolano2021
(antibody interactions, vaccine antigen design)
-
PG9: HIV-1 bnAbs require high levels of activation-induced cytidine deaminase (AID)-catalyzed somatic mutations. Probable mutations occur at sites of frequent AID activity, while improbable mutations occur where AID activity is infrequent. The paper introduced the ARMADiLLO program, which estimates how probable a particular mAb mutation is, and thus the key improbable mutations were defined for a panel of 26 bnAbs. The number of improbable mutations ranged from 7 (PGT128) to 23 (VRC01 and 35O22); PG9 had 14 improbable mutations out of 28 total AA mutations, and 0 indels. Single-amino acid reversion mutants were made for key improbable mutations of 3 bnAbs (CH235, VRC01, and BF520.1), and these mutant mAbs were tested for their neutralization ability. The study also noted that bnAbs that had relatively small numbers of improbable single somatic mutations had other unusual characteristics that were due to additional improbable events, such as indels (PGT128) or extraordinary CDR H3 lengths (VRC26.25).
Wiehe2018
(neutralization)
-
PG9: The study assessed the breadths and potencies of 14 bnAbs against 36 viruses reactivated from peripheral blood CD4+ T cells from ARV-treated HIV-infected individuals by using paired neutralization and infected cell binding assays. Infected cell binding correlated with virus neutralization for 10 of 14 antibodies (VRC01, VRC07-523, 3BNC117, N6, PGT121, 10-1074, PGDM1400, PG9, 10E8, and 10E8v4-V5R-100cF). For example, the correlation for 3BNC117 had r=0.82 and P<0.0001. Heterogeneity was observed, however, with a lack of significant correlation for 2G12, CAP256.VRC26.25, 2F5, and 4E10. The study also performed paired infected cell binding and ADCC assays by using two reservoir virus isolates in combination with 9 bNAbs, and the results were consistent with previous studies indicating that infected cell binding is moderately predictive of ADCC activity for bNAbs with matched Fc domains. These data provide guidance on the selection of antibodies for clinical trials.
Ren2018
(effector function, neutralization, binding affinity, HIV reservoir/latency/provirus)
-
PG9: 3 clonally-related autologously-neutralizing mAbs (43A, 43A1, and 43A2), isolated from rabbit 5743 which was co-immunized with BG505- and B41-based SOSIP soluble trimers [Klasse2016, PMID: 27627672], bind to an immunodominant epitope in V1 overlapping the bnAb N332 glycan supersite without interacting with glycans. Of the 43A family members, only 43A, at 2-50 μg/ml concentration, had limited competition with mAb PGT135 with 67-78% residual binding in a BG505 SOSIP.664 binding assay.
Nogal2020
(antibody interactions)
-
PG9: A panel of 33 CRF02_AG pseudoviruses was generated from HIV-1-infected individuals during early stages of infection. Samples represented a 15-year period 1997-2012. These viruses were best neutralized by the CD4bs-directed bnAbs (VRC01, 3BNC117, NIH45-46G54W, and N6) and the MPER-directed bnAb 10E8 in terms of both potency and breadth. There was a higher resistance to bnAbs targeting the V1V2-glycan region (PG9 and PGT145) and the V3-glycan region (PGT121 and 10-1074). Neutralization by 8ANC195 was also assayed. Combinations of antibodies were predicted by the CombiNaber tool to achieve full coverage across this subtype. There was increased resistance to bnAbs targeting the CD4bs linked to the diversification of CRF02_AG Env over the course of the timespan sampled.
Stefic2019
(neutralization, acute/early infection, subtype comparisons)
-
PG9: The authors review Fc effector functions, which cooperatively with Fab neutralization functions, could be used passively as immunotherapeutic or immunoprophylactic agents of HIV reservoir control or even infection prevention. One effector function, antibody-dependent complement-mediated lysis (ADCML), is seen with IgG1 and IgG3 anti-V1/V2 glycan bnAbs, PG9, PG16, PGT145; but not with 2F5, 4E10, 2G12, VRC01 and 3BNC117 unless they are delivered with anti-regulators of complement activation (RCA) antibodies. Another effector function, antibody-dependent cellular cytotoxicity (ADCC) can slow disease progression by NK-mediated degranulation of infected cells that are coated by bnAbs whose Fc region is recognized by the low affinity NK receptor, FcγRIIIA (or CD16). Strong ADCC was induced by NIH45-46, 3BNC117, 10-1074, PGT121 and 10E8, with intermediate activity for PG16 and VRC01, but no ADCC activation for 12A12, 8ANC195 and 4E10. A final effector function, antibody-dependent phagocytosis (ADP) also eliminates infected cells but through phagocytosis mediated by Fc portions of coating anti-HIV antibodies interacting with other FcγR (or FcαR) on the surface of granulocytes, monocytes or macrophages. This protective mode is less well studied but bnAbs like VRC01 have been engineered to increase phagocytosis by neutrophils. Protein engineering of bispecifics against the surface of infected or reservoir virus cells has potential in the future.
Danesh2020
(antibody interactions, assay or method development, complement, effector function, immunoprophylaxis, neutralization, immunotherapy, early treatment, review, broad neutralizer, HIV reservoir/latency/provirus)
-
PG9: To understand early bnAb responses, 51 HIV-1 clade C infected infants were assayed for neutralization of a 12-virus multi-clade panel. Plasma bnAbs targeting V2-apex on Env were predominant in infant elite and broad neutralizers. In infant elite neutralizers, multi-variant infection was associated with plasma bnAbs targeting diverse autologous viruses. A panel of mAbs (PG9, PG16, PGT145, PGDM1400, VRC26.25, 10-1074, BG18, AIIMS-P01, PGT121, PGT128, PGT135, VRC01, N6, 3BNC117, PGT151, 35O22, 10E8, 4E10, F105, 17b, A32, 48d, b6, 447-52d) was assayed for their ability to neutralize Env clones from infant elite neutralizers; circulating viral variants in infant elite neutralizers were most susceptible to V2-apex bnAbs.
Mishra2020a
(neutralization, polyclonal antibodies)
-
PG9: In vertically-infected infant AIIMS731, a rare HIV-1 mutation in hypervariable loop 2 (L184F) was studied. In patient sequences, this mutation was present in the majority of clones. A panel of 6 V2 bnAbs (PG9, PG16, PGT145, PGDM1400, CAP256.25, and CH01) was assayed for neutralization of 6 patient viral clones. The AIIMS731 viral variants segregated into 4 neutralization-sensitive and 2 resistant clones; sensitive clones carried 184F, while resistant clones carried the rare 184L mutation. A large panel of bnAbs targeting non-V2 epitopes was used to assess the neutralization of the 6 patient viral variants. The bnAb panel consisted of V3/N332 glycan supersite bnAbs (10-1074, BG18, AIIMS-P01, PGT121, PGT128, and PGT135), CD4bs bnAbs (VRC01, VRC03, VRC07-523LS, N6, 3BNC117, and NIH45-46 G54W), a silent face-targeting bnAb (PG05), fusion peptide and gp120-gp41 interface bnAbs (PGT151, 35O22, and N123-VRC34.01), and MPER bnAbs (10E8, 4E10, and 2F5). All of these bnAbs had similar neutralization efficiencies for all 6 clones, suggesting that the L184F mutation was specific for viral escape from neutralization by V2 apex bnAbs. A panel of non-neutralizing mAbs (V3 loop-targeting non-nAbs 447-52D and 19b, and CD4-induced non-nAbs 17b, A32, 48d, and b6), were also assessed; 2 of the variants (the same 2 susceptible to the V2 bnAbs) showed moderate neutralization by 447-52D, 19b, 17b, and 48d. The structure of ligand-free BG505 SOSIP trimer revealed that the side chain of L184 was outward facing and did not make significant intraprotomeric interactions, but upon mutating L184 to F184, a disruption of the accessible surface between the bulky side chain of F184 on one protomer and R165 on the neighboring protomer was seen. Thus, the L184F mutation resulted in increased susceptibility to neutralization by antibodies known to target the relatively more open conformation of Env on tier 1 viruses, suggesting that the rare L184F mutation allowed Env to sample more open states resembling the CD4-bound conformation where the CCR5 binding site is exposed.
Mishra2020
(neutralization, polyclonal antibodies)
-
PG9: This paper isolated and characterized V3-glycan bNAb Ab1485 produced by an elite neutralizing SHIVAD8-EO-infected macaque identified as CE8J. For comparison with Ab1485, the binding of apex mAb PG9 to BG505 was substantially inhibited by itself but not by mAbs 10-1074, 3BNC117, 8ANC195 and VRC34, which all targeted other regions of Env.
Wang2020
(antibody interactions)
-
PG9: A plant-based expression system was used to produce different glycoforms of the bnAbs PG9, PG16, 10–1074, NIH45–46G54W, 10E8, PGT121, PGT128, PGT145, PGT135, and b12. Also produced were mutated forms (N92T) of VRC01 (mVRC01) and NIH45–46G54W (mNIH45–46G54W). The in vivo properties of these mAbs were assessed in macaques to distinguish those most likely to comprise or become a component of an affordable and efficacious immunotherapeutic cocktails. N-glycans within the VL domain impaired the plasma stability of plant-derived bnAbs. While PGT121 and b12 exhibited no immunogenicity in rhesus macaques, VRC01, 10-1074 and NIH45-46G54W elicited high titer anti-idiotypic antibodies. The results indicated that that specific mutations in certain bnAbs caused immunogenicity in macaques. Such immunogenicity in humans would potentially compromise their value for immunotherapy. CHO1-31 was used as a positive control in a neutralization assay.
Rosenberg2015
(anti-idiotype, neutralization, immunotherapy)
-
PG9: HIV-1 env genes were sequenced from 16 mother/infant transmitting pairs. Infant transmitted-founder (T/F) and representative maternal non-transmitted Env variants were identified and used to generate pseudoviruses for paired maternal plasma neutralization analysis. Eighteen out of 21 (85%) infant T/F Env pseudoviruses were neutralization resistant to paired maternal plasma, while all infant T/F viruses were neutralization sensitive to a panel of HIV-1 broadly neutralizing antibodies (2G12, CH01, PG9, PG16, PGT121, PGT126, DH429, b12, VRC01, NIH45-46, CH31, 4E10, 2F5, 10E8, DH512) and variably sensitive to heterologous plasma neutralizing antibodies. Antibody mixture CH01/31 was used as a positive control for neutralization. The infant T/F pseudoviruses were overall more neutralization resistant to paired maternal plasma in comparison to pseudoviruses from maternal non-transmitted variants. These findings suggest that autologous neutralization of circulating viruses by maternal plasma antibodies select for neutralization-resistant viruses that initiate peripartum transmission, raising the speculation that enhancement of this response at the end of pregnancy could reduce infant HIV-1 infection risk.
Kumar2018
(neutralization, acute/early infection, mother-to-infant transmission, transmission pair)
-
PG9: Since cross-reactive antibodies can interfere in immunoassays, HIV-1 mAbs were tested for binding to the SARS-COV-2 spike (S) protein (SARS-COV-2 S cross-reactivity). The following 9 gp120-epitope binding HIV-1 mAbs are cross-reactive with COV-2 S: 2G12, PGT121, PGT126, PGT128, PGT145, PG9, PG16, 10-1074, and 35O22. CD4bs Abs VRC01 and VRC03 are not cross-reactive. Cross-reactivity of the 9 HIV-1 Abs was through glycoepitopes. Glycan-dependent, V3-loop-binding PGT126 and PGT128 as well as 2G12 were the strongest binders of COV-2 S and were found to be immunoreactive but incapable of neutralization or antibody-dependent enhancement (ADE).
Mannar2021
(antibody interactions, effector function, glycosylation, computational prediction, antibody polyreactivity)
-
PG9: Broadly neutralizing HIV-1 immunity associated with VRC01-like antibodies was studied by isolation of VRC01-like neutralizers with CD4bs probe; structural definition of gp120 recognition by RSC3-identified antibodies from different donors; functional complementation of heavy and light chains among VRC01-like antibodies; identification of VRC01 antibodies by 454 pyrosequencing; and cross-donor phylogenetic analysis of sequences derived from the same precursor germline gene. b12, among with other RSC3-reactive antibodies, was used for several comparisons and showed dramatic differences in heavy-chain orientation relative to the VRC01. b12 had 48-66% sequence identity of its heavy and light chains to respective chains of VRC-PG04 and VRC-CH31. PG9 and PG16 Abs were compared to for % somatic hyper mutation.
Wu2011
(structure)
-
PG9: Analyses of all PDB HIV1-Env trimer (prefusion, closed) structures fulfilling certain parameters of resolution were performed to classify them on the basis of (a) antibody class which was informed by parental B cells as well as structural recognition, and (b) Env residues defining recognized HIV epitopes. Structural features of the 206 HIV epitope and bNAb paratopes were correlated with functional properties of the breadth and potency of neutralization against a 208-strain panel. Broadly nAbs with >25% breadth of neutralization belonged to 20 classes of antibodies with a large number of protruding loops and high degree of somatic hypermutation (SHM). Analysis of recognized HIV epitopes placed the bNAbs into 6 categories (viz. V1V2, glycan-V3, CD4-binding site, silent face center, fusion peptide and subunit interface). The epitopes contained high numbers of independent sequence segments and glycosylated surface area. PG9-Env formed a distinct group within the V1V2 category, Class PG9, and it has extensive D-gene contribution. Crystal structure data on B-cell culture identified PG9 Fab complexed to V1V2 region of strain ZM109 was found in PDB ID: 3U2S.
Chuang2019
(antibody binding site, antibody interactions, neutralization, binding affinity, antibody sequence, structure, antibody lineage, broad neutralizer)
-
PG9: In an effort to identify new Env immunogens able to elicit bNAbs, this study looked at Envs derived from rare individuals who possess bNAbs and are elite viral suppressors, hypothesizing that in at least some people the antibodies may mediate durable virus control. The Env proteins recovered from these individuals may more closely resemble the Envs that gave rise to bNAbs compared to the highly diverse viruses isolated from normal progressors. This study identified a treatment-naive elite suppressor, EN3 (patient record #4929), whose serum had broad neutralization. The Env sequences of EN3 had much fewer polymorphisms, compared to those of a normal progressor, EN1 (patient record #4928), who also had broad serum neutralization. This result confirmed other reports of slower virus evolution in elite suppressors. EN3 Envelope proteins were unusual in that most possessed two extra cysteines within an elongated V1 region. The impact of the extra cysteines on the binding to bNAbs, virus infectivity, and sensitivity to neutralization suggested that structural motifs in V1 can affect infectivity, and that rare viruses may be prevented from developing escape. As part of this study, the neutralization of pseudotype viruses for EN3 Env clones was assayed for several bNAbs (PG9, PG16, PGT145, PGT121, PGT128, VRC01, 4E10, and 35O22).
Hutchinson2019
(elite controllers and/or long-term non-progressors, neutralization, vaccine antigen design, polyclonal antibodies)
-
PG9: The Chinese HIV Reference Laboratory produced 124 pseudoviruses from patients with subtype B, BC, and CRF01 infections. These viruses were assigned to tiers based on their neutralization by a panel of patient sera. Their neutralization sensitivities were also measured against a panel of well-characterized mAbs (2F5, b12, 2G12, 4E10, 10E8, VRC01, VRC-CH31, CH01, PG9, PG16, PGT121, PGT126).
Nie2020
(assay or method development, neutralization)
-
PG9: Extensive structural and biochemical analyses demonstrated that PGT145 achieves recognition and neutralization by targeting quaternary structure of the cationic trimer apex with long and unusually stabilized anionic β-hairpin HCDR3 loops. Compared to PGT145, PG9 showed increased breadth, neutralization potency, and maximum percentage neutralization (MPN) in the presence of complex/hybrid glycans. In BG505.Env.C2 alanine-scanning neutralization assays, PG9 had similar results as CH01, consistent with both CH01 and PG9 being representatives of hammerhead-class, and very dissimilar results to PGT145-like antibodies.
Lee2017
(antibody binding site, neutralization)
-
PG9: Three vaccine regimens administered in guinea pigs over 200 weeks were compared for ability to elicit NAb polyclonal sera. While tier 1 NAb responses did increase with vaccination, tier 2 NAb heterologous responses did not. The 3 regimens were C97 (monovalent, Clade C gp140), 4C (tetravalent, 4 Clade C mosaic gp140s), ABCM (tetravalent, Clades A, B, C and mosaic gp140s). Polyclonal sera generated from the 4C and ABCM regimens, compared to the C97 regimen, were able to more successfully outcompete PG9 binding to gp140 antigens.
Bricault2018
(antibody generation, vaccine-induced immune responses, polyclonal antibodies)
-
PG9: Novel Env pseudoviruses were derived from 22 patients in China infected with subtype CRF01_AE viruses. Neutralization IC50 was determined for 11 bNAbs: VRC01, NIH45-46G54W, 3BNC117, PG9, PG16, 2G12, PGT121, 10-1074, 2F5, 4E10, and 10E8. The CRF01_AE pseudoviruses exhibited different susceptibility to these bNAbs. Overall, 4E10, 10E8, and 3BNC117 neutralized all 22 env-pseudotyped viruses, followed by NIH45-46G54W and VRC01, which neutralized more than 90% of the viruses. 2F5, PG9, and PG16 showed only moderate breadth, while the other three bNAbs neutralized none of these pseudoviruses. Specifically, 10E8, NIH45-46G54Wand 3BNC117 showed the highest efficiency, combining neutralization potency and breadth. Mutations at position 160, 169, 171 were associated with resistance to PG9 and PG16, while loss of a potential glycan at position 332 conferred insensitivity to V3-glycan-targeting bNAbs. These results may help in choosing bNAbs that can be used preferentially for prophylactic or therapeutic approaches in China.
Wang2018a
(assay or method development, neutralization, subtype comparisons)
-
PG9: Two conserved tyrosine (Y) residues within the V2 loop of gp120, Y173 and Y177, were mutated individually or in combination, to either phenylalanine (F) or alanine (A) in several strains of diverse subtypes. In general, these mutations increased neutralization sensitivity, with a greater impact of Y177 over Y173 single mutations, of double over single mutations, and of A over F substitutions. The Y173A Y177A double mutation in HIV-1 BaL increased sensitivity to most of the weakly neutralizing MAbs tested (2158, 447-D, 268-D, B4e8, D19, 17b, 48d, 412d) and even rendered the virus sensitive to non-neutralizing antibodies against the CD4 binding site (F105, 654-30D, and b13). In the case of V2 mAb 697-30D, residue Y173 is part of its epitope, and thus abrogates its binding and has no effect on neutralization; the Y177A mutant alone did increase neutralization sensitivity to this mAb. When the double mutant was tested against bnAbs, there was a large decrease in neutralization sensitivity compared to WT for many bnAbs that target V1, V2, or V3 (PG9, PG16, VRC26.08, VRC38, PGT121, PGT122, PGT123, PGT126, PGT128, PGT130, PGT135, VRC24, CH103). The double mutation had lesser or no effect on neutralization by one V3 bnAb (2G12) and by most bnAbs targeting the CD4 binding site (VRC01, VRC07, VRC03, VRC-PG04, VRC-CH31, 12A12, 3BNC117, N6), the gp120-gp41 interface (35O22, PGT151), or the MPER (2F5, 4E10, 10E8).
Guzzo2018
(antibody binding site, neutralization)
-
PG9: To reduce local V2 flexibility and improve the binding of V2-dependent bNAbs and germline precursor bNAbs, the authors designed BG505 SOSIP.664 trimer variants whose V1 and V2 domains were stabilized by introducing disulfide bonds either within the V2 loop or between the V1 and V2 loops. The resulting SOSIP trimer variants — E153C/K178C, E153C/K178C/G152E and I184C/E190C — have improved reactivity with V2 bNAbs and their inferred germline precursors and are more sensitive to neutralization by V2 bNAbs. PGT121, PG9, PG16, and CH01 bound better to the E153C/R178C/G152E mutant than to SOSIP.664. The I184C/E190C mutant bound all the V2 bNAbs (PG9, PG16, PGT145, VRC26.09, and CH01) better than SOSIP.664. I184C/E190C was more sensitive to neutralization by V2 bNAbs compared with BG505 (by 5-fold for PG9, 3-fold for PG16, 6-fold for CH01, and 3-fold for PGDM1400).
deTaeye2019
(neutralization, vaccine antigen design, binding affinity)
-
PG9: The authors used genome-editing techniques (CRISPR-Cas9) to modify HIV specific B cell receptors. In particular, they replaced the heavy chain variable region in B cell lines with that from the HIV broadly neutralizing antibody PG9. The chimeric PG9 antibodies they created could neutralize one or more of the PG9-sensitive viruses, and most neutralized multiple viruses from different clades in a global panel, although none of the chimeric antibodies were as broadly neutralizing as the original PG9 HC/LC pair.
Voss2019
(neutralization, antibody sequence, broad neutralizer, chimeric antibody)
-
PG9: This study looks at the role of somatic mutations within antibody variable and framework regions (FWR) in bNAbs and how these mutations alter thermostability and neutralization as the Ab lineage reaches maturation. The emergence and selection of different mutations in the complementarity-determining and framework regions are necessary to maintain a balance between antibody function and stability. The study shows that all major classes of bNAbs (DH270, CH103, CH235, PG9 etc.) have lower thermostability than their corresponding inferred UCA antibodies. Fab interdomain flexibility mutations are selected early in Ab development.
Henderson2019
(neutralization, antibody lineage, broad neutralizer)
-
PG9: Two HIV-1-infected individuals, VC10014 and VC20013, were monitored from early infection until well after they had developed broadly neutralizing activity. The bNAb activity developed about 1 year after infection and mapped to a single epitope in both subjects. Isolates from each subject, taken at five different time points, were tested against monoclonal bNAbs: VRC01, B12, 2G12, PG9, PG16, 4E10, and 2F5. In subject VC10014, the bNAb activity developed around 1 year postinfection and targeted an epitope that overlaps the CD4-BS and is similar to (but distinct from) bNAb HJ16. In the case of VC20013, the bNAb activity targeted a novel epitope in the MPER that is critically dependent on residue 677 (mutation K677N).
Sather2014
(neutralization, broad neutralizer)
-
PG9: This study demonstrated that bNAb signatures can be utilized to engineer HIV-1 Env vaccine immunogens eliciting Ab responses with greater neutralization breadth. Data from four large virus panels were used to comprehensively map viral signatures associated with bNAb sensitivity, hypervariable region characteristics, and clade effects. The bNAb signatures defined for the V2 epitope region were then employed to inform immunogen design in a proof-of-concept exploration of signature-based epitope targeted (SET) vaccines. V2 bNAb signature-guided mutations were introduced into Env 459C to create a trivalent vaccine which resulted in increased breadth of nAb responses compared with Env 459C alone. PG9 was used as V2 Ab and Clade B was resistant to PG9. Based on structural contacts for PG9, phylogenetically corrected signatures and statistical support for other V2 Abs contacts were analyzed.
Bricault2019
(antibody binding site, neutralization, vaccine antigen design, computational prediction, subtype comparisons, broad neutralizer)
-
PG9: The influence of a V2 State 2/3-stabilizing Env mutation, L193A, on ADCC responses mediated by sera from HIV-1-infected individuals was evaluated. Conformations spontaneously sampled by the Env trimer at the surface of infected cells had a significant impact on ADCC. State 1-preferring ligand PG9 recognized L193A variants of CH58 and CH77 IMCs with less efficiently compared to the WT.
Prevost2018
(effector function)
-
PG9: A simple method to quantify and compare serum neutralization probabilities in described. The method uses logistic regression to model the probability that a serum neutralizes a virus with an ID50 titer above a cutoff. The neutralization potency (NP) identifies where the probabilities of neutralizing and not neutralizing a virus are equal and is not absolute as it depends on the ID50 cutoff. It provides a continuous measure for sera, which builds upon established tier categories now used to rate virus sensitivity. These potency comparisons are similar to comparing geometric mean neutralization titers, but instead are represented in tier-like terms. Increasing the number of bNAbs increases NP and slope, where the higher the slope, the sharper the boundary (lower scatter) between viruses neutralized and not neutralized. PG9 was used in analysis of monoclonal bNAb combinations.
Hraber2018
(assay or method development, neutralization)
-
PG9: This review summarizes current advances in antibody lineage-based design and epitope-based vaccine design. Antibody lineage-based design is described for VRC01, PGT121 and PG9 antibody classes, and epitope-based vaccine design is described for the CD4-binding site, as well as fusion peptide and glycan-V3 cites of vulnerability.
Kwong2018
(antibody binding site, vaccine antigen design, vaccine-induced immune responses, review, antibody lineage, broad neutralizer, junction or fusion peptide)
-
PG9: This review discusses the identification of super-Abs, where and how such Abs may be best applied and future directions for the field. PG9, a prototype super-Ab, was isolated from direct functional screening of B cell clones from an HIV elite neutralizer and was an order of magnitude more potent than first-generation bNAbs. Recently recombinant native-like HIV Env trimers have enabled the identification of exceptionally potent ‘PG9-class’ bNAbs e.g., PG16, PGT141-144, CH01-04, PGDM1400–1412 and CAP256-VRC26.01-12. Antigenic region V2 apex (Table:1)
Walker2018
(antibody binding site, review, broad neutralizer)
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PG9: The authors selected an optimal panel of diverse HIV-1 envelope glycoproteins to represent the antigenic diversity of HIV globally in order to be used as antigen candidates. The selection was based on genetic and geographic diversity, and experimentally and computationally evaluated humoral responses. The eligibility of the envelopes as vaccine candidates was evaluated against a panel of antibodies for breadth, affinity, binding and durability of vaccine-elicited responses. The antigen panel was capable of detecting the spectrum of V2-specific antibodies that target epitopes from the V2 strand C (V2p), the integrin binding motif in V2 (V2i), and the quaternary epitope at the apex of the trimer (V2q).
Yates2018
(vaccine antigen design, vaccine-induced immune responses, binding affinity)
-
PG9: The effects of 16 glycoengineering (GE) methods on the sensitivities of 293T cell-produced pseudoviruses (PVs) to a large panel of bNAbs were investigated. Some bNAbs were dramatically impacted. PG9 and were up to 30-fold more potent against PVs produced with co-transfected α-2,6 sialyltransferase. PGT151 and PGT121 were more potent against PVs with terminal SA removed. 35O22 and CH01 were more potent against PV produced in GNT1-cells. The effects of GE on bNAbs VRC38.01, VRC13 and PGT145 were inconsistent between Env strains, suggesting context-specific glycan clashes. Overexpressing β-galactosyltransferase during PV production 'thinned' glycan coverage, by replacing complex glycans with hybrid glycans. This impacted PV sensitivity to some bNAbs. Maximum percent neutralization by excess bnAb was also improved by GE. Remarkably, some otherwise resistant PVs were rendered sensitive by GE. Germline-reverted versions of some bnAbs usually differed from their mature counterparts, showing glycan indifference or avoidance, suggesting that glycan binding is not germline-encoded but rather, it is gained during affinity maturation. Overall, these GE tools provided new ways to improve bnAb-trimer recognition that may be useful for informing the design of vaccine immunogens to try to elicit similar bnAbs.
Crooks2018
(vaccine antigen design, antibody lineage)
-
PG9: A panel of bnAbs were studied to assess ongoing adaptation of the HIV-1 species to the humoral immunity of the human population. Resistance to neutralization is increasing over time, but concerns only the external glycoprotein gp120, not the MPER, suggesting a high selective pressure on gp120. Almost all the identified major neutralization epitopes of gp120 are affected by this antigenic drift, suggesting that gp120 as a whole has progressively evolved in less than 3 decades.
Bouvin-Pley2014
(neutralization)
-
PG9: A rare glycan hole at the V2 apex is enriched in HIV isolates neutralized by inferred precursors of prototype V2-apex bNAbs. To investigate whether this feature could focus neutralizing responses onto the apex bnAb region, rabbits were immunized with soluble trimers adapted from these Envs. Potent autologous tier 2 neutralizing responses targeting basic residues in strand C of the V2 region, which forms the core epitope for V2-apex bnAbs, were observed. Neutralizing monoclonal antibodies (mAbs) derived from these animals display features promising for subsequent broadening of the response. Four human anti-V2 bnAbs (PG9, CH01, PGT145, and CAP256.09) were used as a basis of comparison.
Voss2017
(vaccine antigen design)
-
PG9: This study describes the generation of CHO cell lines stably expressing the following vaccine Env Ags: CRF01_AE A244 Env gp120 protein (A244.AE) and 6240 Env gp120 protein (6240.B). The antigenic profiles of the molecules were assessed with a panel of well-characterized mAbs recognizing critical epitopes and glycosylation analysis confirming previously identified sites and revealing unknown sites at non-consensus motifs. A244.AE gp120 showed low level of binding to PG9 in ELISA EC50 and Surface Plasmon Resonance (SPR) assays. 6240.B gp120 exhibited binding to PG9.
Wen2018
(glycosylation, vaccine antigen design)
-
PG9: The prophylactic and therapeutic potential of an engineered single gene–encoded tandem bispecific immunoadhesin (IA) molecule BiIA-SG was studied. Before engineering BiIAs, codon-optimized scFvs of bNAbs PG9, PG16, PGT128, VRC01, and Hu5A8 were synthesized. The VL/VH domain of each scFv was engineered as a corresponding IA by fusion with human IgG1-Fc to generate IA-PG9, IA-PG16, IA-PGT128, IA-VRC01, and IA-Hu5A8. While all IAs exhibited specific anti–HIV-1 activity, only IA-PGT128 displayed similar potency and the same sigmoidal slope of 100% neutralization as previously described for the native PGT128, and IA-PGT128 in combination with IA-Hu5A8 exhibited the best synergistic effect based on computational synergy volumes. IA-PGT128 and IA-Hu5A8 were therefore used for BiIA construction.
Wu2018
-
PG9: Assays of poly- and autoreactivity demonstrated that broadly neutralizing NAbs are significantly more poly- and autoreactive than non-neutralizing NAbs. PG9 is polyreactive, but not autoreactive.
Liu2015a
(autoantibody or autoimmunity, antibody polyreactivity)
-
PG9: Panels of C clade pseudoviruses were computationally downselected from the panel of 200 C clade viruses defined by Rademeyer et al. 2016. A 12-virus panel was defined for the purpose of screening sera from vaccinees. Panels of 50 and 100 viruses were defined as smaller sets for use in testing magnitude and breadth against C clade. Published neutralization data for 16 mAbs was taken from CATNAP for the computational selections: 10-1074, 10-1074V, PGT121, PGT128, VRC26.25, VRC26.08, PGDM1400, PG9, PGT145, VRC07-523, 10E8, VRC13, 3BNC117, VRC07, VRC01, 4E10.
Hraber2017
(assay or method development, neutralization)
-
PG9: A panel of 14 pseudoviruses of subtype CRF01_AE was developed to assess the neutralization of several neutralizing antibodies (b12, PG9, PG16, 4E10, 10E8, 2F5, PGT121, PGT126, 2G12). Neutralization was assessed in both TZM-bl and A3R5 cell-based assays. Most viruses were more susceptible to mAb-neutralization in A3R5 than in the TZM-bl cell-based assay. The increased neutralization sensitivity observed in the A3R5 assay was not linked to the year of virus transmission or to the stages of infection, but chronic viruses from the years 1990-92 were more sensitive to neutralization than the more current viruses, in both assays.
Chenine2018
(assay or method development, neutralization, subtype comparisons)
-
PG9: The immunologic effects of mutations in the Env cytoplasmic tail (CT) that included increased surface expression were explored using a vaccinia prime/protein boost protocol in mice. After vaccinia primes, CT- modified Envs induced up to 7-fold higher gp120-specific IgG, and after gp120 protein boosts, they elicited up to 16-fold greater Tier-1 HIV-1 neutralizing antibody titers.
Hogan2018
(vaccine antigen design)
-
PG9: Env trimers were engineered with selective deglycosylation around the CD4 binding site to see if they could be useful vaccine antigens. The neutralization of glycan-deleted trimers was tested for a set of bnAbs (PG9, PGT122, PGT135, b12, CH103, HJ16, VRC01, VRC13, PGT151, 8ANC195, 35O22), and the antigens elicited potent neutralization based on the CD4 supersite. A crystal structure was made of one of these Env trimers bound to Fabs 35O22 and 3H+109L. Guinea pigs vaccinated with these antigens achieved neutralization of deglycosylated Envs. Glycan-deleted Env trimers may be useful as priming antigens to increase the frequency of CD4 site-directed antibodies.
Zhou2017
(glycosylation, neutralization, vaccine antigen design, vaccine-induced immune responses)
-
PG9: Env from of a highly neutralization-resistant isolate, CH120.6, was shown to be very stable and conformationally-homogeneous. Its gp140 trimer retains many antigenic properties of the intact Env, while its monomeric gp120 exposes more epitopes. Thus trimer organization and stability are important determinants for occluding epitopes and conferring resistance to antibodies. Among a panel of 21 mAbs, CH120.6 was resistant to neutralization by all non-neutralizing and strain-specific mAbs, regardless of the location of their epitopes. It was weakly neutralized by several broadly-neutralizing mAbs (VRC01, NIH45-46, 12A12, PG9, PG16, PGT128, 4E10, and 10E8), and well neutralized by only 2 (PGT145 and 10-1074).
Cai2017
(neutralization)
-
PG9: A panel of mAbs (2G12, VRC01, HJ16, 2F5, 4E10, 35O22, PG9, PGT121, PGT126, 10-1074) was tested to compare their efficacy in cell-free versus cell-cell transmission. Almost all bNAbs (with the exception of anti-CD4 mAb Leu3a) blocked cell-free infection with greater potency than cell-cell infection, and showed greater potency in neutralization of cell-free viruses. The lower effectiveness on neutralization was particularly pronounced for transmitted/founder viruses, and less pronounced for chronic and lab-adapted viruses. The study highlights that the ability of an antibody to inhibit cell-cell transmission may be an important consideration in the development of Abs for prophylaxis.
Li2017
(immunoprophylaxis, neutralization)
-
PG9: The next generation of a computational neutralization fingerprinting (NFP) being used as a way to predict polyclonal Ab responses to HIV infection is presented. A new panel of 20 pseudoviruses, termed f61, was developed to aid in the assessment of experimental neutralization. This panel was used to assess 22 well-characterized bNAbs and mixtures thereof (HJ16, VRC01, 8ANC195, IGg1b12, PGT121, PGT128, PGT135, PG9, PGT151, 35O22, 10E8, 2F5, 4E10, VRC27, VRC-CH31, VRC-PG20, PG04, VRC23, 12A12, 3BNC117, PGT145, CH01). The new algorithms accurately predicted VRC01-like and PG9-like antibody specificities.
Doria-Rose2017
(neutralization, computational prediction)
-
PG9: This review focuses on the potential role of HIV-1-specific NAbs in preventing HIV-1 infection. Several NAbs have provided protection from infection in SHIV challenge studies in primates: b12, VRC01, VRC07-523LS, 3BNC117, PG9, PGT121, PGT126, 10-1074, 2G12, 4E10, 2F5, 10E8.
Pegu2017
(immunoprophylaxis, review)
-
PG9: The ability of neutralizing and nonneutralizing mAbs to block infection in models of mucosal transmission was tested. Neutralization potency did not fully predict activity in mucosal tissue. CD4bs-specific bNAbs, in particular VRC01, blocked HIV-1 infection across all cellular and tissue models. MPER (2F5) and outer domain glycan (2G12) bNAbs were also efficient in preventing infection of mucosal tissues, while bNAbs targeting V1-V2 glycans (PG9 and PG16) were more variable. Non-nAbs alone and in combinations, were poorly protective against mucosal infection. The protection provided by specific bNAbs demonstrates their potential over that of nonneutralizing antibodies for preventing mucosal entry. PG9 and PG16 were selected to represent mAbs of the V1-V2 glycan class.
Cheeseman2017
(genital and mucosal immunity, immunoprophylaxis)
-
PG9: To understand HIV neutralization mediated by the MPER, antibodies and viruses were studied from CAP206, a patient known to produce MPER-targeted neutralizing mAbs. 41 human mAbs were isolated from CAP206 at various timepoints after infection, and 4 macaque mAbs were isolated from animals immunized with CAP206 Env proteins. Two rare, naturally-occuring single-residue changes in Env were identified in transmitted/founder viruses (W680G in CAP206 T/F and Y681D in CH505 T/F) that made the viruses less resistant to neutralization. The results point to the role of the MPER in mediating the closed trimer state, and hence the neutralization resistance of HIV. CH58 was one of several mAbs tested for neutralization of transmitted founder viruses isolated from clade C infected individuals CAP206 and CH505, compared to T/F viruses containing MPER mutations that confer enhanced neutralization sensitivity.
Bradley2016a
(neutralization)
-
PG9: This study performed cyclical permutation of the V1 loop of JRFL in order to develop better gp120 trimers to elicit neutralizing antibodies. Some mutated trimers showed improved binding to several mAbs, including VRC01, VRC03, VRC-PG04, PGT128, PGT145, PGDM1400, b6, and F105. Guinea pigs immunized with prospective trimers showed improved neutralization of a panel of HIV-1 pseudoviruses. Binding of PG9 to JRFL was abolished by mutations N156K or N160K.
Kesavardhana2017
(vaccine antigen design, vaccine-induced immune responses)
-
PG9: This study investigated the ability of native, membrane-expressed JR-FL Env trimers to elicit NAbs. Rabbits were immunized with virus-like particles (VLPs) expressing trimers (trimer VLP sera) and DNA expressing native Env trimer, followed by a protein boost (DNA trimer sera). N197 glycan- and residue 230- removal conferred sensitivity to Trimer VLP sera and DNA trimer sera respectively, showing for the first time that strain-specific holes in the "glycan fence" can allow the development of tier 2 NAbs to native spikes. All 3 sera neutralized via quaternary epitopes and exploited natural gaps in the glycan defenses of the second conserved region of JR-FL gp120. A bioinformatics analysis suggested shared features of one of the trimer VLP sera and monoclonal antibody PG9, consistent with its trimer-dependency. PG9 was 1 of 2 reference PG9-like bNAbs - PG9 and PGT145.
Crooks2015
(glycosylation, neutralization)
-
PG9: Env residue N197 on the BG505-SOSIP trimer was mutated to test the effect of its glycosylation on the binding kinetics of CD4BS and other mAbs. Removal of the glycan had little effect on the overall structure of the molecule. Its removal resulted in increased binding of CD4 and CD4BS antibodies (VRC01, VRC03, V3-3074), but little effect on bNAbs targeting other epitopes (PG9, PG16, PGT145, 17b, A32, 2G12, PGT121, PGT126). Two CD4BS-binding antibodies tested (b12, F105) had insufficient breadth to bind the BG505-SOSIP trimer. Removal of the N197 glycan may allow for the development of better SOSIP immunogens, particularly to elicit CD4BS-specific Abs.
Liang2016
(glycosylation, vaccine antigen design)
-
PG9: Binding of PG9 to properly folded and glycosylated fragments of Env V1/V2 (scaffolds) is described. Scaffolds from 3 different clades of HIV-1 bound to PG9 with high affinity. Mutations I169K, E172V, T161M, N156I, S164G, D167G (includng those outside of the antibody contact region) improved binding.
Morales2016
(antibody binding site, vaccine antigen design)
-
PG9: Chimeric antigen receptors (CAR), i.e., fusion proteins made from single-chain antibodies, may be a useful approach to immunotherapy. A set of mAbs were chosen based on their binding to a variety of sites on Env and availability of antibody sequences. The chimeric receptors were created by fusing the antibody's heavy chain, light chain, and two signaling domains into a single molecule. All 7 antibodies used to make the chimeric receptors (10E8, 3BNC117, PGT126, VRC01, X5, PGT128, PG9) showed specific killing of HIV-1 infected cells and suppression of viral replication against a panel of HIV-1 strains.
Ali2016
(immunotherapy, chimeric antibody)
-
PG9: This review classified and mapped the binding regions of 32 bNAbs isolated 2010-2016.
Wu2016
(review)
-
PG9: This study produced Env SOSIP trimers for clades A (strain BG505), B (strain JR-FL), and G (strain X1193). Based on simulations, the MAb-trimer structures of all MAbs tested needed to accommodate at least one glycan, including both antibodies known to require specific glycans (PG9, PGT121, PGT135, 8ANC195, 35O22) and those that bind the CD4-binding site (b12, CH103, HJ16, VRC01, VRC13). A subset of monoclonal antibodies bound to glycan arrays assayed on glass slides (VRC26.09, PGT121, 2G12, PGT128, VRC13, PGT151, 35O22), while most of the antibodies did not have affinity for oligosaccharide in the context of a glycan array (PG9, PGT145, PGDM1400, PGT135, b12, CH103, HJ16, VRC16, VRC01, VRC-PG04, VRC-CH31, VRC-PG20, 3BNC60, 12A12, VRC18b, VRC23, VRC27, 1B2530, 8ANC131, 8ANC134, 8ANC195).
Stewart-Jones2016
(antibody binding site, glycosylation, structure)
-
PG9: This study assessed the ADCC activity of antibodies of varied binding types, including CD4bs (b6, b12, VRC01, PGV04, 3BNC117), V2 (PG9, PG16), V3 (PGT126, PGT121, 10-1074), oligomannose (2G12), MPER (2F5, 4E10, 10E8), CD4i (17b, X5), C1/C5 (A32, C11), cluster I (240D, F240), and cluster II (98-6, 126-7). ADCC activity was correlated with binding to Env on the surfaces of virus-infected cells. ADCC was correlated with neutralization, but not always for lab-adapted viruses such as HIV-1 NLA-3.
vonBredow2016
(effector function)
-
PG9: This review summarizes representative anti-HIV MAbs of the first generation (2G12, b12, 2F5, 4E10) and second generation (PG9, PG16, PGT145, VRC26.09, PGDM1400, PGT121, PGT124, PGT128, PGT135, 10-1074, VRC01, 3BNC117, CH103, PGT151, 35O22, 8ANC195, 10E8). Structures, epitopes, VDJ usage, CDR usage, and degree of somatic hypermutation are compared among these antibodies. The use of SOSIP trimers as immunogens to elicit B-cell responses is discussed.
Burton2016
(review, structure)
-
PG9: HIV-1 bNAb eptiope networks were predicted using 4 algorithms informed by neutralization assays using 282 Env from multiclade viruses. Patch clusters of possible Ab epitope regions were tested for significant sensitivity by site-directed mutagenesis. Epitope (Ab binding site) networks of critical Env residues for 21 bNAb (b12, PG9, PG16, PGT121, PGT122, PGT123, PGT125, PGT126, PGT127, PGT128, PGT130, PGT131, PGT135, PGT136, PGT137, PGT141, PGT142, PGT143, PGT144, PGT145 and PGV04) were delineated and found to be located mostly in variable loops of gp120, particularly in V1/V2.
Evans2014
(antibody binding site, computational prediction)
-
PG9: Two stable homogenous gp140 Env trimer spikes, Clade A 92UG037.8 Env and Clade C C97ZA012 Env, were identified. 293T cells stably transfected with either presented fully functional surface timers, 50% of which were uncleaved. A panel of neutralizing and non-neutralizing Abs were tested for binding to the trimers. V1/V2 glycan bNAb PG9 bound cell surface tightly whether the trimer contained its C-terminal or not, and was competed out by sCD4. It was able to neutralize the 92UG037.8 HIV-1 isolate.
Chen2015
(neutralization, binding affinity)
-
PG9: Factors that independently affect bNAb induction and evolution were identified as viral load, length of untreated infection, and viral diversity. Black subjects induced bNAbs more than white subjects, but this did not correlate with type of Ab response. Fingerprint analyses of induced bNAbs showed strong subtype dependency, with subtype B inducing significantly higher levels of CD4bs Abs and non-subtype B inducing V2-glycan specific Abs. Of the 239 bNAb antibody inducers found from 4,484 HIV-1 infected subjects,the top 105 inducers' neutralization fingerprint and epitope specificity was determined by comparison to the following antibodies - PG9, PG16, PGDM1400, PGT145 (V2 glycan); PGT121, PGT128, PGT130 (V3 glycan); VRC01, PGV04 (CD4bs) and PGT151 (interface) and 2F5, 4E10, 10E8 (MPER).
Rusert2016
(neutralization, subtype comparisons, broad neutralizer)
-
PG9: PGT145 was used to positively isolate a subtype B Env trimer immunogen, B41 SOSIP.664-D7324, that exists in two conformations, closed and partially open. bNAbs tested against the trimer were able to neutralize the B41 pseudovirus with a wide range of potencies. All tested non-NAbs did not neutralize B41 (IC50 >50µg/ml). V1/V2 glycan bNAb, PG9, neutralized B41 psuedovirus and bound B41 trimer well.
Pugach2015
-
PG9: The first generation of HIV trimer soluble immunogens, BG505 SOSIP.664 were tested in a mouse model for generation of nAb to neutralization-resistant circulating HIV strains. No such NAbs were induced, as mouse Abs targeted the bottom of soluble Env trimers, suggesting that the glycan shield of Env trimers is impenetrable to murine B cell receptors and that epitopes at the trimer base should be obscured in immunogen design in order to avoid non-nAb responses. Association and dissociation of known anti-trimer bNAbs (VRC01, PGT121, PGT128, PGT151, PGT135, PG9, 35O22, 3BC315 and PGT145) were found to be far greater than murine generated non-NAbs.
Hu2015
-
PG9: A comprehensive antigenic map of the cleaved trimer BG505 SOSIP.664 was made by bNAb cross-competition. Epitope clusters at the CD4bs, quaternary V1/V2 glycan, N332-oligomannose patch and new gp120-gp41 interface and their interactions were delineated. Epitope overlap, proximal steric inhibition, allosteric inhibition or reorientation of glycans were seen in Ab cross-competition. Thus bNAb binding to trimers can affect surfaces beyond their epitopes. PG9, PG16 and PG145, all V1/V2 glycan trimer apex bNAbs, were strongly, reciprocally competitive with one another. V3 glycan bNAbs PGT121, PGT122, PGT123 inhibited binding of PG9 strongly, but in a non-reciprocal manner.
Derking2015
(antibody interactions, neutralization, binding affinity, structure)
-
PG9: Two clade C recombinant Env glycoprotein trimers, DU422 and ZM197M, with native-like structural and antigenic properties involving epitopes against all known classes of bNAbs, were produced and characterized. These Clade C trimers (10-15% of which are in a partially open form) were more like B41 Clade B trimers which have 50-75% trimers in the partially open configuration than like B505 Clade B trimers, almost 100% in the closed, prefusion state. The Clade C trimers are weakly reactive with the V1/V2 glycan bNAb, PG9, and while neutralization of the DU422 pseudotyped virus is robust, that of the ZM197M pseudovirus is moderate.
Julien2015
(assay or method development, structure)
-
PG9: HIV-1 escape from the N332-glycan dependent bNAb, PGT135, developed in an elite controller but without change to the PGT135-binding Env epitope itself. Instead an insertion increasing V1 length by up to 21 residues concomitant with an additional 1-3 glycans and 2-4 cysteines shields the epitope from PGT135. The majority of viruses tested developed a 14-fold resistance to PGT135 from month 7 to 11. In comparison, no significant difference in HIV-1 against bNAb PG9 was seen.
vandenKerkhof2016
(elite controllers and/or long-term non-progressors, neutralization, escape)
-
PG9: A new trimeric immunogen, BG505 SOSIP.664 gp140, was developed that bound and activated most known neutralizing antibodies but generally did not bind antibodies lacking neuralizing activity. This highly stable immunogen mimics the Env spike of subtype A transmitted/founder (T/F) HIV-1 strain, BG505. Anti-V1/V2 glycan bNAb PG9, neutralized BG505.T332N, the pseudoviral equivalent of the immunogen BG505 SOSIP.664 gp140, and was shown to recognize and bind the immunogen too.
Sanders2013
(assay or method development, neutralization, binding affinity)
-
PG9: This review discusses an array of methods to engineer more effective bNAbs for immunotherapy. Antibody PG9 was mentioned as an example of engineering through rational mutations; PG9-N100(F)Y stabilizes the CDR-H3 in the active conformation, thus improving neutralization.
Hua2016
(immunotherapy, review)
-
PG9: Site-specific analysis of N-glycosylation sites of a soluble recombinant trimerBG505 SOSIP.664 is presented. Neutralization profiles for V1V2 Ab, PG9, to multiple epitopes were determined. Removing the N156 or N160 glycans from either of the BG505 test viruses reduced the neutralization activities of PG9.
Behrens2016
(antibody binding site, glycosylation)
-
PG9: A mathematical model was developed to predict the Ab concentration at which antibody escape variants outcompete their ancestors, and this concentration was termed the mutant selection window (MSW). The MSW was determined experimentally for 12 pairings of diverse HIV strains against 7 bnAbs (b12, 2G12, PG9, PG16, PGT121, PGT128, 2F5). The neutralization of of PG9 was assayed against 5 resistant and 5 sensitive strains.
Magnus2016
(neutralization, escape)
-
PG9: A panel of Env-specific mAbs was isolated from 6 HIV1-infected lactating women. Antibodies in colostrum may help prevent mucosal infection of the infant, so this study aimed to define milk IgGs for future vaccination strategies to reduce HIV transmission during lactation. Despite the high rate of VH1-69 usage among colostrum Env specific B cells, it did not correlate with distinct gp120 epitope specificity or function. PG9 was compared to the newly-derived mAbs; it had no cross-reactivity with gut bacteria, and tested negative in two tests of autoreactivity.
Jeffries2016
(antibody polyreactivity)
-
PG9: The study detailed binding kinetics of the interaction between BG505 SOSIP.664 trimer or its variants (gp120 monomer; first study of disulfide-stabilized variant gp120-gp41ECTO protomer) and several mAbs, both neutralizing (VRC01, PGV04, PG9, PG16, PGT121, PGT122, PGT123, PGT145, PGT151, 2G12) and non-neutralizing (b6, b12, 14e, 19b, F240). V1V2 quarternary-dependent epitope-binding bNAb, PG9, bound trimer best, but less well to protomer and BG505 gp120's monomer.
Yasmeen2014
(antibody binding site, assay or method development)
-
PG9: Neutralization breadth in 157 antiretroviral-naive individuals infected for less than 1 year post-infection was studied and compared to a cohort of 170 untreated chronic patients. A range of neutralizing activities was observed with a panel of six recombinant viruses from five different subtypes. Some sera were broadly reactive, predominantly targeting envelope epitopes within the V2 glycan-dependent region. The Env neutralization breadth was positively associated with time post infection. PG9 has been used as a control in detection of glycan-dependent HIV-1 neutralizing sera.
Sanchez-Merino2016
(neutralization, acute/early infection)
-
PG9: A new, current, mostly tier2 panel of 200 C-clade Env-psuedotyped viruses from early (< 100d) infection in southern Africa was used to assess antibody responses to natural infection and to vaccines. Viruses were assayed with bNAbs targeting the V2 glycan (PG9, VRC26.25), the MPER site (4E10), the CD4 binding site (VRC01), and the V3/C3 glycan site (PGT128). For 4E10 (and all other Abs besides PGT128) there was no significant difference in neutralization between pre-seroconversion and post-seroconversion viruses. Viruses collected pre-seroconversion were more resistant to neutralization by serum than those post-seroconversion. As the epidemic matured over 13 years, viruses also became more resistant to mAbs tested.
Rademeyer2016
(assay or method development, neutralization)
-
PG9: The sequential development of three distinct bnAb responses within a single host, CAP257, over 4.5 years of infection has been described. It showed how escape from the first wave of Abs targeting V2 exposed a second site that was the stimulus for a new wave of glycan dependent bnAbs against the CD4 binding site. These data highlighted how Ab evolution in response to viral escape mutations served to broaden the host immune response to two epitopes. A third wave of neutralization targeting an undefined epitope that did not appear to overlap with the four known sites of vulnerability on the HIV-1 envelope has been reported. These data supported the design of templates for sequential immunization strategies.
Wibmer2013
(escape)
-
PG9: This study examined the neutralization of group N, O, and P primary isolates of HIV-1 by diverse antibodies. Cross-group neutralization was observed only with the bNAbs targeting the N160 glycan-V1/V2 site. Four group O isolates, 1 group N isolate, and the group P isolates were neutralized by PG9 and/or PG16 or PGT145 at low concentrations. None of the non-M primary isolates were neutralized by bNAbs targeting other regions, except 10E8, which weakly neutralized 2 group N isolates, and 35O22 which neutralized 1 group O isolate. Bispecific bNAbs (PG9-iMab and PG16-iMab) very efficiently neutralized all non-M isolates with IC50 below 1 ug/mL, except for 2 group O strains. Anti V1/V2 bNAb PG9 was able to neutralize 5/16 tested non-M primary isolates at an IC50< 10µg/ml, 2 of them highly with a value under 1 µg/ml and 3 moderately.
Morgand2015
(neutralization, subtype comparisons)
-
PG9: The neutralization of 14 bnAbs was assayed against a global panel of 12 or 17 Env pseudoviruses. From IC50, IC80, IC90, and IC99 values, the slope of the dose-response curve was calculated. Each class of Ab had a fairly consistent slope. Neutralization breadth was strongly correlated with slope. An IIP (Instantaneous Inhibitory Potential) value was calculated, based on both the slope and IC50, and this value may be predictive of clinical efficacy. PG9, a V2-glycan bnAb belonged to a group with slopes <1.
Webb2015
(neutralization)
-
PG9: This study evaluated the binding of 15 inferred germline (gl) precursors of bNAbs that are directed to different epitope clusters, to 3 soluble native-like SOSIP.664 Env trimers - BG505, B41 and ZM197M. The trimers bound to some gl precursors, particularly those of V1V2-targeted Abs. These trimers may be useful for designing immunogens able to target gl precursors. V1/V2 apex-binding gl-PG9 precursor bound to 2/3 trimers, BG505 and ZM197M.
Sliepen2015
(binding affinity, antibody lineage)
-
PG9: Computational modeling was used to examine antibody recognition of glycans, using a V1V2 bNAb (PG9) and a V3 bnAb (PGT128). Both PG9 and PGT128 have a long CDR H3 loop that can penetrate the glycan shield and form interactions with gp120. The modeling results showed that the tip of the CDR H3 loop is flexible in the free antibodies and is able to move within the bound conformation, which likely increases the penetrability of the glycan shield.
Qi2016
(glycosylation)
-
PG9: To test whether NAbs can inhibit viral transmission through mucosal tissue, 4 bNAbs (PG9, PG16, VRC01, 4E10) were tested in tissue culture models of human colonic and ectocervical tissues. All 4 nAbs reduced HIV transmission, with a relative efficacy of PG16 > PG9 > VRC01 >> 4E10. The nAbs had a good safety profile and were not affected by the presence of semen.
Scott2015
(immunotherapy)
-
PG9: The study's goal was to produce modified SOSIP trimers that would reduce the exposure - and, by inference, the immunogenicity - of non-NAb epitopes such as V3. The binding of several modified SOSIP trimers was compared among 12 neutralizing (PG9, PG16, PGT145, PGT121, PGT126, 2G12, PGT135, VRC01, CH103, CD4, IgG2, PGT151, 35O22) and 3 non-neutralizing antibodies (14e, 19b, b6). The V3 non-NAbs 447-52D, 39F, 14e, and 19b bound less well to all A316W variant trimers compared to wild-type trimers. Mice and rabbits immunized with modified, stabilized SOSIP trimers developed fewer V3 Ab responses than those immunized with native trimers.
deTaeye2015
(antibody binding site)
-
PG9: Deep-sequencing and computational methods were used to identify HCDR3 sequences in HIV-naïve donors that mediated binding and neutralization of HIV by mimicking the bnAb PG9 long HCDR3 region when expressed in the context of the rest of the PG9 antibody sequence. 2 naturally occurring HCDR3 sequences from 2 different donors of 70 studied were predicted to adopt a PG9-like hammerhead conformation and were able to bind and neutralize PG9-susceptible viruses. In addition, computational design was used to mimic the process of maturation by somatic mutation of HCDR3 sequences from the HIV-1–naïve repertoire that were predicted to adopt a PG9-like hammerhead conformation. Two to seven mutations in eight different HCDR3 sequences facilitated neutralization of HIV when grafted on a PG9 Ab background.
Willis2016
(antibody lineage)
-
PG9: HIV-1 strains were isolated from 60 patients infected with CRFs 01_AE, 07_BC, and 08_BC. Eight CRF01 strains that produced high-titer Env pseudoviruses were studied further. All were sensitive to neutralization by VRC01, PG9, PG16, and NIH45-46, but insensitive to 2G12. The PG9 have affinity for epitopes located in the conserved regions of the V2-V3 loop. Binding of PG9 and PG16 with the virus was largely dependent on the same residues, although PG16 was more sensitive to V3 loop substitutions than PG9. Sequence analysis of PG9- and PG16-resistant viruses revealed complex mutation patterns associated with residues that are critical for PG9/PG16 binding. CNAE14 was shown to be resistant to both PG9 and PG16. It is likely that substitutions S158T, S162T, K305T, and I307T jointly contribute to this resistance phenotype.
Chen2016
(neutralization, subtype comparisons)
-
PG9: A large cross-sectional study of sera from 205 ART-naive patients infected with different HIV clades was tested against a panel of 219 cross-clade Env-pseudotyped viruses. Their neutralization was compared to the neutralization of 10 human bNAbs (10E8, 4E10, VRC01, PG9, PGT145, PGT128, 2F5, CH01, b12, 2G12) tested with a panel of 119 Env-pseudotyped viruses. Results from b12 and 2G12 suggested that these bnAbs may not be as broadly neutralizing as previously thought. PG9 neutralized 86% of the 199 viruses tested.
Hraber2014
(neutralization)
-
PG9: The study compared binding and neutralization of 4 V2 apex bnAbs (PG9, CH01, PGT145, and CAP256.VRC26.09). All recognized a core epitope on V1/V2 (the N-linked glycan at N160 and cysteine-linked lysine rich, HXB2:126-196), which includes residue N160 as well as N173. The lysine rich region on strand C of HIV-1 V2 that is key for binding to the nAb contains the sequence (168)KKQK(171). Inferred germline versions of three of the prototype bnAbs were able to neutralize specific Env isolates. Soluble Env derived from one of these isolates was shown to form a well-ordered Env trimer that could serve as an immunogen to initiate a V2-apex bnAb response. Escape from bnAb PG9 was seen in patient Donor_64 by mutations K169T and K171E. 99% amino acid sequence identity exists between PG9 and CAP256.09 in VH-germline gene.
Andrabi2015
(antibody binding site, neutralization, vaccine antigen design, escape, antibody lineage)
-
PG9: Double, triple or quadruple combinations of fifteen bNAbs that target 4 distinct epitope regions: the CD4 binding site (3BNC117, VRC01, VRC07, VRC07-523, VRC13), the V3-glycan supersite (10–1074, 10-1074V, PGT121, PGT128), the V1/V2-glycan site (PG9, PGT145, PGDM1400, CAP256-VRC26.08, CAP256-VRC26.25), and the gp41 MPER epitope (10E8) were studied. Their neutralization potency and breadth were assayed against a panel of 200 acute/early subtype C strains, and compared to a novel, highly accurate predictive mathematical model (no-overlap Bliss Hill model, CombiNaber tool, LANL HIV Immunology database). These data were used to predict the best combinations of bNAbs for immunotherapy.
Wagh2016
(neutralization, immunotherapy)
-
PG9: An atomic-level understanding of V1V2-directed bNAb recognition in a donor was used in the design of V1V2 scaffolds capable of interacting with quaternary-specific V1V2-directed bNAbs. The cocrystal structure of V1V2 with antibody CH03 from a second donor is reported and Env interactions of antibody CAP256-VRC26 from a third donor are modeled. V1V2-directed bNAbs used strand-strand interactions between a protruding Ab loop and a V1V2 strand but differed in their N-glycan recognition. Ontogeny analysis indicated that protruding loops develop early, and glycan interactions mature over time. Combination of the atomic-level information and negative-stain EM of PG9 in complex with a soluble trimeric Env mimic, BG505 SOSIP.664, suggest that the quaternary dependency of PG9 arises from its recognition of glycan N160 from a neighboring protomer24.
Gorman2016
(glycosylation, structure, antibody lineage)
-
PG9: The human Ab gene repertoires of uninfected and HIV-1-infected individuals were studied at genomic DNA (gDNA) and cDNA levels to determine the frequencies of putative germline Ab genes of known HIV-1 bnAbs. All libraries were deep sequenced and analysed using IMGT/HighV-QUEST software (http://imgt.org/HighV-QUEST/index. The human gDNA Ab libraries were more diverse in heavy and light chain V-gene lineage usage than the cDNA libraries. This implied that the human gDNA Ab gene repertoires may have more potential than the cDNA repertoires to develop HIV-1 bnmAbs. Relatively high frequencies of the VH and VKs and VLs that used the same V-genes and had the same CDR3 lengths as known HIV-1 bnmAbs regardless of (D)J-gene usage. Frequencies of the VLs with the identical VJ recombinations to PG9 were relatively high. The putative germline genes were determined for a set of mAbs (b12, VRC01, VRC03, NIH45-46, 3BNC60, PG9, PGT127, and X5).
Zhang2013
(antibody lineage, germline)
-
PG9: Galactosyl ceramide (Galcer), a glycosphingolipid, is a receptor for the HIV-1 Env glycoprotein. This study has mimicked this interaction by using an artificial membrane containing synthetic Galcer and recombinant HIV-1 Env proteins to identify antibodies that would block the HIV-1 Env-Galcer interaction. HIV-1 ALVAC/AIDSVAX vaccinee-derived MAbs specific for the gp120 C1 region blocked Galcer binding of a transmitted/founder HIV-1 Env gp140. The antibody-dependent cellular cytotoxicity-mediating CH38 IgG and its natural IgA isotype were the most potent blocking antibodies. PG9 exhibited moderate Env-Galcer blocking.
Dennison2014
(antibody binding site, antibody interactions, effector function, glycosylation)
-
PG9: A unified convergent strategy for the rapid production of bi-, tri-, and tetra-antennary complex type N-glycans with and without terminal N-acetylneuraminic acid residues connected via the α-2,6 or α-2,3 linkages is reported which may facilitate the design of carbohydrate-based immunogens. A glycan microarray-based profiling of PG9 was used to understand the binding specificity. No detectable binding for PG9, probably due to (1) very weak binding affinity toward protein/peptide free glycans, (2) the requirement of closely spaced Man5GlcNAc2 (N160) and complex type glycan (N156/163) as PG9 epitopes, and (3) the heterogeneous distribution of NHS groups on glass slides resulting in uneven and low-density glycan arrays.
Shivatare2013
(glycosylation, structure)
-
PG9: The effect of PNGS on viral infectivity and antibody neutralization (2F5, 4E10, b12, VRC01, VRC03, PG9, PG16, 3869) was evaluated through systemic mutations of each PNGS on CRF07_BC strain. Mutations at N197 (C2), N301 (V3), N442 (C4), and N625 (gp41) rendered the virus more susceptible to neutralization by MAbs that recognize the CD4 binding site or gp41. Generally, mutations on V4/V5 loops, C2/C3/C4 regions, and gp41 reduced the neutralization sensitivity to PG16. However, mutation of N289 (C2) made the virus more sensitive to both PG9 and PG16. Mutations at N142 (V1), N355 (C3) and N463 (V5) conferred resistance to neutralization by anti-gp41 MAbs. Available structural information of HIV Env and homology modeling was used to provide a structural basis for the observed biological effects of these mutations.
Wang2013
(neutralization, structure)
-
PG9: Incomplete neutralization may decrease the ability of bnAbs to protect against HIV exposure. In order to determine the extent of non-sigmoidal slopes that plateau at <100% neutralization, a panel of 24 bnMAbs targeting different regions on Env was tested in a quantitative pseudovirus neutralization assay on a panel of 278 viral clones. All bNAbs had some viruses that they neutralized with a plateau <100%, but those targeting the V2 apex and MPER did so more often. All bnMAbs assayed had some viruses for which they had incomplete neutralization and non-sigmoidal neutralization curves. bNAbs were grouped into 3 groups based on their neutralization curves: group 1 antibodies neutralized more than 90% of susceptible viruses to >95% (PGT121-123, PGT125-128, PGT136, PGV04); group 2 was less effective, resulting in neutralization of 60-84% of susceptible viruses to >95% (b12, PGT130-131, PGT135, PGT137, PGT141-143, PGT145, 2G12, PG9); group 3 neutralized only 36-60% of susceptible viruses to >95% (PG16, PGT144, 2F5, 4E10).
McCoy2015
(neutralization)
-
PG9: The neutralization abilities of Abs were enhanced by bioconjugation with aplaviroc, a small-molecule inhibitor of virus entry into host cells. Diazonium hexafluorophosphate was used. The conjugated Abs blocked HIV-1 entry through two mechanisms: by binding to the virus itself and by blocking the CCR5 receptor on host cells. Chemical modification did not significantly alter the potency and the pharmacokinetics. The PG9-aplaviroc conjugate was tested against a panel of 117 HIV-1 strains and was found to neutralize 100% of the viruses. PG9-aplaviroc conjugate IC50s were lower than those of PG9 in neutralization studies of 36 of the 117 HIV-1 strains.
Gavrilyuk2013
(neutralization)
-
PG9: This study investigated the immunogenicity of three ΔV1V2 deleted variants of the HIV-1 Env protein. The mutant ΔV1V2.9.VK induced a prominent response directed to epitopes effectively bound and neutralized the ΔV1V2 Env virus. This Env variant efficiently neutralized tier 1 virus SF162.This did not result in broad neutralization of neutralization-resistant virus isolates. BG505 SOSIP.664 trimers bind very efficiently to quaternary structure dependent, broadly neutralizing PG9 against the V1V2 domain.
Bontjer2013
(vaccine antigen design, structure)
-
PG9: This review surveyed the Vectored Immuno Prophylaxis (VIP) strategy, which involves passive immunization by viral vector-mediated delivery of genes encoding bnAbs for in vivo expression. Recently published studies in humanized mice and macaques were discussed as well as the pros and cons of VIP towards clinical applications to control HIV endemics.
Yang2014
(immunoprophylaxis, review, antibody gene transfer)
-
PG9: The ability of bNAbs to inhibit the HIV cell entry was tested for b12, VRC01,VRC03, PG9, PG16, PGT121, 2F5, 10E8, 2G12. Among them, PGT121, VRC01, and VRC03 potently inhibited HIV entry into CD4+ T cells of infected individuals whose viremia was suppressed by ART.
Chun2014
(immunotherapy)
-
PG9: Pairwise combinations of 6 NAbs (4E10, 2F5, 2G12, b12, PG9, PG16) were tested for neutralization of pseudoviruses and transmitted/founder viruses. Each of the NAbs tested targets a different region of gp120 or gp41. Some pairwise combinations enhanced neutralization synergistically, suggesting that combinations of NAbs may enhance clinical effectiveness.
Miglietta2014
(neutralization)
-
PG9: The infectious virion (iVirions) capture index (IVCI) of different Abs have been determined. bnAbs captured higher proportions of iVirions compared to total virus particles (rVirions) indicating the capacity, breadth and selectively of bnAbs to capture iVirions. IVCI was additive with a mixture of Abs, providing proof of concept for vaccine-induced effect of improved capacity. bnAb PG9 showed significantly high IVCI and captured 100% of CRF01_A/E infectious virions AE.92TH023 and AE.CM244, as well as subtype B MN virus.
Liu2014
(binding affinity)
-
PG9: Study evaluated 4 gp140 Env protein vaccine immunogens derived from an elite neutralizer donor VC10042, an HIV+ African American male from Vanderbilt cohort. Env immunogens, VC10042.05, VC10042.05RM, VC10042.08 and VC10042.ela, elicited high titers of cross-reactive Abs recognizing V1/V2 regions. PG9 exhibited very weak binding with trimeric VC10042.ela and moderate binding with monomeric form of all 4 immunogens.
Carbonetti2014
(elite controllers and/or long-term non-progressors, vaccine-induced immune responses)
-
PG9: The study compared various factors affecting the accessibility of epitopes for antibodies targeting the V2 integrin (V2i) region, versus the V3 region. CD4 treament of BaL and JRFL pseudoviruses increased their neutralization sensitivity to V3 MAbs, but not to V2i MAbs. Viruses grown in a glycosidase inhibitor were more sensitive to neutralization by V3, but not V2i, MAbs. Increasing the time of virus-MAb interaction increased virus neutralization by some V2i MAbs and all V3 MAbs. The structural dynamics of V2i and V3 epitopes has important effects in neutralization. Some experiments also included V2p antibodies CH58, CH59, and PG9 for comparison.
Upadhyay2014
(glycosylation, neutralization)
-
PG9: A gp140 trimer mosaic construct (MosM) was produced based on M group sequences. MosM bound to CD4 as well as multiple bNAbs, including VRC01, 3BNC117, PGT121, PGT126, PGT145, PG9 and PG16. The immunogenicity of this construct, both alone and mixed together with a clade C Env protein vaccine, suggest a promising approach for improving NAb responses.
Nkolola2014
(vaccine antigen design)
-
PG9: Cross-group neutralization of HIV-1 isolates from groups M, N, O, and P was tested with diverse patient sera and bNAbs PG9, PG16, 4E10, b12, 2F5, 2G12, VRC01, VRC03, and HJ16. The primary isolates displayed a wide spectrum of sensitivity to neutralization by the human sera, with some cross-group neutralization clearly observed. Among the bNAbs, only PG9 and PG16 showed any cross-group neutralization. The group N prototype strain YBF30 was highly sensitive to neutralization by PG9, and the interaction between their key residues was confirmed by molecular modeling. The conservation of the PG9/PG16 epitope within groups M and N suggests its relevance as a vaccine immunogen.
Braibant2013
(neutralization, variant cross-reactivity)
-
PG9: The V2 region where PG9, an anti-V1V2 bNAb binds exists as a beta-strand.
Haynes2013
(review)
-
PG9: PG9 was one of 10 MAbs used to study chronic vs. consensus vs. transmitted/founder (T/F) gp41 Envs for immunogenicity. Consensus Envs were the most potent eliciters of response but could only neutralize tier 1 and some tier 2 viruses. T/F Envs elicited the greatest breadth of NAb response; and chronic Envs elicited the lowest level and narrowest response. This V1V2 conformational loop binding Nab bound well at <10 nM to 3/5 chronic Envs, 2/6 Consensus Envs and 2/7 T/F Envs.
Liao2013c
(antibody interactions, binding affinity)
-
PG9: Design, synthesis and antigenic evaluation of novel cyclic V1V2 glycopeptides carrying defined N-linked glycans, N160 and N156/N173 has been reported in terms of PG9 and PG16 binding and neutralization. A Man5GlcNAc2 glycan at N160 and a sialyted N-glycan are crtical for antigen binding.
Amin2013
(glycosylation)
-
PG9: Binding properties of a synthesized V1V2 glycopeptide immunogen that selectively targets bnAbs' naive B cells is reported. The unmutated common ancestor (UCA) of PG9 showed nanomolar affinity to V1V2 bearing Man5GlcNAc2 glycan units. Binding of PG9 was undetectable however in the absence of the V2 backbone peptide suggesting a very weak binding affinity to oligomannose glycan alone. Disulfide-linked dimer formation was also required for PG9 binding to V1V2.
Alam2013
-
PG9: PG9 in combination with NAbs NH45-46m2 and NIH46-42m7 was able to control viremia as well as to reduce routes to escape of YU-2 HIV-1.
Diskin2013
-
PG9: This study showed that the inability of Env to elicit the production of broadly neutralizing Abs is due to the inability of diverse Env to engage the germ line B cell receptor forms of known bNAbs. PG9 showed binding to 61% of the recombinant Envs tested including 7 out of 17 clade B Envs, 11 of 16 clade C Envs, 6 of 7 clade A Envs and the gp120 form of A/E A244 Env. The predicted germ line version of PG9 did not exhibit any detectable binding against these Envs. Ca2+ influx through the PG9 BCR was also tested as a function of binding affinity.
McGuire2014
(antibody interactions, antibody lineage)
-
PG9: The neutralization profile of 1F7, a human CD4bs mAb, is reported and compared to other bnNAbs. 1F7 exhibited extreme potency against primary HIV-1, but limited breadth across clades. PG9 neutralized 83% of a cross-clade panel of 157 HIV-1 isolates (Fig. S1) while 1F7 neutralized only 20% of the isolates.
Gach2013
(neutralization)
-
PG9: This study reports the development of a new cell-line (A3R5)-based highly sensitive Ab detection assay. This T-lymphoblastoid cell-line stably expreses CCR5 and recognizes CCR5-tropic circulating strains of HIV-1. A3R5 cells showed greater neutralization potency compared to the current cell-line of choice TZM-bl. PG9 was used as a reference Ab in neutralization assay comparing A3R5 and TZM-bl.
McLinden2013
(assay or method development)
-
PG9: A highly conserved mechanism of exposure of ADCC epitopes on Env is reported, showing that binding of Env and CD4 within the same HIV-1 infected cell effectively exposes these epitopes. The mechanism might explain the evolutionary advantage of downregulation of cell surface CD4v by the Vpu and Nef proteins. PG9 was used in CD4 coexpression and competitive binding assay.
Veillette2014
(effector function)
-
PG9: Clade A Env sequence, BG505, was identified to bind to bNAbs representative of most of the known NAb classes. This sequence is the best natural sequence match (73%) to the MRCA sequence from 19 Env sequences derived from PG9 and PG16 MAbs' donor. A point mutation at position L111A of BG505 enabled more efficient production of a stable gp120 monomer, preserving the major neutralization epitopes. The antisera produced by this adjuvanted formulation of gp120 competed with bnAbs from 3 classes of non-overlapping epitopes. PG9 showed very high neutralization titer against BG505 pseudovirus in a competitive binding assay as shown in Table 1. Env sequence from PG9 donor showed potential N glycosylation (PNG) sites at position 160 and 156, suggesting that a substitution at one of these sites is not the primary cause of neutralization resistance to PG9 (Table 4). This emphasizes that the BG505 L111Agp120 immunogen can elicit a robust Ab response to PG9.
Hoffenberg2013
(antibody interactions, glycosylation, neutralization)
-
PG9: High affinity binding of PG9 with a soluble SOSIP.664 gp140 trimer constructed from the Clade A BG505 sequence was demonstrated. This enabled structural and biophysical characterization of the PG9:Env trimer complex. Electron microscopy (EM) and other assays indicate that only a single PG9-Fab binds to the Env trimer. EM reconstruction also demonstrated that PG9 recognized the trimer asymmetrically at its apex via contact with 2 of the 3 gp120 protomers. In addition to N156 and N160 glycan interactions with a scaffolded V1/V2 domain, PG9 also makes secondary interactions with an N160 glycan from an adjacent gp120 protomer in the Ab-trimer complex. A glycan mutation to PG9 caused a >10fold reduction of Fab affinity for the BG505 SOSIP.664 gp 140 trimer reflecting adverse effects on trimer binding and virus neutralization. PG9 recognized glycosylated Env proteins with much higher affinity compared to non-glycosylated ones.
Julien2013
(antibody interactions, glycosylation, structure)
-
PG9: To focus immune responses to sites of NAb vulnerability while avoiding immune-evasion by the rest of Env, MPER, V1/V2, and V3 glycan sites were transplanted onto algorithm-identified acceptor scaffolds (proteins with a backbone geometry that recapitulates the antigenicity of the transplanted site). The V1/V2-transplant was not successful in eliciting a robust PG9 response.
Zhou2014
(vaccine antigen design)
-
PG9: This is a review of identified bNAbs, including the ontogeny of B cells that give rise to these antibodies. Breadth and magnitude of neutralization, unique features and similar bNAbs are listed. PG9 is a V1/V2-directed Ab, with breadth 70%, IC50 0.31 μg per ml, and its unique feature is its extended CDR H3, which is often tyrosine-sulfated. Similar MAbs include PG16 and CH01-04.
Kwong2013
(review)
-
PG9: 8 bNAbs (PGT151 family) were isolated from an elite neutralizer. The new bNAbs bind a previously unknown glycan-dependent epitope on the prefusion conformation of gp41. These MAbs are specific for the cleaved Env trimer and do not recognize uncleaved Env trimer. PGT151 family Abs showed 1 log higher neutralization potency than PG9.
Falkowska2014
-
PG9: A statistical model selection method was used to identify a global panel of 12 reference Env clones among 219 Env-pseudotyped viruses that represent the spectrum of neutralizing activity seen with sera from 205 chronically HIV-1-infected individuals. This small final panel was also highly sensitive for detection of many of the known bNAbs, including this one. The small panel of 12 Env clones should facilitate assessments of vacine-elicited NAbs.
Decamp2014
(assay or method development)
-
PG9: The conserved central region of gp120 V2 contains sulfated tyrosines (Tys173 and Tys177) that in the CD4-unbound prefusion state mediate intramolecular interaction between V2 and the conserved base of the third variable loop (V3), functionally mimicking sulfated tyrosines in CCR5 and anti-coreceptor-binding-site antibodies such as 412d. Enhancement of tyrosine sulfation decreased binding and neutralization of HIV-1 BaL by monomeric sCD4, 412d, and anti-V3 antibodies and increased recognition by the trimer-preferring antibodies PG9, PG16, CH01, and PGT145. Conversely, inhibition of tyrosine sulfation increased sensitivity to soluble CD4, 412d, and anti-V3 antibodies and diminished recognition by trimer-preferring antibodies. These results identify the sulfotyrosine-mediated V2-V3 interaction as a critical constraint that stabilizes the native HIV-1 envelope trimer and modulates its sensitivity to neutralization.
Cimbro2014
-
PG9:X-ray crystallography, surface plasmon resonance and pseudovirus neutralization were used to characterize a heavy chain only llama antibody, named JM4. The full-length IgG2b version of JM4 neutralizes over 95% of circulating HIV-1 isolates. JM4 targets a hybrid epitope on gp120 that combines elements from both the CD4 binding region and the coreceptor binding surface. JM4 IgG2b was able to potently neutralize the HIV-1 isolates that were resistant to PG9.
Acharya2013
(neutralization)
-
PG9: 12 somatically related nAbs were isolated from donor CAP256. All nAbs of CAP256-VRC26 lineage had long CDRH3 regions necessary to penetrate the glycan shield and engage the V1V2 epitope. Both CAP256-VRC26 Abs and PG9 class nAbs showed similarity in recognizing the trimeric V1V2 cap. Unlike PG9, the CAP256-VRC26 Abs were only partially and variably sensitive to loss of glycans at N160 and N156.
Doria-Rose2014
(glycosylation)
-
PG9: This is a review of a satellite symposium at the AIDS Vaccine 2012 conference, focusing on antibody gene transfer. Phil Johnson presented results comparing an immunoadhesin form of the antibody PG9 with the native IgG architecture in which he found that the native IgG architecture had a neutralization potency tenfold greater than that of the immunoadhesin, suggesting that natural antibody architectures are more preferable for further clinical development.
Balazs2013
(immunoprophylaxis)
-
PG9: A computational method to predict Ab epitopes at the residue level, based on structure and neutralization panels of diverse viral strains has been described. This method was evaluated using 19 Env-Abs, including PG9, against 181 diverse HIV-1 strains with available Ab-Ag complex structures.
Chuang2013
(computational prediction)
-
PG9: This study reports the glycan binding specificities and atomic level details of PG16 epitope and somatic mechanisms of clonal antibody diversification. Three PG16 specific residues Arg94LC, Ser95LC and His95LC (RSH) are found to be critical for sialic acid binding on complex glycan. RSH residues were introduced into PG9 to produce a chimeric antibody with enhanced neutralization. The co-crystal structure of PG9 bound to V1-V2 is discussed and compared to PG16 and PG9-PG16-RSH chimeric Ab based on its ability to recognize a combination of N-linked glycans and envelope polypeptide. PG9, PG16, and PG9-PG16-RSH were negative in assays of autoreactivity.
Pancera2013
(antibody binding site, autoantibody or autoimmunity, glycosylation, structure, chimeric antibody)
-
PG9: Four V2 MAbs CH58, CH59, HG107 and HG120 were isolated from RV144 Thai HIV-1 vaccinees. These MAbs recognized residue 169, neutralized laboratory HIV-1 (tier 1 strains) and mediated ADCC. PG9 was used in the study as a V1-V2 bnAb control to study the binding of the new mAb isolates. While PG9, PG16 and CH01 binding was abrogated by N160K and N156Q mutations and also by native glycosylation, the binding of CH58 and CH59 was not affected. Crystal structures revealed that CH58, CH59, and PG9 recognize overlapping V2 epitopes in dramatically different conformations, ranging from helical to beta strands.
Liao2013b
(effector function, structure)
-
PG9: The complexity of the epitopes recognized by ADCC responses in HIV-1 infected individuals and candidate vaccine recipients is discussed in this review. PG9 is discussed as the V2 region-targeting, anti-gp120 BNAb exhibiting ADCC activity and having a discontinuous epitope. RV144 vaccine induced mAbs CH58 and CH59 also bind to the same region of PG9, but do not display preferential binding to gp120 and don't bind to glycans in position 156 and 160.
Pollara2013
(effector function, review)
-
PG9: "Neutralization fingerprints" for 30 neutralizing antibodies were determined using a panel of 34 diverse HIV-1 strains. 10 antibody clusters were defined: VRC01-like, PG9-like, PGT128-like, 2F5-like, 10E8-like and separate clusters for b12, CD4, 2G12, HJ16, 8ANC195.
Georgiev2013
(neutralization)
-
PG9: ADCC mediated by CD4i mAbs (or anti-CD4i-epitope mAbs) was studied using a panel of 41 novel mAbs. Three epitope clusters were classified, depending on cross-blocking in ELISA by different mAbs: Cluster A - in the gp120 face, cross-blocking by mAbs A32 and/or C11; Cluster B - in the region proximal to CoRBS (co-receptor binding site) involving V1V2 domain, cross-blocking by E51-M9; Cluster C - CoRBS, cross-blocking by 17b and/or 19e. The ADCC half-maximal effective concentrations of the Cluster A and B mAbs were generally 0.5-1 log lower than those of the Cluster C mAbs, and none of the Cluster A or B mAbs could neutralize HIV-1. Cluster A's A32- and C11-blockable mAbs were suggested to recognize conformational epitopes within the inner domain of gp120 that involve the C1 region. Neutralization potency and breadth were also assessed for these mAbs. No correlation was found between ADCC and neutralization Abs' action or functional responses.
Guan2013
(antibody interactions, effector function)
-
PG9: This study describes an ˜11 Angstrom cryo-EM structure of the trimeric HIV-1 Env precursor in its unliganded state. The three gp120 and gp41 subunits form a cage like structure with an interior void surrounding the trimer axis which restricts Ab access. crystal structure of PG9 was referred in the context of gp120 V1/V2 binding domains.
Mao2012
(structure)
-
PG9: Emergence and evolution of the earliest cross-reactive neutralizing antibody responses were studied in B clade-infected individual, Two distinct epitopes on Env were targeted. First specificity appeared at 3 years post infection and targeted the CD4-binding site. Second specificity appeared a year later. It was due to PG9-like antibodies, which were able to neutralize those viruses not susceptible to the anti-CD4-BS antibodies in AC053.
Mikell2012
(neutralization, rate of progression, polyclonal antibodies)
-
PG9: Neutralization profiles of 7 bnAbs were analyzed against 45 Envs (A, C, D clades), obtained soon after infection (median 59 days). The transmitted variants have distinct characteristics compared to variants from chronic patients, such as shorter variable loops and fewer potential N-linked glycosylation sites (PNGS). PG9 neutralized 49% of these viruses.
Goo2012
(neutralization, rate of progression)
-
PG9: A computational tool (Antibody Database) identifying Env residues affecting antibody activity was developed. As input, the tool incorporates antibody neutralization data from large published pseudovirus panels, corresponding viral sequence data and available structural information. The model consists of a set of rules that provide an estimated IC50 based on Env sequence data, and important residues are found by minimizing the difference between logarithms of actual and estimated IC50. The program was validated by analysis of MAb 8ANC195, which had unknown specificity. Predicted critical N-glycosylation for 8ANC195 were confirmed in vitro and in humanized mice. The key associated residues for each MAb are summarized in the Table 1 of the paper and also in the Neutralizing Antibody Contexts & Features tool at Los Alamos Immunology Database.
West2013
(glycosylation, computational prediction)
-
PG9: Identification of broadly neutralizing antibodies, their epitopes on the HIV-1 spike, the molecular basis for their remarkable breadth, and the B cell ontogenies of their generation and maturation are reviewed. Ontogeny and structure-based classification is presented, based on MAb binding site, type (structural mode of recognition), class (related ontogenies in separate donors) and family (clonal lineage). This MAb's classification: gp120 V1V2 site, penetrating CDR H3 binds two glycans and strand, PG9 class, PG9 family.
Kwong2012
(review, structure, broad neutralizer)
-
PG9: This review discusses the new research developments in bnAbs for HIV-1, Influenza, HCV. Models of the HIV-1 Env spike and of Influenza visrus spike with select bnAbs bound are shown.
Burton2012
(review)
-
PG9: This review discusses how analysis of infection and vaccine candidate-induced antibodies and their genes may guide vaccine design. This MAb is listed as V1/V2 conformational epitope bnAb, isolated after 2009 by neutralization screening of cultured, unselected IgG+ memory B cells.
Bonsignori2012b
(vaccine antigen design, vaccine-induced immune responses, review)
-
PG9: Antigenic properties of 2 biochemically stable and homogeneous gp140 trimers (A clade 92UG037 and C clade CZA97012) were compared with the corresponding gp120 monomers derived from the same percursor sequences. The trimers had nearly all the antigenic properties expected for native viral spikes and were markedly different from monomeric gp120. Both trimers, but not monomers, bound to PG9 and PG16.
Kovacs2012
(antibody binding site, neutralization, binding affinity)
-
PG9: Glycan shield of HIV Env protein helps to escape the Ab recognition. Several of the PGT BnAbs interact directly with the HIV glycan coat. Crystal structures of Fabs PGT127 and PGT128 showed that the high neutralizing potency was mediated by cross-linking Env trimers on the viral surface. PGT128 was compared and referred as an order of magnitude more potent than PG9.
Pejchal2011
(glycosylation, structure, broad neutralizer)
-
PG9: PG9 and PG9-like V1V2-directed MAbs, that require an N-linked glycan at Env 160, were analyzed for gain-of-function mutations. 21 PG9-resistant HIV-1 isolates were analyzed by mutagenesis and neutralization assays. E to K mutations at positions 168, 169, 171 led to the most dramatic improvements on sensitivity to these MAbs (PG9, PG16, CH01, CH04, PGT141, PGT145).
Doria-RoseNA2012
(escape)
-
PG9: The study used the swarm of quasispecies representing Env protein variants to identify mutants conferring sensitivity and resistance to BnAbs. Libraries of Env proteins were cloned and in vitro mutagenesis was used to identify the specific AA responsible for altered neutralization/resistance, which appeared to be associated with conformational changes and exposed epitopes in different regions of gp160. The result showed that sequences in gp41, the CD4bs, and V2 domain act as global regulator of neutralization sensitivity. PG9 was used as BnAb to screen Env clones. wtR clone was weakly sensitive to PG9.
ORourke2012
(neutralization)
-
PG9: Glycan Asn332-targeting broadly cross-neutralizing (BCN) antibodies were studied in 2 C-clade infected women. The ASn332 glycan was absent on infecting virus, but the BCN epitope with Asn332 evolved within 6 months though immune escape from earlier antibodies. Plasma from the subject CAP177 neutralized 88% of a large multi-subtype panel of 225 heterologous viruses, whereas CAP 314 neutralized 46% of 41 heterologous viruses but failed to neutralize viruses that lack glycan at 332. PG9 was referred to have second BCN Ab epitopes at AA 156 and 160 in addition to 332.
Moore2012
(neutralization, escape)
-
PG9: Crystal structures of unliganded core gp120 from HIV-1 clade B, C, and E were determined to understand the mechanism of CD4 binding capacity of unliganded HIV-1. The results suggest that the CD4 bound conformation represents "a ground state" for the gp120 core with variable loop. PG9 was used as a control to prove whether the purified and crystallized gp120 is in the CD4 bound conformational state or not.
Kwon2012
(structure)
-
PG9: Vaccination efficacy of RV144 is described. The authors proposed that RV144 induced antibodies against Env V1/V2. The relationship between vaccine status and V1/V2 sequence have been characterized. The estimated cumulative HIV-1 incidence curve in the vaccine and placebo groups showed immunogenicity for K169 and 1181X genotypes and no immunogenicity for the opposite residues. PG9 was discussed as the quaternary-structure-preferring (QSP) antibody and mutations at positions 169 and 181 were associated with significant alteration in neutralization.
Rolland2012
(vaccine-induced immune responses)
-
PG9: The use of computationally derived B cell clonal lineages as templates for HIV-1 immunogen design is discussed. PG9 has been discussed in terms of immunogenic and functional characteristics of representative HIV-1 BnAbs and their reactions to antigens.
Haynes2012
(antibody interactions, memory cells, vaccine antigen design, review, antibody polyreactivity, broad neutralizer)
-
PG9: Polyclonal B cell responses to conserved neutralization epitopes are reported. Cross-reactive plasma samples were identified and evaluated from 308 subjects tested. PG9 was used as a control mAb in the comprehensive set of assays performed. C1-0763 targeted a region similar to PG9 and PG16 recognizing a V1/V2 loop dependent epitope.
Tomaras2011
(neutralization, polyclonal antibodies)
-
PG9: Several antibodies including 10-1074 were isolated from B-cell clone encoding PGT121, from a clade A-infected African donor using YU-2 gp140 trimers as bait. These antibodies were segregated into PGT121-like (PGT121-123 and 9 members) and 10-1074-like (20 members) groups distinguished by sequence, binding affinity, carbohydrate recognition, neutralizing activity, the V3 loop binding and the role of glycans in epitope formation. PG9 was used as a control. Detail information on the binding and neutralization assays are described in the figures S2-S11.
Mouquet2012a
(glycosylation, neutralization, binding affinity)
-
PG9: YU2 gp140 bait was used to characterize 189 new MAbs representing 51 independent IgG memory B cell clones from 3 clade A or B HIV infected patients exhibiting broad neutralizing activity. PG9 was referred to in discussing the efficiency of YU-2 gp140 trimer as a bait for Ab capture.
Mouquet2011
(neutralization)
-
PG9: The rational design of vaccines to elicit broadly neutralizing antibodies to HIV-1 is discussed in relation to understanding of vaccine recognition sites, the structural basis of interaction with HIV-1 env and vaccine developmental pathways. Role of PG9 has been discussed in terms of humoral immune response during HIV1 infection. The vulnerability sites on the viral spike shows quaternary structural constraints, and maps to the second and third variable regions of gp120 (variable loops V2 and V3). PG9 recognizes these regions and neutralizes 70%–80% of current circulating isolates.
Kwong2011
(antibody binding site, neutralization, vaccine antigen design, review)
-
PG9: A panel of glycan deletion mutants was created by point mutation into HIV gp160, showing that glycans are important targets on HIV-1 glycoproteins for broad neutralizing responses in vivo. Enrichment of high mannose N-linked glycan(HM-glycan) of HIV-1 glycoprotein enhanced neutralizing activity of sera from 8/9 patients. PG9 was used as a control to compare the neutralizing activity of patients' sera.
Lavine2012
(neutralization)
-
PG9: Ab-driven escape and Ab role in infection control and prevention are reviewed. Main focus is on NAbs, but Ab acting through effector mechanisms are also discussed. PG9 is discussed in the context of developing broadly cross-neutralizing antibodies.
Overbaugh2012
(escape, review)
-
PG9: Neutralization activity was compared against MAb 10E8 and other broad and potent neutralizers in a 181-isolate Env-pseudovirus panel. PG9 neutralized 78% of viruses at IC50<50 μg/ml and 65% of viruses at IC50<1 μg/ml, compared with 98% and 72% of MAb 10E8, respectively.
Huang2012a
(neutralization)
-
PG9: Antigenic properties of undigested VLPs and endo H-digested WT trimer VLPs were compared. Binding to E168K+ N189A WT VLPs was dramatic compared to the parent WT VLPs, uncleaved VLPs. There was no significant correlation between E168K+N189A WT VLP binding and PG9 neutralization, while trimer VLP ELISA binding and neutralization exhibited a significant correlation. BN-PAGE shifts using digested E168K + N189A WT trimer VLPs exhibited prominence compared to WT VLPs.
Tong2012
(neutralization, binding affinity)
-
PG9: Broadly neutralizing antibodies circulating in plasma were studied by affinity chromatography and isoelectric focusing. The Abs fell in 2 groups. One group consisted of antibodies with restricted neutralization breadth that had neutral isoelectric points. These Abs bound to envelope monomers and trimers versus core antigens from which variable loops and other domains have been deleted. Another minor group consisted of broadly neutralizing antibodies consistently distinguished by more basic isoelectric points and specificity for epitopes shared by monomeric gp120, gp120 core, or CD4-induced structures. The pI values estimated for neutralizing plasma IgGs were compared to those of human anti-gp120 MAbs, including 5 bnMAbs (PG9, PG16, VRC01, b12, and 2G12), 2 narrowly neutralizing MAbs (17b and E51), and 3 nonneutralizing MAbs (A32, C11, and 19e). bnMAbs PG9 and PG16 exhibited more-neutral pIs (around 7.8), matching the more-neutral end of the plasma-derived fraction series, showing broadly neutralizing, but not most potent activity.
Sajadi2012
(polyclonal antibodies)
-
PG9: Sensitivity to neutralization was studied in 107 full-length Env molecular clones from multiple risk groups in various locations in China. Neutralization sensitivity to plasma pools and bNAbs was not correlated. PG9 neutralized 81% (25/31) and PG16 neutralized 71% (22/31) of the viruses tested. Viruses insensitive to PG9 were all equally insensitive to PG16 but not the other way around, suggesting that PG9 can tolerate more viral glycoprotein amino acid substitutions than PG16.
Shang2011
(glycosylation, neutralization, subtype comparisons)
-
PG9: The sensitivity to PG9 and PG16 of pseudotyped viruses was analysed carrying envelope glycoproteins from the viral quasispecies of three HIV-1 clade CRF01_AE-infected patients. It was confirmed that an acidic residue or a basic residue at position 168 in the V2 loop is a key element determining the sensitivity to PG9 and PG16. In addition, evidence is provided of the involvement of a conserved residue at position 215 of the C2 region in the PG9/PG16 epitopes. Sensitivity to PG9 in 10 Env-pseudotyped viruses was analyzed. Five clones from case 0377 presented a broad and continuous range of sensitivity to PG9. A broader range of sensitivity was observed in case 0978, clone 0978-M3 being resistant to PG9 whereas two other clones, 0978-M1 and 0978-M2, were highly sensitive. Similarly, two clones from case 0858 displayed peculiar patterns of neutralization: clone 0858-M1 was sensitive to neutralization by PG9 only whereas clone 0858-M2 was resistant to PG9. These results showed the broad heterogeneity in sensitivity to PG9 of closely genetically related envelope glycoproteins derived from single viral quasispecies. Clone 0978-M3 from case 0978 was resistant to PG9, whereas clones 0978-M1/M2 were highly sensitive to PG9. 0978-M3 E168K resulted in a high sensitivity to PG9. In contrast, 0978-M2 K168E conferred resistance to PG9. 0858-M2 M215I conferred sensitivity to PG9, whereas the mutant 0858-M2 M475I remained highly resistant to PG9. I215M diminished the sensitivity of all clones to PG9, except that of clone 5008CL2 for PG9.
Thenin2012a
(neutralization)
-
PG9: The interaction of CD4bs-binding MAbs (VRC01, VRC-PG04) and V1V2 glycan-dependent MAbs (PG9, PG16) was analyzed. MAb binding and neutralization studies showed that these two Env targets to not cross-compete and that their combination can mediate additive neutralization. The combination of MAbs VRC01 and PG9 provides a predicted coverage of 97% of 208 isolates at IC50 < 50 μg/ml and of 91% at IC50 < 50 μg/ml. In contrast, the combination of PG9 and PG16 (or the combination of VRC01 and VRC-PG04) was only marginally better than either MAb alone.
Doria-Rose2012
(antibody interactions)
-
PG9: The study showed that alteration between a rare lysine K and a common N-linked glycan at position 160 of HIV-1 gp120 is primarily responsible for toggling between 2909 and PG16/PG9 neutralization sensitivity. These neutralization profiles were mutually exclusive (160K for MAb 2909, 160N for PG16/PG9); there was no case of a virus that was sensitive to both 2909 and PG16/PG9 neutralization. Several more positions were studied: both the PG and 2909 MAbs do not require an asparagine at position 156 for neutralization, both the PG and 2909 antibodies tolerate amino acid variation at position 165, and neither the PG nor the 2909 MAb could tolerate a glutamic acid at position 168.
Wu2011a
(antibody binding site, escape)
-
PG9: An Env obtained from a slow progressing patient was resistant to PG9 and PG16 mAbs. Based on assays of neutralization and glycosylation, it is suggested that the overall neutralization sensitivity of an Env is the outcome of characteristic molecular features of the V2 loop. Neutralization by PG9/16 is balanced by the glycans, net positive charge in the β sheet C region of the V2 loop, and possibly the length of the V2 loop.
Ringe2012
(glycosylation, neutralization)
-
PG9: The neutralization activities of IA versus IgG and Fab versions of three broadly neutralizing antibodies: PG9, PG16, and VRC01 was compared to more fully understand the potential trade-offs in vector and construct design. The potential to combine VCR01 and PG9/PG16 activities to produce a single reagent with two gp120 specificities was also explored. In an Env-pseudotyped HIV-1 neutralization assay against a panel of 30 strains, PG9 neutralized 22 strains in IgG form, 18 stains in Fab form, 20 strains in IA form and 10 strains in scFv form. It was found that the PG9, PG16, and VRC01 IAs were severalfold less potent than their IgG forms.
West2012
(neutralization)
-
PG9: The biological properties of 17 Env-pseudotyped viruses derived from variants of mother–infant pairs infected by HIV-1 strains of the CRF01_AE clade were compared, in order to explore their association with the restrictive transmission of the virus. Maternal clones issued from MIPs (mother-infant pairs) 0377, 0978 and 1021 displayed a broad and continuous range of sensitivity to both PG9 and PG16 whereas all infant clones were highly sensitive to both mAbs PG9 and PG16. When the four MIPs were considered in aggregate, infant clones were significantly more sensitive to PG9 and PG16 compared to maternal clones.
Thenin2012
(neutralization, mother-to-infant transmission)
-
PG9: gp120 was cyclically permuted and new N- and C-termini were created within the V1, V3, and V4 loop regions to reduce the length of the linker joining gp120 and M9. Addition of trimerization domains at the V1 loop of cyclic permutants of gp120 resulted in the formation of predominantly trimeric species, which bound CD4 and neutralizing antibodies b12, PG9, and PG16 with higher affinity.
Saha2012
(binding affinity)
-
PG9: The role of envelope expression context and producer cell type was characterized for nine novel replication-competent chimeric HIV-1 isolates from the dominant circulating HIV-1 subtypes in Africa, where most new HIV-1 infections are occurring. Pseudoviruses generated in 293T cells were the most sensitive to antibody neutralization. There was no difference in the neutralization sensitivity of PBMC versus 293T-derived viruses using the MAb PG9.
Provine2012
(neutralization)
-
PG9: Phenotypic activities of a single transmitted/founder (T/F) virus from 24 acute individuals were compared to that of 17 viruses from chronics. There was a trend towards enhanced sensitivity to neutralization by PG9 of T/F Envs compared to chronic Envs.
Wilen2011
(neutralization)
-
PG9: HIV-1 adaptation to neutralization by MAbs VRC01, PG9, PG16 was studied using HIV-1 variants from historic (1985-1989) and contemporary (2003-2006) seroconverters. PG9 neutralized 52% of contemporary viruses at IC50 < 1 μ g/ml. The median IC50s of PG9 for viruses from historical and contemporary seroconverters were not significantly different. There was no clear correlation between the sensitivity to PG9 and presence or absence of certain amino acids, but more mutations were observed in viruses from contemporary seroconverters than from historical ones, and the absence of a potential N-linked glycosylation site at position 160 of V2 coincided with resistance to PG9.
Euler2011
(glycosylation, neutralization, escape)
-
PG9: Using U87 target cells, PGV04 neutralized 88% of 162 viruses, with IC50<50 μm/mg, with U87 target cells compared to 75% neutralized by PG9. The potency of neutralization was comparable. On the 97-virus panel, using TZM-bl target cells, the breadth of neutralization was similar, but PGV04 had increased potency. The neutralization potency of PG9, PG16, VRC01 and PGV04 was approximately 10-fold greater than that of MAbs b12, 2G12, 2F5 and 4E10. Alanine substitutions D279A, I420A and I423A abrogated PGV04 neutralization, but varied in their effects on VRC01, CD4-IgG and b12.
Falkowska2012
(neutralization, broad neutralizer)
-
PG9: Neutralizing antibody repertoires of 4 HIV-infected donors with remarkably broad and potent neutralizing responses were probed. 17 new monoclonal antibodies that neutralize broadly across clades were rescued. All MAbs exhibited broad cross-clade neutralizing activity, but several showed exceptional potency. Although PG9 neutralized 77% of 162 isolates at IC50<50 μg/ml, it was almost 10-fold less potent than several new antibodies PGT 121-123 and 125-128, for which the median antibody concentration required to inhibit HIV activity by 50% or 90% (IC50 and IC90 values) was almost 10-fold lower than that of PG9, VRC01 and PGV04.
Walker2011
(neutralization, broad neutralizer)
-
PG9: Atomic-level structure of V1/V2 in complex with PG9 is reported. Instead of being confounded by the N-linked glycan that shields most of gp120 from immune recognition, PG9 uses N-linked glycan for binding through a mechanism shared by a number of antibodies capable of effective HIV neutralization. The structure shows that the antibody recognizes glycopeptide conjugates and avoids diversity in V1/V2 by making sequence-independent interactions, such as hydrogen bonds. The structure of PG9 is consistent with published mutational data: some residues such as Phe 176 are critical because they form part of the hydrophobic core on the concave face of the V1/V2 sheet. Others form direct contacts: for example, the tyrosine sulphate at residue 100H of PG9 interacts with residue 168 when it is an Arg (strain ZM109) or Lys (strain CAP45), but would be repelled by a Glu (as in strain JR-FL); JR-FL is resistant to neutralization by PG9, but becomes sensitive if Glu 168 is changed to Lys10. V1/V2–PG9 interaction observed in the scaffolded V1/V2–PG9 crystal structures encompasses much of the PG9/PG16 epitope, and the structural integrity of this epitope is sensitive to appropriate assembly of the viral spike. With both CAP45 and ZM109 strains of gp120, the V1/V2 site recognized by PG9 consists primarily of two glycans and a strand. Minor interaction with strand B and with the B–C connecting loop complete the epitope, with the entire PG9-recognized surface of V1/V2 contained within the B–C hairpin.
McLellan2011
(antibody binding site, structure)
-
PG9: CDR H3 domains derived from 4 anti-HIV mAbs, PG16, PG9, b12, E51, and anti-influenza MAb AVF were genetically linked to glycosil-phosphatidylinositol (GPI) attachment signal of decay-accelerating factor (DAF) to determine whether the exceptionally long and unique structure of the CDR H3 subdomain of PG16 is sufficient for epitope recognition and neutralization. Similar degrees of cell surface expression of CDR H3(PG9)/hinge/His tag/DAFs (GPI-CDR H3(PG9)) was observed compared with those of the other GPI-CDR H3 constructs (PG16, AVF, and E51). GPI-CDR H3(PG9) exhibited the same degree of inhibition against 5 representative HIV-1 pseudotypes as that of GPI-CDR H3(PG16 and E51).
Liu2011
(neutralization, variant cross-reactivity, structure)
-
PG9: One Env clone (4–2.J45) obtained from a recently infected Indian patient (NARI-IVC4) had exceptional neutralization sensitivity compared to other Envs obtained at the same time point from the same patient. 4–2.J45 Env expressing M424 showed relative resistance to PG9 over 4–2.J45 expressing I424, wherein comparable sensitivities were found of other Envs to PG9 except YU2, which showed approximately 8 fold increase in neutralization sensitivity to PG9. The indistinctness in PG9/PG16 sensitivities of 4–2.J45 and YU2 Envs expressing M424 was possibly due to some compensatory and conformational changes elsewhere within Env.
Ringe2011
(neutralization)
-
PG9: Several soluble gp140 Env proteins recognized by PG9 and PG16 were identified, and the effect of Env trimerization, the requirement for specific amino acids at position 160 within the V2 loop, and the importance of proper gp120-gp41 cleavage for MAb binding to soluble gp140s were investigated along with whether and how the kinetics of PG9 and PG16 binding to soluble gp140 correlates with the neutralizing potencies of these MAbs. It is reported that the presence of the extracellular part of gp41 on certain gp140 constructs improves the recognition of the PG9 epitope on the gp120 subunit and the trimerization of soluble gp140 may lead to the partial occlusion of the PG9 epitope. PG9 most efficiently recognized modified SF162 Env, SF162K160N of the small number of soluble gp140 Envs tested. The absence of SF162 neutralization by PG9 is the presence of a lysine at position 160 instead of an asparagine. PG16 recognized a smaller number of gp140s tested here than PG9. It is suggested that any structural differences between the virion-associated Env form and the soluble gp140 form have a greater impact on the PG16 epitope than on the PG9 epitope.
Davenport2011
(antibody binding site, neutralization, binding affinity, structure)
-
PG9: The characteristics of HIV-1-specific NAbs were evaluated in 100 breast-fed infants of HIV-1-positive mothers who were HIV-1 negative at birth and they were monitored until age 2. A panel of eight viruses that included variants representative of those in the study region as well as more diverse strains was used to determine the breadth of the infant NAbs. PG9 had low neutralization potency for 2 (QD435.100 M.ENV.A4 and THRO4156.18) out of 8 pseudoviruses in the panel but high for the rest of them. For maternal variants, PG9 had low neutralization potency for 3 (MF535.B1, MJ613.A2 and MK184.E4) out of 12 variants and high for the rest of them.
Lynch2011
(neutralization, variant cross-reactivity, mother-to-infant transmission)
-
PG9: CAP256, an HIV-1 subtype C-infected (and subsequently superinfected) participant enrolled in the CAPRISA Acute Infection cohort was studied. A subset of mutants were tested for neutralization by PG9/PG16 along with neutralization of ConC by CAP256 plasma nAb. The epitope recognized by CAP256 is distinct from but overlaps that of PG9/PG16.Like CAP256 plasma, both PG9 and PG16 were heavily dependent on K169 and somewhat dependent on K171. A V2 mutation (N160A) had a profound affect on PG9 and PG16 but a more moderate affect on CAP256. The adjacent D167N residue also impacted CAP256 neutralization but not PG9/PG16, and a K168A mutation reduced CAP256 neutralization but in fact enhanced the neutralization of ConC by PG9/16. Both PG9/16 and CAP256, in the context of the ConC backbone, were slightly affected by mutations in the V3 loop (I305, I309, and F317) with mild effect on neutralization sensitivity. The I307A mutation affected both PG9/PG16 slightly but had no discernible effect on CAP256 neutralization. Some similarities between CAP256 and PG9/16 neutralization along with significant differences suggest that the epitopes recognized by these Abs overlapped but were not identical.
Moore2011
(neutralization)
-
PG9: The impact of specific changes at distal sites on antibody binding and neutralization was examined on Q461 variants. The changes at position 675 in conjunction with Thr to Ala at position 569 resulted in a dramatic increase in the neutralization sensitivity to some gp41 and gp120 MAbs and plasma but had less effect on the more potent MAb VRC01. There was an increase in VRC01 neutralization sensitivity to viruses with both mutations with intermediate effect for the individual mutants. There was some detectable PG9 neutralization of the variant bearing the T569A mutation alone but PG9 neutralization was not achieved with a change at position 675 only.
Lovelace2011
(antibody binding site, neutralization, variant cross-reactivity)
-
PG9: This review discusses current understanding of Env neutralization by antibodies in relation to epitope exposure and how this insight might benefit vaccine design strategies. This MAb is in the list of current MAbs with notable cross-neutralizing activity.
Pantophlet2010
(neutralization, variant cross-reactivity, review)
-
PG9: This review outlines the general structure of the gp160 viral envelope, the dynamics of viral entry, the evolution of humoral response, the mechanisms of viral escape and the characterization of broadly neutralizing Abs. It is noted that this MAb shows a significant breadth of neutralization across all clades and extraordinary potency.
Gonzalez2010
(neutralization, variant cross-reactivity, escape, review)
-
PG9: This review discusses recent rational structure-based approaches in HIV vaccine design that helped in understanding the link between Env antigenicity and immunogenicity. PG9 was isolated from a clade A infected donor using a high-throughput functional screening approach. This MAb was mentioned in the context of immunogens based on the epitopes recognized by bNAbs.
Walker2010a
(neutralization, review)
-
PG9: This review discusses the types of B-cell responses desired by HIV-1 vaccines and various methods used for eliciting HIV-1 inhibitory antibodies that include induction and characterization of vaccine-induces B-cell responses. PG9 was mentioned among new MAbs generated by isolating single Env-specific B cells by either single cell sorting by flow cytometry or from memory B-cell cultures coupled with high-throughput neutralization screening assays of B-cell supernatants. PG9 recognizes conserved regions of the variable loops in gp120 and is potent and broadly reactive against approximately 73-79% of HIV-1 strains.
Tomaras2010
(review)
-
PG9: This review discusses strategies for design of neutralizing antibody-based vaccines against HIV-1 and recent major advances in the field regarding isolation of potent broadly neutralizing Abs.
Sattentau2010
(review)
-
PG9: This review focuses on recent vaccine design efforts and investigation of broadly neutralizing Abs and their epitopes to aid in the improvement of immunogen design. NAb epitopes, NAbs response to HIV-1, isolation of novel mAbs, and vaccine-elicited NAb responses in human clinical trials are discussed in this review.
Mascola2010
(review)
-
PG9: Unlike the MPER MAbs tested, PG9 did not show any Env-independent virus capture in the conventional or in the modified version of the virus capture assay.
Leaman2010
-
PG9: Some of the key challenges for the development of an Ab-based HIV vaccine are discussed, such as challenges in identification of epitopes recognized by broadly neutralizing epitopes, the impact of biological mechanisms in addition to Ab neutralization, and the poor persistence of anti-Env Ab responses in the absence of continuous antigenic stimulation.
Lewis2010
(review)
-
PG9: The role of HIV-1 envelope spike density on the virion and the effect it has on MAb avidity, and neutralization potencies of MAbs presented as different isotypes, are reviewed. Engineering approaches and design of immunogens able to elicit intra-spike cross-linking Abs are discussed.
Klein2010
(review)
-
PG9: Novel techniques for generation of broadly neutralizing Abs and how these Ab can aid in development of an effective vaccine are discussed.
Joyce2010
(review)
-
PG9: The review describes several different methods that have been used to isolate and characterize HIV MAbs within the human Ab repertoire. Relative advantages and limitations of methods such as EBV transformation, human hybridoma, non-immortalized B cell culture, combinatorial libraries from B cells and clonal sorting are discussed.
Hammond2010
(review)
-
PG9: This review summarizes novel techniques recently developed for isolation of broadly neutralizing monoclonal Abs from HIV-infected donors. Future challenges and importance of these techniques for development of HIV vaccines is also discussed.
Burton2010
(review)
-
PG9: PG9 epitope structure is reviewed. This review also summarizes data on the evolution of HIV neutralizing Abs, principles of Env immunogen design to elicit broadly neutralizing Abs, and future critical areas of research for development of an Ab-based HIV vaccine.
Hoxie2010
(vaccine antigen design, review)
-
PG9: Novel methods for generation of broadly neutralizing Abs, such as PG9 and PG16 are reviewed. This review also summarizes PG9 and PG16 MAbs, and their similarity to 2909 MAb.
Kwong2009
(review)
-
PG9: Removal of N-linked glycosylation sites was shown to generally lead to a reduction in neutralization sensitivity to PG9, however, the position of the N-linked glycosylation site removed and the magnitude of the effect was isolate dependent. Loss of glycosylation sites in the V1, V2 and V3 loops had greatest effect on reduced neutralization sensitivity. Removal of the N160 glycan was the only substitution that universally eliminated sensitivity to neutralization by PG9. Binding of PG9 to Env transfected cells and to gp120 was not competed by monosaccharides indicating that PG9 sensitivity to glycosylation was due to the effect of glycans on gp120 conformation and PG9 epitope accessibility.
Doores2010
(antibody binding site, glycosylation, neutralization, binding affinity)
-
PG9: The CDR H3 region was shown critical for neutralization activity of the Ab. Affinity maturation of PG9 correlated with Ab neutralization breadth, as light chain V-gene reversion produced chimeric Abs with less neutralization. N-linked glycosylation of PG9 was not required for neutralization. Fab and IgG formats of PG9 had comparable neutralization potencies. The likely site of PG9 reaction with Env was determined to consist of CDR L1 and L2 and the CDR H3 elements.
Pancera2010
(glycosylation, neutralization)
-
PG9: Broadly neutralizing sera from elite neutralizers exhibited significant sensitivities to mutations I165A, N332A, and N160K. PG9 neutralization activity was tested for pseudoviruses with the mutations relative to the WT. PG9 was shown to require N160K glycosylation for potent neutralizing activity. Pseudoviruses produced in cells treated with kifunensine were found resistant to PG9 neutralization. Donor sera that exhibited sensitivity to N160K showed diminished neutralizing activity against kifunensine-treated pseudoviruses, indicating that PG16 and PG9 MAbs mediate most of the sera neutralizing activity. PG16 and PG9 - like Ab were found in 21% of the donors.
Walker2010
(glycosylation, neutralization)
-
PG9: Crystal structure of PG9 light chain was determined and a homology model of Fab PG9 was constructed for comparison to PG16 MAb. PG9 was shown to have a long CDR H3 that forms a unique stable subdomain. A 7-residue specificity loop within CDR H3 was shown to confer fine specificity of PG16 and PG9 MAbs, and to contain important contacts to gp120 as replacement of the 7 residues abolished PG9 neutralization. CDR H3 tyrosine for PG9 was doubly sulfated, and tyrosine sulfation was shown to play a role in both binding and neutralization. Glycosylation of PG9 light chain did not have a significant effect on neutralization.
Pejchal2010
(glycosylation, neutralization, binding affinity, structure)
-
PG9: This MAb was derived from clade A infected patient. PG9 failed to bind to recombinant gp120 or gp41 but exhibited high neutralization breadth and potency, neutralizing 127 out of 162 cross-clade viruses with a potency exceeding that of b12, 2G12, and 2F5. PG9 also potently neutralized IAVI-C18 virus, that is neutralization resistant to all four bNAbs. PG9 competed for gp120 binding with Abs against V2, V3 and CD4i. N-glycosylation sites N156 and N160 in the V2 region were critical in forming PG9 epitope. PG9 preferred binding to trimeric Env due to subunit presentation in this form. This Ab had a long CDRH3 loop.
Walker2009a
(antibody generation, glycosylation, neutralization, variant cross-reactivity, binding affinity)
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Bontjer2013
Ilja Bontjer, Mark Melchers, Tommy Tong, Thijs van Montfort, Dirk Eggink, David Montefiori, William C. Olson, John P. Moore, James M. Binley, Ben Berkhout, and Rogier W. Sanders. Comparative Immunogenicity of Evolved V1V2-Deleted HIV-1 Envelope Glycoprotein Trimers. PLoS One, 8(6):e67484, 26 Jun 2013. PubMed ID: 23840716.
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Bouvin-Pley2014
M. Bouvin-Pley, M. Morgand, L. Meyer, C. Goujard, A. Moreau, H. Mouquet, M. Nussenzweig, C. Pace, D. Ho, P. J. Bjorkman, D. Baty, P. Chames, M. Pancera, P. D. Kwong, P. Poignard, F. Barin, and M. Braibant. Drift of the HIV-1 Envelope Glycoprotein gp120 Toward Increased Neutralization Resistance over the Course of the Epidemic: A Comprehensive Study Using the Most Potent and Broadly Neutralizing Monoclonal Antibodies. J. Virol., 88(23):13910-13917, Dec 2014. PubMed ID: 25231299.
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Bradley2016a
Todd Bradley, Ashley Trama, Nancy Tumba, Elin Gray, Xiaozhi Lu, Navid Madani, Fatemeh Jahanbakhsh, Amanda Eaton, Shi-Mao Xia, Robert Parks, Krissey E. Lloyd, Laura L. Sutherland, Richard M. Scearce, Cindy M. Bowman, Susan Barnett, Salim S. Abdool-Karim, Scott D. Boyd, Bruno Melillo, Amos B. Smith, 3rd., Joseph Sodroski, Thomas B. Kepler, S. Munir Alam, Feng Gao, Mattia Bonsignori, Hua-Xin Liao, M Anthony Moody, David Montefiori, Sampa Santra, Lynn Morris, and Barton F. Haynes. Amino Acid Changes in the HIV-1 gp41 Membrane Proximal Region Control Virus Neutralization Sensitivity. EBioMedicine, 12:196-207, Oct 2016. PubMed ID: 27612593.
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Braibant2013
Martine Braibant, Eun-Yeung Gong, Jean-Christophe Plantier, Thierry Moreau, Elodie Alessandri, François Simon, and Francis Barin. Cross-Group Neutralization of HIV-1 and Evidence for Conservation of the PG9/PG16 Epitopes within Divergent Groups. AIDS, 27(8):1239-1244, 15 May 2013. PubMed ID: 23343910.
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Bricault2018
Christine A. Bricault, James M. Kovacs, Alexander Badamchi-Zadeh, Krisha McKee, Jennifer L. Shields, Bronwyn M. Gunn, George H. Neubauer, Fadi Ghantous, Julia Jennings, Lindsey Gillis, James Perry, Joseph P. Nkolola, Galit Alter, Bing Chen, Kathryn E. Stephenson, Nicole Doria-Rose, John R. Mascola, Michael S. Seaman, and Dan H. Barouch. Neutralizing Antibody Responses following Long-Term Vaccination with HIV-1 Env gp140 in Guinea Pigs. J. Virol., 92(13), 1 Jul 2018. PubMed ID: 29643249.
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Bricault2019
Christine A. Bricault, Karina Yusim, Michael S. Seaman, Hyejin Yoon, James Theiler, Elena E. Giorgi, Kshitij Wagh, Maxwell Theiler, Peter Hraber, Jennifer P. Macke, Edward F. Kreider, Gerald H. Learn, Beatrice H. Hahn, Johannes F. Scheid, James M. Kovacs, Jennifer L. Shields, Christy L. Lavine, Fadi Ghantous, Michael Rist, Madeleine G. Bayne, George H. Neubauer, Katherine McMahan, Hanqin Peng, Coraline Chéneau, Jennifer J. Jones, Jie Zeng, Christina Ochsenbauer, Joseph P. Nkolola, Kathryn E. Stephenson, Bing Chen, S. Gnanakaran, Mattia Bonsignori, LaTonya D. Williams, Barton F. Haynes, Nicole Doria-Rose, John R. Mascola, David C. Montefiori, Dan H. Barouch, and Bette Korber. HIV-1 Neutralizing Antibody Signatures and Application to Epitope-Targeted Vaccine Design. Cell Host Microbe, 25(1):59-72.e8, 9 Jan 2019. PubMed ID: 30629920.
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Burton2010
Dennis R. Burton and Robin A. Weiss. A Boost for HIV Vaccine Design. Science, 329(5993):770-773, 13 Aug 2010. PubMed ID: 20705840.
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Burton2012
Dennis R. Burton, Pascal Poignard, Robyn L. Stanfield, and Ian A. Wilson. Broadly Neutralizing Antibodies Present New Prospects to Counter Highly Antigenically Diverse Viruses. Science, 337(6091):183-186, 13 Jul 2012. PubMed ID: 22798606.
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Burton2016
Dennis R. Burton and Lars Hangartner. Broadly Neutralizing Antibodies to HIV and Their Role in Vaccine Design. Annu. Rev. Immunol., 34:635-659, 20 May 2016. PubMed ID: 27168247.
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Cai2017
Yongfei Cai, Selen Karaca-Griffin, Jia Chen, Sai Tian, Nicholas Fredette, Christine E. Linton, Sophia Rits-Volloch, Jianming Lu, Kshitij Wagh, James Theiler, Bette Korber, Michael S. Seaman, Stephen C. Harrison, Andrea Carfi, and Bing Chen. Antigenicity-Defined Conformations of an Extremely Neutralization-Resistant HIV-1 Envelope Spike. Proc. Natl. Acad. Sci. U.S.A., 114(17):4477-4482, 25 Apr 2017. PubMed ID: 28396421.
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Carbonetti2014
Sara Carbonetti, Brian G. Oliver, Jolene Glenn, Leonidas Stamatatos, and D. Noah Sather. Soluble HIV-1 Envelope Immunogens Derived from an Elite Neutralizer Elicit Cross-Reactive V1V2 Antibodies and Low Potency Neutralizing Antibodies. PLoS One, 9(1):e86905, 2014. PubMed ID: 24466285.
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Cheeseman2017
Hannah M. Cheeseman, Natalia J. Olejniczak, Paul M. Rogers, Abbey B. Evans, Deborah F. L. King, Paul Ziprin, Hua-Xin Liao, Barton F. Haynes, and Robin J. Shattock. Broadly Neutralizing Antibodies Display Potential for Prevention of HIV-1 Infection of Mucosal Tissue Superior to That of Nonneutralizing Antibodies. J. Virol., 91(1), 1 Jan 2017. PubMed ID: 27795431.
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Chen2015
Jia Chen, James M. Kovacs, Hanqin Peng, Sophia Rits-Volloch, Jianming Lu, Donghyun Park, Elise Zablowsky, Michael S. Seaman, and Bing Chen. Effect of the Cytoplasmic Domain on Antigenic Characteristics of HIV-1 Envelope Glycoprotein. Science, 349(6244):191-195, 10 Jul 2015. PubMed ID: 26113642.
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Chen2016
Danying Chen, Xiaozhou He, Jingrong Ye, Pengxiang Zhao, Yi Zeng, and Xia Feng. Genetic and Phenotypic Analysis of CRF01\_AE HIV-1 env Clones from Patients Residing in Beijing, China. AIDS Res. Hum. Retroviruses, 32(10-11):1113-1124, Nov 2016. PubMed ID: 27066910.
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Chenine2018
Agnes-Laurence Chenine, Melanie Merbah, Lindsay Wieczorek, Sebastian Molnar, Brendan Mann, Jenica Lee, Anne-Marie O'Sullivan, Meera Bose, Eric Sanders-Buell, Gustavo H. Kijak, Carolina Herrera, Robert McLinden, Robert J. O'Connell, Nelson L. Michael, Merlin L. Robb, Jerome H. Kim, Victoria R. Polonis, and Sodsai Tovanabutra. Neutralization Sensitivity of a Novel HIV-1 CRF01\_AE Panel of Infectious Molecular Clones. J. Acquir. Immune Defic. Syndr., 78(3):348-355, 1 Jul 2018. PubMed ID: 29528942.
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Chuang2013
Gwo-Yu Chuang, Priyamvada Acharya, Stephen D. Schmidt, Yongping Yang, Mark K. Louder, Tongqing Zhou, Young Do Kwon, Marie Pancera, Robert T. Bailer, Nicole A. Doria-Rose, Michel C. Nussenzweig, John R. Mascola, Peter D. Kwong, and Ivelin S. Georgiev. Residue-Level Prediction of HIV-1 Antibody Epitopes Based on Neutralization of Diverse Viral Strains. J. Virol., 87(18):10047-10058, Sep 2013. PubMed ID: 23843642.
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Chuang2019
Gwo-Yu Chuang, Jing Zhou, Priyamvada Acharya, Reda Rawi, Chen-Hsiang Shen, Zizhang Sheng, Baoshan Zhang, Tongqing Zhou, Robert T. Bailer, Venkata P. Dandey, Nicole A. Doria-Rose, Mark K. Louder, Krisha McKee, John R. Mascola, Lawrence Shapiro, and Peter D. Kwong. Structural Survey of Broadly Neutralizing Antibodies Targeting the HIV-1 Env Trimer Delineates Epitope Categories and Characteristics of Recognition. Structure, 27(1):196-206.e6, 2 Jan 2019. PubMed ID: 30471922.
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Chun2014
Tae-Wook Chun, Danielle Murray, Jesse S. Justement, Jana Blazkova, Claire W. Hallahan, Olivia Fankuchen, Kathleen Gittens, Erika Benko, Colin Kovacs, Susan Moir, and Anthony S. Fauci. Broadly Neutralizing Antibodies Suppress HIV in the Persistent Viral Reservoir. Proc. Natl. Acad. Sci. U.S.A., 111(36):13151-13156, 9 Sep 2014. PubMed ID: 25157148.
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Cimbro2014
Raffaello Cimbro, Thomas R. Gallant, Michael A. Dolan, Christina Guzzo, Peng Zhang, Yin Lin, Huiyi Miao, Donald Van Ryk, James Arthos, Inna Gorshkova, Patrick H. Brown, Darrell E. Hurt, and Paolo Lusso. Tyrosine Sulfation in the Second Variable Loop (V2) of HIV-1 gp120 Stabilizes V2-V3 Interaction and Modulates Neutralization Sensitivity. Proc. Natl. Acad. Sci. U.S.A., 111(8):3152-3157, 25 Feb 2014. PubMed ID: 24569807.
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Crooks2015
Ema T. Crooks, Tommy Tong, Bimal Chakrabarti, Kristin Narayan, Ivelin S. Georgiev, Sergey Menis, Xiaoxing Huang, Daniel Kulp, Keiko Osawa, Janelle Muranaka, Guillaume Stewart-Jones, Joanne Destefano, Sijy O'Dell, Celia LaBranche, James E. Robinson, David C. Montefiori, Krisha McKee, Sean X. Du, Nicole Doria-Rose, Peter D. Kwong, John R. Mascola, Ping Zhu, William R. Schief, Richard T. Wyatt, Robert G. Whalen, and James M. Binley. Vaccine-Elicited Tier 2 HIV-1 Neutralizing Antibodies Bind to Quaternary Epitopes Involving Glycan-Deficient Patches Proximal to the CD4 Binding Site. PLoS Pathog, 11(5):e1004932, May 2015. PubMed ID: 26023780.
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Crooks2018
Ema T. Crooks, Samantha L. Grimley, Michelle Cully, Keiko Osawa, Gillian Dekkers, Kevin Saunders, Sebastian Ramisch, Sergey Menis, William R. Schief, Nicole Doria-Rose, Barton Haynes, Ben Murrell, Evan Mitchel Cale, Amarendra Pegu, John R. Mascola, Gestur Vidarsson, and James M. Binley. Glycoengineering HIV-1 Env Creates `Supercharged' and `Hybrid' Glycans to Increase Neutralizing Antibody Potency, Breadth and Saturation. PLoS Pathog., 14(5):e1007024, May 2018. PubMed ID: 29718999.
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Danesh2020
Ali Danesh, Yanqin Ren, and R. Brad Jones. Roles of Fragment Crystallizable-Mediated Effector Functions in Broadly Neutralizing Antibody Activity against HIV. Curr. Opin. HIV AIDS, 15(5):316-323, Sep 2020. PubMed ID: 32732552.
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Davenport2011
Thaddeus M. Davenport, Della Friend, Katharine Ellingson, Hengyu Xu, Zachary Caldwell, George Sellhorn, Zane Kraft, Roland K. Strong, and Leonidas Stamatatos. Binding Interactions between Soluble HIV Envelope Glycoproteins and Quaternary-Structure-Specific Monoclonal Antibodies PG9 and PG16. J. Virol., 85(14):7095-7107, Jul 2011. PubMed ID: 21543501.
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Decamp2014
Allan deCamp, Peter Hraber, Robert T. Bailer, Michael S. Seaman, Christina Ochsenbauer, John Kappes, Raphael Gottardo, Paul Edlefsen, Steve Self, Haili Tang, Kelli Greene, Hongmei Gao, Xiaoju Daniell, Marcella Sarzotti-Kelsoe, Miroslaw K. Gorny, Susan Zolla-Pazner, Celia C. LaBranche, John R. Mascola, Bette T. Korber, and David C. Montefiori. Global Panel of HIV-1 Env Reference Strains for Standardized Assessments of Vaccine-Elicited Neutralizing Antibodies. J. Virol., 88(5):2489-2507, Mar 2014. PubMed ID: 24352443.
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Dennison2014
S. Moses Dennison, Kara M. Anasti, Frederick H. Jaeger, Shelley M. Stewart, Justin Pollara, Pinghuang Liu, Erika L. Kunz, Ruijun Zhang, Nathan Vandergrift, Sallie Permar, Guido Ferrari, Georgia D. Tomaras, Mattia Bonsignori, Nelson L. Michael, Jerome H Kim, Jaranit Kaewkungwal, Sorachai Nitayaphan, Punnee Pitisuttithum, Supachai Rerks-Ngarm, Hua-Xin Liao, Barton F. Haynes, and S. Munir Alam. Vaccine-Induced HIV-1 Envelope gp120 Constant Region 1-Specific Antibodies Expose a CD4-Inducible Epitope and Block the Interaction of HIV-1 gp140 with Galactosylceramide. J. Virol., 88(16):9406-9417, Aug 2014. PubMed ID: 24920809.
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Derking2015
Ronald Derking, Gabriel Ozorowski, Kwinten Sliepen, Anila Yasmeen, Albert Cupo, Jonathan L. Torres, Jean-Philippe Julien, Jeong Hyun Lee, Thijs van Montfort, Steven W. de Taeye, Mark Connors, Dennis R. Burton, Ian A. Wilson, Per-Johan Klasse, Andrew B. Ward, John P. Moore, and Rogier W. Sanders. Comprehensive Antigenic Map of a Cleaved Soluble HIV-1 Envelope Trimer. PLoS Pathog, 11(3):e1004767, Mar 2015. PubMed ID: 25807248.
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deTaeye2015
Steven W. de Taeye, Gabriel Ozorowski, Alba Torrents de la Peña, Miklos Guttman, Jean-Philippe Julien, Tom L. G. M. van den Kerkhof, Judith A. Burger, Laura K. Pritchard, Pavel Pugach, Anila Yasmeen, Jordan Crampton, Joyce Hu, Ilja Bontjer, Jonathan L. Torres, Heather Arendt, Joanne DeStefano, Wayne C. Koff, Hanneke Schuitemaker, Dirk Eggink, Ben Berkhout, Hansi Dean, Celia LaBranche, Shane Crotty, Max Crispin, David C. Montefiori, P. J. Klasse, Kelly K. Lee, John P. Moore, Ian A. Wilson, Andrew B. Ward, and Rogier W. Sanders. Immunogenicity of Stabilized HIV-1 Envelope Trimers with Reduced Exposure of Non-Neutralizing Epitopes. Cell, 163(7):1702-1715, 17 Dec 2015. PubMed ID: 26687358.
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deTaeye2019
Steven W. de Taeye, Eden P. Go, Kwinten Sliepen, Alba Torrents de la Peña, Kimberly Badal, Max Medina-Ramírez, Wen-Hsin Lee, Heather Desaire, Ian A. Wilson, John P. Moore, Andrew B. Ward, and Rogier W. Sanders. Stabilization of the V2 Loop Improves the Presentation of V2 Loop-Associated Broadly Neutralizing Antibody Epitopes on HIV-1 Envelope Trimers. J. Biol. Chem., 294(14):5616-5631, 5 Apr 2019. PubMed ID: 30728245.
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Dingens2019
Adam S. Dingens, Dana Arenz, Haidyn Weight, Julie Overbaugh, and Jesse D. Bloom. An Antigenic Atlas of HIV-1 Escape from Broadly Neutralizing Antibodies Distinguishes Functional and Structural Epitopes. Immunity, 50(2):520-532.e3, 19 Feb 2019. PubMed ID: 30709739.
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Diskin2013
Ron Diskin, Florian Klein, Joshua A. Horwitz, Ariel Halper-Stromberg, D. Noah Sather, Paola M. Marcovecchio, Terri Lee, Anthony P. West, Jr., Han Gao, Michael S. Seaman, Leonidas Stamatatos, Michel C. Nussenzweig, and Pamela J. Bjorkman. Restricting HIV-1 Pathways for Escape Using Rationally Designed Anti-HIV-1 Antibodies. J. Exp. Med., 210(6):1235-1249, 3 Jun 2013. PubMed ID: 23712429.
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Doores2010
Katie J. Doores and Dennis R. Burton. Variable Loop Glycan Dependency of the Broad and Potent HIV-1-Neutralizing Antibodies PG9 and PG16. J. Virol., 84(20):10510-10521, Oct 2010. PubMed ID: 20686044.
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Doria-Rose2012
Nicole A. Doria-Rose, Mark K. Louder, Zhongjia Yang, Sijy O'Dell, Martha Nason, Stephen D. Schmidt, Krisha McKee, Michael S. Seaman, Robert T. Bailer, and John R. Mascola. HIV-1 Neutralization Coverage Is Improved by Combining Monoclonal Antibodies That Target Independent Epitopes. J. Virol., 86(6):3393-3397, Mar 2012. PubMed ID: 22258252.
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Doria-Rose2014
Nicole A. Doria-Rose, Chaim A. Schramm, Jason Gorman, Penny L. Moore, Jinal N. Bhiman, Brandon J. DeKosky, Michael J. Ernandes, Ivelin S. Georgiev, Helen J. Kim, Marie Pancera, Ryan P. Staupe, Han R. Altae-Tran, Robert T. Bailer, Ema T. Crooks, Albert Cupo, Aliaksandr Druz, Nigel J. Garrett, Kam H. Hoi, Rui Kong, Mark K. Louder, Nancy S. Longo, Krisha McKee, Molati Nonyane, Sijy O'Dell, Ryan S. Roark, Rebecca S. Rudicell, Stephen D. Schmidt, Daniel J. Sheward, Cinque Soto, Constantinos Kurt Wibmer, Yongping Yang, Zhenhai Zhang, NISC Comparative Sequencing Program, James C. Mullikin, James M. Binley, Rogier W. Sanders, Ian A. Wilson, John P. Moore, Andrew B. Ward, George Georgiou, Carolyn Williamson, Salim S. Abdool Karim, Lynn Morris, Peter D. Kwong, Lawrence Shapiro, and John R. Mascola. Developmental Pathway for Potent V1V2-Directed HIV-Neutralizing Antibodies. Nature, 509(7498):55-62, 1 May 2014. PubMed ID: 24590074.
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Doria-Rose2017
Nicole A. Doria-Rose, Han R. Altae-Tran, Ryan S. Roark, Stephen D. Schmidt, Matthew S. Sutton, Mark K. Louder, Gwo-Yu Chuang, Robert T. Bailer, Valerie Cortez, Rui Kong, Krisha McKee, Sijy O'Dell, Felicia Wang, Salim S. Abdool Karim, James M. Binley, Mark Connors, Barton F. Haynes, Malcolm A. Martin, David C. Montefiori, Lynn Morris, Julie Overbaugh, Peter D. Kwong, John R. Mascola, and Ivelin S. Georgiev. Mapping Polyclonal HIV-1 Antibody Responses via Next-Generation Neutralization Fingerprinting. PLoS Pathog., 13(1):e1006148, Jan 2017. PubMed ID: 28052137.
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Doria-RoseNA2012
Nicole A. Doria-Rose, Ivelin Georgiev, Sijy O'Dell, Gwo-Yu Chuang, Ryan P. Staupe, Jason S. McLellan, Jason Gorman, Marie Pancera, Mattia Bonsignori, Barton F. Haynes, Dennis R. Burton, Wayne C. Koff, Peter D. Kwong, and John R. Mascola. A Short Segment of the HIV-1 gp120 V1/V2 Region Is a Major Determinant of Resistance to V1/V2 Neutralizing Antibodies. J. Virol., Aug 2012. PubMed ID: 22623764.
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Escolano2021
Amelia Escolano, Harry .B Gristick, Rajeev Gautam, Andrew T. DeLaitsch, Morgan E. Abernathy, Zhi Yang, Haoqing Wang, Magnus A. G. Hoffmann, Yoshiaki Nishimura, Zijun Wang, Nicholas Koranda, Leesa M. Kakutani, Han Gao, Priyanthi N. P. Gnanapragasam, Henna Raina, Ana Gazumyan, Melissa Cipolla, Thiago Y. Oliveira, Victor Ramos, Darrell J. Irvine, Murillo Silva, Anthony P. West, Jr., Jennifer R. Keeffe, Christopher O. Barnes, Michael S. Seaman, Michel C. Nussenzweig, Malcolm A. Martin, and Pamela J. Bjorkman. Sequential Immunization of Macaques Elicits Heterologous Neutralizing Antibodies Targeting the V3-Glycan Patch of HIV-1 Env. Sci. Transl. Med., 13(621):eabk1533, 24 Nov 2021. PubMed ID: 34818054.
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Euler2011
Zelda Euler, Evelien M. Bunnik, Judith A. Burger, Brigitte D. M. Boeser-Nunnink, Marlous L. Grijsen, Jan M. Prins, and Hanneke Schuitemaker. Activity of Broadly Neutralizing Antibodies, Including PG9, PG16, and VRC01, against Recently Transmitted Subtype B HIV-1 Variants from Early and Late in the Epidemic. J. Virol., 85(14):7236-7245, Jul 2011. PubMed ID: 21561918.
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Evans2014
Mark C. Evans, Pham Phung, Agnes C. Paquet, Anvi Parikh, Christos J. Petropoulos, Terri Wrin, and Mojgan Haddad. Predicting HIV-1 Broadly Neutralizing Antibody Epitope Networks Using Neutralization Titers and a Novel Computational Method. BMC Bioinformatics, 15:77, 19 Mar 2014. PubMed ID: 24646213.
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Falkowska2012
Emilia Falkowska, Alejandra Ramos, Yu Feng, Tongqing Zhou, Stephanie Moquin, Laura M. Walker, Xueling Wu, Michael S. Seaman, Terri Wrin, Peter D. Kwong, Richard T. Wyatt, John R. Mascola, Pascal Poignard, and Dennis R. Burton. PGV04, an HIV-1 gp120 CD4 Binding Site Antibody, Is Broad and Potent in Neutralization but Does Not Induce Conformational Changes Characteristic of CD4. J. Virol., 86(8):4394-4403, Apr 2012. PubMed ID: 22345481.
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Falkowska2014
Emilia Falkowska, Khoa M. Le, Alejandra Ramos, Katie J. Doores, Jeong Hyun Lee, Claudia Blattner, Alejandro Ramirez, Ronald Derking, Marit J. van Gils, Chi-Hui Liang, Ryan Mcbride, Benjamin von Bredow, Sachin S. Shivatare, Chung-Yi Wu, Po-Ying Chan-Hui, Yan Liu, Ten Feizi, Michael B. Zwick, Wayne C. Koff, Michael S. Seaman, Kristine Swiderek, John P. Moore, David Evans, James C. Paulson, Chi-Huey Wong, Andrew B. Ward, Ian A. Wilson, Rogier W. Sanders, Pascal Poignard, and Dennis R. Burton. Broadly Neutralizing HIV Antibodies Define a Glycan-Dependent Epitope on the Prefusion Conformation of gp41 on Cleaved Envelope Trimers. Immunity, 40(5):657-668, 15 May 2014. PubMed ID: 24768347.
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Gach2013
Johannes S. Gach, Heribert Quendler, Tommy Tong, Kristin M. Narayan, Sean X. Du, Robert G. Whalen, James M. Binley, Donald N. Forthal, Pascal Poignard, and Michael B. Zwick. A Human Antibody to the CD4 Binding Site of gp120 Capable of Highly Potent but Sporadic Cross Clade Neutralization of Primary HIV-1. PLoS One, 8(8):e72054, 2013. PubMed ID: 23991039.
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Gavrilyuk2013
Julia Gavrilyuk, Hitoshi Ban, Hisatoshi Uehara, Shannon J. Sirk, Karen Saye-Francisco, Angelica Cuevas, Elise Zablowsky, Avinash Oza, Michael S. Seaman, Dennis R. Burton, and Carlos F. Barbas, 3rd. Antibody Conjugation Approach Enhances Breadth and Potency of Neutralization of Anti-HIV-1 Antibodies and CD4-IgG. J. Virol., 87(9):4985-4993, May 2013. PubMed ID: 23427154.
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Georgiev2013
Ivelin S. Georgiev, Nicole A. Doria-Rose, Tongqing Zhou, Young Do Kwon, Ryan P. Staupe, Stephanie Moquin, Gwo-Yu Chuang, Mark K. Louder, Stephen D. Schmidt, Han R. Altae-Tran, Robert T. Bailer, Krisha McKee, Martha Nason, Sijy O'Dell, Gilad Ofek, Marie Pancera, Sanjay Srivatsan, Lawrence Shapiro, Mark Connors, Stephen A. Migueles, Lynn Morris, Yoshiaki Nishimura, Malcolm A. Martin, John R. Mascola, and Peter D. Kwong. Delineating Antibody Recognition in Polyclonal Sera from Patterns of HIV-1 Isolate Neutralization. Science, 340(6133):751-756, 10 May 2013. PubMed ID: 23661761.
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Gonzalez2010
Nuria Gonzalez, Amparo Alvarez, and Jose Alcami. Broadly Neutralizing Antibodies and their Significance for HIV-1 Vaccines. Curr. HIV Res., 8(8):602-612, Dec 2010. PubMed ID: 21054253.
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Goo2012
Leslie Goo, Zahra Jalalian-Lechak, Barbra A. Richardson, and Julie Overbaugh. A Combination of Broadly Neutralizing HIV-1 Monoclonal Antibodies Targeting Distinct Epitopes Effectively Neutralizes Variants Found in Early Infection. J. Virol., 86(19):10857-10861, Oct 2012. PubMed ID: 22837204.
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Gorman2016
Jason Gorman, Cinque Soto, Max M. Yang, Thaddeus M. Davenport, Miklos Guttman, Robert T. Bailer, Michael Chambers, Gwo-Yu Chuang, Brandon J. DeKosky, Nicole A. Doria-Rose, Aliaksandr Druz, Michael J. Ernandes, Ivelin S. Georgiev, Marissa C. Jarosinski, M. Gordon Joyce, Thomas M. Lemmin, Sherman Leung, Mark K. Louder, Jonathan R. McDaniel, Sandeep Narpala, Marie Pancera, Jonathan Stuckey, Xueling Wu, Yongping Yang, Baoshan Zhang, Tongqing Zhou, NISC Comparative Sequencing Program, James C. Mullikin, Ulrich Baxa, George Georgiou, Adrian B. McDermott, Mattia Bonsignori, Barton F. Haynes, Penny L. Moore, Lynn Morris, Kelly K. Lee, Lawrence Shapiro, John R. Mascola, and Peter D. Kwong. Structures of HIV-1 Env V1V2 with Broadly Neutralizing Antibodies Reveal Commonalities That Enable Vaccine Design. Nat. Struct. Mol. Biol., 23(1):81-90, Jan 2016. PubMed ID: 26689967.
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Guan2013
Yongjun Guan, Marzena Pazgier, Mohammad M. Sajadi, Roberta Kamin-Lewis, Salma Al-Darmarki, Robin Flinko, Elena Lovo, Xueji Wu, James E. Robinson, Michael S. Seaman, Timothy R. Fouts, Robert C. Gallo, Anthony L. DeVico, and George K. Lewis. Diverse Specificity and Effector Function Among Human Antibodies to HIV-1 Envelope Glycoprotein Epitopes Exposed by CD4 Binding. Proc. Natl. Acad. Sci. U.S.A., 110(1):E69-E78, 2 Jan 2013. PubMed ID: 23237851.
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Javier Guenaga, Viktoriya Dubrovskaya, Natalia de Val, Shailendra K. Sharma, Barbara Carrette, Andrew B. Ward, and Richard T. Wyatt. Structure-Guided Redesign Increases the Propensity of HIV Env To Generate Highly Stable Soluble Trimers. J. Virol., 90(6):2806-2817, 30 Dec 2015. PubMed ID: 26719252.
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Guzzo2018
Christina Guzzo, Peng Zhang, Qingbo Liu, Alice L. Kwon, Ferzan Uddin, Alexandra I. Wells, Hana Schmeisser, Raffaello Cimbro, Jinghe Huang, Nicole Doria-Rose, Stephen D. Schmidt, Michael A. Dolan, Mark Connors, John R. Mascola, and Paolo Lusso. Structural Constraints at the Trimer Apex Stabilize the HIV-1 Envelope in a Closed, Antibody-Protected Conformation. mBio, 9(6), 11 Dec 2018. PubMed ID: 30538178.
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Philip W. Hammond. Accessing the Human Repertoire for Broadly Neutralizing HIV Antibodies. MAbs, 2(2):157-164, Mar-Apr 2010. PubMed ID: 20168075.
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Barton F. Haynes, Garnett Kelsoe, Stephen C. Harrison, and Thomas B. Kepler. B-Cell-Lineage Immunogen Design in Vaccine Development with HIV-1 as a Case Study. Nat. Biotechnol., 30(5):423-433, May 2012. PubMed ID: 22565972.
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Haynes2013
Barton F. Haynes and M. Juliana McElrath. Progress in HIV-1 Vaccine Development. Curr. Opin. HIV AIDS, 8(4):326-332, Jul 2013. PubMed ID: 23743722.
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Henderson2019
Rory Henderson, Brian E. Watts, Hieu N. Ergin, Kara Anasti, Robert Parks, Shi-Mao Xia, Ashley Trama, Hua-Xin Liao, Kevin O. Saunders, Mattia Bonsignori, Kevin Wiehe, Barton F. Haynes, and S. Munir Alam. Selection of Immunoglobulin Elbow Region Mutations Impacts Interdomain Conformational Flexibility in HIV-1 Broadly Neutralizing Antibodies. Nat. Commun., 10(1):654, 8 Feb 2019. PubMed ID: 30737386.
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Hoffenberg2013
Simon Hoffenberg, Rebecca Powell, Alexei Carpov, Denise Wagner, Aaron Wilson, Sergei Kosakovsky Pond, Ross Lindsay, Heather Arendt, Joanne DeStefano, Sanjay Phogat, Pascal Poignard, Steven P. Fling, Melissa Simek, Celia LaBranche, David Montefiori, Terri Wrin, Pham Phung, Dennis Burton, Wayne Koff, C. Richter King, Christopher L. Parks, and Michael J. Caulfield. Identification of an HIV-1 Clade A Envelope That Exhibits Broad Antigenicity and Neutralization Sensitivity and Elicits Antibodies Targeting Three Distinct Epitopes. J. Virol., 87(10):5372-5383, May 2013. PubMed ID: 23468492.
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Hogan2018
Michael J. Hogan, Angela Conde-Motter, Andrea P. O. Jordan, Lifei Yang, Brad Cleveland, Wenjin Guo, Josephine Romano, Houping Ni, Norbert Pardi, Celia C. LaBranche, David C. Montefiori, Shiu-Lok Hu, James A. Hoxie, and Drew Weissman. Increased Surface Expression of HIV-1 Envelope Is Associated with Improved Antibody Response in Vaccinia Prime/Protein Boost Immunization. Virology, 514:106-117, 15 Jan 2018. PubMed ID: 29175625.
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James A. Hoxie. Toward an Antibody-Based HIV-1 Vaccine. Annu. Rev. Med., 61:135-52, 2010. PubMed ID: 19824826.
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Peter Hraber, Michael S. Seaman, Robert T. Bailer, John R. Mascola, David C. Montefiori, and Bette T. Korber. Prevalence of Broadly Neutralizing Antibody Responses during Chronic HIV-1 Infection. AIDS, 28(2):163-169, 14 Jan 2014. PubMed ID: 24361678.
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Hraber2017
Peter Hraber, Cecilia Rademeyer, Carolyn Williamson, Michael S. Seaman, Raphael Gottardo, Haili Tang, Kelli Greene, Hongmei Gao, Celia LaBranche, John R. Mascola, Lynn Morris, David C. Montefiori, and Bette Korber. Panels of HIV-1 Subtype C Env Reference Strains for Standardized Neutralization Assessments. J. Virol., 91(19), 1 Oct 2017. PubMed ID: 28747500.
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Hraber2018
Peter Hraber, Bette Korber, Kshitij Wagh, David Montefiori, and Mario Roederer. A Single, Continuous Metric To Define Tiered Serum Neutralization Potency against Hiv. eLife, 7, 19 Jan 2018. PubMed ID: 29350181.
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Joyce K. Hu, Jordan C. Crampton, Albert Cupo, Thomas Ketas, Marit J. van Gils, Kwinten Sliepen, Steven W. de Taeye, Devin Sok, Gabriel Ozorowski, Isaiah Deresa, Robyn Stanfield, Andrew B. Ward, Dennis R. Burton, Per Johan Klasse, Rogier W. Sanders, John P. Moore, and Shane Crotty. Murine Antibody Responses to Cleaved Soluble HIV-1 Envelope Trimers Are Highly Restricted in Specificity. J. Virol., 89(20):10383-10398, Oct 2015. PubMed ID: 26246566.
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Hua2016
Casey K. Hua and Margaret E. Ackerman. Engineering Broadly Neutralizing Antibodies for HIV Prevention and Therapy. Adv. Drug Deliv. Rev., 103:157-173, 1 Aug 2016. PubMed ID: 26827912.
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Huang2012a
Jinghe Huang, Gilad Ofek, Leo Laub, Mark K. Louder, Nicole A. Doria-Rose, Nancy S. Longo, Hiromi Imamichi, Robert T. Bailer, Bimal Chakrabarti, Shailendra K. Sharma, S. Munir Alam, Tao Wang, Yongping Yang, Baoshan Zhang, Stephen A. Migueles, Richard Wyatt, Barton F. Haynes, Peter D. Kwong, John R. Mascola, and Mark Connors. Broad and Potent Neutralization of HIV-1 by a gp41-Specific Human Antibody. Nature, 491(7424):406-412, 15 Nov 2012. PubMed ID: 23151583.
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Hutchinson2019
Jennie M. Hutchinson, Kathryn A. Mesa, David L. Alexander, Bin Yu, Sara M. O'Rourke, Kay L. Limoli, Terri Wrin, Steven G. Deeks, and Phillip W. Berman. Unusual Cysteine Content in V1 Region of gp120 from an Elite Suppressor That Produces Broadly Neutralizing Antibodies. Front. Immunol., 10:1021, 2019. PubMed ID: 31156622.
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Jeffries2016
T. L. Jeffries, Jr., C. R. Sacha, J. Pollara, J. Himes, F. H. Jaeger, S. M. Dennison, E. McGuire, E. Kunz, J. A. Eudailey, A. M. Trama, C. LaBranche, G. G. Fouda, K. Wiehe, D. C. Montefiori, B. F. Haynes, H.-X. Liao, G. Ferrari, S. M. Alam, M. A. Moody, and S. R. Permar. The Function and Affinity Maturation of HIV-1 gp120-Specific Monoclonal Antibodies Derived from Colostral B Cells. Mucosal. Immunol., 9(2):414-427, Mar 2016. PubMed ID: 26242599.
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Joyce2010
Joseph G. Joyce and Jan ter Meulen. Pushing the Envelope on HIV-1 Neutralization. Nat. Biotechnol., 28(9):929-931, Sep 2010. PubMed ID: 20829830.
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Julien2013
Jean-Philippe Julien, Jeong Hyun Lee, Albert Cupo, Charles D. Murin, Ronald Derking, Simon Hoffenberg, Michael J. Caulfield, C. Richter King, Andre J. Marozsan, Per Johan Klasse, Rogier W. Sanders, John P. Moore, Ian A. Wilson, and Andrew. B Ward. Asymmetric Recognition of the HIV-1 Trimer by Broadly Neutralizing Antibody PG9. Proc. Natl. Acad. Sci. U.S.A., 110(11):4351-4356, 12 Mar 2013. PubMed ID: 23426631.
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Julien2015
Jean-Philippe Julien, Jeong Hyun Lee, Gabriel Ozorowski, Yuanzi Hua, Alba Torrents de la Peña, Steven W. de Taeye, Travis Nieusma, Albert Cupo, Anila Yasmeen, Michael Golabek, Pavel Pugach, P. J. Klasse, John P. Moore, Rogier W. Sanders, Andrew B. Ward, and Ian A. Wilson. Design and Structure of Two HIV-1 Clade C SOSIP.664 Trimers That Increase the Arsenal of Native-Like Env Immunogens. Proc. Natl. Acad. Sci. U.S.A., 112(38):11947-11952, 22 Sep 2015. PubMed ID: 26372963.
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Kesavardhana2017
Sannula Kesavardhana, Raksha Das, Michael Citron, Rohini Datta, Linda Ecto, Nonavinakere Seetharam Srilatha, Daniel DiStefano, Ryan Swoyer, Joseph G. Joyce, Somnath Dutta, Celia C. LaBranche, David C. Montefiori, Jessica A. Flynn, and Raghavan Varadarajan. Structure-Based Design of Cyclically Permuted HIV-1 gp120 Trimers That Elicit Neutralizing Antibodies. J. Biol. Chem., 292(1):278-291, 6 Jan 2017. PubMed ID: 27879316.
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Klein2010
Joshua S. Klein and Pamela J. Bjorkman. Few and Far Between: How HIV May Be Evading Antibody Avidity. PLoS Pathog., 6(5):e1000908, May 2010. PubMed ID: 20523901.
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Kovacs2012
James M. Kovacs, Joseph P. Nkolola, Hanqin Peng, Ann Cheung, James Perry, Caroline A. Miller, Michael S. Seaman, Dan H. Barouch, and Bing Chen. HIV-1 Envelope Trimer Elicits More Potent Neutralizing Antibody Responses than Monomeric gp120. Proc. Natl. Acad. Sci. U.S.A., 109(30):12111-12116, 24 Jul 2012. PubMed ID: 22773820.
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Kreer2020
Christoph Kreer, Henning Gruell, Thierry Mora, Aleksandra M. Walczak, and Florian Klein. Exploiting B Cell Receptor Analyses to Inform on HIV-1 Vaccination Strategies. Vaccines (Basel), 8(1):13 doi, Jan 2020. PubMed ID: 31906351
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Kulp2017
Daniel W. Kulp, Jon M. Steichen, Matthias Pauthner, Xiaozhen Hu, Torben Schiffner, Alessia Liguori, Christopher A. Cottrell, Colin Havenar-Daughton, Gabriel Ozorowski, Erik Georgeson, Oleksandr Kalyuzhniy, Jordan R. Willis, Michael Kubitz, Yumiko Adachi, Samantha M. Reiss, Mia Shin, Natalia de Val, Andrew B. Ward, Shane Crotty, Dennis R. Burton, and William R. Schief. Structure-Based Design of Native-Like HIV-1 Envelope Trimers to Silence Non-Neutralizing Epitopes and Eliminate CD4 Binding. Nat. Commun., 8(1):1655, 21 Nov 2017. PubMed ID: 29162799.
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Kumar2018
Amit Kumar, Claire E. P. Smith, Elena E. Giorgi, Joshua Eudailey, David R. Martinez, Karina Yusim, Ayooluwa O. Douglas, Lisa Stamper, Erin McGuire, Celia C. LaBranche, David C. Montefiori, Genevieve G. Fouda, Feng Gao, and Sallie R. Permar. Infant Transmitted/Founder HIV-1 Viruses from Peripartum Transmission Are Neutralization Resistant to Paired Maternal Plasma. PLoS Pathog., 14(4):e1006944, Apr 2018. PubMed ID: 29672607.
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Kwon2012
Young Do Kwon, Andrés Finzi, Xueling Wu, Cajetan Dogo-Isonagie, Lawrence K. Lee, Lucas R. Moore, Stephen D. Schmidt, Jonathan Stuckey, Yongping Yang, Tongqing Zhou, Jiang Zhu, David A. Vicic, Asim K. Debnath, Lawrence Shapiro, Carole A. Bewley, John R. Mascola, Joseph G. Sodroski, and Peter D. Kwong. Unliganded HIV-1 gp120 Core Structures Assume the CD4-Bound Conformation with Regulation by Quaternary Interactions and Variable Loops. Proc. Natl. Acad. Sci. U.S.A., 109(15):5663-5668, 10 Apr 2012. PubMed ID: 22451932.
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Kwon2015
Young Do Kwon, Marie Pancera, Priyamvada Acharya, Ivelin S. Georgiev, Emma T. Crooks, Jason Gorman, M. Gordon Joyce, Miklos Guttman, Xiaochu Ma, Sandeep Narpala, Cinque Soto, Daniel S. Terry, Yongping Yang, Tongqing Zhou, Goran Ahlsen, Robert T. Bailer, Michael Chambers, Gwo-Yu Chuang, Nicole A. Doria-Rose, Aliaksandr Druz, Mark A. Hallen, Adam Harned, Tatsiana Kirys, Mark K. Louder, Sijy O'Dell, Gilad Ofek, Keiko Osawa, Madhu Prabhakaran, Mallika Sastry, Guillaume B. E. Stewart-Jones, Jonathan Stuckey, Paul V. Thomas, Tishina Tittley, Constance Williams, Baoshan Zhang, Hong Zhao, Zhou Zhou, Bruce R. Donald, Lawrence K. Lee, Susan Zolla-Pazner, Ulrich Baxa, Arne Schön, Ernesto Freire, Lawrence Shapiro, Kelly K. Lee, James Arthos, James B. Munro, Scott C. Blanchard, Walther Mothes, James M. Binley, Adrian B. McDermott, John R. Mascola, and Peter D. Kwong. Crystal Structure, Conformational Fixation and Entry-Related Interactions of Mature Ligand-Free HIV-1 Env. Nat. Struct. Mol. Biol., 22(7):522-531, Jul 2015. PubMed ID: 26098315.
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Kwong2009
Peter D. Kwong, John R. Mascola, and Gary J. Nabel. Mining the B Cell Repertoire for Broadly Neutralizing Monoclonal Antibodies to HIV-1. Cell Host Microbe, 6(4):292-294, 22 Oct 2009. PubMed ID: 19837366.
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Kwong2011
Peter D. Kwong, John R. Mascola, and Gary J. Nabel. Rational Design of Vaccines to Elicit Broadly Neutralizing Antibodies to HIV-1. Cold Spring Harb. Perspect. Med., 1(1):a007278, Sep 2011. PubMed ID: 22229123.
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Kwong2012
Peter D. Kwong and John R. Mascola. Human Antibodies that Neutralize HIV-1: Identification, Structures, and B Cell Ontogenies. Immunity, 37(3):412-425, 21 Sep 2012. PubMed ID: 22999947.
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Kwong2013
Peter D. Kwong, John R. Mascola, and Gary J. Nabel. Broadly Neutralizing Antibodies and the Search for an HIV-1 Vaccine: The End of the Beginning. Nat. Rev. Immunol., 13(9):693-701, Sep 2013. PubMed ID: 23969737.
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Kwong2018
Peter D. Kwong and John R. Mascola. HIV-1 Vaccines Based on Antibody Identification, B Cell Ontogeny, and Epitope Structure. Immunity, 48(5):855-871, 15 May 2018. PubMed ID: 29768174.
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Lavine2012
Christy L. Lavine, Socheata Lao, David C. Montefiori, Barton F. Haynes, Joseph G. Sodroski, Xinzhen Yang, and NIAID Center for HIV/AIDS Vaccine Immunology (CHAVI). High-Mannose Glycan-Dependent Epitopes Are Frequently Targeted in Broad Neutralizing Antibody Responses during Human Immunodeficiency Virus Type 1 Infection. J. Virol., 86(4):2153-2164, Feb 2012. PubMed ID: 22156525.
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Leaman2010
Daniel P. Leaman, Heather Kinkead, and Michael B. Zwick. In-Solution Virus Capture Assay Helps Deconstruct Heterogeneous Antibody Recognition of Human Immunodeficiency Virus Type 1. J. Virol., 84(7):3382-3395, Apr 2010. PubMed ID: 20089658.
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Leaman2013
Daniel P. Leaman and Michael B. Zwick. Increased Functional Stability and Homogeneity of Viral Envelope Spikes through Directed Evolution. PLoS Pathog., 9(2):e1003184, Feb 2013. PubMed ID: 23468626.
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Lee2017
Jeong Hyun Lee, Raiees Andrabi, Ching-Yao Su, Anila Yasmeen, Jean-Philippe Julien, Leopold Kong, Nicholas C. Wu, Ryan McBride, Devin Sok, Matthias Pauthner, Christopher A. Cottrell, Travis Nieusma, Claudia Blattner, James C. Paulson, Per Johan Klasse, Ian A. Wilson, Dennis R. Burton, and Andrew B. Ward. A Broadly Neutralizing Antibody Targets the Dynamic HIV Envelope Trimer Apex via a Long, Rigidified, and Anionic beta-Hairpin Structure. Immunity, 46(4):690-702, 18 Apr 2017. PubMed ID: 28423342.
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Lewis2010
George K. Lewis. Challenges of Antibody-Mediated Protection against HIV-1. Expert Rev. Vaccines, 9(7):683-687, Jul 2010. PubMed ID: 20624038.
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Li2017
Hongru Li, Chati Zony, Ping Chen, and Benjamin K. Chen. Reduced Potency and Incomplete Neutralization of Broadly Neutralizing Antibodies against Cell-to-Cell Transmission of HIV-1 with Transmitted Founder Envs. J. Virol., 91(9), 1 May 2017. PubMed ID: 28148796.
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Liang2016
Yu Liang, Miklos Guttman, James A. Williams, Hans Verkerke, Daniel Alvarado, Shiu-Lok Hu, and Kelly K. Lee. Changes in Structure and Antigenicity of HIV-1 Env Trimers Resulting from Removal of a Conserved CD4 Binding Site-Proximal Glycan. J. Virol., 90(20):9224-9236, 15 Oct 2016. PubMed ID: 27489265.
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Liao2013b
Hua-Xin Liao, Mattia Bonsignori, S. Munir Alam, Jason S. McLellan, Georgia D. Tomaras, M. Anthony Moody, Daniel M. Kozink, Kwan-Ki Hwang, Xi Chen, Chun-Yen Tsao, Pinghuang Liu, Xiaozhi Lu, Robert J. Parks, David C. Montefiori, Guido Ferrari, Justin Pollara, Mangala Rao, Kristina K. Peachman, Sampa Santra, Norman L. Letvin, Nicos Karasavvas, Zhi-Yong Yang, Kaifan Dai, Marie Pancera, Jason Gorman, Kevin Wiehe, Nathan I. Nicely, Supachai Rerks-Ngarm, Sorachai Nitayaphan, Jaranit Kaewkungwal, Punnee Pitisuttithum, James Tartaglia, Faruk Sinangil, Jerome H. Kim, Nelson L. Michael, Thomas B. Kepler, Peter D. Kwong, John R. Mascola, Gary J. Nabel, Abraham Pinter, Susan Zolla-Pazner, and Barton F. Haynes. Vaccine Induction of Antibodies Against a Structurally Heterogeneous Site of Immune Pressure within HIV-1 Envelope Protein Variable Regions 1 and 2. Immunity, 38(1):176-186, 24 Jan 2013. PubMed ID: 23313589.
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Liao2013c
Hua-Xin Liao, Chun-Yen Tsao, S. Munir Alam, Mark Muldoon, Nathan Vandergrift, Ben-Jiang Ma, Xiaozhi Lu, Laura L. Sutherland, Richard M. Scearce, Cindy Bowman, Robert Parks, Haiyan Chen, Julie H. Blinn, Alan Lapedes, Sydeaka Watson, Shi-Mao Xia, Andrew Foulger, Beatrice H. Hahn, George M. Shaw, Ron Swanstrom, David C. Montefiori, Feng Gao, Barton F. Haynes, and Bette Korber. Antigenicity and Immunogenicity of Transmitted/Founder, Consensus, and Chronic Envelope Glycoproteins of Human Immunodeficiency Virus Type 1. J. Virol., 87(8):4185-4201, Apr 2013. PubMed ID: 23365441.
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Liu2011
Lihong Liu, Michael Wen, Weiming Wang, Shumei Wang, Lifei Yang, Yong Liu, Mengran Qian, Linqi Zhang, Yiming Shao, Jason T. Kimata, and Paul Zhou. Potent and Broad Anti-HIV-1 Activity Exhibited by a Glycosyl-Phosphatidylinositol-Anchored Peptide Derived from the CDR H3 of Broadly Neutralizing Antibody PG16. J. Virol., 85(17):8467-8476, Sep 2011. PubMed ID: 21715497.
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Liu2014
Pinghuang Liu, Latonya D. Williams, Xiaoying Shen, Mattia Bonsignori, Nathan A. Vandergrift, R. Glenn Overman, M. Anthony Moody, Hua-Xin Liao, Daniel J. Stieh, Kerrie L. McCotter, Audrey L. French, Thomas J. Hope, Robin Shattock, Barton F. Haynes, and Georgia D. Tomaras. Capacity for Infectious HIV-1 Virion Capture Differs by Envelope Antibody Specificity. J. Virol., 88(9):5165-5170, May 2014. PubMed ID: 24554654.
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Liu2015a
Mengfei Liu, Guang Yang, Kevin Wiehe, Nathan I. Nicely, Nathan A. Vandergrift, Wes Rountree, Mattia Bonsignori, S. Munir Alam, Jingyun Gao, Barton F. Haynes, and Garnett Kelsoe. Polyreactivity and Autoreactivity among HIV-1 Antibodies. J. Virol., 89(1):784-798, Jan 2015. PubMed ID: 25355869.
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Lovelace2011
Erica Lovelace, Hengyu Xu, Catherine A. Blish, Roland Strong, and Julie Overbaugh. The Role of Amino Acid Changes in the Human Immunodeficiency Virus Type 1 Transmembrane Domain in Antibody Binding and Neutralization. Virology, 421(2):235-244, 20 Dec 2011. PubMed ID: 22029936.
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Lynch2011
John B. Lynch, Ruth Nduati, Catherine A. Blish, Barbra A. Richardson, Jennifer M. Mabuka, Zahra Jalalian-Lechak, Grace John-Stewart, and Julie Overbaugh. The Breadth and Potency of Passively Acquired Human Immunodeficiency Virus Type 1-Specific Neutralizing Antibodies Do Not Correlate with the Risk of Infant Infection. J. Virol., 85(11):5252-5261, Jun 2011. PubMed ID: 21411521.
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Magnus2016
Carsten Magnus, Lucia Reh, and Alexandra Trkola. HIV-1 Resistance to Neutralizing Antibodies: Determination of Antibody Concentrations Leading to Escape Mutant Evolution. Virus Res., 218:57-70, 15 Jun 2016. PubMed ID: 26494166.
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Malherbe2014
Delphine C. Malherbe, Franco Pissani, D. Noah Sather, Biwei Guo, Shilpi Pandey, William F. Sutton, Andrew B. Stuart, Harlan Robins, Byung Park, Shelly J. Krebs, Jason T. Schuman, Spyros Kalams, Ann J. Hessell, and Nancy L. Haigwood. Envelope variants circulating as initial neutralization breadth developed in two HIV-infected subjects stimulate multiclade neutralizing antibodies in rabbits. J Virol, 88(22):12949-67 doi, Nov 2014. PubMed ID: 25210191
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Mannar2021
Dhiraj Mannar, Karoline Leopold, and Sriram Subramaniam. Glycan Reactive Anti-HIV-1 Antibodies bind the SARS-CoV-2 Spike Protein But Do Not Block Viral Entry. Sci. Rep., 11(1):12448, 14 Jun 2021. PubMed ID: 34127709.
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Mao2012
Youdong Mao, Liping Wang, Christopher Gu, Alon Herschhorn, Shi-Hua Xiang, Hillel Haim, Xinzhen Yang, and Joseph Sodroski. Subunit Organization of the Membrane-Bound HIV-1 Envelope Glycoprotein Trimer. Nat. Struct. Mol. Biol., 19(9):893-899, Sep 2012. PubMed ID: 22864288.
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Mascola2010
John R. Mascola and David C. Montefiori. The Role of Antibodies in HIV Vaccines. Annu. Rev. Immunol., 28:413-444, Mar 2010. PubMed ID: 20192810.
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McCoy2015
Laura E. McCoy, Emilia Falkowska, Katie J. Doores, Khoa Le, Devin Sok, Marit J. van Gils, Zelda Euler, Judith A. Burger, Michael S. Seaman, Rogier W. Sanders, Hanneke Schuitemaker, Pascal Poignard, Terri Wrin, and Dennis R. Burton. Incomplete Neutralization and Deviation from Sigmoidal Neutralization Curves for HIV Broadly Neutralizing Monoclonal Antibodies. PLoS Pathog., 11(8):e1005110, Aug 2015. PubMed ID: 26267277.
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McGuire2014
Andrew T. McGuire, Jolene A. Glenn, Adriana Lippy, and Leonidas Stamatatos. Diverse Recombinant HIV-1 Envs Fail to Activate B Cells Expressing the Germline B Cell Receptors of the Broadly Neutralizing Anti-HIV-1 Antibodies PG9 and 447-52D. J. Virol., 88(5):2645-2657, Mar 2014. PubMed ID: 24352455.
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McLellan2011
Jason S. McLellan, Marie Pancera, Chris Carrico, Jason Gorman, Jean-Philippe Julien, Reza Khayat, Robert Louder, Robert Pejchal, Mallika Sastry, Kaifan Dai, Sijy O'Dell, Nikita Patel, Syed Shahzad-ul-Hussan, Yongping Yang, Baoshan Zhang, Tongqing Zhou, Jiang Zhu, Jeffrey C. Boyington, Gwo-Yu Chuang, Devan Diwanji, Ivelin Georgiev, Young Do Kwon, Doyung Lee, Mark K. Louder, Stephanie Moquin, Stephen D. Schmidt, Zhi-Yong Yang, Mattia Bonsignori, John A. Crump, Saidi H. Kapiga, Noel E. Sam, Barton F. Haynes, Dennis R. Burton, Wayne C. Koff, Laura M. Walker, Sanjay Phogat, Richard Wyatt, Jared Orwenyo, Lai-Xi Wang, James Arthos, Carole A. Bewley, John R. Mascola, Gary J. Nabel, William R. Schief, Andrew B. Ward, Ian A. Wilson, and Peter D. Kwong. Structure of HIV-1 gp120 V1/V2 Domain with Broadly Neutralizing Antibody PG9. Nature, 480(7377):336-343, 15 Dec 2011. PubMed ID: 22113616.
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McLinden2013
Robert J. McLinden, Celia C. LaBranche, Agnès-Laurence Chenine, Victoria R. Polonis, Michael A. Eller, Lindsay Wieczorek, Christina Ochsenbauer, John C. Kappes, Stephen Perfetto, David C. Montefiori, Nelson L. Michael, and Jerome H. Kim. Detection of HIV-1 Neutralizing Antibodies in a Human CD4+/CXCR4+/CCR5+ T-Lymphoblastoid Cell Assay System. PLoS One, 8(11):e77756, 2013. PubMed ID: 24312168.
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Miglietta2014
Riccardo Miglietta, Claudia Pastori, Assunta Venuti, Christina Ochsenbauer, and Lucia Lopalco. Synergy in Monoclonal Antibody Neutralization of HIV-1 Pseudoviruses and Infectious Molecular Clones. J. Transl. Med., 12:346, 2014. PubMed ID: 25496375.
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Mikell2012
Iliyana Mikell and Leonidas Stamatatos. Evolution of Cross-Neutralizing Antibody Specificities to the CD4-BS and the Carbohydrate Cloak of the HIV Env in an HIV-1-Infected Subject. PLoS One, 7(11):e49610, 2012. PubMed ID: 23152926.
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Mishra2020
Nitesh Mishra, Shaifali Sharma, Ayushman Dobhal, Sanjeev Kumar, Himanshi Chawla, Ravinder Singh, Bimal Kumar Das, Sushil Kumar Kabra, Rakesh Lodha, and Kalpana Luthra. A Rare Mutation in an Infant-Derived HIV-1 Envelope Glycoprotein Alters Interprotomer Stability and Susceptibility to Broadly Neutralizing Antibodies Targeting the Trimer Apex. J. Virol., 94(19), 15 Sep 2020. PubMed ID: 32669335.
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Mishra2020a
Nitesh Mishra, Shaifali Sharma, Ayushman Dobhal, Sanjeev Kumar, Himanshi Chawla, Ravinder Singh, Muzamil Ashraf Makhdoomi, Bimal Kumar Das, Rakesh Lodha, Sushil Kumar Kabra, and Kalpana Luthra. Broadly Neutralizing Plasma Antibodies Effective against Autologous Circulating Viruses in Infants with Multivariant HIV-1 Infection. Nat. Commun., 11(1):4409, 2 Sep 2020. PubMed ID: 32879304.
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Moore2011
Penny L. Moore, Elin S. Gray, Daniel Sheward, Maphuti Madiga, Nthabeleng Ranchobe, Zhong Lai, William J. Honnen, Molati Nonyane, Nancy Tumba, Tandile Hermanus, Sengeziwe Sibeko, Koleka Mlisana, Salim S. Abdool Karim, Carolyn Williamson, Abraham Pinter, Lynn Morris, and CAPRISA 002 Study. Potent and Broad Neutralization of HIV-1 Subtype C by Plasma Antibodies Targeting a Quaternary Epitope Including Residues in the V2 loop. J. Virol., 85(7):3128-3141, Apr 2011. PubMed ID: 21270156.
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Moore2012
Penny L. Moore, Elin S. Gray, C. Kurt Wibmer, Jinal N. Bhiman, Molati Nonyane, Daniel J. Sheward, Tandile Hermanus, Shringkhala Bajimaya, Nancy L. Tumba, Melissa-Rose Abrahams, Bronwen E. Lambson, Nthabeleng Ranchobe, Lihua Ping, Nobubelo Ngandu, Quarraisha Abdool Karim, Salim S. Abdool Karim, Ronald I. Swanstrom, Michael S. Seaman, Carolyn Williamson, and Lynn Morris. Evolution of an HIV Glycan-Dependent Broadly Neutralizing Antibody Epitope through Immune Escape. Nat. Med., 18(11):1688-1692, Nov 2012. PubMed ID: 23086475.
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Morales2016
Javier F. Morales, Bin Yu, Gerardo Perez, Kathryn A. Mesa, David L. Alexander, and Phillip W. Berman. Fragments of the V1/V2 Domain of HIV-1 Glycoprotein 120 Engineered for Improved Binding to the Broadly Neutralizing PG9 antibody. Mol. Immunol., 77:14-25, Sep 2016. PubMed ID: 27449907.
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Morgand2015
Marion Morgand, Mélanie Bouvin-Pley, Jean-Christophe Plantier, Alain Moreau, Elodie Alessandri, François Simon, Craig S. Pace, Marie Pancera, David D. Ho, Pascal Poignard, Pamela J. Bjorkman, Hugo Mouquet, Michel C. Nussenzweig, Peter D. Kwong, Daniel Baty, Patrick Chames, Martine Braibant, and Francis Barin. A V1V2 Neutralizing Epitope Is Conserved in Divergent Non-M Groups of HIV-1. J. Acquir. Immune Defic. Syndr., 21 Sep 2015. PubMed ID: 26413851.
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Mouquet2011
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Mouquet2012a
Hugo Mouquet, Louise Scharf, Zelda Euler, Yan Liu, Caroline Eden, Johannes F. Scheid, Ariel Halper-Stromberg, Priyanthi N. P. Gnanapragasam, Daniel I. R. Spencer, Michael S. Seaman, Hanneke Schuitemaker, Ten Feizi, Michel C. Nussenzweig, and Pamela J. Bjorkman. Complex-Type N-Glycan Recognition by Potent Broadly Neutralizing HIV Antibodies. Proc. Natl. Acad. Sci. U.S.A, 109(47):E3268-E3277, 20 Nov 2012. PubMed ID: 23115339.
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Moyo2018
Thandeka Moyo, June Ereño-Orbea, Rajesh Abraham Jacob, Clara E. Pavillet, Samuel Mundia Kariuki, Emily N. Tangie, Jean-Philippe Julien, and Jeffrey R. Dorfman. Molecular Basis of Unusually High Neutralization Resistance in Tier 3 HIV-1 Strain 253-11. J. Virol., 92(14), 15 Jul 2018. PubMed ID: 29618644.
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Nie2020
Jianhui Nie, Weijin Huang, Qiang Liu, and Youchun Wang. HIV-1 Pseudoviruses Constructed in China Regulatory Laboratory. Emerg. Microbes Infect., 9(1):32-41, 2020. PubMed ID: 31859609.
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Nkolola2014
Joseph P. Nkolola, Christine A. Bricault, Ann Cheung, Jennifer Shields, James Perry, James M. Kovacs, Elena Giorgi, Margot van Winsen, Adrian Apetri, Els C. M. Brinkman-van der Linden, Bing Chen, Bette Korber, Michael S. Seaman, and Dan H. Barouch. Characterization and Immunogenicity of a Novel Mosaic M HIV-1 gp140 Trimer. J. Virol., 88(17):9538-9552, 1 Sep 2014. PubMed ID: 24965452.
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Nogal2020
Bartek Nogal, Laura E. McCoy, Marit J. van Gils, Christopher A. Cottrell, James E. Voss, Raiees Andrabi, Matthias Pauthner, Chi-Hui Liang, Terrence Messmer, Rebecca Nedellec, Mia Shin, Hannah L. Turner, Gabriel Ozorowski, Rogier W. Sanders, Dennis R. Burton, and Andrew B. Ward. HIV Envelope Trimer-Elicited Autologous Neutralizing Antibodies Bind a Region Overlapping the N332 Glycan Supersite. Sci. Adv., 6(23):eaba0512, Jun 2020. PubMed ID: 32548265.
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ORourke2012
Sara M. O'Rourke, Becky Schweighardt, Pham Phung, Kathryn A. Mesa, Aaron L. Vollrath, Gwen P. Tatsuno, Briana To, Faruk Sinangil, Kay Limoli, Terri Wrin, and Phillip W. Berman. Sequences in Glycoprotein gp41, the CD4 Binding Site, and the V2 Domain Regulate Sensitivity and Resistance of HIV-1 to Broadly Neutralizing Antibodies. J. Virol., 86(22):12105-12114, Nov 2012. PubMed ID: 22933284.
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Overbaugh2012
Julie Overbaugh and Lynn Morris. The Antibody Response against HIV-1. Cold Spring Harb. Perspect. Med., 2(1):a007039, Jan 2012. PubMed ID: 22315717.
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Pancera2010
Marie Pancera, Jason S. McLellan, Xueling Wu, Jiang Zhu, Anita Changela, Stephen D. Schmidt, Yongping Yang, Tongqing Zhou, Sanjay Phogat, John R. Mascola, and Peter D. Kwong. Crystal Structure of PG16 and Chimeric Dissection with Somatically Related PG9: Structure-Function Analysis of Two Quaternary-Specific Antibodies That Effectively Neutralize HIV-1. J. Virol., 84(16):8098-8110, Aug 2010. PubMed ID: 20538861.
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Pancera2013
Marie Pancera, Syed Shahzad-ul-Hussan, Nicole A. Doria-Rose, Jason S. McLellan, Robert T. Bailer, Kaifan Dai, Sandra Loesgen, Mark K. Louder, Ryan P. Staupe, Yongping Yang, Baoshan Zhang, Robert Parks, Joshua Eudailey, Krissey E. Lloyd, Julie Blinn, S. Munir Alam, Barton F. Haynes, Mohammed N. Amin, Lai-Xi Wang, Dennis R. Burton, Wayne C. Koff, Gary J. Nabel, John R. Mascola, Carole A. Bewley, and Peter D. Kwong. Structural Basis for Diverse N-Glycan Recognition by HIV-1-Neutralizing V1-V2-Directed Antibody PG16. Nat. Struct. Mol. Biol., 20(7):804-813, Jul 2013. PubMed ID: 23708607.
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Pantophlet2010
Ralph Pantophlet. Antibody Epitope Exposure and Neutralization of HIV-1. Curr. Pharm. Des., 16(33):3729-3743, 2010. PubMed ID: 21128886.
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Pegu2017
Amarendra Pegu, Ann J. Hessell, John R. Mascola, and Nancy L. Haigwood. Use of Broadly Neutralizing Antibodies for HIV-1 Prevention. Immunol. Rev., 275(1):296-312, Jan 2017. PubMed ID: 28133803.
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Pejchal2010
Robert Pejchal, Laura M. Walker, Robyn L. Stanfield, Sanjay K. Phogat, Wayne C. Koff, Pascal Poignard, Dennis R. Burton, and Ian A. Wilson. Structure and Function of Broadly Reactive Antibody PG16 Reveal an H3 Subdomain That Mediates Potent Neutralization of HIV-1. Proc. Natl. Acad. Sci. U.S.A., 107(25):11483-11488, 22 Jun 2010. PubMed ID: 20534513.
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Pejchal2011
Robert Pejchal, Katie J. Doores, Laura M. Walker, Reza Khayat, Po-Ssu Huang, Sheng-Kai Wang, Robyn L. Stanfield, Jean-Philippe Julien, Alejandra Ramos, Max Crispin, Rafael Depetris, Umesh Katpally, Andre Marozsan, Albert Cupo, Sebastien Maloveste, Yan Liu, Ryan McBride, Yukishige Ito, Rogier W. Sanders, Cassandra Ogohara, James C. Paulson, Ten Feizi, Christopher N. Scanlan, Chi-Huey Wong, John P. Moore, William C. Olson, Andrew B. Ward, Pascal Poignard, William R. Schief, Dennis R. Burton, and Ian A. Wilson. A Potent and Broad Neutralizing Antibody Recognizes and Penetrates the HIV Glycan Shield. Science, 334(6059):1097-1103, 25 Nov 2011. PubMed ID: 21998254.
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Pollara2013
Justin Pollara, Mattia Bonsignori, M. Anthony Moody, Marzena Pazgier, Barton F. Haynes, and Guido Ferrari. Epitope Specificity of Human Immunodeficiency Virus-1 Antibody Dependent Cellular Cytotoxicity (ADCC) Responses. Curr. HIV Res., 11(5):378-387, Jul 2013. PubMed ID: 24191939.
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Prevost2018
Jérémie Prévost, Jonathan Richard, Shilei Ding, Beatriz Pacheco, Roxanne Charlebois, Beatrice H Hahn, Daniel E Kaufmann, and Andrés Finzi. Envelope Glycoproteins Sampling States 2/3 Are Susceptible to ADCC by Sera from HIV-1-Infected Individuals. Virology, 515:38-45, Feb 2018. PubMed ID: 29248757.
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Provine2012
Nicholas M. Provine, Valerie Cortez, Vrasha Chohan, and Julie Overbaugh. The Neutralization Sensitivity of Viruses Representing Human Immunodeficiency Virus Type 1 Variants of Diverse Subtypes from Early in Infection Is Dependent on Producer Cell, as Well as Characteristics of the Specific Antibody and Envelope Variant. Virology, 427(1):25-33, 25 May 2012. PubMed ID: 22369748.
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Pugach2015
Pavel Pugach, Gabriel Ozorowski, Albert Cupo, Rajesh Ringe, Anila Yasmeen, Natalia de Val, Ronald Derking, Helen J. Kim, Jacob Korzun, Michael Golabek, Kevin de Los Reyes, Thomas J. Ketas, Jean-Philippe Julien, Dennis R. Burton, Ian A. Wilson, Rogier W. Sanders, P. J. Klasse, Andrew B. Ward, and John P. Moore. A Native-Like SOSIP.664 Trimer Based on an HIV-1 Subtype B env Gene. J. Virol., 89(6):3380-3395, Mar 2015. PubMed ID: 25589637.
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Qi2016
Yifei Qi, Sunhwan Jo, and Wonpil Im. Roles of Glycans in Interactions between gp120 and HIV Broadly Neutralizing Antibodies. Glycobiology, 26(3):251-260, Mar 2016. PubMed ID: 26537503.
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Rademeyer2016
Cecilia Rademeyer, Bette Korber, Michael S. Seaman, Elena E. Giorgi, Ruwayhida Thebus, Alexander Robles, Daniel J. Sheward, Kshitij Wagh, Jetta Garrity, Brittany R. Carey, Hongmei Gao, Kelli M. Greene, Haili Tang, Gama P. Bandawe, Jinny C. Marais, Thabo E. Diphoko, Peter Hraber, Nancy Tumba, Penny L. Moore, Glenda E. Gray, James Kublin, M. Juliana McElrath, Marion Vermeulen, Keren Middelkoop, Linda-Gail Bekker, Michael Hoelscher, Leonard Maboko, Joseph Makhema, Merlin L. Robb, Salim Abdool Karim, Quarraisha Abdool Karim, Jerome H. Kim, Beatrice H. Hahn, Feng Gao, Ronald Swanstrom, Lynn Morris, David C. Montefiori, and Carolyn Williamson. Features of Recently Transmitted HIV-1 Clade C Viruses that Impact Antibody Recognition: Implications for Active and Passive Immunization. PLoS Pathog., 12(7):e1005742, Jul 2016. PubMed ID: 27434311.
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Ren2018
Yanqin Ren, Maria Korom, Ronald Truong, Dora Chan, Szu-Han Huang, Colin C. Kovacs, Erika Benko, Jeffrey T. Safrit, John Lee, Hermes Garbán, Richard Apps, Harris Goldstein, Rebecca M. Lynch, and R. Brad Jones. Susceptibility to Neutralization by Broadly Neutralizing Antibodies Generally Correlates with Infected Cell Binding for a Panel of Clade B HIV Reactivated from Latent Reservoirs. J. Virol., 92(23), 1 Dec 2018. PubMed ID: 30209173.
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Ringe2011
Rajesh Ringe, Deepak Sharma, Susan Zolla-Pazner, Sanjay Phogat, Arun Risbud, Madhuri Thakar, Ramesh Paranjape, and Jayanta Bhattacharya. A Single Amino Acid Substitution in the C4 Region in gp120 Confers Enhanced Neutralization of HIV-1 by Modulating CD4 Binding Sites and V3 Loop. Virology, 418(2):123-132, 30 Sep 2011. PubMed ID: 21851958.
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Ringe2012
Rajesh Ringe, Sanjay Phogat, and Jayanta Bhattacharya. Subtle Alteration of Residues Including N-Linked Glycans in V2 Loop Modulate HIV-1 Neutralization by PG9 and PG16 Monoclonal Antibodies. Virology, 426(1):34-41, 25 Apr 2012. PubMed ID: 22314018.
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Roark2021
Ryan S. Roark, Hui Li, Wilton B. Williams, Hema Chug, Rosemarie D. Mason, Jason Gorman, Shuyi Wang, Fang-Hua Lee, Juliette Rando, Mattia Bonsignori, Kwan-Ki Hwang, Kevin O. Saunders, Kevin Wiehe, M. Anthony Moody, Peter T. Hraber, Kshitij Wagh, Elena E. Giorgi, Ronnie M. Russell, Frederic Bibollet-Ruche, Weimin Liu, Jesse Connell, Andrew G. Smith, Julia DeVoto, Alexander I. Murphy, Jessica Smith, Wenge Ding, Chengyan Zhao, Neha Chohan, Maho Okumura, Christina Rosario, Yu Ding, Emily Lindemuth, Anya M. Bauer, Katharine J. Bar, David Ambrozak, Cara W. Chao, Gwo-Yu Chuang, Hui Geng, Bob C. Lin, Mark K. Louder, Richard Nguyen, Baoshan Zhang, Mark G. Lewis, Donald D. Raymond, Nicole A. Doria-Rose, Chaim A. Schramm, Daniel C. Douek, Mario Roederer, Thomas B. Kepler, Garnett Kelsoe, John R. Mascola, Peter D. Kwong, Bette T. Korber, Stephen C. Harrison, Barton F. Haynes, Beatrice H. Hahn, and George M. Shaw. Recapitulation of HIV-1 Env-Antibody Coevolution in Macaques Leading to Neutralization Breadth. Science, 371(6525), 8 Jan 2021. PubMed ID: 33214287.
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Rolland2012
Morgane Rolland, Paul T. Edlefsen, Brendan B. Larsen, Sodsai Tovanabutra, Eric Sanders-Buell, Tomer Hertz, Allan C. deCamp, Chris Carrico, Sergey Menis, Craig A. Magaret, Hasan Ahmed, Michal Juraska, Lennie Chen, Philip Konopa, Snehal Nariya, Julia N. Stoddard, Kim Wong, Hong Zhao, Wenjie Deng, Brandon S. Maust, Meera Bose, Shana Howell, Adam Bates, Michelle Lazzaro, Annemarie O'Sullivan, Esther Lei, Andrea Bradfield, Grace Ibitamuno, Vatcharain Assawadarachai, Robert J. O'Connell, Mark S. deSouza, Sorachai Nitayaphan, Supachai Rerks-Ngarm, Merlin L. Robb, Jason S. McLellan, Ivelin Georgiev, Peter D. Kwong, Jonathan M. Carlson, Nelson L. Michael, William R. Schief, Peter B. Gilbert, James I. Mullins, and Jerome H. Kim. Increased HIV-1 Vaccine Efficacy against Viruses with Genetic Signatures in Env V2. Nature, 490(7420):417-420, 18 Oct 2012. PubMed ID: 22960785.
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Rosenberg2015
Yvonne Rosenberg, Markus Sack, David Montefiori, Celia Labranche, Mark Lewis, Lori Urban, Lingjun Mao, Rainer Fischer, and Xiaoming Jiang. Pharmacokinetics and Immunogenicity of Broadly Neutralizing HIV Monoclonal Antibodies in Macaques. PLoS One, 10(3):e0120451, 25 Mar 2015. PubMed ID: 25807114.
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Rudometova2022
N. B. Rudometova, N. S. Shcherbakova, D. N. Shcherbakov, O. S. Taranov, B. N. Zaitsev, and L. I. Karpenko. Construction and Characterization of HIV-1 env-Pseudoviruses of the Recombinant Form CRF63_02A and Subtype A6. Bull Exp Biol Med, 172(6):729-733 doi, Apr 2022. PubMed ID: 35501651
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Rusert2016
Peter Rusert, Roger D. Kouyos, Claus Kadelka, Hanna Ebner, Merle Schanz, Michael Huber, Dominique L. Braun, Nathanael Hozé, Alexandra Scherrer, Carsten Magnus, Jacqueline Weber, Therese Uhr, Valentina Cippa, Christian W. Thorball, Herbert Kuster, Matthias Cavassini, Enos Bernasconi, Matthias Hoffmann, Alexandra Calmy, Manuel Battegay, Andri Rauch, Sabine Yerly, Vincent Aubert, Thomas Klimkait, Jürg Böni, Jacques Fellay, Roland R. Regoes, Huldrych F. Günthard, Alexandra Trkola, and Swiss HIV Cohort Study. Determinants of HIV-1 Broadly Neutralizing Antibody Induction. Nat. Med., 22(11):1260-1267, Nov 2016. PubMed ID: 27668936.
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Saha2012
Piyali Saha, Sanchari Bhattacharyya, Sannula Kesavardhana, Edward Roshan Miranda, P. Shaik Syed Ali, Deepak Sharma, and Raghavan Varadarajan. Designed Cyclic Permutants of HIV-1 gp120: Implications for Envelope Trimer Structure and Immunogen Design. Biochemistry, 51(9):1836-1847, 6 Mar 2012. PubMed ID: 22329717.
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Sajadi2012
Mohammad M. Sajadi, George K. Lewis, Michael S. Seaman, Yongjun Guan, Robert R. Redfield, and Anthony L. DeVico. Signature Biochemical Properties of Broadly Cross-Reactive HIV-1 Neutralizing Antibodies in Human Plasma. J. Virol., 86(9):5014-5025, May 2012. PubMed ID: 22379105.
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Sanchez-Merino2016
V. Sanchez-Merino, A. Fabra-Garcia, N. Gonzalez, D. Nicolas, A. Merino-Mansilla, C. Manzardo, J. Ambrosioni, A. Schultz, A. Meyerhans, J. R. Mascola, J. M. Gatell, J. Alcami, J. M. Miro, and E. Yuste. Detection of Broadly Neutralizing Activity within the First Months of HIV-1 Infection. J. Virol., 90(11):5231-5245, 1 Jun 2016. PubMed ID: 26984721.
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Sanders2013
Rogier W. Sanders, Ronald Derking, Albert Cupo, Jean-Philippe Julien, Anila Yasmeen, Natalia de Val, Helen J. Kim, Claudia Blattner, Alba Torrents de la Peña, Jacob Korzun, Michael Golabek, Kevin de los Reyes, Thomas J. Ketas, Marit J. van Gils, C. Richter King, Ian A. Wilson, Andrew B. Ward, P. J. Klasse, and John P. Moore. A Next-Generation Cleaved, Soluble HIV-1 Env Trimer, BG505 SOSIP.664 gp140, Expresses Multiple Epitopes for Broadly Neutralizing but not Non-Neutralizing Antibodies. PLoS Pathog., 9(9):e1003618, Sep 2013. PubMed ID: 24068931.
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Sather2014
D. Noah Sather, Sara Carbonetti, Delphine C. Malherbe, Franco Pissani, Andrew B. Stuart, Ann J. Hessell, Mathew D. Gray, Iliyana Mikell, Spyros A. Kalams, Nancy L. Haigwood, and Leonidas Stamatatos. Emergence of Broadly Neutralizing Antibodies and Viral Coevolution in Two Subjects during the Early Stages of Infection with Human Immunodeficiency Virus Type 1. J. Virol., 88(22):12968-12981, Nov 2014. PubMed ID: 25122781.
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Sattentau2010
Quentin J. Sattentau and Andrew J. McMichael. New Templates for HIV-1 Antibody-Based Vaccine Design. F1000 Biol. Rep., 2:60, 2010. PubMed ID: 21173880.
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Schorcht2020
Anna Schorcht, Tom L. G. M. van den Kerkhof, Christopher A. Cottrell, Joel D. Allen, Jonathan L. Torres, Anna-Janina Behrens, Edith E. Schermer, Judith A. Burger, Steven W. de Taeye, Alba Torrents de la Peña, Ilja Bontjer, Stephanie Gumbs, Gabriel Ozorowski, Celia C. LaBranche, Natalia de Val, Anila Yasmeen, Per Johan Klasse, David C. Montefiori, John P. Moore, Hanneke Schuitemaker, Max Crispin, Marit J. van Gils, Andrew B. Ward, and Rogier W. Sanders. Neutralizing Antibody Responses Induced by HIV-1 Envelope Glycoprotein SOSIP Trimers Derived from Elite Neutralizers. J. Virol., 94(24), 23 Nov 2020. PubMed ID: 32999024.
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Scott2015
Yanille M. Scott, Seo Young Park, and Charlene S. Dezzutti. Broadly Neutralizing Anti-HIV Antibodies Prevent HIV Infection of Mucosal Tissue Ex Vivo. Antimicrob. Agents Chemother., 60(2):904-912, Feb 2016. PubMed ID: 26596954.
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Shang2011
Hong Shang, Xiaoxu Han, Xuanling Shi, Teng Zuo, Mark Goldin, Dan Chen, Bing Han, Wei Sun, Hao Wu, Xinquan Wang, and Linqi Zhang. Genetic and Neutralization Sensitivity of Diverse HIV-1 env Clones from Chronically Infected Patients in China. J. Biol. Chem., 286(16):14531-14541, 22 Apr 2011. PubMed ID: 21325278.
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Shivatare2013
Sachin S. Shivatare, Shih-Huang Chang, Tsung-I Tsai, Chien-Tai Ren, Hong-Yang Chuang, Li Hsu, Chih-Wei Lin, Shiou-Ting Li, Chung-Yi Wu, and Chi-Huey Wong. Efficient Convergent Synthesis of Bi-, Tri-, and Tetra-Antennary Complex Type N-Glycans and Their HIV-1 Antigenicity. J. Am. Chem. Soc., 135(41):15382-15391, 16 Oct 2013. PubMed ID: 24032650.
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Sliepen2015
Kwinten Sliepen, Max Medina-Ramirez, Anila Yasmeen, John P. Moore, Per Johan Klasse, and Rogier W. Sanders. Binding of Inferred Germline Precursors of Broadly Neutralizing HIV-1 Antibodies to Native-Like Envelope Trimers. Virology, 486:116-120, Dec 2015. PubMed ID: 26433050.
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Sliepen2019
Kwinten Sliepen, Byung Woo Han, Ilja Bontjer, Petra Mooij, Fernando Garces, Anna-Janina Behrens, Kimmo Rantalainen, Sonu Kumar, Anita Sarkar, Philip J. M. Brouwer, Yuanzi Hua, Monica Tolazzi, Edith Schermer, Jonathan L. Torres, Gabriel Ozorowski, Patricia van der Woude, Alba Torrents de la Pena, Marielle J. van Breemen, Juan Miguel Camacho-Sanchez, Judith A. Burger, Max Medina-Ramirez, Nuria Gonzalez, Jose Alcami, Celia LaBranche, Gabriella Scarlatti, Marit J. van Gils, Max Crispin, David C. Montefiori, Andrew B. Ward, Gerrit Koopman, John P. Moore, Robin J. Shattock, Willy M. Bogers, Ian A. Wilson, and Rogier W. Sanders. Structure and immunogenicity of a stabilized HIV-1 envelope trimer based on a group-M consensus sequence. Nat Commun, 10(1):2355 doi, May 2019. PubMed ID: 31142746
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Stefic2019
Karl Stefic, Mélanie Bouvin-Pley, Asma Essat, Clara Visdeloup, Alain Moreau, Cécile Goujard, Marie-Laure Chaix, Martine Braibant, Laurence Meyer, and Francis Barin. Sensitivity to Broadly Neutralizing Antibodies of Recently Transmitted HIV-1 Clade CRF02\_AG Viruses with a Focus on Evolution over Time. J. Virol., 93(2), 15 Jan 2019. PubMed ID: 30404804.
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Stewart-Jones2016
Guillaume B. E. Stewart-Jones, Cinque Soto, Thomas Lemmin, Gwo-Yu Chuang, Aliaksandr Druz, Rui Kong, Paul V. Thomas, Kshitij Wagh, Tongqing Zhou, Anna-Janina Behrens, Tatsiana Bylund, Chang W. Choi, Jack R. Davison, Ivelin S. Georgiev, M. Gordon Joyce, Young Do Kwon, Marie Pancera, Justin Taft, Yongping Yang, Baoshan Zhang, Sachin S. Shivatare, Vidya S. Shivatare, Chang-Chun D. Lee, Chung-Yi Wu, Carole A. Bewley, Dennis R. Burton, Wayne C. Koff, Mark Connors, Max Crispin, Ulrich Baxa, Bette T. Korber, Chi-Huey Wong, John R. Mascola, and Peter D. Kwong. Trimeric HIV-1-Env Structures Define Glycan Shields from Clades A, B, and G. Cell, 165(4):813-826, 5 May 2016. PubMed ID: 27114034.
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Thenin2012
Suzie Thenin, Tanawan Samleerat, Elsa Tavernier, Nicole Ngo-Giang-Huong, Gonzague Jourdain, Marc Lallemant, Francis Barin, and Martine Braibant. Envelope Glycoproteins of Human Immunodeficiency Virus Type 1 Variants Issued from Mother-Infant Pairs Display a Wide Spectrum of Biological Properties. Virology, 426(1):12-21, 25 Apr 2012. PubMed ID: 22310702.
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Thenin2012a
Suzie Thenin, Emmanuelle Roch, Tanawan Samleerat, Thierry Moreau, Antoine Chaillon, Alain Moreau, Francis Barin, and Martine Braibant. Naturally Occurring Substitutions of Conserved Residues in Human Immunodeficiency Virus Type 1 Variants of Different Clades Are Involved in PG9 and PG16 Resistance to Neutralization. J. Gen. Virol., 93(7):1495-1505, Jul 2012. PubMed ID: 22492917.
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Tomaras2010
Georgia D. Tomaras and Barton F. Haynes. Strategies for Eliciting HIV-1 Inhibitory Antibodies. Curr. Opin. HIV AIDS, 5(5):421-427, Sep 2010. PubMed ID: 20978384.
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Tomaras2011
Georgia D. Tomaras, James M. Binley, Elin S. Gray, Emma T. Crooks, Keiko Osawa, Penny L. Moore, Nancy Tumba, Tommy Tong, Xiaoying Shen, Nicole L. Yates, Julie Decker, Constantinos Kurt Wibmer, Feng Gao, S. Munir Alam, Philippa Easterbrook, Salim Abdool Karim, Gift Kamanga, John A. Crump, Myron Cohen, George M. Shaw, John R. Mascola, Barton F. Haynes, David C. Montefiori, and Lynn Morris. Polyclonal B Cell Responses to Conserved Neutralization Epitopes in a Subset of HIV-1-Infected Individuals. J. Virol., 85(21):11502-11519, Nov 2011. PubMed ID: 21849452.
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Tong2012
Tommy Tong, Ema T. Crooks, Keiko Osawa, and James M. Binley. HIV-1 Virus-Like Particles Bearing Pure Env Trimers Expose Neutralizing Epitopes but Occlude Nonneutralizing Epitopes. J. Virol., 86(7):3574-3587, Apr 2012. PubMed ID: 22301141.
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Upadhyay2014
Chitra Upadhyay, Luzia M. Mayr, Jing Zhang, Rajnish Kumar, Miroslaw K. Gorny, Arthur Nádas, Susan Zolla-Pazner, and Catarina E. Hioe. Distinct Mechanisms Regulate Exposure of Neutralizing Epitopes in the V2 and V3 Loops of HIV-1 Envelope. J. Virol., 88(21):12853-12865, Nov 2014. PubMed ID: 25165106.
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vandenKerkhof2013
Tom L. G. M. van den Kerkhof, K. Anton Feenstra, Zelda Euler, Marit J. van Gils, Linda W. E. Rijsdijk, Brigitte D. Boeser-Nunnink, Jaap Heringa, Hanneke Schuitemaker, and Rogier W. Sanders. HIV-1 Envelope Glycoprotein Signatures That Correlate with the Development of Cross-Reactive Neutralizing Activity. Retrovirology, 10:102, 23 Sep 2013. PubMed ID: 24059682.
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Tom L. G. M. van den Kerkhof, Steven W. de Taeye, Brigitte D. Boeser-Nunnink, Dennis R. Burton, Neeltje A. Kootstra, Hanneke Schuitemaker, Rogier W. Sanders, and Marit J. van Gils. HIV-1 escapes from N332-directed antibody neutralization in an elite neutralizer by envelope glycoprotein elongation and introduction of unusual disulfide bonds. Retrovirology, 13(1):48, 7 Jul 2016. PubMed ID: 27388013.
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Veillette2014
Maxime Veillette, Anik Désormeaux, Halima Medjahed, Nour-Elhouda Gharsallah, Mathieu Coutu, Joshua Baalwa, Yongjun Guan, George Lewis, Guido Ferrari, Beatrice H. Hahn, Barton F. Haynes, James E. Robinson, Daniel E. Kaufmann, Mattia Bonsignori, Joseph Sodroski, and Andres Finzi. Interaction with Cellular CD4 Exposes HIV-1 Envelope Epitopes Targeted by Antibody-Dependent Cell-Mediated Cytotoxicity. J. Virol., 88(5):2633-2644, Mar 2014. PubMed ID: 24352444.
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vonBredow2016
Benjamin von Bredow, Juan F. Arias, Lisa N. Heyer, Brian Moldt, Khoa Le, James E. Robinson, Susan Zolla-Pazner, Dennis R. Burton, and David T. Evans. Comparison of Antibody-Dependent Cell-Mediated Cytotoxicity and Virus Neutralization by HIV-1 Env-Specific Monoclonal Antibodies. J. Virol., 90(13):6127-6139, 1 Jul 2016. PubMed ID: 27122574.
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Voss2017
James E. Voss, Raiees Andrabi, Laura E. McCoy, Natalia de Val, Roberta P. Fuller, Terrence Messmer, Ching-Yao Su, Devin Sok, Salar N. Khan, Fernando Garces, Laura K. Pritchard, Richard T. Wyatt, Andrew B. Ward, Max Crispin, Ian A. Wilson, and Dennis R. Burton. Elicitation of Neutralizing Antibodies Targeting the V2 Apex of the HIV Envelope Trimer in a Wild-Type Animal Model. Cell Rep., 21(1):222-235, 3 Oct 2017. PubMed ID: 28978475.
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Voss2019
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Displaying record number 2642
Download this epitope
record as JSON.
MAb ID |
PGT128 (PGT-128) |
HXB2 Location |
Env |
Env Epitope Map
|
Author Location |
|
Epitope |
|
Ab Type |
gp120 V3 // V3 glycan (V3g) |
Neutralizing |
P View neutralization details |
Contacts and Features |
View contacts and features |
Species
(Isotype)
|
human(IgG1) |
Patient |
Donor 36 |
Immunogen |
HIV-1 infection |
Keywords |
anti-idiotype, antibody binding site, antibody gene transfer, antibody generation, antibody interactions, antibody lineage, antibody polyreactivity, antibody sequence, assay or method development, autoantibody or autoimmunity, autologous responses, binding affinity, broad neutralizer, chimeric antibody, computational prediction, contact residues, dynamics, effector function, elite controllers and/or long-term non-progressors, escape, germline, glycosylation, immunoprophylaxis, immunotherapy, kinetics, memory cells, mimics, mutation acquisition, neutralization, polyclonal antibodies, rate of progression, review, SIV, structure, subtype comparisons, therapeutic vaccine, vaccine antigen design, vaccine-induced immune responses, variant cross-reactivity, viral fitness and/or reversion |
Notes
Showing 110 of
110 notes.
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PGT128: Eighty clusters of overlapping epitopes that could bind to MHC Class II HLA-DR1*01:01 (DR1) allele were identified by LC-MS/MS using a cell-free processing system that incorporated soluble DR1, HLA-DM (DM), cathepsins, and full-length protein antigens (Gag, Pol, Env, Vif, Tat, Rev, and Nef). Sixteen of Env CD4+ T cell epitopes identified in this study, which were primarily located in the vicinity of the gp120/gp41 interface or the CD4bs, were assessed for overlap with bnAb binding footprints. Only unglycosylated TGE320-328 (TGEIIGDIR) overlapped with the binding footprint of V3 glycan-targeting bnAb PGT127/128.
Sengupta2023
(antibody binding site)
-
PGT128: The study describes the generation, crystal structure, and immunogenic properties of a native-like Env SOSIP trimer based on a group M consensus (ConM) sequence. A crystal structure of ConM SOSIP.v7 trimer together with nAbs PGT124 and 35O22 revealed that ConM SOSIP.v7 is structurally similar to other Env trimers. In rabbits, the ConM SOSIP trimer induced serum nAbs that neutralized the autologous Tier 1A virus (ConM from 2004) and a related Tier 1B ConS virus (ConM from 2001). These responses target the trimer apex and were enhanced when the trimers were presented on ferritin nanoparticles. The neutralization of ConM and ConS pseudoviruses was tested against a large panel of nAbs and non-nAbs (2219, 2557, 3074, 3869, 447-52D, 830A, 654-30D, 1008-30D, 1570D, 729-30D, F105, 181D, 246D, 50-69D, sCD4, VRC01, 3BNC117, CH31, PG9, PG16, CH01, PGDM1400, PGT128, PGT121, 10-1074, PGT151, VRC43.01, 2G12, DH511.2_K3, 10E8, 2F5, 4E10); most nAbs were able to neutralize these pseudoviruses. Soluble ConM trimers were able to weakly activate B cells expressing PGT121 and PG16 BCRs but were inactive against those expressing VRC01 and PGT145. In contrast, at the same molar amount of trimers, the ConM SOSIP.v7-ferritin nanoparticles activated all 4 B cells efficiently. Binding of bnAbs 2G12 and PGT145 and non-nAbs F105 and 19b to ConM SOSIP.v7 trimer and SOSIP showed that the ferritin-bound trimer bound more avidly than the soluble trimer. This study shows that native-like HIV-1 Env trimers can be generated from consensus sequences, and such immunogens might be suitable vaccine components to prime and/or boost desirable nAb responses.
Sliepen2019
(neutralization, vaccine antigen design)
-
PGT128: A SHIV carrying a highly neutralization-sensitive Env (SHIVCNE40) was passaged in macaques. SHIVCNE40 developed enhanced replication kinetics associated with neutralization resistance against autologous serum, CD4-Ig, and several nAbs (17b, 3BNC117, N6, PGT145, PGT121, PGT128, 35O22, 2F5, 10E8). A gp41 substitution, E658K, was the major determinant for this resistance. Structural modeling and functional verification indicate that the substitution disrupts an intermolecular salt bridge with the neighboring protomer, thereby promoting fusion and facilitating immune evasion. This effect is applicable across many HIV-1 viruses of diverse subtypes. These results highlight the critical role of gp41 in shaping the neutralization profile and conformation of Env during viral adaptation. The unique intermolecular salt bridge could potentially be utilized for rational vaccine design involving more stable HIV-1 Env trimers.
Wang2019
(mutation acquisition, neutralization, structure)
-
PGT128: A panel of 30 contemporary subtype B pseudoviruses (PSVs) was generated. Neutralization sensitivities of these PSVs were compared with subtype B strains from earlier in the pandemic using 31 nAbs (PG9, PG16, PGT145, PGDM1400, CH02, CH03, CH04, 830A, PGT121, PGT126, PGT128, PGT130, 10-1074, 2192, 2219, 3074, 3869, 447-52D, b12, NIH45-46, VRC01, VRC03, 3BNC117, HJ16, sCD4, 10E8, 4E10, 2F5, 7H6, 2G12, 35O22). A significant reduction in Env neutralization sensitivity was observed for 27 out of 31 nAbs for the contemporary, as compared to earlier-decade subtype B PSVs. A decline in neutralization sensitivity was observed across all Env domains; the nAbs that were most potent early in the pandemic suffered the greatest decline in potency over time. A metaanalysis demonstrated this trend across multiple subtypes. As HIV-1 Env diversification continues, changes in Env antigenicity and neutralization sensitivity should continue to be evaluated to inform the development of improved vaccine and antibody products to prevent and treat HIV-1.
Wieczorek2023
(neutralization, viral fitness and/or reversion)
-
PGT128:This study identified a B cell lineage of bNAbs in an HIV-1 elite post-treatment controller (ePTC; donor: PTC-005002). Circulating viruses in PTC escaped bNAb pressure but remained sensitive to autologous neutralization by other Ab populations. PGT128 was used as a reference control IgG. Inhibition of EPTC112 binding to SOSIP was mainly evidenced with anti-V3-glycan bNAb PGT128 (55%–77% blocking range)
Molinos-Albert2023
(binding affinity)
-
PGT128: Two conserved tyrosine (Y) residues within the V2 loop of gp120, Y173 and Y177, were mutated individually or in combination, to either phenylalanine (F) or alanine (A) in several strains of diverse subtypes. In general, these mutations increased neutralization sensitivity, with a greater impact of Y177 over Y173 single mutations, of double over single mutations, and of A over F substitutions. The Y173A Y177A double mutation in HIV-1 BaL increased sensitivity to most of the weakly neutralizing MAbs tested (2158, 447-D, 268-D, B4e8, D19, 17b, 48d, 412d) and even rendered the virus sensitive to non-neutralizing antibodies against the CD4 binding site (F105, 654-30D, and b13). In the case of V2 mAb 697-30D, residue Y173 is part of its epitope, and thus abrogates its binding and has no effect on neutralization; the Y177A mutant alone did increase neutralization sensitivity to this mAb. When the double mutant was tested against bnAbs, there was a large decrease in neutralization sensitivity compared to WT for many bnAbs that target V1, V2, or V3 (PG9, PG16, VRC26.08, VRC38, PGT121, PGT122, PGT123, PGT126, PGT128, PGT130, PGT135, VRC24, CH103). The double mutation had lesser or no effect on neutralization by one V3 bnAb (2G12) and by most bnAbs targeting the CD4 binding site (VRC01, VRC07, VRC03, VRC-PG04, VRC-CH31, 12A12, 3BNC117, N6), the gp120-gp41 interface (35O22, PGT151), or the MPER (2F5, 4E10, 10E8).
Guzzo2018
(antibody binding site, neutralization)
-
PGT128: This study explored the basis of the neutralization resistance of tier 3 virus 253-11 (subtype CRF02_AG). Virus 253-11 was resistant to neutralization by 17b, b12, VRC03, F105, SCD4, CH12, Z13e1, PG16, PGT145, 2G12, PGT121, PGT126, PGT128, PGT130, 39F, F240, and 35O22; the virus was sensitive to 3BNC117, NIH45-46G54W, VRC01, 10E8, 2F5, 4E10, PG9, VRC26.26, 10-1074, and PGT151. Virus 253-11 was strikingly resistant to most tested antibodies that target V3/glycans, despite possessing key potential N-linked glycosylation sites, especially N301 and N332, needed for the recognition of this class of antibodies. The resistance of 253-11 was not associated with an unusually long V1/V2 loop, nor with polymorphisms in the V3 loop and N-linked glycosylation sites. The 253-11 MPER was rarely recognized by sera, but was more often recognized in a chimera consisting of a HIV-2 backbone with the 253-11 MPER, suggesting steric or kinetic hindrance of the MPER. Mutations in the 253-11 MPER previously reported to increase the lifetime of the prefusion Env conformation (Y681H, L669S), decreased the resistance of 253-11 to several mAbs, presumably destabilizing its otherwise stable, closed trimer structure. A crystal structure of a recombinant 253-11 SOSIP trimer revealed that the heptad repeat helices in gp41 are drawn in close proximity to the trimer axis and that gp120 protomers also showed a relatively compact form around the trimer axis.
Moyo2018
(neutralization, structure)
-
PGT128: This study assessed the ability of single bNAbs and triple bNAb combinations to mediate polyfunctional antiviral activity against a panel of cross-clade simian-human immunodeficiency viruses (SHIVs), which are commonly used as tools for validation of therapeutic strategies in nonhuman primate models. Most bnAbs assayed were capable of mediating both neutralizing and nonneutralizing effector functions (ADCC and ADCP) against cross-clade SHIVs, although the susceptibility to V3 glycan-specific bNAbs was highly strain dependent. Several triple bNAb combinations were identified comprising of CD4 binding site-, V2-glycan-, and gp120-gp41 interface-targeting bNAbs that are capable of mediating synergistic polyfunctional antiviral activities against multiple clade A, B, C, and D SHIVs. In assays using the transmitted/founder SHIV.C.CH505, there was a correlation between the neutralization potencies and nonneutralizing effector functions of bnAbs: PGT128 was negative for neutralization, ADCC, and binding to infected cells.
Berendam2021
(effector function, neutralization, binding affinity, broad neutralizer)
-
PGT128: This study used directed evolution to overcome the instability and heterogeneity of a primary Env isolate (ADA) in order to design better immunogens. HIV-1 virions were subjected to iterative cycles of destabilization and replication to select for Envs with enhanced stability. Several mutations in Env were associated with increased trimer stability, primarily in the heptad repeat regions of gp41 and V1 of gp120. Mutations from the most stable Envs were combined into a variant Env, termed "comb-mut", with superior homogeneity and stability. Comb-mut had greater binding affinity for PGT128, PG9, PG16, 2G12, VRC01, b12, and CD4-IgG2, but decreased binding to 4E10, 2F5, b6, 19b, 17b, 7B2, and D50. Comb-mut was more sensitive to neutralization by PG9. One specific mutation (K574) was shown to decrease the neutralization IC50 of mAbs b12, 2F5, 4E10, b6, 2G12, 8K8 and inhibitors sCD4, T-20, and PF-68742. Several of the Env substitutions were shown to stabilize Env spikes from HIV-1 clades A, B, and C. Spike stabilizing mutations may be useful in the development of Env immunogens that stably retain native, trimeric structure.
Leaman2013
(mimics, vaccine antigen design, binding affinity)
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PGT128: Using subtype A BG505 Env structural information, improved variants of subtype B JRFL and subtype C 16055 Env native flexibly linked (NFL) trimers were generated. The trimer-derived (TD) residues that increased well-ordered, homogeneous, stable, and soluble trimers did not require positive or negative selection as previously needed [Guenaga2015, PLoS Pathos. 11(1):e1004570]. PGT128 and PGT121 both bound the NFL TD Env with high avidity, this was particularly relevant to the 16055 TD trimer in which N332 was introduced into the supersite for glycan presence as opposed to the native 16055 Env.
Guenaga2015a
(antibody interactions, assay or method development, vaccine antigen design, structure)
-
PGT128: Most published structures of bnAbs, yet none of non- or poorly-neutralizing mAbs, were structurally compatible with a newly generated crystal structure of a mature ligand-free endoglycosidase H-treated BG505 SOSIP.664 Env trimer. Robust binding of the structurally incompatible V3- and CD4-bs targeting nAbs could be induced with CD4. A “DS” variant of BG505 SOSIP.664, containing a stabilizing disulfide bond between 201C and 433C mutations, was developed and appeared to represent an obligate intermediate in that it bound only a single CD4 and remained in a prefusion closed conformation. BnAb PGT128 was structurally compatible with BG505 SOSIP.664 and had a breadth of 64% (IC50 < 50 μg/ml) in a panel of 170 diverse HIV-1 pseudoviruses. PGT128 had SPR KD values of 158 and 78.4 nM, respectively, when binding to BG505 SOSIP.664 wildtype and DS variant.
Kwon2015
(neutralization, vaccine antigen design, binding affinity, structure)
-
PGT128: This study reports on bispecific antibodies in which one arm is a single-chain (scFv) form of a V2-glycan antibody (VRC26.25 or PGT145), and the other arm is a V3-glycan Fab (10-1074, PGT121, or PGT128). A linker was used consisting of 10 repeats of tetraglycine-serine (10GS); additionally, KIH (knob in hole) mutations were introduced for stabilization. Some of these bispecific antibodies are markedly more potent than their parental bNAbs, likely because they simultaneously engage both the V2-apex and V3-glycan epitopes of Env.
Davis-Gardner2020
(neutralization, broad neutralizer)
-
PGT128: This study examined whether HIV-1-specific bnAbs are capable of cross-neutralizing simian immunodeficiency viruses (SIVs) from chimpanzees (n=11) or western gorillas (n=1). BnAbs directed against the epitopes at the CD4 binding site (VRC01, VRC03, VRC-PG04, VRC-CH03, VRC-CH31, F105, b13, NIH45-46G54W, 45-46m2, 45-46m7), V3 (10-1074, PGT121, PGT128, PGT135, and 2G12), and gp41-gp120 interface (8ANC195, 35O22, PGT151, PGT152, PGT158) failed to neutralize SIVcpz and SIVgor strains. V2-directed bNabs (PG9, PG16, PGT145) as well as llama-derived heavy-chain only antibodies recognizing the CD4 binding site or gp41 epitopes (JM4, J3, 3E3, 2E7, 11F1F, Bi-2H10) were either completely inactive or neutralized only a fraction of SIVcpz strains. In contrast, neutralization of SIVcpz and SIVgor strains was achieved with low-nanomolar potency by one antibody targeting the MPER region of gp41 (10E8), as well as functional CD4 and CCR5 receptor mimetics (eCD4-Ig, eCD4-Igmim2, CD4-218.3-E51, CD4-218.3-E51-mim2), mono- and bispecific anti-human CD4 mAbs (iMab, PG9-iMab, PG16-iMab, LM52, LM52-PGT128), and CCR5 receptor mAbs (PRO140, PRO140-10E8). Importantly, the latter antibodies blocked virus entry not only in TZM-bl cells but also in Cf2Th cells expressing chimpanzee CD4 and CCR5, and neutralized SIVcpz in chimpanzee CD4+ T cells. These findings provide new insight into the protective capacity of anti-HIV-1 bnAbs and identify candidates for further development to combat SIV infection.
Barbian2015
(neutralization, SIV, binding affinity)
-
PGT128: A recombinant native-like Env SOSIP trimer, AMC009, was developed based on viral founder sequences of elite neutralizer H18877. The subtype B AMC009 Env was defined as a Tier 2 virus based on a neutralization assay against well known nAbs (VRC01, 3BNC117, CH31, CH01, PG9, PG16, PGDM1400, 10-1074, PGT128, PGT121, PGT151, VRC34.01, 2G12, 2F5, 4E10, DH511.2.K3_4, 10E8, and the mAb mixture CH01-31).The AMC009 SOSIP protein formed stable native-like trimers that displayed multiple bnAb epitopes. Its overall structure was similar to that of BG505 SOSIP.664, and it resembled one from another elite neutralizer, AMC011, in having a dense and complete glycan shield. When tested as immunogens in rabbits, AMC009 trimers did not induce autologous neutralizing antibody responses efficiently, while the AMC011 trimers did so very weakly, outcomes that may reflect the completeness of their glycan shields. The AMC011 trimer induced antibodies that occasionally cross-neutralized heterologous tier 2 viruses, sometimes at high titer. Cross-neutralizing antibodies were more frequently elicited by a trivalent combination of AMC008, AMC009, and AMC011 trimers, all derived from subtype B viruses. Each of these three individual trimers could deplete the nAb activity from rabbit sera. Mapping the polyclonal sera by electron microscopy revealed that antibodies of multiple specificities could bind to sites on both autologous and heterologous trimers.
Schorcht2020
(neutralization, vaccine-induced immune responses, structure)
-
PGT128: A macaque sequential immunization protocol with increasingly native-like V3-glycan-targeting Env trimers multimerized onto virus-like particles elicited multiple on-target mAbs with heterologous, yet generally weak, neutralization activity and minimal protection in a subsequent intrarectal heterologous challenge with SHIVDH12-V3AD8. The priming immunogen was RC1-4fill (clade A/E, RC1 with 4 additional glycans), a low affinity Env trimer with additional glycans to facilitate V3-glycan targeting and mask BG505 glycan hole, while the boosting immunogens were 11MUTB-4fill (clade A/E), B41-5MUT or B41 wildtype (clade B), AMC011/Du422 (clade B/C), and consensus group M/consensus clade C Env trimers. Rabbits were also immunized once with RC1-4 fill-VLP and produced V3-targeting mAbs with binding poses distinct from the known V3-targeting bnAbs (10-1074, PGT135, PGT128 and BG18). In a RC1 binding assay, PGT128 Fab competed substantially with the shared PGT121/10-1074 inferred germline precursor and moderately with isolated macaque mAbs (Ab1271, Ab1368, Ab1456, Ab1457, and Ab1461), bnAb 10-1074 and itself. After priming, serum from the 8 immunized macaques also displayed strong competition with V3-glycan-targeting PGT128 but this effect diminished after each boost, despite increasing serum responses to RC1. This suggests increasing off-target responses as the immunization protocol progressed, consistent with nsEMPEM observations.
Escolano2021
(antibody interactions, vaccine antigen design, vaccine-induced immune responses)
-
PGT128: HIV-1 bnAbs require high levels of activation-induced cytidine deaminase (AID)-catalyzed somatic mutations. Probable mutations occur at sites of frequent AID activity, while improbable mutations occur where AID activity is infrequent. The paper introduced the ARMADiLLO program, which estimates how probable a particular mAb mutation is, and thus the key improbable mutations were defined for a panel of 26 bnAbs. The number of improbable mutations ranged from 7 (PGT128) to 23 (VRC01 and 35O22); PGT128 had 7 improbable mutations out of 53 total AA mutations, and 11 indels. Single-amino acid reversion mutants were made for key improbable mutations of 3 bnAbs (CH235, VRC01, and BF520.1), and these mutant mAbs were tested for their neutralization ability. The study also noted that bnAbs that had relatively small numbers of improbable single somatic mutations had other unusual characteristics that were due to additional improbable events, such as indels (PGT128) or extraordinary CDR H3 lengths (VRC26.25).
Wiehe2018
(neutralization)
-
PGT128: 3 clonally-related autologously-neutralizing mAbs (43A, 43A1, and 43A2), isolated from rabbit 5743 which was co-immunized with BG505- and B41-based SOSIP soluble trimers [Klasse2016, PMID: 27627672], bind to an immunodominant epitope in V1 overlapping the bnAb N332 glycan supersite without interacting with glycans. All 43A family members, at 2-50 μg/ml concentrations, competed strongly with PGT128 with 8-17% residual binding in a BG505 SOSIP.664 binding assay. Negative-stain electron microscopy determined that the 43A family has an overlapping epitope near the base of V3 and a similar angle of approach as bnAb PGT128. PGT128 made more extensive contacts with Env using its approx. 20 aa-long CDRH3, when compared to 43A2 which interacted with its 13 aa CDRL3. Analysis of known crystal structure of putative precursor of PGT128 Fab bound to BG505 SOSIP.664 (PDB 5ACO) revealed that, compared to an unbound state, the V1 loop has undergone a conformational change to provide PGT121 with access to the GDIR motif. The structures of PGT128 and 43A2 had substantial overlap which suggested that they directly compete for D325, a component of the GDIR motif. Contacts with gp120 side chains can be found in the Env Features and Contacts database at hiv.lanl.gov.
Nogal2020
(antibody interactions, structure, contact residues)
-
PGT128: Of 40 total Env trimer-targeting mAbs isolated from 6 macaques either after 3 priming immunizations with artificial consensus stabilized native-like HIV-1 immunogen ConM SOSIP.v7 or subsequent 2 boosting immunizations with the closely related ConSOSL.UFO.664 immunogen, the V1V2V3 region was immunodominant for the 22 (55%) mAbs that neutralized ConM and/or ConS virus. PGT128 had 75% and 79% residual binding, respectively, when competing individually against biotinylated V1V2V3-targeting mAbs CM02A and CM05A1.
Reiss2022
(antibody interactions, vaccine antigen design)
-
PGT128: To understand early bnAb responses, 51 HIV-1 clade C infected infants were assayed for neutralization of a 12-virus multi-clade panel. Plasma bnAbs targeting V2-apex on Env were predominant in infant elite and broad neutralizers. In infant elite neutralizers, multi-variant infection was associated with plasma bnAbs targeting diverse autologous viruses. A panel of mAbs (PG9, PG16, PGT145, PGDM1400, VRC26.25, 10-1074, BG18, AIIMS-P01, PGT121, PGT128, PGT135, VRC01, N6, 3BNC117, PGT151, 35O22, 10E8, 4E10, F105, 17b, A32, 48d, b6, 447-52d) was assayed for their ability to neutralize Env clones from infant elite neutralizers; circulating viral variants in infant elite neutralizers were most susceptible to V2-apex bnAbs.
Mishra2020a
(neutralization, polyclonal antibodies)
-
PGT128: In vertically-infected infant AIIMS731, a rare HIV-1 mutation in hypervariable loop 2 (L184F) was studied. In patient sequences, this mutation was present in the majority of clones. A panel of 6 V2 bnAbs (PG9, PG16, PGT145, PGDM1400, CAP256.25, and CH01) was assayed for neutralization of 6 patient viral clones. The AIIMS731 viral variants segregated into 4 neutralization-sensitive and 2 resistant clones; sensitive clones carried 184F, while resistant clones carried the rare 184L mutation. A large panel of bnAbs targeting non-V2 epitopes was used to assess the neutralization of the 6 patient viral variants. The bnAb panel consisted of V3/N332 glycan supersite bnAbs (10-1074, BG18, AIIMS-P01, PGT121, PGT128, and PGT135), CD4bs bnAbs (VRC01, VRC03, VRC07-523LS, N6, 3BNC117, and NIH45-46 G54W), a silent face-targeting bnAb (PG05), fusion peptide and gp120-gp41 interface bnAbs (PGT151, 35O22, and N123-VRC34.01), and MPER bnAbs (10E8, 4E10, and 2F5). All of these bnAbs had similar neutralization efficiencies for all 6 clones, suggesting that the L184F mutation was specific for viral escape from neutralization by V2 apex bnAbs. A panel of non-neutralizing mAbs (V3 loop-targeting non-nAbs 447-52D and 19b, and CD4-induced non-nAbs 17b, A32, 48d, and b6), were also assessed; 2 of the variants (the same 2 susceptible to the V2 bnAbs) showed moderate neutralization by 447-52D, 19b, 17b, and 48d. The structure of ligand-free BG505 SOSIP trimer revealed that the side chain of L184 was outward facing and did not make significant intraprotomeric interactions, but upon mutating L184 to F184, a disruption of the accessible surface between the bulky side chain of F184 on one protomer and R165 on the neighboring protomer was seen. Thus, the L184F mutation resulted in increased susceptibility to neutralization by antibodies known to target the relatively more open conformation of Env on tier 1 viruses, suggesting that the rare L184F mutation allowed Env to sample more open states resembling the CD4-bound conformation where the CCR5 binding site is exposed.
Mishra2020
(neutralization, polyclonal antibodies)
-
PGT128: This report characterizes an additional antiviral activity of some bnAbs to block HIV-1 release by tethering viral particles at the surface of infected cells in vitro in a bivalency-dependent manner. After cultivation of infected primary CD4+ T cells with individual bnAbs, supernatant p24 levels were negatively correlated with cell-associated Gag levels, Env binding and neutralization potency while cell-associated Gag levels and Env binding positively correlated with each other and individually with neutralization potency. The capacity to mediate this tethering activity varied among different classes of mAbs: 0/3 non-neutralizing mAbs, 1/5 bnAbs targeting the MPER or gp120/gp41 interface and 9/9 of the bnAbs targeting the V3 and V1/V1 loops or the CD4bs demonstrated this activity against at least 1/3 diverse viral strains (AD8, CH058 and vKB18). Five of these latter 9 bnAbs, including bnAb 10-1074 which had the most potent effect observed in study when cultivated with vKB18-infected CD4+ T cells, displayed tethering activity against all 3 strains. Surface aggregation of mature virions and bnAb 10-1074 was observed in CH058-infected primary CD4+ T cells and CHME macrophage-like cells. V3-targeting bnAb PGT128 displayed tethering activity against all 3 strains.
Dufloo2022
(binding affinity)
-
PGT128: A plant-based expression system was used to produce different glycoforms of the bnAbs PG9, PG16, 10–1074, NIH45–46G54W, 10E8, PGT121, PGT128, PGT145, PGT135, and b12. Also produced were mutated forms (N92T) of VRC01 (mVRC01) and NIH45–46G54W (mNIH45–46G54W). The in vivo properties of these mAbs were assessed in macaques to distinguish those most likely to comprise or become a component of an affordable and efficacious immunotherapeutic cocktails. N-glycans within the VL domain impaired the plasma stability of plant-derived bnAbs. While PGT121 and b12 exhibited no immunogenicity in rhesus macaques, VRC01, 10-1074 and NIH45-46G54W elicited high titer anti-idiotypic antibodies. The results indicated that that specific mutations in certain bnAbs caused immunogenicity in macaques. Such immunogenicity in humans would potentially compromise their value for immunotherapy. CHO1-31 was used as a positive control in a neutralization assay.
Rosenberg2015
(anti-idiotype, neutralization, immunotherapy)
-
PGT128: Since cross-reactive antibodies can interfere in immunoassays, HIV-1 mAbs were tested for binding to the SARS-COV-2 spike (S) protein (SARS-COV-2 S cross-reactivity). The following 9 gp120-epitope binding HIV-1 mAbs are cross-reactive with COV-2 S: 2G12, PGT121, PGT126, PGT128, PGT145, PG9, PG16, 10-1074, and 35O22. CD4bs Abs VRC01 and VRC03 are not cross-reactive. Cross-reactivity of the 9 HIV-1 Abs was through glycoepitopes. Glycan-dependent, V3-loop-binding PGT126 and PGT128 as well as 2G12 were the strongest binders of COV-2 S and were found to be immunoreactive but incapable of neutralization or antibody-dependent enhancement (ADE).
Mannar2021
(antibody interactions, effector function, glycosylation, computational prediction, antibody polyreactivity)
-
PGT128: The crystal structure of Fab NC-Cow1 was determined. The NC-Cow1 structure was then determined in a quaternary complex with BG505 SOSIP.664, in which human Fabs PGT128 and 35022 were added to facilitate formation of diffraction-quality crystals. The exceptionally long (60 residues) CDR H3 of the heavy chain of NC-Cow1 forms a mini domain (knob) on an extended stalk that navigates through the dense glycan shield on Env to target a small footprint on the gp120 CD4bs with no contact of the other CDRs to the rest of the Env trimer.
Stanfield2020
(structure)
-
PGT128: Analyses of all PDB HIV1-Env trimer (prefusion, closed) structures fulfilling certain parameters of resolution were performed to classify them on the basis of (a) antibody class which was informed by parental B cells as well as structural recognition, and (b) Env residues defining recognized HIV epitopes. Structural features of the 206 HIV epitope and bNAb paratopes were correlated with functional properties of the breadth and potency of neutralization against a 208-strain panel. Broadly nAbs with >25% breadth of neutralization belonged to 20 classes of antibodies with a large number of protruding loops and high degree of somatic hypermutation (SHM). Analysis of recognized HIV epitopes placed the bNAbs into 6 categories (viz. V1V2, glycan-V3, CD4-binding site, silent face center, fusion peptide and subunit interface). The epitopes contained high numbers of independent sequence segments and glycosylated surface area. PGT128-Env formed a distinct group within the Glycan-V3 category, Class PGT128. Cryo-EM data on PGT128 complexed to BG505 SOSIP.664 trimer was found in PDB ID: 5ACO.
Chuang2019
(antibody binding site, antibody interactions, neutralization, binding affinity, antibody sequence, structure, antibody lineage, broad neutralizer)
-
PGT128: An elite controller patient (VA40774) was identified as having an Env V1 domain that was unusually long and contained 2 additional N-glycosylation sites and 2 additional cysteine residues, relative to HXB2. When this V1 region was put into other viral backbones, the resulting virus had lower infectivity. The long V1 domain is sufficient for partial or complete escape from neutralization by V3-glycan targeting antibodies 10-1074 and PGT121, but not by another V3-glycan bNAb (PGT128) nor by other classes of bNAbs.
Silver2019
(elite controllers and/or long-term non-progressors, neutralization)
-
PGT128: In an effort to identify new Env immunogens able to elicit bNAbs, this study looked at Envs derived from rare individuals who possess bNAbs and are elite viral suppressors, hypothesizing that in at least some people the antibodies may mediate durable virus control. The Env proteins recovered from these individuals may more closely resemble the Envs that gave rise to bNAbs compared to the highly diverse viruses isolated from normal progressors. This study identified a treatment-naive elite suppressor, EN3 (patient record #4929), whose serum had broad neutralization. The Env sequences of EN3 had much fewer polymorphisms, compared to those of a normal progressor, EN1 (patient record #4928), who also had broad serum neutralization. This result confirmed other reports of slower virus evolution in elite suppressors. EN3 Envelope proteins were unusual in that most possessed two extra cysteines within an elongated V1 region. The impact of the extra cysteines on the binding to bNAbs, virus infectivity, and sensitivity to neutralization suggested that structural motifs in V1 can affect infectivity, and that rare viruses may be prevented from developing escape. As part of this study, the neutralization of pseudotype viruses for EN3 Env clones was assayed for several bNAbs (PG9, PG16, PGT145, PGT121, PGT128, VRC01, 4E10, and 35O22).
Hutchinson2019
(elite controllers and/or long-term non-progressors, neutralization, vaccine antigen design, polyclonal antibodies)
-
PGT128: An ART-naive HIV-controlling patient SA003 was found to have a high level of serum bNAb activity, and broadly neutralizing mAb LN01 IgG3 was isolated from patient serum. MAb PGT128 was used as a comparison in an assay of ADCC; PGT128 had moderate to strong ADCC activity against cells infected with 4 tested strains.
Pinto2019
(effector function)
-
PGT128: An R5 virus isolated from chronic patient NAB01 (Patient Record# 4723) was adapted in culture to growth in the presence of target cells expressing reduced levels of CD4. Entry kinetics of the virus were altered, and these alterations resulted in extended exposure of CD4-induced neutralization-sensitive epitopes to CD4. Adapted and control viruses were assayed for their neutralization by a panel of neutralizing antibodies targeting several different regions of Env (PGT121, PGT128, 1-79, 447-52d, b6, b12, VRC01, 17b, 4E10, 2F5, Z13e1). Adapted viruses showed greater sensitivity to antibodies targeting the CD4 binding site and the V3 loop. This evolution of Env resulted in increased CD4 affinity but decreased viral fitness, a phenomenon seen also in the immune-privileged CNS, particularly in macrophages.
Beauparlant2017
(neutralization, viral fitness and/or reversion, dynamics, kinetics)
-
PGT128: Chemoenzymatic synthesis, antigenicity, and immunogenicity of the V3 N334 glycopeptides from HIV-1 A244 gp120 have been reported. A synthetic V3 glycopeptide carrying a N334 high-mannose glycan was recognized by bNAb PGT128 and PGT126 but not by 10-1074. Rabbit immunization with the synthetic three-component A244 glycopeptide immunogen elicited substantial glycan-dependent antibodies with broad reactivity to various HIV-1 gp120/gp140 carrying N332 or N334 glycosylation sites. PGT128 could bind to all the V3 glycopeptides and carrying a high-mannose glycan at the N334, N301, or N295 site with moderate affinity, but no binding was observed to V3 glycopeptides bearing sialylated complex-type glycan (Fig: S1).
Cai2018
(glycosylation, vaccine antigen design, structure)
-
PGT128: Without SOSIP changes, cleaved Env trimers disintegrate into their gp120 and gp41-ectodomain (gp41_ECTO) components. This study demonstrates that the gp41_ECTO component is the primary source of this Env metastability and that replacing wild-type gp41_ECTO with BG505 gp41_ECTO of the uncleaved prefusion-optimized design is a general and effective strategy for trimer stabilization. A panel of 11 bNAbs, including the the N332 supersite recognized by PGT121, PGT128, PGT135, and 2G12, was used to assess conserved neutralizing epitopes on the trimer surface, and the main result was that the substitution was found to significantly improve trimer binding to bNAbs VRC01, PGT151, and 35O22, with P values (paired t test) of 0.0229, 0.0269, and 0.0407, respectively.
He2018
(antibody interactions, glycosylation, vaccine antigen design)
-
PGT128: This study looks at the role of somatic mutations within antibody variable and framework regions (FWR) in bNAbs and how these mutations alter thermostability and neutralization as the Ab lineage reaches maturation. The emergence and selection of different mutations in the complementarity-determining and framework regions are necessary to maintain a balance between antibody function and stability. The study shows that all major classes of bNAbs (DH270, CH103, CH235, VRC01, PGT lineage etc.) have lower thermostability than their corresponding inferred UCA antibodies. Fab interdomain flexibility mutations are selected early in Ab development.
Henderson2019
(neutralization, antibody lineage, broad neutralizer)
-
PGT128: This study demonstrated that bNAb signatures can be utilized to engineer HIV-1 Env vaccine immunogens eliciting Ab responses with greater neutralization breadth. Data from four large virus panels were used to comprehensively map viral signatures associated with bNAb sensitivity, hypervariable region characteristics, and clade effects. The bNAb signatures defined for the V2 epitope region were then employed to inform immunogen design in a proof-of-concept exploration of signature-based epitope targeted (SET) vaccines. V2 bNAb signature-guided mutations were introduced into Env 459C to create a trivalent vaccine which resulted in increased breadth of nAb responses compared with Env 459C alone. PGT128 was used for machine learning regression prediction and to analyze statistical details (Table S4).
Bricault2019
(antibody binding site, neutralization, vaccine antigen design, computational prediction, broad neutralizer)
-
PGT128: A simple method to quantify and compare serum neutralization probabilities in described. The method uses logistic regression to model the probability that a serum neutralizes a virus with an ID50 titer above a cutoff. The neutralization potency (NP) identifies where the probabilities of neutralizing and not neutralizing a virus are equal and is not absolute as it depends on the ID50 cutoff. It provides a continuous measure for sera, which builds upon established tier categories now used to rate virus sensitivity. These potency comparisons are similar to comparing geometric mean neutralization titers, but instead are represented in tier-like terms. Increasing the number of bNAbs increases NP and slope, where the higher the slope, the sharper the boundary (lower scatter) between viruses neutralized and not neutralized. PGT128 was used in analysis of monoclonal bNAb combinations.
Hraber2018
(assay or method development, neutralization)
-
PGT128: This review discusses how the identification of super-antibodies, where and how such antibodies may be best applied and future directions for the field. PGT121, a prototype super-Ab, was isolated from human B cell clones. Antigenic region V3 glycan (Table:1).
Walker2018
(antibody binding site, review, broad neutralizer)
-
PGT128: The authors selected an optimal panel of diverse HIV-1 envelope glycoproteins to represent the antigenic diversity of HIV globally in order to be used as antigen candidates. The selection was based on genetic and geographic diversity, and experimentally and computationally evaluated humoral responses. The eligibility of the envelopes as vaccine candidates was evaluated against a panel of antibodies for breadth, affinity, binding and durability of vaccine-elicited responses. The antigen panel was capable of detecting the spectrum of V2-specific antibodies that target epitopes from the V2 strand C (V2p), the integrin binding motif in V2 (V2i), and the quaternary epitope at the apex of the trimer (V2q).
Yates2018
(vaccine antigen design, vaccine-induced immune responses, binding affinity)
-
PGT128: Polyreactive properties of natural and artificially engineered HIV-1 bNAbs were studied, with almost 60% of the tested HIV-1 bNAbs (including this one) exhibiting low to high polyreactivity in different immunoassays. A previously unappreciated polyreactive binding for PGT121, PGT128, NIH45-46W, m2, and m7 was reported. Binding affinity, thermodynamic, and molecular dynamics analyses revealed that the co-emergence of enhanced neutralizing capacities and polyreactivity was due to an intrinsic conformational flexibility of the antigen-binding sites of bNAbs, allowing a better accommodation of divergent HIV-1 Env variants.
Prigent2018
(antibody polyreactivity)
-
PGT128: A systems glycobiology approach was applied to reverse engineer the relationship between bNAb binding and glycan effects on Env proteins. Glycan occupancy was interrogated across every potential N-glycan site in 94 recombinant gp120 antigens. Using a Bayesian machine learning algorithm, bNAb-specific glycan footprints were identified and used to design antigens that selectively alter bNAb antigenicity. The novel synthesized antigens unsuccessfully bound to target bNAbs with enhanced and selective antigenicity.
Yu2018
(glycosylation, vaccine antigen design)
-
PGT128: This review discusses current HIV bNAb immunogen design strategies, recent progress made in the development of animal models to evaluate potential vaccine candidates, advances in the technology to analyze antibody responses, and emerging concepts in understanding B cell developmental pathways that may facilitate HIV vaccine design strategies.
Andrabi2018
(vaccine antigen design, review)
-
PGT128: A panel of bnAbs were studied to assess ongoing adaptation of the HIV-1 species to the humoral immunity of the human population. Resistance to neutralization is increasing over time, but concerns only the external glycoprotein gp120, not the MPER, suggesting a high selective pressure on gp120. Almost all the identified major neutralization epitopes of gp120 are affected by this antigenic drift, suggesting that gp120 as a whole has progressively evolved in less than 3 decades.
Bouvin-Pley2014
(neutralization)
-
PGT128: The first cryo-EM structure of a cross-linked vaccine antigen was solved. The 4.2 Å structure of HIV-1 BG505 SOSIP soluble recombinant Env in complex with a bNAb PGV04 Fab fragment revealed how cross-linking affects key properties of the trimer. ISOSIP and GLA-SOSIP trimers were compared for antigenicity by ELISA, using a large panel of mAbs previously determined to react with BG505 Env. Non-NAbs globally lost reactivity (7-fold median loss of binding), likely because of covalent stabilization of the cross-linked ‘closed’ form of the GLA-SOSIP trimer that binds non-NAbs weakly or not at all. V3-specific non-NAbs showed 2.1–3.3-fold reduced binding. Three autologous rabbit monoclonal NAbs to the N241/N289 ‘glycan-hole’ surface, showed a median ˜1.5-fold reduction in binding. V3 non-NAb 4025 showed residual binding to the GLA-SOSIP trimer. By contrast, bNAbs like PGT128 broadly retained reactivity significantly better than non-NAbs, with exception of PGT145 (3.3-5.3 fold loss of binding in ELISA and SPR).
Schiffner2018
(vaccine antigen design, binding affinity, structure)
-
PGT128: This study describes the generation of CHO cell lines stably expressing the following vaccine Env Ags: CRF01_AE A244 Env gp120 protein (A244.AE) and 6240 Env gp120 protein (6240.B). The antigenic profiles of the molecules were assessed with a panel of well-characterized mAbs recognizing critical epitopes and glycosylation analysis confirming previously identified sites and revealing unknown sites at non-consensus motifs. A244.AE gp120 bound to PGT128 in ELISA EC50 and Surface Plasmon Resonance (SPR) assays. 6240.B gp120 exhibited binding to PGT128.
Wen2018
(glycosylation, vaccine antigen design)
-
PGT128: The prophylactic and therapeutic potential of an engineered single gene–encoded tandem bispecific immunoadhesin (IA) molecule BiIA-SG was studied. Before engineering BiIAs, codon-optimized scFvs of bNAbs PG9, PG16, PGT128, VRC01, and Hu5A8 were synthesized. The VL/VH domain of each scFv was engineered as a corresponding IA by fusion with human IgG1-Fc to generate IA-PG9, IA-PG16, IA-PGT128, IA-VRC01, and IA-Hu5A8. While all IAs exhibited specific anti–HIV-1 activity, only IA-PGT128 displayed similar potency and the same sigmoidal slope of 100% neutralization as previously described for the native PGT128, and IA-PGT128 in combination with IA-Hu5A8 exhibited the best synergistic effect based on computational synergy volumes. IA-PGT128 and IA-Hu5A8 were therefore used for BiIA construction. 2 BiIAs were constructed: a double gene–encoded (DG) bispecific IA (BiIA-DG) with the modified IgG1-Fc domain, and a single gene–encoded (SG) BiIA (BiIA-SG) through fusion of the PGT128 VL/VH to the N-terminal of IA-Hu5A8 VL/VH in tandem, resulting in a structurally unique molecule with 4 scFv binding domains (2 for HIV-1 gp120 and 2 for CD4) as compared with BiIA-DG or other bispecific bnAbs that contain 2 scFv binding domains (1 for each of the 2 target antigens). The neutralizing breadth and potency of the new BiIA-SG molecule were higher than those of the original neutralizing PGT128 mAb, or the BiIA-DG with a single scFv domain. BiIA-SG neutralized all 124 HIV-1–pseudotyped viruses tested, and in humanized mice, an injection of BiIA-SG conferred sterile protection when administered prior to challenges with diverse live HIV-1 stains.
Wu2018
-
PGT128: Assays of poly- and autoreactivity demonstrated that broadly neutralizing NAbs are significantly more poly- and autoreactive than non-neutralizing NAbs. PGT128 is polyreactive, but not autoreactive.
Liu2015a
(autoantibody or autoimmunity, antibody polyreactivity)
-
PGT128: Panels of C clade pseudoviruses were computationally downselected from the panel of 200 C clade viruses defined by Rademeyer et al. 2016. A 12-virus panel was defined for the purpose of screening sera from vaccinees. Panels of 50 and 100 viruses were defined as smaller sets for use in testing magnitude and breadth against C clade. Published neutralization data for 16 mAbs was taken from CATNAP for the computational selections: 10-1074, 10-1074V, PGT121, PGT128, VRC26.25, VRC26.08, PGDM1400, PG9, PGT145, VRC07-523, 10E8, VRC13, 3BNC117, VRC07, VRC01, 4E10.
Hraber2017
(assay or method development, neutralization)
-
PGT128: Repetitive immunization of macaques over 3 years with an Env expressing V3-high mannose glycan, CON-S gp140CFI, elicited plasma antibodies neturalizing HIV-1 expressing high mannose glycans only. NAb DH501 was isolated and found to possess a structure where 3 VH chain CDRs formed a cavity into which the HIV-1 Env V3-glycan could insert. Rhesus DH501 possessed characteristics of V3-glycan bNAb precursors, and it could block PGT128 binding to V3.
Saunders2017
(vaccine-induced immune responses, structure)
-
PGT128: This study showed evidence of escape of circulating HIV-1 clade C in an individual from autologous BCN antibodies by three distinct mechanisms, 1) due to a N332S mutation (2) by increasing V1 loop length and (3) incorporation of protective N-glycan residues in V1 loop. Pseudotyped viruses expressing autologous Envs were found to be resistant to autologous BCN plasma, PGT121 and PGT128 despite the majority of Envs containing an intact N332 residue. Resistance of the Envs to neutralization was found to be correlated with a N332S mutation and acquisition of protective N-glycans.
Deshpande2016
(autologous responses, glycosylation, escape)
-
PGT128: DS-SOSIP.4mut (4mut) was identified as the most immunogenic and stable of 4 engineered, soluble, closed prefusion HIV-1 Env trimers. 4mut contained 4 mutations (M154, M300, M302 and L320) designed to form hydrophobic interactions between V1V1 and V3 loops. After V3-negative selection, V3-glycan-targeted mAb PGT128 recognized 4mut, the other 3 designed trimers (DS-SOSIP.6mut containing 4mut mutations, Y177W and I420M, DS-SOSIP.I423F and DS-SOSIP.A316W), and related trimers DS-SOSIP and BG505 SOSIP.664. Each DS-SOSIP variant was able to elicit trimer-specific responses, comparable to BG505 SOSIP.664, in guinea pigs after 4 immunizations, but none elicited heterologous neutralizing activity. Crystal structures were generated for 4mut and 6mut.
Chuang2017
(vaccine antigen design, vaccine-induced immune responses)
-
PGT128: Env from of a highly neutralization-resistant isolate, CH120.6, was shown to be very stable and conformationally-homogeneous. Its gp140 trimer retains many antigenic properties of the intact Env, while its monomeric gp120 exposes more epitopes. Thus trimer organization and stability are important determinants for occluding epitopes and conferring resistance to antibodies. Among a panel of 21 mAbs, CH120.6 was resistant to neutralization by all non-neutralizing and strain-specific mAbs, regardless of the location of their epitopes. It was weakly neutralized by several broadly-neutralizing mAbs (VRC01, NIH45-46, 12A12, PG9, PG16, PGT128, 4E10, and 10E8), and well neutralized by only 2 (PGT145 and 10-1074).
Cai2017
(neutralization)
-
PGT128: Man9-V3, a synthetic minimal immunogen designed to reflect the HIV-1 native Env V3-glycan bNAb epitope, binds memory B cells and V3-glycan bNAbs as well as germline bNAbs. Man9-V3 was used to isolate a bNAb from an HIV-1+ subject and also induce V3-glycan-targeting antibodies in rhesus macaques. Using the crystal structure of PGT128-gp120 Env OD (outer domain), Man9-V3 glycopeptide was synthesized based on Clade B JRFL with deletion of residues 305-320, retention of P321 and stabilization of disulfide bridge C296-C331. PGT128 neutralization of Man9-V3 was biphasic. Lower-order oligomannose glycans (Man5 and Man6) did not bind PGT128.
Alam2017
(antibody binding site)
-
PGT128: Mice twice-primed with DNA plasmids encoding HIV-1 gp120 and gag and given a double boost with HIV-1 virus-like particles (VLPs) i.e. DDVV immunization, elicited Env-specific antibody responses as well as Env- and Gag-specific CTL responses. In vivo electroporation (EP) was used to increase breadth and potency of response. Human anti-gp120 high mannose patch (centered on N137, N301, N332, N397) PGT128 was used to prove that the VLP spike included the broad neutralization epitope recognized by it.
Huang2017a
(therapeutic vaccine, variant cross-reactivity)
-
PGT128: The next generation of a computational neutralization fingerprinting (NFP) being used as a way to predict polyclonal Ab responses to HIV infection is presented. A new panel of 20 pseudoviruses, termed f61, was developed to aid in the assessment of experimental neutralization. This panel was used to assess 22 well-characterized bNAbs and mixtures thereof (HJ16, VRC01, 8ANC195, IGg1b12, PGT121, PGT128, PGT135, PG9, PGT151, 35O22, 10E8, 2F5, 4E10, VRC27, VRC-CH31, VRC-PG20, PG04, VRC23, 12A12, 3BNC117, PGT145, CH01). The new algorithms accurately predicted VRC01-like and PG9-like antibody specificities.
Doria-Rose2017
(neutralization, computational prediction)
-
PGT128: This review summarizes vaccine approaches to counter HIV diversity. A structural map illustrated the contact regions of several bNAbs: VRC26.09, PGT128, CH235.12, and 10E8. Structures illustrating the bNAbs' tolerance for sequence variation were illustrated for CH235.12, PGT128, VRC26.09, and 10E8. CD4BS bNAbs such as VRC01 and CH235.12 illustrate that bNAbs bind to both conserved and hypervariable regions of Env.
Korber2017
(antibody binding site, vaccine antigen design, review)
-
PGT128: The study isolated 3 new V3-glycan antibody lineages (DH270, DH272, DH475) from donor CH848, who was followed for 5 years starting from the time of transmission. The DH272 and DH475 lineages had neutralization patterns that likely selected for observed viral escape variants, which, in turn, stimulated the DH270 lineage to potent neutralization breadth. DH270 antibodies were recovered from memory B cells at all three sampling times (weeks 205, 232, and 234 post-infection). Like some previously-characterized Abs (PGT121, PGT128, 10-1074), the DH270 lineage mAbs bound to Env N332, and their neutralization was reduced or abrogated by mutation of this residue. PGT128 neutralized 128/207 heterologous pseudoviruses with IC50 value of <50 μ/ml and demonstrated an inverse correlation between potency and V1 length. Structural analysis determined that gp140 trimer-bound DH270.1 Fabs, compared to PGT124, PGT128 or PGT135 Fabs, had a more horizontal orientation.
Bonsignori2017
(antibody binding site, neutralization, structure)
-
PGT128: This study performed cyclical permutation of the V1 loop of JRFL in order to develop better gp120 trimers to elicit neutralizing antibodies. Some mutated trimers showed improved binding to several mAbs, including VRC01, VRC03, VRC-PG04, PGT128, PGT145, PGDM1400, b6, and F105. Guinea pigs immunized with prospective trimers showed improved neutralization of a panel of HIV-1 pseudoviruses. Binding of PGT128 to JRFL was abolished by mutation N332T.
Kesavardhana2017
(vaccine antigen design, vaccine-induced immune responses)
-
PGT128: The study compared the binding characteristics of V3-glycan antibodies, specifically PGT121, PGT128, PGT135, PCDN38A, and 3 newly-derived lineages of mAbs from Donor N170. The gene usage for PGT128 is given as: IGHV 4-39*07, IGHJ 5*02, IGLV L3-8*01, IGLJ L2 or 3.
Longo2016
(antibody binding site, antibody sequence, germline)
-
PGT128: This study investigated the ability of native, membrane-expressed JR-FL Env trimers to elicit NAbs. Rabbits were immunized with virus-like particles (VLPs) expressing trimers (trimer VLP sera) and DNA expressing native Env trimer, followed by a protein boost (DNA trimer sera). N197 glycan- and residue 230- removal conferred sensitivity to Trimer VLP sera and DNA trimer sera respectively, showing for the first time that strain-specific holes in the "glycan fence" can allow the development of tier 2 NAbs to native spikes. All 3 sera neutralized via quaternary epitopes and exploited natural gaps in the glycan defenses of the second conserved region of JR-FL gp120. PGT128 was 1 of 2 reference PGT128-like bNAbs - PGT121 and PGT128.
Crooks2015
(glycosylation, neutralization)
-
PGT128: New antibodies were isolated from 3 patients: Donor 14 (PDGM11, PGDM12, PGDM13, PGDM14), Donor 82 (PGDM21), and Donor 26 (PGDM31). These bnAbs bound both the GDIR peptide (Env 324-327) and the high-mannose patch glycans, enabling broad reactivity. N332 glycan was absolutely required for neutralization, while N301 glycan modestly affected neutralization. Removing N156 and N301 glycans together while retaining N332 glycan abrogated neutralization for PGDM12 and PGDM21. Neutralization by PGDM11-14 bnAbs depended on R327A and H330A substitutions and neutralization by PGDM21 depended on D325A and H330A substitutions. G324A mutation resulted in slight loss of neutralization for both antibody families. In comparison, 2G12 and PGT135 did not show any dependence on residues in the 324GDIR327 region for neutralization activity, although PGT135 did show dependence on H330.
Sok2016
(antibody binding site, glycosylation)
-
PGT128: Chimeric antigen receptors, i.e., fusion proteins made from single-chain antibodies, may be a useful approach to immunotherapy. A set of mAbs were chosen based on their binding to a variety of sites on Env and availability of antibody sequences. The chimeric receptors were created by fusing the antibody's heavy chain, light chain, and two signaling domains into a single molecule. All 7 antibodies used to make the chimeric receptors (10E8, 3BNC117, PGT126, VRC01, X5, PGT128, PG9) showed specific killing of HIV-1 infected cells and suppression of viral replication against a panel of HIV-1 strains.
Ali2016
(immunotherapy, chimeric antibody)
-
PGT128: This review classified and mapped the binding regions of 32 bNAbs isolated 2010-2016.
Wu2016
(review)
-
PGT128: This study produced Env SOSIP trimers for clades A (strain BG505), B (strain JR-FL), and G (strain X1193). Based on simulations, the MAb-trimer structures of all MAbs tested needed to accommodate at least one glycan, including both antibodies known to require specific glycans (PG9, PGT121, PGT135, 8ANC195, 35O22) and those that bind the CD4-binding site (b12, CH103, HJ16, VRC01, VRC13). A subset of monoclonal antibodies bound to glycan arrays assayed on glass slides (VRC26.09, PGT121, 2G12, PGT128, VRC13, PGT151, 35O22), while most of the antibodies did not have affinity for oligosaccharide in the context of a glycan array (PG9, PGT145, PGDM1400, PGT135, b12, CH103, HJ16, VRC16, VRC01, VRC-PG04, VRC-CH31, VRC-PG20, 3BNC60, 12A12, VRC18b, VRC23, VRC27, 1B2530, 8ANC131, 8ANC134, 8ANC195).
Stewart-Jones2016
(antibody binding site, glycosylation, structure)
-
PGT128: This review summarizes representative anti-HIV MAbs of the first generation (2G12, b12, 2F5, 4E10) and second generation (PG9, PG16, PGT145, VRC26.09, PGDM1400, PGT121, PGT124, PGT128, PGT135, 10-1074, VRC01, 3BNC117, CH103, PGT151, 35O22, 8ANC195, 10E8). Structures, epitopes, VDJ usage, CDR usage, and degree of somatic hypermutation are compared among these antibodies. The use of SOSIP trimers as immunogens to elicit B-cell responses is discussed.
Burton2016
(review, structure)
-
PGT128: HIV-1 bNAb eptiope networks were predicted using 4 algorithms informed by neutralization assays using 282 Env from multiclade viruses. Patch clusters of possible Ab epitope regions were tested for significant sensitivity by site-directed mutagenesis. Epitope (Ab binding site) networks of critical Env residues for 21 bNAb (b12, PG9, PG16, PGT121, PGT122, PGT123, PGT125, PGT126, PGT127, PGT128, PGT130, PGT131, PGT135, PGT136, PGT137, PGT141, PGT142, PGT143, PGT144, PGT145 and PGV04) were delineated and found to be located mostly in variable loops of gp120, particularly in V1/V2.
Evans2014
(antibody binding site, computational prediction)
-
PGT128: Two stable homogenous gp140 Env trimer spikes, Clade A 92UG037.8 Env and Clade C C97ZA012 Env, were identified. 293T cells stably transfected with either presented fully functional surface timers, 50% of which were uncleaved. A panel of neutralizing and non-neutralizing Abs were tested for binding to the trimers. V3 glycan bNAb PGT128 bound cell surface tightly whether the trimer contained its C-terminal or not, and was sometimes weakly competed out by sCD4. It was able to neutralize the 92UG037.8 HIV-1 isolate weakly.
Chen2015
(neutralization, binding affinity)
-
PGT128: Factors that independently affect bNAb induction and evolution were identified as viral load, length of untreated infection, and viral diversity. Black subjects induced bNAbs more than white subjects, but this did not correlate with type of Ab response. Fingerprint analyses of induced bNAbs showed strong subtype dependency, with subtype B inducing significantly higher levels of CD4bs Abs and non-subtype B inducing V2-glycan specific Abs. Of the 239 bNAb antibody inducers found from 4,484 HIV-1 infected subjects,the top 105 inducers' neutralization fingerprint and epitope specificity was determined by comparison to the following antibodies - PG9, PG16, PGDM1400, PGT145 (V2 glycan); PGT121, PGT128, PGT130 (V3 glycan); VRC01, PGV04 (CD4bs) and PGT151 (interface) and 2F5, 4E10, 10E8 (MPER).
Rusert2016
(neutralization, subtype comparisons, broad neutralizer)
-
PGT128: The first generation of HIV trimer soluble immunogens, BG505 SOSIP.664 were tested in a mouse model for generation of nAb to neutralization-resistant circulating HIV strains. No such NAbs were induced, as mouse Abs targeted the bottom of soluble Env trimers, suggesting that the glycan shield of Env trimers is impenetrable to murine B cell receptors and that epitopes at the trimer base should be obscured in immunogen design in order to avoid non-nAb responses. Association and dissociation of known anti-trimer bNAbs (VRC01, PGT121, PGT128, PGT151, PGT135, PG9, 35O22, 3BC315 and PGT145) were found to be far greater than murine generated non-NAbs.
Hu2015
-
PGT128: A comprehensive antigenic map of the cleaved trimer BG505 SOSIP.664 was made by bNAb cross-competition. Epitope clusters at the CD4bs, quaternary V1/V2 glycan, N332-oligomannose patch and new gp120-gp41 interface and their interactions were delineated. Epitope overlap, proximal steric inhibition, allosteric inhibition or reorientation of glycans were seen in Ab cross-competition. Thus bNAb binding to trimers can affect surfaces beyond their epitopes. PGT128, PGT121, PGT122, PGT123, PGT125 and PGT126, all N332-V3 glycan oligomannose patch bNAbs, were strongly, reciprocally competitive with one another. PGT128 also inhibited binding of CD4bs Abs, CH31 and VRC01 and markedly but incompletely inhibited CD4-IgG2. Reciprocal enhancement of binding was seen between NIH45-46 and PGT128.
Derking2015
(antibody interactions, neutralization, binding affinity, structure)
-
PGT128: Env trimer BG505 SOSIP.664 as well as the clade B trimer B41 SOSIP.664 were stabilized using a bifunctional aldehyde (glutaraldehye, GLA) or a heterobifunctional cross-linker, EDC/NHS with modest effects on antigenicity and barely any on biochemistry or structural morphology. ELISA, DSC and SPR were used to test recognition of the trimers by bNAbs, which was preserved and by weakly NAbs or non-NAbs, which was reduced. Cross-linking partially preserves quaternary morphology so that affinity chromatography by positive selection using quaternary epitope-specific bNAabs, and negative selection using non-NAbs, enriched antigenic characteristics of the trimers. Binding of the anti-N332-supersite glycan bNAb PGT128 to trimers was minimally affected by trimer cross-linking.
Schiffner2016
(assay or method development, binding affinity, structure)
-
PGT128: A new trimeric immunogen, BG505 SOSIP.664 gp140, was developed that bound and activated most known neutralizing antibodies but generally did not bind antibodies lacking neuralizing activity. This highly stable immunogen mimics the Env spike of subtype A transmitted/founder (T/F) HIV-1 strain, BG505. Anti-V3 glycan bNAb PGT128, neutralized BG505.T332N, the pseudoviral equivalent of the immunogen BG505 SOSIP.664 gp140, and was shown to recognize and bind the immunogen too.
Sanders2013
(assay or method development, neutralization, binding affinity)
-
PGT128: Using an escape virus isolated from the PGT125-131 donor, this study found that mutating the V3 core and repositioning critical N-linked glycosylations N295 and N332 could restore virus sensitivity. PGT128 and PGT130 required different sets of changes in order to restore sensitivity, suggesting that this family of bNAbs has two recognition classes (Fig. 2). For example N332 repositioning and 7 amino acid mutations V307I, H308R, E321D, V322I, N325D, P326I, F320H restored PGT128 but not PGT130 virus sensitivity.
Krumm2016
(glycosylation, escape)
-
PGT128: This paper analyzed site-specific glycosylation of a soluble, recombinant trimer (BG505 SOSIP.664). This trimer mapped the extremes of simplicity and diversity of glycan processing at individual sites and revealed a mosaic of dense clusters of oligomannose glycans on the outer domain. Although individual sites usually minimally affect the global integrity of the glycan shield, they identified examples of how deleting some glycans can subtly influence neutralization by bNAbs that bind at distant sites. The network of bNAb-targeted glycans should be preserved on vaccine antigens. Neutralization profiles for mannose-patch binding Ab, PGT128, to multiple epitopes were determined. Deleting the N137 glycan rendered both BG505 test viruses more sensitive to PGT128. Removing the N262, N295 and N301 glycans from either of the BG505 test viruses reduced the neutralization activities of PGT128. The glycan epitopes for PGT128 are particularly strongly impaired when the N448 glycan is deleted from the BG505.T332 virus.
Behrens2016
(antibody binding site, glycosylation)
-
PGT128: A mathematical model was developed to predict the Ab concentration at which antibody escape variants outcompete their ancestors, and this concentration was termed the mutant selection window (MSW). The MSW was determined experimentally for 12 pairings of diverse HIV strains against 7 bnAbs (b12, 2G12, PG9, PG16, PGT121, PGT128, 2F5). The neutralization of PGT128 was assayed against BG505 (resistant strain) and BG505-T332N (sensitive strain).
Magnus2016
(neutralization, escape)
-
PGT128: The study detailed binding kinetics of the interaction between BG505 SOSIP.664 trimer or its variants (gp120 monomer; first study of disulfide-stabilized variant gp120-gp41ECTO protomer) and several mAbs, both neutralizing (VRC01, PGV04, PG9, PG16, PGT121, PGT122, PGT123, PGT145, PGT151, 2G12) and non-neutralizing (b6, b12, 14e, 19b, F240). V3-base-dependent bNAb, PGT128, recognized trimer better than protomer and monomer, but dissociated faster from protomer, monomer.
Yasmeen2014
(antibody binding site, assay or method development)
-
PGT128: A new, current, mostly tier2 panel of 200 C-clade Env-psuedotyped viruses from early (< 100d) infection in southern Africa was used to assess antibody responses to natural infection and to vaccines. Viruses were assayed with bNAbs targeting the V2 glycan (PG9, VRC26.25), the MPER site (4E10), the CD4 binding site (VRC01), and the V3/C3 glycan site (PGT128). For PGT128 (but no other Abs tested) pre-seroconversion viruses were significantly more resistant to neutralization than were post-seroconversion viruses. Viruses collected pre-seroconversion were also more resistant to neutralization by serum than those post-seroconversion. As the epidemic matured over 13 years, viruses became more resistant to mAbs tested as well.
Rademeyer2016
(assay or method development, neutralization)
-
PGT128: This study examined the neutralization of group N, O, and P primary isolates of HIV-1 by diverse antibodies. Cross-group neutralization was observed only with the bNAbs targeting the N160 glycan-V1/V2 site. Four group O isolates, 1 group N isolate, and the group P isolates were neutralized by PG9 and/or PG16 or PGT145 at low concentrations. None of the non-M primary isolates were neutralized by bNAbs targeting other regions, except 10E8, which weakly neutralized 2 group N isolates, and 35O22 which neutralized 1 group O isolate. Bispecific bNAbs (PG9-iMab and PG16-iMab) very efficiently neutralized all non-M isolates with IC50 below 1 ug/mL, except for 2 group O strains. Anti-V3 bNAb PGT128 was unable to neutralize any of the 16 tested non-M primary isolates at an IC50< 10µg/ml.
Morgand2015
(neutralization)
-
PGT128: Using improved technologies in high-resolution, single-particle cryoelectron microscopy, this study refines and builds natively glycosylated high mannose patch-binding bnAb PGT128 HIV-1 Env structures in solution to 4.36 angstrom resolution. This structure was used to analyze the complete epitope of PGT128, in the context of the trimer expressed with native glycans for the first time. Differences seen from the previous X-ray structure include (1) a more disordered, less helical structure for both the α0 of gp12059-63 and C-terminus gp41 as well as (2) a downward shift in the HR2 helix of gp41 with respect to PGT128.
Lee2015a
(structure)
-
PGT128: The neutralization of 14 bnAbs was assayed against a global panel of 12 or 17 Env pseudoviruses. From IC50, IC80, IC90, and IC99 values, the slope of the dose-response curve was calculated. Each class of Ab had a fairly consistent slope. Neutralization breadth was strongly correlated with slope. An IIP (Instantaneous Inhibitory Potential) value was calculated, based on both the slope and IC50, and this value may be predictive of clinical efficacy. PGT128, a V3-glycan bnAb belonged to a group with slopes >1.
Webb2015
(neutralization)
-
PGT128: This study evaluated the binding of 15 inferred germline (gl) precursors of bNAbs that are directed to different epitope clusters, to 3 soluble native-like SOSIP.664 Env trimers - BG505, B41 and ZM197M. The trimers bound to some gl precursors, particularly those of V1V2-targeted Abs. These trimers may be useful for designing immunogens able to target gl precursors. V3 glycan-binding gl-PGT128 did not bind to any trimers.
Sliepen2015
(binding affinity, antibody lineage)
-
PGT128: The crystal structure of the BG505 SOSIP Env trimer in complex with PGT128 and 8ANC195 revealed the antibody epitopes and sites of Env vulnerability. PGT128 was shown to bind N137, N156, N301,and N332, with an indirect interaction with N262. 8ANC195 was shown to bind to N234, N276, and N637.
Kong2015a
(structure)
-
PGT128: Computational modeling was used to examine antibody recognition of glycans, using a V1V2 bNAb (PG9) and a V3 bnAb (PGT128). Both PG9 and PGT128 have a long CDR H3 loop that can penetrate the glycan shield and form interactions with gp120. The modeling results showed that the tip of the CDR H3 loop is flexible in the free antibodies and is able to move within the bound conformation, which likely increases the possibility to penetrate the glycan shield.
Qi2016
(glycosylation)
-
PGT128: The IGHV region is central to Ag binding and consists of 48 functional genes. IGHV repertoire of 28 HIV-infected South African women, 13 of whom developed bNAbs, was sequenced. Novel IGHV repertoires were reported, including 85 entirely novel sequences and 38 sequences that matched rearranged sequences in non-IMGT databases. There were no significant differences in germline IGHV repertoires between individuals who do and do not develop bNAbs. IGHV gene usage of multiple well known HIV-1 bNAbs was also analyzed and 14 instances were identified where the novel non-IMGT alleles identified in this study, provided the same or a better match than their currently defined IMGT allele. For PGT128 the published IMGT predicted allele was IGHV4-39*07 and alternate allele predicted from IGHV alleles in 28 South African individuals was IGHV4-39*7m2, with synonymous G298C nucleotide change.
Scheepers2015
(antibody lineage)
-
PGT128: This review summarized bNAb immunotherapy studies. Several bnAbs have been shown to decrease viremia in vivo, and are a prospect for preventative vaccinations. bNAbs have 3 possible immune effector functions: (1) directly neutralizing virions, (2) mediating anti-viral activity through Fc-FcR interactions, and (3) binding to viral antigen to be taken up by dendritic cells. In contrast to anti-HIV mAbs, antibodies against host cell CD4 and CCR5 receptors (iMab and PRO 140) are hindered by their short half-life in vivo. MAb PGT128 has been associated with viral suppression in humanized mice.
Halper-Stromberg2016
(immunotherapy, review)
-
PGT128: A large cross-sectional study of sera from 205 ART-naive patients infected with different HIV clades was tested against a panel of 219 cross-clade Env-pseudotyped viruses. Their neutralization was compared to the neutralization of 10 human bNAbs (10E8, 4E10, VRC01, PG9, PGT145, PGT128, 2F5, CH01, b12, 2G12) tested with a panel of 119 Env-pseudotyped viruses. Results from b12 and 2G12 suggested that these bnAbs may not be as broadly neutralizing as previously thought. PGT128 neutralized 59% of the 199 viruses tested.
Hraber2014
(neutralization)
-
PGT128: Double, triple or quadruple combinations of fifteen bNAbs that target 4 distinct epitope regions: the CD4 binding site (3BNC117, VRC01, VRC07, VRC07-523, VRC13), the V3-glycan supersite (10–1074, 10-1074V, PGT121, PGT128), the V1/V2-glycan site (PG9, PGT145, PGDM1400, CAP256-VRC26.08, CAP256-VRC26.25), and the gp41 MPER epitope (10E8) were studied. Their neutralization potency and breadth were assayed against a panel of 200 acute/early subtype C strains, and compared to a novel, highly accurate predictive mathematical model (no-overlap Bliss Hill model, CombiNaber tool, LANL HIV Immunology database). These data were used to predict the best combinations of bNAbs for immunotherapy.
Wagh2016
(neutralization, immunotherapy)
-
PGT128: This study describes a new level of complexity in antibody recognition of the mixed glycan-protein epitopes of the N332 region of HIV gp120. A combination of three antibody families that target the high-mannose patch can lead to 99% neutralization coverage of a large panel of viruses containing the N332/334 glycan site and up to 66% coverage for viruses that lack the N332/334 glycan site. PGT128 was only capable of neutralizing half of the N334 isolates.The PGT121 family of antibodies neutralized N332 glycan site viruses more effectively overall than the PGT128 family or PGT135.
Sok2014a
(antibody interactions, glycosylation)
-
PGT128: Incomplete neutralization may decrease the ability of bnAbs to protect against HIV exposure. In order to determine the extent of non-sigmoidal slopes that plateau at <100% neutralization, a panel of 24 bnMAbs targeting different regions on Env was tested in a quantitative pseudovirus neutralization assay on a panel of 278 viral clones. All bNAbs had some viruses that they neutralized with a plateau <100%, but those targeting the V2 apex and MPER did so more often. All bnMAbs assayed had some viruses for which they had incomplete neutralization and non-sigmoidal neutralization curves. bNAbs were grouped into 3 groups based on their neutralization curves: group 1 antibodies neutralized more than 90% of susceptible viruses to >95% (PGT121-123, PGT125-128, PGT136, PGV04); group 2 was less effective, resulting in neutralization of 60-84% of susceptible viruses to >95% (b12, PGT130-131, PGT135, PGT137, PGT141-143, PGT145, 2G12, PG9); group 3 neutralized only 36-60% of susceptible viruses to >95% (PG16, PGT144, 2F5, 4E10).
McCoy2015
(neutralization)
-
PGT128: Vectored Immuno Prophylaxis (VIP), involves passive immunization by viral vector-mediated delivery of genes encoding bnAbs for in vivo expression. Robust protection against virus infection was observed in preclinical settings when animals were given VIP to express monoclonal neutralizing Abs. This review article surveyed the status of antibody gene transfer, VIP experiments against HIV and its related virus conduced in humanized mice and macaque monkeys, and discuss the pros and cons of VIP and its opportunities and challenges towards clinical applications to control HIV/AIDS endemics.
Yang2014
(immunoprophylaxis, review, antibody gene transfer)
-
PGT128: Computational prediction of bNAb epitopes from experimental neutralization activity data is presented. The approach relies on compressed sensing (CS) and mutual information (MI) methodologies and requires the sequences of the viral strains but does not require structural information. For PGT128, CS predicted 23 and MI predicted 2 positions, overlapping in positions 332, 334.
Ferguson2013
(computational prediction, broad neutralizer)
-
PGT128: To focus the immune response to sites of NAb vulnerability while avoiding immune-evasion by the rest of Env, MPER, V1/V2, and V3 glycan sites were transplanted onto algorithm-identified acceptor scaffolds (proteins with a backbone geometry that recapitulates the antigenicity of the transplanted site). 7/22 short V3 glycan transplants (contained only 3 N-linked glycans and 25 Env residues), were highly successful in eliciting a robust PGT128 response.
Zhou2014
(vaccine antigen design)
-
PGT128: The crystal structure of PGT135 with gp120, CD4 and Fab 17b was analyzed to study how PGT135 recognizes its Asn332 glycan-dependent epitope. The combined structural studies of PGT 135, PGT 128 and 2G12 show this Asn332-dependent epitope is highly accessible and much more extensive than initially appreciated, allowing for multiple binding modes and varied angles of approach, thus representing a supersite of vulnerability for antibody neutralization.
Kong2013
(structure)
-
PGT128: This is a review of identified bNAbs, including the ontogeny of B cells that give rise to these antibodies. Breadth and magnitude of neutralization, unique features and similar bNAbs are listed. PGT128 is a V3-glycan Ab, with breadth 56%, IC50 0.11 μg per ml, and its unique feature listed is that it recognizes V3 glycan. Similar MAbs include PGT125-127, PGT130, PGT131.
Kwong2013
(review)
-
PGT128: The newly identified and defined epitope for PGT151 family MAbs binds to a site of vulnerability that does not overlap with any other bnAb epitopes. PGT128 was used as an anti-gp41 mAb to compare its binding with other PGT151 family Abs.
Blattner2014
-
PGT128: 8 bNAbs (PGT151 family) were isolated from an elite neutralizer. The new bNAbs bind a previously unknown glycan-dependent epitope on the prefusion conformation of gp41. These MAbs are specific for the cleaved Env trimer and do not recognize uncleaved Env trimer. PGT128 was used for comparison.
Falkowska2014
-
PGT128: A statistical model selection method was used to identify a global panel of 12 reference Env clones among 219 Env-pseudotyped viruses that represent the spectrum of neutralizing activity seen with sera from 205 chronically HIV-1-infected individuals. This small final panel was also highly sensitive for detection of many of the known bNAbs, including this one. The small panel of 12 Env clones should facilitate assessments of vacine-elicited NAbs.
Decamp2014
(assay or method development)
-
PGT128:X-ray crystallography, surface plasmon resonance and pseudovirus neutralization were used to characterize a heavy chain only llama antibody, named JM4. The full-length IgG2b version of JM4 neutralizes over 95% of circulating HIV-1 isolates. JM4 targets a hybrid epitope on gp120 that combines elements from both the CD4 binding region and the coreceptor binding surface. JM4 IgG2b was able to potently neutralize the HIV-1 isolates that were resistant to PGT128.
Acharya2013
(neutralization)
-
PGT128: This is a review of a satellite symposium at the AIDS Vaccine 2012 conference, focusing on antibody gene transfer. Michel Nussenzweig presented studies exploring the possibility that antibodies might also be used to treat established infections. They found that combinations of five broadly neutralizing antibodies NIH45-46G54W, PG16, PGT128, 10-1074 and 3BC176 MAbs, controlled HIV-1 infection and suppressed the viral load to below the limit of detection during the entire therapy period of up to 60 days.
Balazs2013
(immunoprophylaxis, immunotherapy)
-
PGT128: Diversity of Ab recognition at the N332 site was assessed using chimeric antibodies made of heavy and light chains of N332-directed bNAbs PGT121-137. Recognition was good when heavy and light chains came from the same donor, and poor when they came from different donors, indicating multiple modes of recognition.
Pancera2013a
(chimeric antibody)
-
PGT128: "Neutralization fingerprints" for 30 neutralizing antibodies were determined using a panel of 34 diverse HIV-1 strains. 10 antibody clusters were defined: VRC01-like, PG9-like, PGT128-like, 2F5-like, 10E8-like and separate clusters for b12, CD4, 2G12, HJ16, 8ANC195.
Georgiev2013
(neutralization)
-
PGT128: This study uncovered a potentially significant contribution of VH replacement products which are highly enriched in IgH genes for the generation of anti-HIV Abs including anti-gp41, anti-V3 loop, anti-gp120, CD4i and PGT Abs. IgH encoding PGT Abs are likely generated from multiple rounds of VH replacements. The details of PGT128 VH replacement products in IgH gene and mutations and amino acid sequence analysis are described in Table 1, Table 2 and Fig 4.
Liao2013a
(antibody sequence)
-
PGT128: Neutralization profiles of 7 bnAbs were analyzed against 45 Envs (A, C, D clades), obtained soon after infection (median 59 days). The transmitted variants have distinct characteristics compared to variants from chronic patients, such as shorter variable loops and fewer potential N-linked glycosylation sites (PNGS). PGT128 neutralized only 27% of these viruses. However, PGT128 and NIH45-46W did not compete for neutralization and a combination of these mAbs neutralized 96% of these viruses, with PGT121 neutralizing the only 2 viruses not neutralized by this combination. This suggests that optimal neutralization coverage of transmitted variants can be achieved by combining a potent CD4bs NAb with one or more glycan-dependent mAbs.
Goo2012
(antibody interactions, neutralization, rate of progression)
-
PGT128: Identification of broadly neutralizing antibodies, their epitopes on the HIV-1 spike, the molecular basis for their remarkable breadth, and the B cell ontogenies of their generation and maturation are reviewed. Ontogeny and structure-based classification is presented, based on MAb binding site, type (structural mode of recognition), class (related ontogenies in separate donors) and family (clonal lineage). This MAb's classification: gp120 glycan-V3 site, type penetrating CDR H3 binds two glycans and strand, PGT128 class, PGT128 family.
Kwong2012
(review, structure, broad neutralizer)
-
PGT128: This review discusses the new research developments in bnAbs for HIV-1, Influenza, HCV. Models of the HIV-1 Env spike and of Influenza visrus spike with select bnAbs bound are shown.
Burton2012
(review)
-
PGT128: This review discusses how analysis of infection and vaccine candidate-induced antibodies and their genes may guide vaccine design. This MAb is listed as V3 epitope involving carbohydrates bnAb, isolated after 2009 by neutralization screening of cultured, unselected IgG+ memory B cells.
Bonsignori2012b
(vaccine antigen design, vaccine-induced immune responses, review)
-
PGT128: Somatic hypermutations are preferably found in CDR loops, which alter the Ab combining sites, but not the overall structure of the variable domain. FWR of CDR are usually resistant to and less tolerant of mutations. This study reports that most bnAbs require somatic mutations in the FWRs which provide flexibility, increasing Ab breadth and potency. To determine the consequence of FWR mutations the framework residues were reverted to the Ab's germline counterpart (FWR-GL) and binding and neutralizing properties were then evaluated. PGT128, which recognizes the base of the V3 loop, was among the 17 bnAbs which were used in studying the mutations in FWR. PGT128 was used in comparing the Ab framework amino acid replacement vs. interactive surface area on Ab.
Klein2013
(neutralization, structure, antibody lineage)
-
PGT128: Glycan shield of HIV Env protein helps to escape the Ab recognition. Several of the PGT BnAbs interact directly with the HIV glycan coat. Crystal structures of Fabs PGT127 and PGT128 showed that the high neutralizing potency was mediated by cross-linking Env trimers on the viral surface. PGT128 binds to Man8/9 glycans on gp120 and potently neutralize across the clades.
Pejchal2011
(glycosylation, structure, broad neutralizer)
-
PGT128: Glycan Asn332-targeting broadly cross-neutralizing (BCN) antibodies were studied in 2 C-clade infected women. The ASn332 glycan was absent on infecting virus, but the BCN epitope with Asn332 evolved within 6 months though immune escape from earlier antibodies. Plasma from the subject CAP177 neutralized 88% of a large multi-subtype panel of 225 heterologous viruses, whereas CAP 314 neutralized 46% of 41 heterologous viruses but failed to neutralize viruses that lack glycan at 332. Crystal structure revealed that PGT128 penetrates the glycan shield and target high mannose glycans at 302 and 332 to neutralize.
Moore2012
(neutralization, escape, structure)
-
PGT128: The use of computationally derived B cell clonal lineages as templates for HIV-1 immunogen design is discussed. PGT128 has been discussed in terms of immunogenic and functional characteristics of representative HIV-1 BnAbs and their reactions to antigens.
Haynes2012
(antibody interactions, memory cells, vaccine antigen design, review, antibody polyreactivity, broad neutralizer)
-
PGT128: HIV therapy by combinations of 5 bNAbs was tested in YU2-infected humanized mice. Penta-mix (PG16, 45-46W, 3BC176, PGT128 and 10-1074) was the most effective in controlling viraemia compared to tri-mix (PG16, 45-46, 3BC176) and monotherapy (Fig S9). Viral escape with PGT128 monotherapy was associated with mutations at residues 332 or 334, both of which abrogate the potential N-linked glycosylation site in V1/V2 loop.
Klein2012a
(escape, immunotherapy)
-
PGT128: Several antibodies including 10-1074 were isolated from B-cell clone encoding PGT121, from a clade A-infected African donor using YU-2 gp140 trimers as bait. These antibodies were segregated into PGT121-like (PGT121-123 and 9 members) and 10-1074-like (20 members) groups distinguished by sequence, binding affinity, carbohydrate recognition, neutralizing activity, the V3 loop binding and the role of glycans in epitope formation. PGT128 was used as a control in virus neutralization assay. Detail information on the binding and neutralization assays are described in the figures S2-S11.
Mouquet2012a
(glycosylation, binding affinity, broad neutralizer)
-
PGT128: Neutralizing antibody repertoires of 4 HIV-infected donors with remarkably broad and potent neutralizing responses were probed. 17 new monoclonal antibodies that neutralize broadly across clades were rescued. These MAbs were not polyreactive. All MAbs exhibited broad cross-clade neutralizing activity, but several showed exceptional potency. PGT128 neutralized 72% of 162 isolates from major HIV clades at IC50<50 μg/ml, which was lower than 93% by VRC01, but the median antibody concentration required to inhibit HIV activity by 50% or 90% (IC50 and IC90 values) was almost 10-fold lower (that is, more potent) that of PG9, VRC01 and PGV04, and 100-fold lower than that of b12, 2G12 and 4E10. PGT MAbs 121-123, 130, 131 and 135-137 bound to monomeric gp120 and competed with glycan-specific 2G12 MAb and all MAbs except PGT 135-137 also competed with a V3-loop-specific antibody and did not bind to gp120ΔV3, suggesting that their epitopes are in proximity to or contiguous with V3. Glycan array analysis revealed that PGT MAbs 125–128 and 130 bound specifically to both Man8GlcNAc2 and Man9GlcNAc2, whereas the remaining antibodies showed no detectable binding to high-mannose glycans. Alanine substitution analysis suggested that N-linked glycans at positions 332 and/or 301 were important for neutralization by PGT MAbs 125–128, 130 and 131, suggesting their direct involvement in epitope formation.
Walker2011
(antibody binding site, antibody generation, variant cross-reactivity, broad neutralizer)
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Beauparlant2017
David Beauparlant, Peter Rusert, Carsten Magnus, Claus Kadelka, Jacqueline Weber, Therese Uhr, Osvaldo Zagordi, Corinna Oberle, Maria J. Duenas-Decamp, Paul R. Clapham, Karin J. Metzner, Huldrych F. Günthard, and Alexandra Trkola. Delineating CD4 Dependency of HIV-1: Adaptation to Infect Low Level CD4 Expressing Target Cells Widens Cellular Tropism But Severely Impacts on Envelope Functionality. PLoS Pathog., 13(3):e1006255, Mar 2017. PubMed ID: 28264054.
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Behrens2016
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Blattner2014
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Bonsignori2017
Mattia Bonsignori, Edward F. Kreider, Daniela Fera, R. Ryan Meyerhoff, Todd Bradley, Kevin Wiehe, S. Munir Alam, Baptiste Aussedat, William E. Walkowicz, Kwan-Ki Hwang, Kevin O. Saunders, Ruijun Zhang, Morgan A. Gladden, Anthony Monroe, Amit Kumar, Shi-Mao Xia, Melissa Cooper, Mark K. Louder, Krisha McKee, Robert T. Bailer, Brendan W. Pier, Claudia A. Jette, Garnett Kelsoe, Wilton B. Williams, Lynn Morris, John Kappes, Kshitij Wagh, Gift Kamanga, Myron S. Cohen, Peter T. Hraber, David C. Montefiori, Ashley Trama, Hua-Xin Liao, Thomas B. Kepler, M. Anthony Moody, Feng Gao, Samuel J. Danishefsky, John R. Mascola, George M. Shaw, Beatrice H. Hahn, Stephen C. Harrison, Bette T. Korber, and Barton F. Haynes. Staged Induction of HIV-1 Glycan-Dependent Broadly Neutralizing Antibodies. Sci. Transl. Med., 9(381), 15 Mar 2017. PubMed ID: 28298420.
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Bricault2019
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Burton2016
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Cai2017
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Cai2018
Hui Cai, Rou-Shu Zhang, Jared Orwenyo, John Giddens, Qiang Yang, Celia C. LaBranche, David C. Montefiori, and Lai-Xi Wang. Synthetic HIV V3 Glycopeptide Immunogen Carrying a N334 N-Glycan Induces Glycan-Dependent Antibodies with Promiscuous Site Recognition. J. Med. Chem., 61(22):10116-10125, 21 Nov 2018. PubMed ID: 30384610.
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Chen2015
Jia Chen, James M. Kovacs, Hanqin Peng, Sophia Rits-Volloch, Jianming Lu, Donghyun Park, Elise Zablowsky, Michael S. Seaman, and Bing Chen. Effect of the Cytoplasmic Domain on Antigenic Characteristics of HIV-1 Envelope Glycoprotein. Science, 349(6244):191-195, 10 Jul 2015. PubMed ID: 26113642.
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Chuang2017
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Chuang2019
Gwo-Yu Chuang, Jing Zhou, Priyamvada Acharya, Reda Rawi, Chen-Hsiang Shen, Zizhang Sheng, Baoshan Zhang, Tongqing Zhou, Robert T. Bailer, Venkata P. Dandey, Nicole A. Doria-Rose, Mark K. Louder, Krisha McKee, John R. Mascola, Lawrence Shapiro, and Peter D. Kwong. Structural Survey of Broadly Neutralizing Antibodies Targeting the HIV-1 Env Trimer Delineates Epitope Categories and Characteristics of Recognition. Structure, 27(1):196-206.e6, 2 Jan 2019. PubMed ID: 30471922.
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Crooks2015
Ema T. Crooks, Tommy Tong, Bimal Chakrabarti, Kristin Narayan, Ivelin S. Georgiev, Sergey Menis, Xiaoxing Huang, Daniel Kulp, Keiko Osawa, Janelle Muranaka, Guillaume Stewart-Jones, Joanne Destefano, Sijy O'Dell, Celia LaBranche, James E. Robinson, David C. Montefiori, Krisha McKee, Sean X. Du, Nicole Doria-Rose, Peter D. Kwong, John R. Mascola, Ping Zhu, William R. Schief, Richard T. Wyatt, Robert G. Whalen, and James M. Binley. Vaccine-Elicited Tier 2 HIV-1 Neutralizing Antibodies Bind to Quaternary Epitopes Involving Glycan-Deficient Patches Proximal to the CD4 Binding Site. PLoS Pathog, 11(5):e1004932, May 2015. PubMed ID: 26023780.
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Davis-Gardner2020
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Decamp2014
Allan deCamp, Peter Hraber, Robert T. Bailer, Michael S. Seaman, Christina Ochsenbauer, John Kappes, Raphael Gottardo, Paul Edlefsen, Steve Self, Haili Tang, Kelli Greene, Hongmei Gao, Xiaoju Daniell, Marcella Sarzotti-Kelsoe, Miroslaw K. Gorny, Susan Zolla-Pazner, Celia C. LaBranche, John R. Mascola, Bette T. Korber, and David C. Montefiori. Global Panel of HIV-1 Env Reference Strains for Standardized Assessments of Vaccine-Elicited Neutralizing Antibodies. J. Virol., 88(5):2489-2507, Mar 2014. PubMed ID: 24352443.
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Derking2015
Ronald Derking, Gabriel Ozorowski, Kwinten Sliepen, Anila Yasmeen, Albert Cupo, Jonathan L. Torres, Jean-Philippe Julien, Jeong Hyun Lee, Thijs van Montfort, Steven W. de Taeye, Mark Connors, Dennis R. Burton, Ian A. Wilson, Per-Johan Klasse, Andrew B. Ward, John P. Moore, and Rogier W. Sanders. Comprehensive Antigenic Map of a Cleaved Soluble HIV-1 Envelope Trimer. PLoS Pathog, 11(3):e1004767, Mar 2015. PubMed ID: 25807248.
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Deshpande2016
Suprit Deshpande, Shilpa Patil, Rajesh Kumar, Tandile Hermanus, Kailapuri G. Murugavel, Aylur K. Srikrishnan, Suniti Solomon, Lynn Morris, and Jayanta Bhattacharya. HIV-1 Clade C Escapes Broadly Neutralizing Autologous Antibodies with N332 Glycan Specificity by Distinct Mechanisms. Retrovirology, 13(1):60, 30 Aug 2016. PubMed ID: 27576440.
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Doria-Rose2017
Nicole A. Doria-Rose, Han R. Altae-Tran, Ryan S. Roark, Stephen D. Schmidt, Matthew S. Sutton, Mark K. Louder, Gwo-Yu Chuang, Robert T. Bailer, Valerie Cortez, Rui Kong, Krisha McKee, Sijy O'Dell, Felicia Wang, Salim S. Abdool Karim, James M. Binley, Mark Connors, Barton F. Haynes, Malcolm A. Martin, David C. Montefiori, Lynn Morris, Julie Overbaugh, Peter D. Kwong, John R. Mascola, and Ivelin S. Georgiev. Mapping Polyclonal HIV-1 Antibody Responses via Next-Generation Neutralization Fingerprinting. PLoS Pathog., 13(1):e1006148, Jan 2017. PubMed ID: 28052137.
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Dufloo2022
Jérémy Dufloo, Cyril Planchais, Stéphane Frémont, Valérie Lorin, Florence Guivel-Benhassine, Karl Stefic, Nicoletta Casartelli, Arnaud Echard, Philippe Roingeard, Hugo Mouquet, Olivier Schwartz, and Timothée Bruel. Broadly Neutralizing Anti-HIV-1 Antibodies Tether Viral Particles at the Surface of Infected Cells. Nat. Commun., 13(1):630, 2 Feb 2022. PubMed ID: 35110562.
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Escolano2021
Amelia Escolano, Harry .B Gristick, Rajeev Gautam, Andrew T. DeLaitsch, Morgan E. Abernathy, Zhi Yang, Haoqing Wang, Magnus A. G. Hoffmann, Yoshiaki Nishimura, Zijun Wang, Nicholas Koranda, Leesa M. Kakutani, Han Gao, Priyanthi N. P. Gnanapragasam, Henna Raina, Ana Gazumyan, Melissa Cipolla, Thiago Y. Oliveira, Victor Ramos, Darrell J. Irvine, Murillo Silva, Anthony P. West, Jr., Jennifer R. Keeffe, Christopher O. Barnes, Michael S. Seaman, Michel C. Nussenzweig, Malcolm A. Martin, and Pamela J. Bjorkman. Sequential Immunization of Macaques Elicits Heterologous Neutralizing Antibodies Targeting the V3-Glycan Patch of HIV-1 Env. Sci. Transl. Med., 13(621):eabk1533, 24 Nov 2021. PubMed ID: 34818054.
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Evans2014
Mark C. Evans, Pham Phung, Agnes C. Paquet, Anvi Parikh, Christos J. Petropoulos, Terri Wrin, and Mojgan Haddad. Predicting HIV-1 Broadly Neutralizing Antibody Epitope Networks Using Neutralization Titers and a Novel Computational Method. BMC Bioinformatics, 15:77, 19 Mar 2014. PubMed ID: 24646213.
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Falkowska2014
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Ferguson2013
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Goo2012
Leslie Goo, Zahra Jalalian-Lechak, Barbra A. Richardson, and Julie Overbaugh. A Combination of Broadly Neutralizing HIV-1 Monoclonal Antibodies Targeting Distinct Epitopes Effectively Neutralizes Variants Found in Early Infection. J. Virol., 86(19):10857-10861, Oct 2012. PubMed ID: 22837204.
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Guenaga2015a
Javier Guenaga, Viktoriya Dubrovskaya, Natalia de Val, Shailendra K. Sharma, Barbara Carrette, Andrew B. Ward, and Richard T. Wyatt. Structure-Guided Redesign Increases the Propensity of HIV Env To Generate Highly Stable Soluble Trimers. J. Virol., 90(6):2806-2817, 30 Dec 2015. PubMed ID: 26719252.
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Guzzo2018
Christina Guzzo, Peng Zhang, Qingbo Liu, Alice L. Kwon, Ferzan Uddin, Alexandra I. Wells, Hana Schmeisser, Raffaello Cimbro, Jinghe Huang, Nicole Doria-Rose, Stephen D. Schmidt, Michael A. Dolan, Mark Connors, John R. Mascola, and Paolo Lusso. Structural Constraints at the Trimer Apex Stabilize the HIV-1 Envelope in a Closed, Antibody-Protected Conformation. mBio, 9(6), 11 Dec 2018. PubMed ID: 30538178.
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Halper-Stromberg2016
Ariel Halper-Stromberg and Michel C Nussenzweig. Towards HIV-1 Remission: Potential Roles for Broadly Neutralizing Antibodies. J. Clin. Invest., 126(2):415-423, Feb 2016. PubMed ID: 26752643.
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Haynes2012
Barton F. Haynes, Garnett Kelsoe, Stephen C. Harrison, and Thomas B. Kepler. B-Cell-Lineage Immunogen Design in Vaccine Development with HIV-1 as a Case Study. Nat. Biotechnol., 30(5):423-433, May 2012. PubMed ID: 22565972.
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Linling He, Sonu Kumar, Joel D. Allen, Deli Huang, Xiaohe Lin, Colin J. Mann, Karen L. Saye-Francisco, Jeffrey Copps, Anita Sarkar, Gabrielle S. Blizard, Gabriel Ozorowski, Devin Sok, Max Crispin, Andrew B. Ward, David Nemazee, Dennis R. Burton, Ian A. Wilson, and Jiang Zhu. HIV-1 Vaccine Design through Minimizing Envelope Metastability. Sci. Adv., 4(11):eaau6769, Nov 2018. PubMed ID: 30474059.
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Henderson2019
Rory Henderson, Brian E. Watts, Hieu N. Ergin, Kara Anasti, Robert Parks, Shi-Mao Xia, Ashley Trama, Hua-Xin Liao, Kevin O. Saunders, Mattia Bonsignori, Kevin Wiehe, Barton F. Haynes, and S. Munir Alam. Selection of Immunoglobulin Elbow Region Mutations Impacts Interdomain Conformational Flexibility in HIV-1 Broadly Neutralizing Antibodies. Nat. Commun., 10(1):654, 8 Feb 2019. PubMed ID: 30737386.
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Hraber2014
Peter Hraber, Michael S. Seaman, Robert T. Bailer, John R. Mascola, David C. Montefiori, and Bette T. Korber. Prevalence of Broadly Neutralizing Antibody Responses during Chronic HIV-1 Infection. AIDS, 28(2):163-169, 14 Jan 2014. PubMed ID: 24361678.
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Hraber2017
Peter Hraber, Cecilia Rademeyer, Carolyn Williamson, Michael S. Seaman, Raphael Gottardo, Haili Tang, Kelli Greene, Hongmei Gao, Celia LaBranche, John R. Mascola, Lynn Morris, David C. Montefiori, and Bette Korber. Panels of HIV-1 Subtype C Env Reference Strains for Standardized Neutralization Assessments. J. Virol., 91(19), 1 Oct 2017. PubMed ID: 28747500.
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Hraber2018
Peter Hraber, Bette Korber, Kshitij Wagh, David Montefiori, and Mario Roederer. A Single, Continuous Metric To Define Tiered Serum Neutralization Potency against Hiv. eLife, 7, 19 Jan 2018. PubMed ID: 29350181.
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Hu2015
Joyce K. Hu, Jordan C. Crampton, Albert Cupo, Thomas Ketas, Marit J. van Gils, Kwinten Sliepen, Steven W. de Taeye, Devin Sok, Gabriel Ozorowski, Isaiah Deresa, Robyn Stanfield, Andrew B. Ward, Dennis R. Burton, Per Johan Klasse, Rogier W. Sanders, John P. Moore, and Shane Crotty. Murine Antibody Responses to Cleaved Soluble HIV-1 Envelope Trimers Are Highly Restricted in Specificity. J. Virol., 89(20):10383-10398, Oct 2015. PubMed ID: 26246566.
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Huang2017a
Xun Huang, Qianqian Zhu, Xiaoxing Huang, Lifei Yang, Yufeng Song, Ping Zhu, and Paul Zhou. In Vivo Electroporation in DNA-VLP Prime-Boost Preferentially Enhances HIV-1 Envelope-Specific IgG2a, Neutralizing Antibody and CD8 T Cell Responses. Vaccine, 35(16):2042-2051, 11 Apr 2017. PubMed ID: 28318765.
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Hutchinson2019
Jennie M. Hutchinson, Kathryn A. Mesa, David L. Alexander, Bin Yu, Sara M. O'Rourke, Kay L. Limoli, Terri Wrin, Steven G. Deeks, and Phillip W. Berman. Unusual Cysteine Content in V1 Region of gp120 from an Elite Suppressor That Produces Broadly Neutralizing Antibodies. Front. Immunol., 10:1021, 2019. PubMed ID: 31156622.
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Kesavardhana2017
Sannula Kesavardhana, Raksha Das, Michael Citron, Rohini Datta, Linda Ecto, Nonavinakere Seetharam Srilatha, Daniel DiStefano, Ryan Swoyer, Joseph G. Joyce, Somnath Dutta, Celia C. LaBranche, David C. Montefiori, Jessica A. Flynn, and Raghavan Varadarajan. Structure-Based Design of Cyclically Permuted HIV-1 gp120 Trimers That Elicit Neutralizing Antibodies. J. Biol. Chem., 292(1):278-291, 6 Jan 2017. PubMed ID: 27879316.
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Klein2012a
Florian Klein, Ariel Halper-Stromberg, Joshua A. Horwitz, Henning Gruell, Johannes F. Scheid, Stylianos Bournazos, Hugo Mouquet, Linda A. Spatz, Ron Diskin, Alexander Abadir, Trinity Zang, Marcus Dorner, Eva Billerbeck, Rachael N. Labitt, Christian Gaebler, Paola M. Marcovecchio, Reha-Baris Incesu, Thomas R. Eisenreich, Paul D. Bieniasz, Michael S. Seaman, Pamela J. Bjorkman, Jeffrey V. Ravetch, Alexander Ploss, and Michel C. Nussenzweig. HIV Therapy by a Combination of Broadly Neutralizing Antibodies in Humanized Mice. Nature, 492(7427):118-122, 6 Dec 2012. PubMed ID: 23103874.
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Klein2013
Florian Klein, Ron Diskin, Johannes F. Scheid, Christian Gaebler, Hugo Mouquet, Ivelin S. Georgiev, Marie Pancera, Tongqing Zhou, Reha-Baris Incesu, Brooks Zhongzheng Fu, Priyanthi N. P. Gnanapragasam, Thiago Y. Oliveira, Michael S. Seaman, Peter D. Kwong, Pamela J. Bjorkman, and Michel C. Nussenzweig. Somatic Mutations of the Immunoglobulin Framework Are Generally Required for Broad and Potent HIV-1 Neutralization. Cell, 153(1):126-138, 28 Mar 2013. PubMed ID: 23540694.
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Kong2013
Leopold Kong, Jeong Hyun Lee, Katie J. Doores, Charles D. Murin, Jean-Philippe Julien, Ryan McBride, Yan Liu, Andre Marozsan, Albert Cupo, Per-Johan Klasse, Simon Hoffenberg, Michael Caulfield, C. Richter King, Yuanzi Hua, Khoa M. Le, Reza Khayat, Marc C. Deller, Thomas Clayton, Henry Tien, Ten Feizi, Rogier W. Sanders, James C. Paulson, John P. Moore, Robyn L. Stanfield, Dennis R. Burton, Andrew B. Ward, and Ian A. Wilson. Supersite of Immune Vulnerability on the Glycosylated Face of HIV-1 Envelope Glycoprotein gp120. Nat. Struct. Mol. Biol., 20(7):796-803, Jul 2013. PubMed ID: 23708606.
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Kong2015a
Leopold Kong, Alba Torrents de la Peña, Marc C. Deller, Fernando Garces, Kwinten Sliepen, Yuanzi Hua, Robyn L. Stanfield, Rogier W. Sanders, and Ian A. Wilson. Complete Epitopes for Vaccine Design Derived from a Crystal Structure of the Broadly Neutralizing Antibodies PGT128 and 8ANC195 in Complex with an HIV-1 Env trimer. Acta Crystallogr. D Biol. Crystallogr., 71(Pt 10):2099-2108, Oct 2015. PubMed ID: 26457433.
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Korber2017
Bette Korber, Peter Hraber, Kshitij Wagh, and Beatrice H. Hahn. Polyvalent Vaccine Approaches to Combat HIV-1 Diversity. Immunol. Rev., 275(1):230-244, Jan 2017. PubMed ID: 28133800.
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Krumm2016
Stefanie A. Krumm, Hajer Mohammed, Khoa M. Le, Max Crispin, Terri Wrin, Pascal Poignard, Dennis R. Burton, and Katie J. Doores. Mechanisms of Escape from the PGT128 Family of Anti-HIV Broadly Neutralizing Antibodies. Retrovirology, 13:8, 2 Feb 2016. PubMed ID: 26837192.
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Kwon2015
Young Do Kwon, Marie Pancera, Priyamvada Acharya, Ivelin S. Georgiev, Emma T. Crooks, Jason Gorman, M. Gordon Joyce, Miklos Guttman, Xiaochu Ma, Sandeep Narpala, Cinque Soto, Daniel S. Terry, Yongping Yang, Tongqing Zhou, Goran Ahlsen, Robert T. Bailer, Michael Chambers, Gwo-Yu Chuang, Nicole A. Doria-Rose, Aliaksandr Druz, Mark A. Hallen, Adam Harned, Tatsiana Kirys, Mark K. Louder, Sijy O'Dell, Gilad Ofek, Keiko Osawa, Madhu Prabhakaran, Mallika Sastry, Guillaume B. E. Stewart-Jones, Jonathan Stuckey, Paul V. Thomas, Tishina Tittley, Constance Williams, Baoshan Zhang, Hong Zhao, Zhou Zhou, Bruce R. Donald, Lawrence K. Lee, Susan Zolla-Pazner, Ulrich Baxa, Arne Schön, Ernesto Freire, Lawrence Shapiro, Kelly K. Lee, James Arthos, James B. Munro, Scott C. Blanchard, Walther Mothes, James M. Binley, Adrian B. McDermott, John R. Mascola, and Peter D. Kwong. Crystal Structure, Conformational Fixation and Entry-Related Interactions of Mature Ligand-Free HIV-1 Env. Nat. Struct. Mol. Biol., 22(7):522-531, Jul 2015. PubMed ID: 26098315.
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Kwong2012
Peter D. Kwong and John R. Mascola. Human Antibodies that Neutralize HIV-1: Identification, Structures, and B Cell Ontogenies. Immunity, 37(3):412-425, 21 Sep 2012. PubMed ID: 22999947.
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Kwong2013
Peter D. Kwong, John R. Mascola, and Gary J. Nabel. Broadly Neutralizing Antibodies and the Search for an HIV-1 Vaccine: The End of the Beginning. Nat. Rev. Immunol., 13(9):693-701, Sep 2013. PubMed ID: 23969737.
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Leaman2013
Daniel P. Leaman and Michael B. Zwick. Increased Functional Stability and Homogeneity of Viral Envelope Spikes through Directed Evolution. PLoS Pathog., 9(2):e1003184, Feb 2013. PubMed ID: 23468626.
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Lee2015a
Jeong Hyun Lee, Natalia de Val, Dmitry Lyumkis, and Andrew B. Ward. Model Building and Refinement of a Natively Glycosylated HIV-1 Env Protein by High-Resolution Cryoelectron Microscopy. Structure, 23(10):1943-1951, 6 Oct 2015. PubMed ID: 26388028.
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Liao2013a
Hongyan Liao, Jun-tao Guo, Miles D. Lange, Run Fan, Michael Zemlin, Kaihong Su, Yongjun Guan, and Zhixin Zhang. Contribution of V(H) Replacement Products to the Generation of Anti-HIV Antibodies. Clin. Immunol., 146(1):46-55, Jan 2013. PubMed ID: 23220404.
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Liu2015a
Mengfei Liu, Guang Yang, Kevin Wiehe, Nathan I. Nicely, Nathan A. Vandergrift, Wes Rountree, Mattia Bonsignori, S. Munir Alam, Jingyun Gao, Barton F. Haynes, and Garnett Kelsoe. Polyreactivity and Autoreactivity among HIV-1 Antibodies. J. Virol., 89(1):784-798, Jan 2015. PubMed ID: 25355869.
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Longo2016
Nancy S. Longo, Matthew S. Sutton, Andrea R. Shiakolas, Javier Guenaga, Marissa C. Jarosinski, Ivelin S. Georgiev, Krisha McKee, Robert T. Bailer, Mark K. Louder, Sijy O'Dell, Mark Connors, Richard T. Wyatt, John R. Mascola, and Nicole A. Doria-Rose. Multiple Antibody Lineages in One Donor Target the Glycan-V3 Supersite of the HIV-1 Envelope Glycoprotein and Display a Preference for Quaternary Binding. J. Virol., 90(23):10574-10586, 1 Dec 2016. PubMed ID: 27654288.
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Magnus2016
Carsten Magnus, Lucia Reh, and Alexandra Trkola. HIV-1 Resistance to Neutralizing Antibodies: Determination of Antibody Concentrations Leading to Escape Mutant Evolution. Virus Res., 218:57-70, 15 Jun 2016. PubMed ID: 26494166.
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Mannar2021
Dhiraj Mannar, Karoline Leopold, and Sriram Subramaniam. Glycan Reactive Anti-HIV-1 Antibodies bind the SARS-CoV-2 Spike Protein But Do Not Block Viral Entry. Sci. Rep., 11(1):12448, 14 Jun 2021. PubMed ID: 34127709.
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McCoy2015
Laura E. McCoy, Emilia Falkowska, Katie J. Doores, Khoa Le, Devin Sok, Marit J. van Gils, Zelda Euler, Judith A. Burger, Michael S. Seaman, Rogier W. Sanders, Hanneke Schuitemaker, Pascal Poignard, Terri Wrin, and Dennis R. Burton. Incomplete Neutralization and Deviation from Sigmoidal Neutralization Curves for HIV Broadly Neutralizing Monoclonal Antibodies. PLoS Pathog., 11(8):e1005110, Aug 2015. PubMed ID: 26267277.
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Mishra2020
Nitesh Mishra, Shaifali Sharma, Ayushman Dobhal, Sanjeev Kumar, Himanshi Chawla, Ravinder Singh, Bimal Kumar Das, Sushil Kumar Kabra, Rakesh Lodha, and Kalpana Luthra. A Rare Mutation in an Infant-Derived HIV-1 Envelope Glycoprotein Alters Interprotomer Stability and Susceptibility to Broadly Neutralizing Antibodies Targeting the Trimer Apex. J. Virol., 94(19), 15 Sep 2020. PubMed ID: 32669335.
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Mishra2020a
Nitesh Mishra, Shaifali Sharma, Ayushman Dobhal, Sanjeev Kumar, Himanshi Chawla, Ravinder Singh, Muzamil Ashraf Makhdoomi, Bimal Kumar Das, Rakesh Lodha, Sushil Kumar Kabra, and Kalpana Luthra. Broadly Neutralizing Plasma Antibodies Effective against Autologous Circulating Viruses in Infants with Multivariant HIV-1 Infection. Nat. Commun., 11(1):4409, 2 Sep 2020. PubMed ID: 32879304.
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Molinos-Albert2023
Luis M. Molinos-Albert, Eduard Baquero, Melanie Bouvin-Pley, Valerie Lorin, Caroline Charre, Cyril Planchais, Jordan D. Dimitrov, Valerie Monceaux, Matthijn Vos, Laurent Hocqueloux, Jean-Luc Berger, Michael S. Seaman, Martine Braibant, Veronique Avettand-Fenoel, Asier Saez-Cirion, and Hugo Mouquet. Anti-V1/V3-glycan broadly HIV-1 neutralizing antibodies in a post-treatment controller. Cell Host Microbe, 31(8):1275-1287e8 doi, Aug 2023. PubMed ID: 37433296
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Moore2012
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Morgand2015
Marion Morgand, Mélanie Bouvin-Pley, Jean-Christophe Plantier, Alain Moreau, Elodie Alessandri, François Simon, Craig S. Pace, Marie Pancera, David D. Ho, Pascal Poignard, Pamela J. Bjorkman, Hugo Mouquet, Michel C. Nussenzweig, Peter D. Kwong, Daniel Baty, Patrick Chames, Martine Braibant, and Francis Barin. A V1V2 Neutralizing Epitope Is Conserved in Divergent Non-M Groups of HIV-1. J. Acquir. Immune Defic. Syndr., 21 Sep 2015. PubMed ID: 26413851.
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Mouquet2012a
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Moyo2018
Thandeka Moyo, June Ereño-Orbea, Rajesh Abraham Jacob, Clara E. Pavillet, Samuel Mundia Kariuki, Emily N. Tangie, Jean-Philippe Julien, and Jeffrey R. Dorfman. Molecular Basis of Unusually High Neutralization Resistance in Tier 3 HIV-1 Strain 253-11. J. Virol., 92(14), 15 Jul 2018. PubMed ID: 29618644.
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Nogal2020
Bartek Nogal, Laura E. McCoy, Marit J. van Gils, Christopher A. Cottrell, James E. Voss, Raiees Andrabi, Matthias Pauthner, Chi-Hui Liang, Terrence Messmer, Rebecca Nedellec, Mia Shin, Hannah L. Turner, Gabriel Ozorowski, Rogier W. Sanders, Dennis R. Burton, and Andrew B. Ward. HIV Envelope Trimer-Elicited Autologous Neutralizing Antibodies Bind a Region Overlapping the N332 Glycan Supersite. Sci. Adv., 6(23):eaba0512, Jun 2020. PubMed ID: 32548265.
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Pancera2013a
Marie Pancera, Yongping Yang, Mark K. Louder, Jason Gorman, Gabriel Lu, Jason S. McLellan, Jonathan Stuckey, Jiang Zhu, Dennis R. Burton, Wayne C. Koff, John R. Mascola, and Peter D. Kwong. N332-Directed Broadly Neutralizing Antibodies Use Diverse Modes of HIV-1 Recognition: Inferences from Heavy-Light Chain Complementation of Function. PLoS One, 8(2):e55701, 2013. PubMed ID: 23431362.
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Pejchal2011
Robert Pejchal, Katie J. Doores, Laura M. Walker, Reza Khayat, Po-Ssu Huang, Sheng-Kai Wang, Robyn L. Stanfield, Jean-Philippe Julien, Alejandra Ramos, Max Crispin, Rafael Depetris, Umesh Katpally, Andre Marozsan, Albert Cupo, Sebastien Maloveste, Yan Liu, Ryan McBride, Yukishige Ito, Rogier W. Sanders, Cassandra Ogohara, James C. Paulson, Ten Feizi, Christopher N. Scanlan, Chi-Huey Wong, John P. Moore, William C. Olson, Andrew B. Ward, Pascal Poignard, William R. Schief, Dennis R. Burton, and Ian A. Wilson. A Potent and Broad Neutralizing Antibody Recognizes and Penetrates the HIV Glycan Shield. Science, 334(6059):1097-1103, 25 Nov 2011. PubMed ID: 21998254.
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Pinto2019
Dora Pinto, Craig Fenwick, Christophe Caillat, Chiara Silacci, Serafima Guseva, François Dehez, Christophe Chipot, Sonia Barbieri, Andrea Minola, David Jarrossay, Georgia D. Tomaras, Xiaoying Shen, Agostino Riva, Maciej Tarkowski, Olivier Schwartz, Timothée Bruel, Jérémy Dufloo, Michael S. Seaman, David C. Montefiori, Antonio Lanzavecchia, Davide Corti, Giuseppe Pantaleo, and Winfried Weissenhorn. Structural Basis for Broad HIV-1 Neutralization by the MPER-Specific Human Broadly Neutralizing Antibody LN01. Cell Host Microbe, 26(5):623-637.e8, 13 Nov 2019. PubMed ID: 31653484.
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Prigent2018
Julie Prigent, Annaëlle Jarossay, Cyril Planchais, Caroline Eden, Jérémy Dufloo, Ayrin Kök, Valérie Lorin, Oxana Vratskikh, Thérèse Couderc, Timothée Bruel, Olivier Schwartz, Michael S. Seaman, Ohlenschläger, Jordan D. Dimitrov, and Hugo Mouquet. Conformational Plasticity in Broadly Neutralizing HIV-1 Antibodies Triggers Polyreactivity. Cell Rep., 23(9):2568-2581, 29 May 2018. PubMed ID: 29847789.
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Yifei Qi, Sunhwan Jo, and Wonpil Im. Roles of Glycans in Interactions between gp120 and HIV Broadly Neutralizing Antibodies. Glycobiology, 26(3):251-260, Mar 2016. PubMed ID: 26537503.
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Rademeyer2016
Cecilia Rademeyer, Bette Korber, Michael S. Seaman, Elena E. Giorgi, Ruwayhida Thebus, Alexander Robles, Daniel J. Sheward, Kshitij Wagh, Jetta Garrity, Brittany R. Carey, Hongmei Gao, Kelli M. Greene, Haili Tang, Gama P. Bandawe, Jinny C. Marais, Thabo E. Diphoko, Peter Hraber, Nancy Tumba, Penny L. Moore, Glenda E. Gray, James Kublin, M. Juliana McElrath, Marion Vermeulen, Keren Middelkoop, Linda-Gail Bekker, Michael Hoelscher, Leonard Maboko, Joseph Makhema, Merlin L. Robb, Salim Abdool Karim, Quarraisha Abdool Karim, Jerome H. Kim, Beatrice H. Hahn, Feng Gao, Ronald Swanstrom, Lynn Morris, David C. Montefiori, and Carolyn Williamson. Features of Recently Transmitted HIV-1 Clade C Viruses that Impact Antibody Recognition: Implications for Active and Passive Immunization. PLoS Pathog., 12(7):e1005742, Jul 2016. PubMed ID: 27434311.
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Reiss2022
E. I. M. M. Reiss, M. M. van Haaren, J. van Schooten, M. A. F. Claireaux, P. Maisonnasse, A. Antanasijevic, J. D. Allen, I. Bontjer, J. L. Torres, W.-H. Lee, G. Ozorowski, N. Vázquez Bernat, M. Kaduk, Y. Aldon, J. A. Burger, H. Chawla, A. Aartse, M. Tolazzi, H. Gao, P. Mundsperger, M. Crispin, D. C. Montefiori, G. B. Karlsson Hedestam, G. Scarlatti, A. B. Ward, R. Le Grand, R. Shattock, N. Dereuddre-Bosquet, R. W. Sanders, and M. J. van Gils. Fine-Mapping the Immunodominant Antibody Epitopes on Consensus Sequence-Based HIV-1 Envelope Trimer Vaccine Candidates. NPJ Vaccines, 7(1):152, 25 Nov 2022. PubMed ID: 36433972.
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Rosenberg2015
Yvonne Rosenberg, Markus Sack, David Montefiori, Celia Labranche, Mark Lewis, Lori Urban, Lingjun Mao, Rainer Fischer, and Xiaoming Jiang. Pharmacokinetics and Immunogenicity of Broadly Neutralizing HIV Monoclonal Antibodies in Macaques. PLoS One, 10(3):e0120451, 25 Mar 2015. PubMed ID: 25807114.
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Peter Rusert, Roger D. Kouyos, Claus Kadelka, Hanna Ebner, Merle Schanz, Michael Huber, Dominique L. Braun, Nathanael Hozé, Alexandra Scherrer, Carsten Magnus, Jacqueline Weber, Therese Uhr, Valentina Cippa, Christian W. Thorball, Herbert Kuster, Matthias Cavassini, Enos Bernasconi, Matthias Hoffmann, Alexandra Calmy, Manuel Battegay, Andri Rauch, Sabine Yerly, Vincent Aubert, Thomas Klimkait, Jürg Böni, Jacques Fellay, Roland R. Regoes, Huldrych F. Günthard, Alexandra Trkola, and Swiss HIV Cohort Study. Determinants of HIV-1 Broadly Neutralizing Antibody Induction. Nat. Med., 22(11):1260-1267, Nov 2016. PubMed ID: 27668936.
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Sanders2013
Rogier W. Sanders, Ronald Derking, Albert Cupo, Jean-Philippe Julien, Anila Yasmeen, Natalia de Val, Helen J. Kim, Claudia Blattner, Alba Torrents de la Peña, Jacob Korzun, Michael Golabek, Kevin de los Reyes, Thomas J. Ketas, Marit J. van Gils, C. Richter King, Ian A. Wilson, Andrew B. Ward, P. J. Klasse, and John P. Moore. A Next-Generation Cleaved, Soluble HIV-1 Env Trimer, BG505 SOSIP.664 gp140, Expresses Multiple Epitopes for Broadly Neutralizing but not Non-Neutralizing Antibodies. PLoS Pathog., 9(9):e1003618, Sep 2013. PubMed ID: 24068931.
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Saunders2017
Kevin O. Saunders, Nathan I. Nicely, Kevin Wiehe, Mattia Bonsignori, R. Ryan Meyerhoff, Robert Parks, William E. Walkowicz, Baptiste Aussedat, Nelson R. Wu, Fangping Cai, Yusuf Vohra, Peter K. Park, Amanda Eaton, Eden P. Go, Laura L. Sutherland, Richard M. Scearce, Dan H. Barouch, Ruijun Zhang, Tarra Von Holle, R. Glenn Overman, Kara Anasti, Rogier W. Sanders, M. Anthony Moody, Thomas B. Kepler, Bette Korber, Heather Desaire, Sampa Santra, Norman L. Letvin, Gary J. Nabel, David C. Montefiori, Georgia D. Tomaras, Hua-Xin Liao, S. Munir Alam, Samuel J. Danishefsky, and Barton F. Haynes. Vaccine Elicitation of High Mannose-Dependent Neutralizing Antibodies against the V3-Glycan Broadly Neutralizing Epitope in Nonhuman Primates. Cell Rep., 18(9):2175-2188, 28 Feb 2017. PubMed ID: 28249163.
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Scheepers2015
Cathrine Scheepers, Ram K. Shrestha, Bronwen E. Lambson, Katherine J. L. Jackson, Imogen A. Wright, Dshanta Naicker, Mark Goosen, Leigh Berrie, Arshad Ismail, Nigel Garrett, Quarraisha Abdool Karim, Salim S. Abdool Karim, Penny L. Moore, Simon A. Travers, and Lynn Morris. Ability to Develop Broadly Neutralizing HIV-1 Antibodies Is Not Restricted by the Germline Ig Gene Repertoire. J. Immunol., 194(9):4371-4378, 1 May 2015. PubMed ID: 25825450.
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Schiffner2016
Torben Schiffner, Natalia de Val, Rebecca A. Russell, Steven W. de Taeye, Alba Torrents de la Peña, Gabriel Ozorowski, Helen J. Kim, Travis Nieusma, Florian Brod, Albert Cupo, Rogier W. Sanders, John P. Moore, Andrew B. Ward, and Quentin J. Sattentau. Chemical Cross-Linking Stabilizes Native-Like HIV-1 Envelope Glycoprotein Trimer Antigens. J. Virol., 90(2):813-828, 28 Oct 2015. PubMed ID: 26512083.
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Schiffner2018
Torben Schiffner, Jesper Pallesen, Rebecca A. Russell, Jonathan Dodd, Natalia de Val, Celia C. LaBranche, David Montefiori, Georgia D. Tomaras, Xiaoying Shen, Scarlett L. Harris, Amin E. Moghaddam, Oleksandr Kalyuzhniy, Rogier W. Sanders, Laura E. McCoy, John P. Moore, Andrew B. Ward, and Quentin J. Sattentau. Structural and Immunologic Correlates of Chemically Stabilized HIV-1 Envelope Glycoproteins. PLoS Pathog., 14(5):e1006986, May 2018. PubMed ID: 29746590.
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Schorcht2020
Anna Schorcht, Tom L. G. M. van den Kerkhof, Christopher A. Cottrell, Joel D. Allen, Jonathan L. Torres, Anna-Janina Behrens, Edith E. Schermer, Judith A. Burger, Steven W. de Taeye, Alba Torrents de la Peña, Ilja Bontjer, Stephanie Gumbs, Gabriel Ozorowski, Celia C. LaBranche, Natalia de Val, Anila Yasmeen, Per Johan Klasse, David C. Montefiori, John P. Moore, Hanneke Schuitemaker, Max Crispin, Marit J. van Gils, Andrew B. Ward, and Rogier W. Sanders. Neutralizing Antibody Responses Induced by HIV-1 Envelope Glycoprotein SOSIP Trimers Derived from Elite Neutralizers. J. Virol., 94(24), 23 Nov 2020. PubMed ID: 32999024.
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Silver2019
Zachary A. Silver, Gordon M. Dickinson, Michael S. Seaman, and Ronald C. Desrosiers. A Highly Unusual V1 Region of Env in an Elite Controller of HIV Infection. J. Virol., 93(10), 15 May 2019. PubMed ID: 30842322.
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Sliepen2015
Kwinten Sliepen, Max Medina-Ramirez, Anila Yasmeen, John P. Moore, Per Johan Klasse, and Rogier W. Sanders. Binding of Inferred Germline Precursors of Broadly Neutralizing HIV-1 Antibodies to Native-Like Envelope Trimers. Virology, 486:116-120, Dec 2015. PubMed ID: 26433050.
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Sliepen2019
Kwinten Sliepen, Byung Woo Han, Ilja Bontjer, Petra Mooij, Fernando Garces, Anna-Janina Behrens, Kimmo Rantalainen, Sonu Kumar, Anita Sarkar, Philip J. M. Brouwer, Yuanzi Hua, Monica Tolazzi, Edith Schermer, Jonathan L. Torres, Gabriel Ozorowski, Patricia van der Woude, Alba Torrents de la Pena, Marielle J. van Breemen, Juan Miguel Camacho-Sanchez, Judith A. Burger, Max Medina-Ramirez, Nuria Gonzalez, Jose Alcami, Celia LaBranche, Gabriella Scarlatti, Marit J. van Gils, Max Crispin, David C. Montefiori, Andrew B. Ward, Gerrit Koopman, John P. Moore, Robin J. Shattock, Willy M. Bogers, Ian A. Wilson, and Rogier W. Sanders. Structure and immunogenicity of a stabilized HIV-1 envelope trimer based on a group-M consensus sequence. Nat Commun, 10(1):2355 doi, May 2019. PubMed ID: 31142746
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Sok2014a
Devin Sok, Katie J. Doores, Bryan Briney, Khoa M. Le, Karen L. Saye-Francisco, Alejandra Ramos, Daniel W. Kulp, Jean-Philippe Julien, Sergey Menis, Lalinda Wickramasinghe, Michael S. Seaman, William R. Schief, Ian A. Wilson, Pascal Poignard, and Dennis R. Burton. Promiscuous Glycan Site Recognition by Antibodies to the High-Mannose Patch of gp120 Broadens Neutralization of HIV. Sci. Transl. Med., 6(236):236ra63, 14 May 2014. PubMed ID: 24828077.
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Sok2016
Devin Sok, Matthias Pauthner, Bryan Briney, Jeong Hyun Lee, Karen L. Saye-Francisco, Jessica Hsueh, Alejandra Ramos, Khoa M. Le, Meaghan Jones, Joseph G. Jardine, Raiza Bastidas, Anita Sarkar, Chi-Hui Liang, Sachin S. Shivatare, Chung-Yi Wu, William R. Schief, Chi-Huey Wong, Ian A. Wilson, Andrew B. Ward, Jiang Zhu, Pascal Poignard, and Dennis R. Burton. A Prominent Site of Antibody Vulnerability on HIV Envelope Incorporates a Motif Associated with CCR5 Binding and Its Camouflaging Glycans. Immunity, 45(1):31-45, 19 Jul 2016. PubMed ID: 27438765.
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Stanfield2020
Robyn L. Stanfield, Zachary T. Berndsen, Ruiqi Huang, Devin Sok, Gabrielle Warner, Jonathan L. Torres, Dennis R. Burton, Andrew B. Ward, Ian A. Wilson, and Vaughn V. Smider. Structural Basis of Broad HIV Neutralization by a Vaccine-Induced Cow Antibody. Sci. Adv., 6(22):eaba0468, May 2020. PubMed ID: 32518821.
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Stewart-Jones2016
Guillaume B. E. Stewart-Jones, Cinque Soto, Thomas Lemmin, Gwo-Yu Chuang, Aliaksandr Druz, Rui Kong, Paul V. Thomas, Kshitij Wagh, Tongqing Zhou, Anna-Janina Behrens, Tatsiana Bylund, Chang W. Choi, Jack R. Davison, Ivelin S. Georgiev, M. Gordon Joyce, Young Do Kwon, Marie Pancera, Justin Taft, Yongping Yang, Baoshan Zhang, Sachin S. Shivatare, Vidya S. Shivatare, Chang-Chun D. Lee, Chung-Yi Wu, Carole A. Bewley, Dennis R. Burton, Wayne C. Koff, Mark Connors, Max Crispin, Ulrich Baxa, Bette T. Korber, Chi-Huey Wong, John R. Mascola, and Peter D. Kwong. Trimeric HIV-1-Env Structures Define Glycan Shields from Clades A, B, and G. Cell, 165(4):813-826, 5 May 2016. PubMed ID: 27114034.
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Wagh2016
Kshitij Wagh, Tanmoy Bhattacharya, Carolyn Williamson, Alex Robles, Madeleine Bayne, Jetta Garrity, Michael Rist, Cecilia Rademeyer, Hyejin Yoon, Alan Lapedes, Hongmei Gao, Kelli Greene, Mark K. Louder, Rui Kong, Salim Abdool Karim, Dennis R. Burton, Dan H. Barouch, Michel C. Nussenzweig, John R. Mascola, Lynn Morris, David C. Montefiori, Bette Korber, and Michael S. Seaman. Optimal Combinations of Broadly Neutralizing Antibodies for Prevention and Treatment of HIV-1 Clade C Infection. PLoS Pathog., 12(3):e1005520, Mar 2016. PubMed ID: 27028935.
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Walker2018
Laura M. Walker and Dennis R. Burton. Passive Immunotherapy of Viral Infections: `Super-Antibodies' Enter the Fray. Nat. Rev. Immunol., 18(5):297-308, May 2018. PubMed ID: 29379211.
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Wang2019
Qian Wang, Lihong Liu, Wuze Ren, Agegnehu Gettie, Hua Wang, Qingtai Liang, Xuanling Shi, David C. Montefiori, Tongqing Zhou, and Linqi Zhang. A Single Substitution in gp41 Modulates the Neutralization Profile of SHIV during In Vivo Adaptation. Cell Rep., 27(9):2593-2607.e5, 28 May 2019. PubMed ID: 31141685.
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Webb2015
Nicholas E. Webb, David C. Montefiori, and Benhur Lee. Dose-Response Curve Slope Helps Predict Therapeutic Potency and Breadth of HIV Broadly Neutralizing Antibodies. Nat. Commun., 6:8443, 29 Sep 2015. PubMed ID: 26416571.
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Wen2018
Yingxia Wen, Hung V. Trinh, Christine E Linton, Chiara Tani, Nathalie Norais, DeeAnn Martinez-Guzman, Priyanka Ramesh, Yide Sun, Frank Situ, Selen Karaca-Griffin, Christopher Hamlin, Sayali Onkar, Sai Tian, Susan Hilt, Padma Malyala, Rushit Lodaya, Ning Li, Gillis Otten, Giuseppe Palladino, Kristian Friedrich, Yukti Aggarwal, Celia LaBranche, Ryan Duffy, Xiaoying Shen, Georgia D. Tomaras, David C. Montefiori, William Fulp, Raphael Gottardo, Brian Burke, Jeffrey B. Ulmer, Susan Zolla-Pazner, Hua-Xin Liao, Barton F. Haynes, Nelson L. Michael, Jerome H. Kim, Mangala Rao, Robert J. O'Connell, Andrea Carfi, and Susan W. Barnett. Generation and Characterization of a Bivalent Protein Boost for Future Clinical Trials: HIV-1 Subtypes CR01\_AE and B gp120 Antigens with a Potent Adjuvant. PLoS One, 13(4):e0194266, 2018. PubMed ID: 29698406.
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Wieczorek2023
Lindsay Wieczorek, Eric Sanders-Buell, Michelle Zemil, Eric Lewitus, Erin Kavusak, Jonah Heller, Sebastian Molnar, Mekhala Rao, Gabriel Smith, Meera Bose, Amy Nguyen, Adwitiya Dhungana, Katherine Okada, Kelly Parisi, Daniel Silas, Bonnie Slike, Anuradha Ganesan, Jason Okulicz, Tahaniyat Lalani, Brian K. Agan, Trevor A. Crowell, Janice Darden, Morgane Rolland, Sandhya Vasan, Julie Ake, Shelly J. Krebs, Sheila Peel, Sodsai Tovanabutra, and Victoria R. Polonis. Evolution of HIV-1 envelope towards reduced neutralization sensitivity, as demonstrated by contemporary HIV-1 subtype B from the United States. PLoS Pathog, 19(12):e1011780 doi, Dec 2023. PubMed ID: 38055771
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Wiehe2018
Kevin Wiehe, Todd Bradley, R. Ryan Meyerhoff, Connor Hart, Wilton B. Williams, David Easterhoff, William J. Faison, Thomas B. Kepler, Kevin O. Saunders, S. Munir Alam, Mattia Bonsignori, and Barton F. Haynes. Functional Relevance of Improbable Antibody Mutations for HIV Broadly Neutralizing Antibody Development. Cell Host Microbe, 23(6):759-765.e6, 13 Jun 2018. PubMed ID: 29861171.
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Wu2016
Xueling Wu and Xiang-Peng Kong. Antigenic Landscape of the HIV-1 Envelope and New Immunological Concepts Defined by HIV-1 Broadly Neutralizing Antibodies. Curr. Opin. Immunol., 42:56-64, Oct 2016. PubMed ID: 27289425.
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Wu2018
Xilin Wu, Jia Guo, Mengyue Niu, Minghui An, Li Liu, Hui Wang, Xia Jin, Qi Zhang, Ka Shing Lam, Tongjin Wu, Hua Wang, Qian Wang, Yanhua Du, Jingjing Li, Lin Cheng, Hang Ying Tang, Hong Shang, Linqi Zhang, Paul Zhou, and Zhiwei Chen. Tandem bispecific neutralizing antibody eliminates HIV-1 infection in humanized mice. J Clin Invest, 128(6):2239-2251, Jun 1 2018. PubMed ID: 29461979.
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Yang2014
Lili Yang and Pin Wang. Passive Immunization against HIV/AIDS by Antibody Gene Transfer. Viruses, 6(2):428-447, Feb 2014. PubMed ID: 24473340.
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Yasmeen2014
Anila Yasmeen, Rajesh Ringe, Ronald Derking, Albert Cupo, Jean-Philippe Julien, Dennis R. Burton, Andrew B. Ward, Ian A. Wilson, Rogier W. Sanders, John P. Moore, and Per Johan Klasse. Differential Binding of Neutralizing and Non-Neutralizing Antibodies to Native-Like Soluble HIV-1 Env Trimers, Uncleaved Env Proteins, and Monomeric Subunits. Retrovirology, 11:41, 2014. PubMed ID: 24884783.
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Yates2018
Nicole L. Yates, Allan C. deCamp, Bette T. Korber, Hua-Xin Liao, Carmela Irene, Abraham Pinter, James Peacock, Linda J. Harris, Sheetal Sawant, Peter Hraber, Xiaoying Shen, Supachai Rerks-Ngarm, Punnee Pitisuttithum, Sorachai Nitayapan, Phillip W. Berman, Merlin L. Robb, Giuseppe Pantaleo, Susan Zolla-Pazner, Barton F. Haynes, S. Munir Alam, David C. Montefiori, and Georgia D. Tomaras. HIV-1 Envelope Glycoproteins from Diverse Clades Differentiate Antibody Responses and Durability among Vaccinees. J. Virol., 92(8), 15 Apr 2018. PubMed ID: 29386288.
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Yu2018
Wen-Han Yu, Peng Zhao, Monia Draghi, Claudia Arevalo, Christina B. Karsten, Todd J. Suscovich, Bronwyn Gunn, Hendrik Streeck, Abraham L. Brass, Michael Tiemeyer, Michael Seaman, John R. Mascola, Lance Wells, Douglas A. Lauffenburger, and Galit Alter. Exploiting Glycan Topography for Computational Design of Env Glycoprotein Antigenicity. PLoS Comput. Biol., 14(4):e1006093, Apr 2018. PubMed ID: 29677181.
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Zhou2014
Jing Zhou, Ning Gan, Tianhua Li, Futao Hu, Xing Li, Lihong Wang, and Lei Zheng. A Cost-Effective Sandwich Electrochemiluminescence Immunosensor for Ultrasensitive Detection of HIV-1 Antibody Using Magnetic Molecularly Imprinted Polymers as Capture Probes. Biosens. Bioelectron., 54:199-206, 15 Apr 2014. PubMed ID: 24280050.
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Sengupta2023
Srona Sengupta, Josephine Zhang, Madison C. Reed, Jeanna Yu, Aeryon Kim, Tatiana N. Boronina, Nathan L. Board, James O. Wrabl, Kevin Shenderov, Robin A. Welsh, Weiming Yang, Andrew E. Timmons, Rebecca Hoh, Robert N. Cole, Steven G. Deeks, Janet D. Siliciano, Robert F. Siliciano, and Scheherazade Sadegh-Nasseri. A cell-free antigen processing system informs HIV-1 epitope selection and vaccine design. J Exp Med, 220(7):e20221654 doi, Jul 2023. PubMed ID: 37058141
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