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• NIH45-46: 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. NIH45-46 was used for analyzing clade sensitivity and the CD4bs signature summaries. Bricault2019 (antibody binding site, vaccine antigen design, computational epitope prediction, broad neutralizer)
• NIH45-46: This review discusses the identification of super-Abs, where and how such Abs may be best applied and future directions for the field. NIH45-46 was isolated from human B cell clones and is functionally similar to VRC01. Antigenic region CD4 binding site (Table:1). Walker2018 (antibody binding site, review, broad neutralizer)
• NIH45-46: 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)
• NIH45-46: 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. SOSIP 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 NIH45-46 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)
• NIH45-46: Assays of poly- and autoreactivity demonstrated that broadly neutralizing NAbs are significantly more poly- and autoreactive than non-neutralizing NAbs. NIH45-46 is polyreactive, but not autoreactive. Liu2015a (autoantibody or autoimmunity, antibody polyreactivity)
• NIH45-46: 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)
• NIH45-46: In neutralization assays of antibody mixtures, there was a modest synergy between the CD4bs VRC01 and either of the two CD4i MAbs E51 and 412d. The synergy is likely the result of the ability of CD4i antibodies (E51 or 412d) to induce the open state and facilitate access to the CD4 binding site. The presence of E51 enhanced the Env binding of VRC01, NIH45-46, NIH45-46^G54W, and to a lesser extent 3BNC117. Gardner2016 (antibody interactions)
• NIH45-46: 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. Consistent with CD4bs bNAbs, NIH45-46 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)
• NIH45-46: 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. As with CD4bs binding bNAbs, NIH45-46 is inhibited by sCD4. It enhanced binding of several V1/V2-glycan, V3-glycan or outer domain (OD)-glycan bNAbs; and also modestly enhanced binding of non-NAb, 17b. OD-glycan bNAbs, PGT135 and PGT136, though ˜ 5x less efficient binders of trimer, were able to unidirectionally inhibit binding of NIH45-46, as also other CD4bs bNAbs, VRC01, 2BNC60, 3BNC117. Derking2015 (antibody interactions, neutralization, binding affinity, structure)
• NIH45-46: Two clade C recombinant Env glycoprotein trimers, DU422 and ZM197M, with native-like structural and antigenic properties involving epitopes for 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 have high affinity for bNAb NIH45-46, and the structure of a complex of ZM197M SOSIP.664 with NIH45-46 single-chain Fv at 4.4 A by X-ray crystallography had a 0.95 correlation with the structure of the Clade A trimer. Julien2015 (assay or method development, structure)
• NIH45-46: 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-CD4bs bNAb NIH45-46 to trimers was minimally affected by trimer cross-linking. Schiffner2016 (assay or method development, binding affinity, structure)
• NIH45-46: 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-CD4bs bNAb NIH45-46 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)
• NIH45-46: VRC01-class bNAb like NIH45-46 protects animals from experimental infection and could contribute to an effective vaccine response. Their predicted germline forms (gl) bind Env inefficiently, which may explain why they are not elicited by HIV-1 Env-immunization. This paper describes modifications that expand the glVRC01-class antibody-recognition potential of the 426c Env. McGuire2016 (antibody interactions, antibody lineage)
• NIH45-46: A subset of bNAbs that inhibit both cell-free and cell-mediated infection in primary CD4+ lymphocytes have been identified. These antibodies target either the CD4-binding site or the glycan/V3 loop on HIV-1 gp120 and act at low concentrations by inhibiting multiple steps of viral cell to cell transmission. This property of blocking viral transmission to plasmacytoid DCs and interfering with type-I IFN production should be considered an important characteristic defining the potency for therapeutic or prophylactic antiviral strategies. NIH45-46 was the most active antibody preventing the cell to cell transmission of virus. Malbec2013
• NIH45-46: 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. 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)
• NIH45-46: This study presented structures of germline-reverted VRC01-class bNAbs alone and complexed with 426c-based gp120 immunogens. Germline bNAb–426c gp120 complexes showed preservation of VRC01-class signature residues and gp120 contacts, but detectably different binding modes compared to mature bNAb-gp120 complexes. It reported that unlike most antibodies, the overall final structures of VRC01 class antibodies are formed before the antibodies mature. NIH45-46GL make all predicted HC VRC01-class signature contacts with the CD4-binding loop, the V5 loop, and loop D to bind to gp120. Scharf2016 (structure)
• NIH45-46: A panel of antibodies was tested for binding, stability, and ADCC activity on HIV-infected cells. The differences in killing efficiency were linked to changes in binding of the antibody and the accessibility of the Fc region when bound to infected cells. Ab NIH45-46 had strong ADCC. Bruel2016 (ADCC, binding affinity)
• NIH45-46: The rate of maturation and extent of diversity for the VRC01 lineage were characterized through longitudinal sampling of peripheral B cell transcripts from donor 45 over 15 years and co-crystal structures. VRC01-lineage clades underwent continuous evolution, with rates of ˜2 substitutions per 100 nucleotides per year, comparable with HIV-1 evolution. 39 VRC01-lineage Abs segregated into three major clades, and all Abs from donor 45 contained a cysteine at position 98 (99 in some sequences due to a 1-aa insertion) which was used as a signature to assess membership in the VRC01 lineage. Of 1,041 curated NGS sequences assigned to the VRC01 lineage, six did not contain the cysteine while 1,035 did (99.4%). NIH45-46 appeared to be somatic variants from a single VRC01 lineage. Wu2015 (antibody lineage)
• NIH45-46: 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. CNAE08,CNAE14, CNAE17, and CNAE31 were all shown to be highly resistant to NIH45-46. Chen2016 (neutralization, subtype comparisons)
• NIH45-46: 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)
• NIH45-46: 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 CD4BS antibodies b12, 2G12 and NIH45-46. Upadhyay2014 (glycosylation, neutralization)
• NIH45-46: A set of potent VRC01-like (PVL) MAbs were generated from VRC01-derivatve NIH45-46^G54W and they were more potent than even NIH45-46 or NIH45-46^G54W, cross-recognizing viruses across clades. The novel antibodies designed based on crystal structure were NIH45-46m2, NIH45-46m7, NIH45-46m25 and NIH45-46m28, with NIH45-46m2 being the single most broad and potent antibody till date. 45-46m2 and 45-46m7 in combination with each other and a third antibody were able to thwart viral escape routes. Diskin2013 (antibody generation, variant cross-reactivity, structure)
• NIH45-46: Envs from clades A, B and C were screened for binding to the germline predecessors of anti-CD4bs bNAbs b12, NIH45-46 and 3BNC60. Mature Abs reacted with diverse Envs, but not the germ-line Abs. Engineered chimeric Abs with mature and germ-line heavy and light chain combinations showed the importance of both mature chains for the cross-reactivity. Hoot2013 (antibody lineage, chimeric antibody)
• NIH45-46: The structures of germline Ab VH1-2*02 alone and a chimeric germline heavy chain/mature light chain NIH45-46 MAb complexed with gp120 are reported. VH1-2*02 residues make extensive contacts, but not the critical CDRH3 contacts with gp120 inner domain, which confer improved potency to NIH45-46. Scharf2013 (structure)
• NIH45-46: Next generation sequencing was applied to a new donor C38 (different from donor NIH45) to identify VRC01 class bNAbs. VRC01 class heavy chains were selected through a cross-donor phylogenetic analysis. VRC01 class light chains were identified through a five-amino-acid sequence motif. (CDR L3 length of 5 amino acids and Q or E at position 96 (Kabat numbering) or position 4 within the CDR L3 sequence.) NIH45-46 was used to compare the heavy & light chain sequences as a template of VRC01 class Ab. Zhu2013a (antibody sequence)
• NIH45-46: This is a review of a satellite symposium at the AIDS Vaccine 2012 conference, focusing on antibody gene transfer. Pamela Bjorkman presented studies that have used structure-based design to improve the potency of antibodies to the CD4-binding site on gp120, as well as to overcome the common escape mutations the virus acquires to evade such antibodies. MAb 45-46m2, neutralized 96% of HIV strains in a cross-clade panel and neutralized a set of viral isolates resistant to all other known broadly neutralizing antibodies. A second variant, 45-46m7, designed to thwart resistance to the engineered antibody NIH45-46G54W, restores the neutralization of consensus escape mutants and thus effectively targets a common route of viral escape from this class of antibodies. 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)
• NIH45-46: 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, NIH45-46, against 181 diverse HIV-1 strains with available Ab-Ag complex structures. Chuang2013 (computational epitope prediction)
• NIH45-46: "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. This mAb belongs to VRC01-like cluster. Georgiev2013 (neutralization)
• NIH45-46: Systematic computational analyses of gp120 plasticity and conformational transition in complexes with CD4 binding fragments, mimetic proteins and Ab fragments is described to explain the molecular mechanisms by which gp120 interacts with the CD4bs at local and subdomain levels. An isotopic elastic network analysis, a full atomic normal mode analysis and simulation of conformational transitions were used to compare the gp120 structures in CD4 bound and Ab-bound states. NIH45-46 was mentioned in the context of CD4 binding sites. Korkut2012 (structure)
• NIH45-46: 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 epitope prediction)
• NIH45-46: 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 CD4-binding site, CD4-mimicry by heavy chain, VRC01 class, VRC01 family. Kwong2012 (review, structure, broad neutralizer)
• NIH45-46: This review discusses how analysis of infection and vaccine candidate-induced antibodies and their genes may guide vaccine design. This MAb is listed as CD4 binding site bnAb, isolated after 2009 by fluorescence-activated cell sorting (FACS) and 454 deep sequencing. Bonsignori2012b (vaccine antigen design, vaccine-induced immune responses, review)
• NIH45-46: 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. NIH45-46, a CD4Bs Ab, was among the 17 bnAbs which were used in studying the mutations in FWR. NIH 45-46 was used in comparing the Ab framework amino acid replacement vs. interactive surface area on Ab. Klein2013 (neutralization, structure, antibody lineage)
• NIH45-46: This study shows that Env immunogens fail to engage the germline-reverted forms of known bnAbs that target CD4BS. However, the elimination of a conserved NLGS at Asn276 in Loop D and the NLGS at positions 460 and 463, located in variable region 5 of Env increased the binding and activation of VRC01 and NIH45-46. This study showed that elimination of NLGS from these regions of Clade C Env 426c increases NIH45-46 binding. McGuire2013 (neutralization, antibody lineage)
• NIH45-46: Computational and crystallographic analysis and in vitro screening were employed to design a gp120 outer domain immunogen (eOD-GT6) that could bind to VRC01-class bNAbs and to their germline precursors. When multimerized on nanoparticles, eOD-GT6 activated germline and mature VRC01-class B cells and thus can be a promising vaccine prime. eOD-GT6 had 10 mutations relative to HXB2. Removal of glycans at positions 276 and 463 was necessary for GL affinity and removal of glycans at positions 386 and 403 also improved affinity. T278R, I371F, N460V are involved in the binding interface. L260F, K357R, G471S stabilize loops involved in the interface. eOD-GT6 bound both NIH45-46 mature and germline antibodies. Jardine2013 (glycosylation, vaccine antigen design, structure, antibody lineage)
• NIH45-46: Concomitant virus evolution and antibody maturation, leading to induction of a lineage of broadly neutralizing antibodies CH103-CH106, were followed in an African patient CH505 for 34 months from the time of infection. Compared to 30-36% VRC01, CH31 and NIH45-46 mutation frequencies of the published CD4 binding sites, CH103-CH106 exhibited 13-17% mutations. Liao2013 (broad neutralizer)
• NIH45-46: Existing structural and sequence data was analyzed. A set of signature features for potent VRC01-like (PVL) and almost PVL abs was proposed and verified by mutagenesis. NIH45-46 has been referred as a PVL in discussing the breadth and potency of antiCD4 abs. Sequences of VRC01, NIH45-46 and VRC-PG04 revealed a striking correlation for the length of CDRL3 (5 residues). West2012a (antibody lineage)
• NIH45-46: The use of computationally derived B cell clonal lineages as templates for HIV-1 immunogen design is discussed. NIH45046 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)
• 45-46: 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. 45-46 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, neutralization, binding affinity)
• NIH45-46: Neutralization activity was compared against MAb 10E8 and other broad and potent neutralizers in a 181-isolate Env-pseudovirus panel. 2F5 neutralized 85% of viruses at IC50<50 μg/ml and 76% of viruses at IC50<1 μg/ml, compared with 98% and 72% of MAb 10E8, respectively. Huang2012a (neutralization)
• NIH45-46: The sera of 113 HIV-1 seroconverters from three cohorts were analyzed for binding to a set of well-characterized gp120 core and resurfaced stabilized core (RSC3) protein probes, and their cognate CD4bs knockout mutants. NIH45-46 bound very strongly to the gp120 core and RSC3, weakly bound to RSC3/G367R but did not bind to gp120 core D368R, RSC3 Δ3711, and RSC3 Δ3711/P363N. Lynch2012 (binding affinity)
• NIH45-46: The crystal structure of the NIH45-46–gp120 complex verified that NIH45-46 targets the CD4bs. The primary binding surface is the outer domain, including the CD4 binding loop, loop D, and loop V5, but CDRH3_NIH45-46 reaches toward the gp120 inner domain. The most notable difference between NIH45-46 and VRC01 is the four-residue insertion in CDRH3 (residues 99a-99d), which contributes to increased interaction between NIH45-46 and the gp120 inner domain, correlated with enhanced neutralization. Structure-based design was used to create several NIH45-46 mutants with a single substitution at position 54 in CDRH2 to increase contact with the gp120 bridging sheet. NIH45-46_G54W was significantly more potent than NIH45-46_G54. On a panel of 82 viruses from all clades, including NIH45-46-sensitive, resistant and weakly neutralized strains, NIH45-46_G54W gained de novo neutralization activity against 6 NIH45-46–resistant strains, including 3 that were sensitive to VRC01 but resistant to NIH45-46, and for some strains that NIH45-46 neutralizes poorly, NIH45-46_G54W was significantly more potent. Diskin2011 (antibody binding site, neutralization, structure)
• NIH45-46: 576 new HIV antibodies were cloned from 4 unrelated individuals producing expanded clones of potent broadly neutralizing CD4bs antibodies that bind to 2CC core. In order to amplify highly somatically mutated immunoglobulin genes, new primer set with 5' primer set further upstream from the potentially mutated region was used. Despite extensive hypermutation, the new antibodies shared a consensus sequence of 68 IgH chain amino acids and arose independently from two related IgH genes. NIH45-46, a new more potent clonal variant of VRC01, arises from IgVH1-2 and IgVK3-11 germline genes and neutralized 100% of 118 isolates representing major HIV-1 clades, with IC50<50μg/ml. NIH45-46 was more potent than VRC01 on 62 of the viruses tested but still less potent than 3BNC117. NIH45-46 was polyreactive - reacted with dsDNA, LPS, ssDNA and insulin. Scheid2011 (antibody generation, neutralization, antibody sequence, antibody polyreactivity, broad neutralizer)

References

Showing 44 of 44 references.

Isolation Paper
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Balazs2013 Alejandro B. Balazs and Anthony P. West, Jr. Antibody Gene Transfer for HIV Immunoprophylaxis. Nat. Immunol., 14(1):1-5, Jan 2013. PubMed ID: 23238748. Show all entries for this paper.

Bonsignori2012b Mattia Bonsignori, S. Munir Alam, Hua-Xin Liao, Laurent Verkoczy, Georgia D. Tomaras, Barton F. Haynes, and M. Anthony Moody. HIV-1 Antibodies from Infection and Vaccination: Insights for Guiding Vaccine Design. Trends Microbiol., 20(11):532-539, Nov 2012. PubMed ID: 22981828. Show all entries for this paper.

Bruel2016 Timothée Bruel, Florence Guivel-Benhassine, Sonia Amraoui, Marine Malbec, Léa Richard, Katia Bourdic, Daniel Aaron Donahue, Valérie Lorin, Nicoletta Casartelli, Nicolas Noël, Olivier Lambotte, Hugo Mouquet, and Olivier Schwartz. Elimination of HIV-1-Infected Cells by Broadly Neutralizing Antibodies. Nat. Commun., 7:10844, 3 Mar 2016. PubMed ID: 26936020. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

Diskin2011 Ron Diskin, Johannes F. Scheid, Paola M. Marcovecchio, Anthony P. West, Jr., Florian Klein, Han Gao, Priyanthi N. P. Gnanapragasam, Alexander Abadir, Michael S. Seaman, Michel C. Nussenzweig, and Pamela J. Bjorkman. Increasing the Potency and Breadth of an HIV Antibody by Using Structure-Based Rational Design. Science, 334(6060):1289-1293, 2 Dec 2011. PubMed ID: 22033520. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

Hoot2013 Sam Hoot, Andrew T. McGuire, Kristen W. Cohen, Roland K. Strong, Lars Hangartner, Florian Klein, Ron Diskin, Johannes F. Scheid, D. Noah Sather, Dennis R. Burton, and Leonidas Stamatatos. Recombinant HIV Envelope Proteins Fail to Engage Germline Versions of Anti-CD4bs bNAbs. PLoS Pathog., 9(1):e1003106, Jan 2013. PubMed ID: 23300456. Show all entries for this paper.

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. Show all entries for this paper.

Jardine2013 Joseph Jardine, Jean-Philippe Julien, Sergey Menis, Takayuki Ota, Oleksandr Kalyuzhniy, Andrew McGuire, Devin Sok, Po-Ssu Huang, Skye MacPherson, Meaghan Jones, Travis Nieusma, John Mathison, David Baker, Andrew B. Ward, Dennis R. Burton, Leonidas Stamatatos, David Nemazee, Ian A. Wilson, and William R. Schief. Rational HIV Immunogen Design to Target Specific Germline B Cell Receptors. Science, 340(6133):711-716, 10 May 2013. PubMed ID: 23539181. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

Korkut2012 Anil Korkut and Wayne A. Hendrickson. Structural Plasticity and Conformational Transitions of HIV Envelope Glycoprotein gp120. PLoS One, 7(12):e52170, 2012. PubMed ID: 23300605. Show all entries for this paper.

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. Show all entries for this paper.

Liao2013 Hua-Xin Liao, Rebecca Lynch, Tongqing Zhou, Feng Gao, S. Munir Alam, Scott D. Boyd, Andrew Z. Fire, Krishna M. Roskin, Chaim A. Schramm, Zhenhai Zhang, Jiang Zhu, Lawrence Shapiro, NISC Comparative Sequencing Program, James C. Mullikin, S. Gnanakaran, Peter Hraber, Kevin Wiehe, Garnett Kelsoe, Guang Yang, Shi-Mao Xia, David C. Montefiori, Robert Parks, Krissey E. Lloyd, Richard M. Scearce, Kelly A. Soderberg, Myron Cohen, Gift Kamanga, Mark K. Louder, Lillian M. Tran, Yue Chen, Fangping Cai, Sheri Chen, Stephanie Moquin, Xiulian Du, M. Gordon Joyce, Sanjay Srivatsan, Baoshan Zhang, Anqi Zheng, George M. Shaw, Beatrice H. Hahn, Thomas B. Kepler, Bette T. M. Korber, Peter D. Kwong, John R. Mascola, and Barton F. Haynes. Co-Evolution of a Broadly Neutralizing HIV-1 Antibody and Founder Virus. Nature, 496(7446):469-476, 25 Apr 2013. PubMed ID: 23552890. Show all entries for this paper.

Lynch2012 Rebecca M. Lynch, Lillian Tran, Mark K. Louder, Stephen D. Schmidt, Myron Cohen, CHAVI 001 Clinical Team Members, Rebecca DerSimonian, Zelda Euler, Elin S. Gray, Salim Abdool Karim, Jennifer Kirchherr, David C. Montefiori, Sengeziwe Sibeko, Kelly Soderberg, Georgia Tomaras, Zhi-Yong Yang, Gary J. Nabel, Hanneke Schuitemaker, Lynn Morris, Barton F. Haynes, and John R. Mascola. The Development of CD4 Binding Site Antibodies during HIV-1 Infection. J. Virol., 86(14):7588-7595, Jul 2012. PubMed ID: 22573869. Show all entries for this paper.

Malbec2013 Marine Malbec, Françoise Porrot, Rejane Rua, Joshua Horwitz, Florian Klein, Ari Halper-Stromberg, Johannes F. Scheid, Caroline Eden, Hugo Mouquet, Michel C. Nussenzweig, and Olivier Schwartz. Broadly Neutralizing Antibodies That Inhibit HIV-1 Cell to Cell Transmission. J. Exp. Med., 210(13):2813-2821, 16 Dec 2013. PubMed ID: 24277152. Show all entries for this paper.

McGuire2013 Andrew T. McGuire, Sam Hoot, Anita M. Dreyer, Adriana Lippy, Andrew Stuart, Kristen W. Cohen, Joseph Jardine, Sergey Menis, Johannes F. Scheid, Anthony P. West, William R. Schief, and Leonidas Stamatatos. Engineering HIV Envelope Protein To Activate Germline B Cell Receptors of Broadly Neutralizing Anti-CD4 Binding Site Antibodies. J. Exp. Med., 210(4):655-663, 8 Apr 2013. PubMed ID: 23530120. Show all entries for this paper.

McGuire2016 Andrew T. McGuire, Matthew D. Gray, Pia Dosenovic, Alexander D. Gitlin, Natalia T. Freund, John Petersen, Colin Correnti, William Johnsen, Robert Kegel, Andrew B. Stuart, Jolene Glenn, Michael S. Seaman, William R. Schief, Roland K. Strong, Michel C. Nussenzweig, and Leonidas Stamatatos. Specifically Modified Env Immunogens Activate B-Cell Precursors of Broadly Neutralizing HIV-1 Antibodies in Transgenic Mice. Nat. Commun., 7:10618, 24 Feb 2016. PubMed ID: 26907590. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

Scharf2013 Louise Scharf, Anthony P. West, Jr., Han Gao, Terri Lee, Johannes F. Scheid, Michel C. Nussenzweig, Pamela J. Bjorkman, and Ron Diskin. Structural Basis for HIV-1 gp120 Recognition by a Germ-Line Version of a Broadly Neutralizing Antibody. Proc. Natl. Acad. Sci. U.S.A., 110(15):6049-6054, 9 Apr 2013. PubMed ID: 23524883. Show all entries for this paper.

Scharf2016 Louise Scharf, Anthony P. West, Jr., Stuart A. Sievers, Courtney Chen, Siduo Jiang, Han Gao, Matthew D. Gray, Andrew T. McGuire, Johannes F. Scheid, Michel C. Nussenzweig, Leonidas Stamatatos, and Pamela J. Bjorkman. Structural Basis for Germline Antibody Recognition of HIV-1 Immunogens. Elife, 5, 21 Mar 2016. PubMed ID: 26997349. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

West2012a Anthony P. West, Jr., Ron Diskin, Michel C. Nussenzweig, and Pamela J. Bjorkman. Structural Basis for Germ-Line Gene Usage of a Potent Class of Antibodies Targeting the CD4-Binding Site of HIV-1 gp120. Proc. Natl. Acad. Sci. U.S.A., 109(30):E2083-E2090, 24 Jul 2012. PubMed ID: 22745174. Show all entries for this paper.

West2013 Anthony P. West, Jr., Louise Scharf, Joshua Horwitz, Florian Klein, Michel C. Nussenzweig, and Pamela J. Bjorkman. Computational Analysis of Anti-HIV-1 Antibody Neutralization Panel Data to Identify Potential Functional Epitope Residues. Proc. Natl. Acad. Sci. U.S.A., 110(26):10598-10603, 25 Jun 2013. PubMed ID: 23754383. Show all entries for this paper.

Wu2015 Xueling Wu, Zhenhai Zhang, Chaim A. Schramm, M. Gordon Joyce, Young Do Kwon, Tongqing Zhou, Zizhang Sheng, Baoshan Zhang, Sijy O'Dell, Krisha McKee, Ivelin S. Georgiev, Gwo-Yu Chuang, Nancy S. Longo, Rebecca M. Lynch, Kevin O. Saunders, Cinque Soto, Sanjay Srivatsan, Yongping Yang, Robert T. Bailer, Mark K. Louder, NISC Comparative Sequencing Program, James C. Mullikin, Mark Connors, Peter D. Kwong, John R. Mascola, and Lawrence Shapiro. Maturation and Diversity of the VRC01-Antibody Lineage over 15 Years of Chronic HIV-1 Infection. Cell, 161(3):470-485, 23 Apr 2015. PubMed ID: 25865483. Show all entries for this paper.

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. Show all entries for this paper.

Zhang2013 Yu Zhang, Tingting Yuan, Jingjing Li, Yanyu Zhang, Jianqing Xu, Yiming Shao, Zhiwei Chen, and Mei-Yun Zhang. The Potential of the Human Immune System to Develop Broadly Neutralizing HIV-1 Antibodies: Implications for Vaccine Development. AIDS, 27(16):2529-2539, 23 Oct 2013. PubMed ID: 24100711. Show all entries for this paper.

Zhu2013a Jiang Zhu, Xueling Wu, Baoshan Zhang, Krisha McKee, Sijy O'Dell, Cinque Soto, Tongqing Zhou, Joseph P. Casazza, NISC Comparative Sequencing Program, James C. Mullikin, Peter D. Kwong, John R. Mascola, and Lawrence Shapiro. De Novo Identification of VRC01 Class HIV-1-Neutralizing Antibodies by Next-Generation Sequencing of B-Cell Transcripts. Proc. Natl. Acad. Sci. U.S.A., 110(43):E4088-E4097, 22 Oct 2013. PubMed ID: 24106303. Show all entries for this paper.

Gardner2016 Matthew R. Gardner, Christoph H. Fellinger, Neha R. Prasad, Amber S. Zhou, Hema R. Kondur, Vinita R. Joshi, Brian D. Quinlan, and Michael Farzan. CD4-Induced Antibodies Promote Association of the HIV-1 Envelope Glycoprotein with CD4-Binding Site Antibodies. J. Virol., 90(17):7822-7832, 1 Sep 2016. PubMed ID: 27334589. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

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. Show all entries for this paper.

Virnik2018 Konstantin Virnik, Edmund Nesti, Cody Dail, Aaron Scanlan, Alexei Medvedev, Russell Vassell, Andrew T. McGuire, Leonidas Stamatatos, and Ira Berkower. Live Rubella Vectors Can Express Native HIV Envelope Glycoproteins Targeted by Broadly Neutralizing Antibodies and Prime the Immune Response to an Envelope Protein Boost. Vaccine, 36(34):5166-5172, 16 Aug 2018. PubMed ID: 30037665. Show all entries for this paper.