ABSTRACT
Neutralizing antibodies (NAbs) to multiple epitopes on the HIV-1-envelope glycoprotein (Env) have been isolated from infected persons. The potency of NAbs is measured more often than the size of the persistent fraction of infectivity at maximum neutralization, which may also influence preventive efficacy of active or passive immunization and the therapeutic outcome of the latter. Many NAbs neutralize HIV-1 CZA97.012, a clone of a Clade-C isolate, to ~100%. But here NAb PGT151, directed to a fusion-peptide epitope, left a persistent fraction of 15%. NAb PGT145, ligating the Env-trimer apex, left no detectable persistent fraction. The divergence in persistent fractions was further analyzed by depletion of pseudoviral populations of the most PGT151- and PGT145-reactive virions. Thereby, neutralization by the non-depleting NAb increased, whereas neutralization by the depleting NAb decreased. Furthermore, depletion by PGT151 increased sensitivity to autologous neutralization by sera from rabbits immunized with soluble native-like CZA97.012 trimer: substantial persistent fractions were reduced. NAbs in these sera target epitopes comprising residue D411 at the V4-Ć19 transition in a defect of the glycan shield on CZA97.012 Env. NAb binding to affinity-fractionated soluble native-like CZA97.012 trimer differed commensurately with neutralization in analyses by ELISA and surface plasmon resonance. Glycan differences between PGT151- and PGT145-purified trimer fractions were then demonstrated by mass spectrometry, providing one explanation for the differential antigenicity. These differences were interpreted in relation to a new structure at 3.4-Ć resolution of the soluble CZA97.012 trimer determined by cryo-electron microscopy. The trimer adopted a closed conformation, refuting apex opening as the cause of reduced PGT145 binding to the PGT151-purified form. The evidence suggests that differences in binding and neutralization after trimer purification or pseudovirus depletion with PGT145 or PGT151 are caused by variation in glycosylation, and that some glycan variants affect antigenicity through direct effects on antibody contacts, whereas others act allosterically.
Subject(s)
HIV Infections , HIV-1 , Animals , Rabbits , HIV Antibodies , Cryoelectron Microscopy , Antibodies, Neutralizing , Epitopes , Antigens, Viral , Polysaccharides/metabolism , env Gene Products, Human Immunodeficiency VirusABSTRACT
The human immunodeficiency virus type 1 (HIV-1) trimeric envelope glycoprotein (Env) is heavily glycosylated, creating a dense glycan shield that protects the underlying peptidic surface from antibody recognition. The absence of conserved glycans, due to missing potential N-linked glycosylation sites (PNGS), can result in strain-specific, autologous neutralizing antibody (NAb) responses. Here, we sought to gain a deeper understanding of the autologous neutralization by introducing holes in the otherwise dense glycan shields of the AMC011 and AMC016 SOSIP trimers. Specifically, when we knocked out the N130 and N289 glycans, which are absent from the well-characterized B41 SOSIP trimer, we observed stronger autologous NAb responses. We also analyzed the highly variable NAb responses induced in rabbits by diverse SOSIP trimers from subtypes A, B, and C. Statistical analysis, using linear regression, revealed that the cumulative area exposed on a trimer by glycan holes correlates with the magnitude of the autologous NAb response. IMPORTANCE Forty years after the first description of HIV-1, the search for a protective vaccine is still ongoing. The sole target for antibodies that can neutralize the virus are the trimeric envelope glycoproteins (Envs) located on the viral surface. The glycoprotein surface is covered with glycans that shield off the underlying protein components from recognition by the immune system. However, the Env trimers of some viral strains have holes in the glycan shield. Immunized animals developed antibodies against such glycan holes. These antibodies are generally strain specific. Here, we sought to gain a deeper understanding of what drives these specific immune responses. First, we show that strain-specific neutralizing antibody responses can be increased by creating artificial holes in the glycan shield. Second, when studying a diverse set of Env trimers with different characteristics, we found that the surface area of the glycan holes contributes prominently to the induction of strain-specific neutralizing antibodies.
Subject(s)
HIV Infections/immunology , HIV-1/immunology , Polysaccharides/metabolism , Protein Multimerization , env Gene Products, Human Immunodeficiency Virus/immunology , env Gene Products, Human Immunodeficiency Virus/metabolism , AIDS Vaccines/immunology , Amino Acids/chemistry , Amino Acids/immunology , Amino Acids/metabolism , Animals , Antibodies, Neutralizing/immunology , Antibody Formation/immunology , Antigens, Viral/immunology , Glycosylation , HIV Antibodies/immunology , HIV Infections/metabolism , HIV Infections/virology , HIV-1/genetics , Host-Pathogen Interactions , Humans , Immunization , Models, Molecular , Protein Conformation , Protein Multimerization/immunology , Rabbits , Sequence Deletion , Structure-Activity Relationship , env Gene Products, Human Immunodeficiency Virus/chemistry , env Gene Products, Human Immunodeficiency Virus/geneticsABSTRACT
Incessant antigenic evolution enables the persistence and spread of influenza virus in the human population. As the principal target of the immune response, the hemagglutinin (HA) surface antigen on influenza viruses continuously acquires and replaces N-linked glycosylation sites to shield immunogenic protein epitopes using host-derived glycans. Anti-glycan antibodies, such as 2G12, target the HIV-1 envelope protein (Env), which is even more extensively glycosylated and contains under-processed oligomannose-type clusters on its dense glycan shield. Here, we illustrate that 2G12 can also neutralize human seasonal influenza A H3N2 viruses that have evolved to present similar oligomannose-type clusters on their HAs from around 20 years after the 1968 pandemic. Using structural biology and mass spectrometric approaches, we find that two N-glycosylation sites close to the receptor binding site (RBS) on influenza hemagglutinin represent the oligomannose cluster recognized by 2G12. One of these glycan sites is highly conserved in all human H3N2 strains and the other emerged during virus evolution. These two N-glycosylation sites have also become crucial for fitness of recent H3N2 strains. These findings shed light on the evolution of the glycan shield on influenza virus and suggest 2G12-like antibodies can potentially act as broad neutralizers to target human enveloped viruses.
Subject(s)
Antibodies, Viral/immunology , HIV-1/immunology , Hemagglutinin Glycoproteins, Influenza Virus/immunology , Influenza A Virus, H3N2 Subtype/immunology , Broadly Neutralizing Antibodies , Cross Reactions , HIV Infections/immunology , Humans , Influenza, Human/immunologyABSTRACT
Lassa virus is an Old World arenavirus endemic to West Africa that causes severe hemorrhagic fever. Vaccine development has focused on the envelope glycoprotein complex (GPC) that extends from the virion envelope. The often inadequate antibody immune response elicited by both vaccine and natural infection has been, in part, attributed to the abundance of N-linked glycosylation on the GPC. Here, using a virus-like-particle system that presents Lassa virus GPC in a native-like context, we determine the composite population of each of the N-linked glycosylation sites presented on the trimeric GPC spike. Our analysis reveals the presence of underprocessed oligomannose-type glycans, which form punctuated clusters that obscure the proteinous surface of both the GP1 attachment and GP2 fusion glycoprotein subunits of the Lassa virus GPC. These oligomannose clusters are seemingly derived as a result of sterically reduced accessibility to glycan processing enzymes, and limited amino acid diversification around these sites supports their role protecting against the humoral immune response. Combined, our data provide a structure-based blueprint for understanding how glycans render the glycoprotein spikes of Lassa virus and other Old World arenaviruses immunologically resistant targets.
Subject(s)
Lassa virus/chemistry , Oligosaccharides/chemistry , Viral Envelope Proteins/chemistry , Glycosylation , Lassa virus/immunology , Oligosaccharides/immunology , Viral Envelope Proteins/immunologyABSTRACT
In HIV-1 vaccine research, native-like, soluble envelope glycoprotein SOSIP trimers are widely used for immunizing animals. The epitopes of autologous neutralizing antibodies (NAbs) induced by the BG505 and B41 SOSIP trimers in rabbits and macaques have been mapped to a few holes in the glycan shields that cover most of the protein surfaces. For BG505 trimers, the dominant autologous NAb epitope in rabbits involves residues that line a cavity caused by the absence of a glycan at residue 241. Here, we blocked this epitope in BG505 SOSIPv4.1 trimer immunogens by knocking in an N-linked glycan at residue 241. We then opened holes elsewhere on the trimer by knocking out single N-linked glycans at residues 197, 234, 276, 332, and 355 and found that NAb responses induced by the 241-glycan-bearing BG505 trimers were frequently redirected to the newly opened sites. The strongest evidence for redirection of the NAb response to neoepitopes, through the opening and closing of glycan holes, was obtained from trimer immunogen groups with the highest occupancy of the N241 site. We also attempted to knock in the N289-glycan to block the sole autologous NAb epitope on the B41 SOSIP.v4.1 trimer. Although a retrospective analysis showed that the new N289-glycan site was substantially underoccupied, we found some evidence for redirection of the NAb response to a neoepitope when this site was knocked in and the N356-glycan site knocked out. In neither study, however, was redirection associated with increased neutralization of heterologous tier 2 viruses.IMPORTANCE Engineered SOSIP trimers mimic envelope-glycoprotein spikes, which stud the surface of HIV-1 particles and mediate viral entry into cells. When used for immunizing test animals, they elicit antibodies that neutralize resistant sequence-matched HIV-1 isolates. These neutralizing antibodies recognize epitopes in holes in the glycan shield that covers the trimer. Here, we added glycans to block the most immunogenic neutralization epitopes on BG505 and B41 SOSIP trimers. In addition, we removed selected other glycans to open new holes that might expose new immunogenic epitopes. We immunized rabbits with the various glycan-modified trimers and then dissected the specificities of the antibody responses. Thus, in principle, the antibody response might be diverted from one site to a more cross-reactive one, which would help in the induction of broadly neutralizing antibodies by HIV-1 vaccines based on envelope glycoproteins.
Subject(s)
Antibodies, Neutralizing/immunology , Glycoproteins/immunology , env Gene Products, Human Immunodeficiency Virus/immunology , AIDS Vaccines/immunology , Animals , Antibody Formation , Antigens, Viral/immunology , Epitopes/immunology , Female , Glycoproteins/metabolism , HIV Antibodies/immunology , HIV Infections/virology , HIV-1/metabolism , Immunization , Polysaccharides/metabolism , Rabbits , env Gene Products, Human Immunodeficiency Virus/metabolismABSTRACT
The development of domain-exchanged antibodies offers a route to high-affinity targeting to clustered multivalent epitopes, such as those associated with viral infections and many cancers. One strategy to generate these antibodies is to introduce mutations into target antibodies to drive domain exchange using the only known naturally occurring domain-exchanged anti-HIV (anti-human immunodeficiency virus) IgG1 antibody, 2G12 , as a template. Here, we show that domain exchange can be sensitively monitored by ion-mobility mass spectrometry and gas-phase collision-induced unfolding. Using native 2G12 and a mutated form that disrupts domain exchange such that it has a canonical IgG1 architecture ( 2G12 I19R ), we show that the two forms can be readily distinguished by their unfolding profiles. Importantly, the same signature of domain exchange is observed for both intact antibody and isolated Fab fragments. The development of a mass spectrometric method to detect antibody domain exchange will enable rapid screening and selection of candidate antibodies engineered to exhibit this and other unusual quaternary antibody architectures.
Subject(s)
Immunoglobulin G/chemistry , Mass Spectrometry/methods , Antibodies, Monoclonal , Antibodies, Neutralizing , Broadly Neutralizing Antibodies , HIV Antibodies , Humans , Immunoglobulin Fab Fragments , Immunoglobulin G/genetics , Mutant Proteins , Protein Engineering , Protein Structure, Quaternary , Protein UnfoldingABSTRACT
Protection from immunodeficiency virus challenge in nonhuman primates (NHPs) by a first-generation HIV broadly neutralizing antibody (bnAb) b12 has previously been shown to benefit from interaction between the bnAb and FcĆĀ³ receptors (FcĆĀ³Rs) on immune cells. To investigate the mechanism of protection for a more potent second-generation bnAb currently in clinical trials, PGT121, we carried out a series of NHP studies. These studies included treating with PGT121 at a concentration at which only half of the animals were protected to avoid potential masking of FcĆĀ³R effector function benefits by dominant neutralization and using a new variant that more completely eliminated all rhesus FcĆĀ³R binding than earlier variants. In contrast to b12, which required FcĆĀ³R binding for optimal protection, we concluded that PGT121-mediated protection is not augmented by FcĆĀ³R interaction. Thus, for HIV-passive antibody prophylaxis, these results, together with existing literature, emphasize the importance of neutralization potency for clinical antibodies, with effector function requiring evaluation for individual antibodies.
Subject(s)
HIV Infections , HIV-1 , Simian Acquired Immunodeficiency Syndrome , Simian Immunodeficiency Virus , Animals , Antibodies, Neutralizing , Broadly Neutralizing Antibodies , HIV Antibodies , HIV Infections/prevention & control , Macaca mulattaABSTRACT
Artificial glycan holes on recombinant Env-based vaccines occur when a potential N-linked glycosylation site (PNGS) is under-occupied, but not on their viral counterparts. Native-like SOSIP trimers, including clinical candidates, contain such holes in the glycan shield that induce strain-specific neutralizing antibodies (NAbs) or non-NAbs. To eliminate glycan holes and mimic the glycosylation of native BG505 Env, we replace all 12 NxS sequons on BG505 SOSIP with NxT. All PNGS, except N133 and N160, are nearly fully occupied. Occupancy of the N133 site is increased by changing N133 to NxS, whereas occupancy of the N160 site is restored by reverting the nearby N156 sequon to NxS. Hence, PNGS in close proximity, such as in the N133-N137 and N156-N160 pairs, affect each other's occupancy. We further apply this approach to improve the occupancy of several Env strains. Increasing glycan occupancy should reduce off-target immune responses to vaccine antigens.
Subject(s)
HIV-1/metabolism , Polysaccharides/metabolism , Protein Multimerization , env Gene Products, Human Immunodeficiency Virus/chemistry , env Gene Products, Human Immunodeficiency Virus/metabolism , Animals , CHO Cells , Cricetulus , Cryoelectron Microscopy , Glycosylation , HEK293 Cells , Hexosyltransferases/metabolism , Humans , Membrane Proteins/metabolism , Models, Molecular , Polysaccharides/chemistry , Solubility , env Gene Products, Human Immunodeficiency Virus/ultrastructureABSTRACT
Severe acute respiratory syndrome (SARS) and Middle East respiratory syndrome (MERS) coronaviruses (CoVs) are zoonotic pathogens with high fatality rates and pandemic potential. Vaccine development focuses on the principal target of the neutralizing humoral immune response, the spike (S) glycoprotein. Coronavirus S proteins are extensively glycosylated, encoding around 66-87 N-linked glycosylation sites per trimeric spike. Here, we reveal a specific area of high glycan density on MERS S that results in the formation of oligomannose-type glycan clusters, which were absent on SARS and HKU1 CoVs. We provide a comparison of the global glycan density of coronavirus spikes with other viral proteins including HIV-1 envelope, Lassa virus glycoprotein complex, and influenza hemagglutinin, where glycosylation plays a known role in shielding immunogenic epitopes. Overall, our data reveal how organisation of glycosylation across class I viral fusion proteins influence not only individual glycan compositions but also the immunological pressure across the protein surface.
Subject(s)
Glycoproteins/immunology , Middle East Respiratory Syndrome Coronavirus , Polysaccharides , Spike Glycoprotein, Coronavirus/immunology , Viral Fusion Proteins/immunology , Coronavirus Infections/immunology , Coronavirus Infections/virology , Cryoelectron Microscopy , Epitopes/chemistry , Epitopes/immunology , Epitopes/metabolism , Glycoproteins/chemistry , Glycoproteins/ultrastructure , Glycosylation , HEK293 Cells , HIV-1/immunology , HIV-1/metabolism , Humans , Immune Evasion/physiology , Lassa virus/immunology , Lassa virus/metabolism , Middle East Respiratory Syndrome Coronavirus/immunology , Middle East Respiratory Syndrome Coronavirus/metabolism , Orthomyxoviridae/immunology , Orthomyxoviridae/metabolism , Polysaccharides/chemistry , Polysaccharides/immunology , Spike Glycoprotein, Coronavirus/chemistry , Spike Glycoprotein, Coronavirus/ultrastructure , Viral Fusion Proteins/chemistry , Viral Fusion Proteins/ultrastructure , Viral Proteins/chemistry , Viral Proteins/immunology , Viral Proteins/ultrastructureABSTRACT
Numerous broadly neutralizing antibodies (bnAbs) have been identified that target the glycans of the HIV-1 envelope spike. Neutralization breadth is notable given that glycan processing can be substantially influenced by the presence or absence of neighboring glycans. Here, using a stabilized recombinant envelope trimer, we investigate the degree to which mutations in the glycan network surrounding an epitope impact the fine glycan processing of antibody targets. Using cryo-electron microscopy and site-specific glycan analysis, we reveal the importance of glycans in the formation of the 2G12 bnAb epitope and show that the epitope is only subtly impacted by variations in the glycan network. In contrast, we show that the PG9 and PG16 glycan-based epitopes at the trimer apex are dependent on the presence of the highly conserved surrounding glycans. Glycan networks underpin the conservation of bnAb epitopes and are an important parameter in immunogen design.
Subject(s)
Epitopes/chemistry , HIV-1/immunology , Polysaccharides/chemistry , env Gene Products, Human Immunodeficiency Virus/chemistry , Antibodies, Monoclonal/chemistry , Antibodies, Monoclonal/immunology , Antigen-Antibody Complex/chemistry , Broadly Neutralizing Antibodies/chemistry , Broadly Neutralizing Antibodies/immunology , Epitopes/genetics , Epitopes/immunology , HEK293 Cells , HIV Antibodies/chemistry , HIV Antibodies/immunology , Humans , Molecular Docking Simulation , Mutation , Polysaccharides/immunology , env Gene Products, Human Immunodeficiency Virus/genetics , env Gene Products, Human Immunodeficiency Virus/immunologyABSTRACT
Antigenic mimicry is a fundamental tenet of structure-based vaccinology. Vaccine strategies for the human immunodeficiency virus type 1 (HIV-1) focus on the mimicry of its envelope spike (Env) due to its exposed location on the viral membrane and role in mediating infection. However, the virus has evolved to minimize the immunogenicity of conserved epitopes on the envelope spike. This principle is starkly illustrated by the presence of an extensive array of host-derived glycans, which act to shield the underlying protein from antibody recognition. Despite these hurdles, a subset of HIV-infected individuals eventually develop broadly neutralizing antibodies that recognize these virally presented glycans. Effective HIV-1 immunogens are therefore likely to involve some degree of mimicry of both the protein and glycan components of Env. As such, considerable efforts have been made to characterize the structure of the envelope spike and its glycan shield. This review summarizes the recent progress made in this field, with an emphasis on our growing understanding of the factors shaping the glycan shield of Env derived from both virus and soluble immunogens. We argue that recombinant mimics of the envelope spike are currently capable of capturing many features of the native viral glycan shield. Finally, we explore strategies through which the immunogenicity of Env glycans may be enhanced in the development of future immunogens.
Subject(s)
AIDS Vaccines/immunology , HIV Infections/immunology , HIV-1/immunology , AIDS Vaccines/therapeutic use , Antibodies, Neutralizing/immunology , Epitopes/immunology , HIV Infections/prevention & control , Humans , Models, Molecular , Molecular Mimicry , Polysaccharides/immunology , env Gene Products, Human Immunodeficiency Virus/immunologyABSTRACT
Extracted arrival time distributions of negative ion CID-derived fragments produced prior to traveling-wave ion mobility separation were evaluated for their ability to provide structural information on N-linked glycans. Fragmentation of high-mannose glycans released from several glycoproteins, including those from viral sources, provided over 50 fragments, many of which gave unique collisional cross-sections and provided additional information used to assign structural isomers. For example, cross-ring fragments arising from cleavage of the reducing terminal GlcNAc residue on Man8GlcNAc2 isomers have unique collision cross-sections enabling isomers to be differentiated in mixtures. Specific fragment collision cross-sections enabled identification of glycans, the antennae of which terminated in the antigenic α-galactose residue, and ions defining the composition of the 6-antenna of several of the glycans were also found to have different cross-sections from isomeric ions produced in the same spectra. Potential mechanisms for the formation of the various ions are discussed and the estimated collisional cross-sections are tabulated. Graphical Abstract Ć”Ā Ā.
Subject(s)
Mannose/analysis , Polysaccharides/chemistry , Animals , Carbohydrate Sequence , Glycoproteins/chemistry , Ions/analysis , Isomerism , Mass SpectrometryABSTRACT
Many broadly neutralizing antibodies (bnAbs) against HIV-1 recognize and/or penetrate the glycan shield on native, virion-associated envelope glycoprotein (Env) spikes. The same bnAbs also bind to recombinant, soluble trimeric immunogens based on the SOSIP design. While SOSIP trimers are close structural and antigenic mimics of virion Env, the extent to which their glycan structures resemble ones on infectious viruses is undefined. Here, we compare the overall glycosylation of gp120 and gp41 subunits from BG505 (clade A) virions produced in a lymphoid cell line with those from recombinant BG505 SOSIP trimers, including CHO-derived clinical grade material. We also performed detailed site-specific analyses of gp120. Glycans relevant to key bnAb epitopes are generally similar on the recombinant SOSIP and virion-derived Env proteins, although the latter do contain hotspots of elevated glycan processing. Knowledge of native versus recombinant Env glycosylation will guide vaccine design and manufacturing programs.
Subject(s)
HIV-1/immunology , Virion/metabolism , Glycosylation , HumansABSTRACT
The HIV-1 envelope glycoprotein trimer is covered by an array of N-linked glycans that shield it from immune surveillance. The high density of glycans on the trimer surface imposes steric constraints limiting the actions of glycan-processing enzymes, so that multiple under-processed structures remain on specific areas. These oligomannose glycans are recognized by broadly neutralizing antibodies (bNAbs) that are not thwarted by the glycan shield but, paradoxically, target it. Our site-specific glycosylation analysis of a soluble, recombinant trimer (BG505 SOSIP.664) maps the extremes of simplicity and diversity of glycan processing at individual sites and reveals 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, we identify 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.
Subject(s)
HIV Envelope Protein gp120/metabolism , HIV-1/metabolism , Polysaccharides/metabolism , Antibodies, Neutralizing/immunology , Chromatography, Affinity , Chromatography, High Pressure Liquid , Glycopeptides/analysis , Glycosylation , HEK293 Cells , HIV Envelope Protein gp120/genetics , Humans , Polysaccharides/analysis , Polysaccharides/immunology , Recombinant Proteins/biosynthesis , Recombinant Proteins/chemistry , Recombinant Proteins/isolation & purification , Spectrometry, Mass, Matrix-Assisted Laser Desorption-IonizationABSTRACT
Effective use of adenovirus-5 (Ad5) in cancer therapy is heavily dependent on the degree to which the virus's natural tropism can be subverted to one that favours tumour cells. This is normally achieved through either engineering of the viral fiber knob or the use of bispecific adaptors that display both adenovirus and tumour antigen receptors. One of the main limitations of these strategies is the need to tailor each engineering event to any given tumour antigen. Here, we explore bispecific adaptors that can utilise established anti-cancer therapeutic antibodies. Conjugates containing bacterially derived antibody binding motifs are efficient at retargeting virus to antibody targets. Here, we develop a humanized strategy whereby we synthesise a re-targeting adaptor based on a chimeric Ad5 ligand/antibody receptor construct. This adaptor acts as a molecular bridge analogous to therapeutic antibody mediated cross-linking of cytotoxic effector and tumour cells during immunotherapy. As a proof or principle, we demonstrate how this adaptor allows efficient viral recognition and entry into carcinoma cells through the therapeutic monoclonal antibodies Herceptin/trastuzumab and bavituximab. We show that targeting can be augmented by use of contemporary antibody enhancement strategies such as the selective elimination of competing serum IgG using "receptor refocusing" enzymes and we envisage that further improvements are achievable by enhancing the affinities between the adaptor and its ligands. Humanized bispecific adaptors offer the promise of a versatile retargeting technology that can exploit both clinically approved adenovirus and therapeutic antibodies.
Subject(s)
Adenoviridae/genetics , Antibodies, Bispecific/immunology , Antibodies, Monoclonal/immunology , Antigens, Neoplasm/immunology , Antigens, Viral/immunology , Receptors, IgG/immunology , Trastuzumab/immunology , Adenoviridae/immunology , Amino Acid Sequence , Antibodies, Bispecific/chemistry , Antibodies, Bispecific/genetics , Antibodies, Monoclonal/chemistry , Antigens, Neoplasm/chemistry , Antigens, Neoplasm/genetics , Antigens, Viral/chemistry , Antigens, Viral/genetics , Antineoplastic Agents/chemistry , Antineoplastic Agents/immunology , Bacterial Proteins/chemistry , Bacterial Proteins/metabolism , Breast Neoplasms/genetics , Breast Neoplasms/immunology , Breast Neoplasms/pathology , Breast Neoplasms/therapy , Cell Line, Tumor , Coxsackie and Adenovirus Receptor-Like Membrane Protein/genetics , Coxsackie and Adenovirus Receptor-Like Membrane Protein/immunology , Female , Genetic Vectors , Glycoside Hydrolases/chemistry , Glycoside Hydrolases/metabolism , HEK293 Cells , Humans , Immunoconjugates/chemistry , Immunoconjugates/genetics , Immunotherapy/methods , Molecular Sequence Data , Protein Binding , Protein Engineering , Receptor, ErbB-2/genetics , Receptor, ErbB-2/immunology , Receptors, IgG/chemistry , Receptors, IgG/genetics , Recombinant Fusion Proteins/chemistry , Recombinant Fusion Proteins/genetics , Recombinant Fusion Proteins/immunology , Trastuzumab/chemistryABSTRACT
A highly glycosylated, trimeric envelope glycoprotein (Env) mediates HIV-1 cell entry. The high density and heterogeneity of the glycans shield Env from recognition by the immune system, but paradoxically, many potent broadly neutralizing antibodies (bNAbs) recognize epitopes involving this glycan shield. To better understand Env glycosylation and its role in bNAb recognition, we characterized a soluble, cleaved recombinant trimer (BG505 SOSIP.664) that is a close structural and antigenic mimic of native Env. Large, unprocessed oligomannose-type structures (Man8-9GlcNAc2) are notably prevalent on the gp120 components of the trimer, irrespective of the mammalian cell expression system or the bNAb used for affinity purification. In contrast, gp41 subunits carry more highly processed glycans. The glycans on uncleaved, non-native oligomeric gp140 proteins are also highly processed. A homogeneous, oligomannose-dominated glycan profile is therefore a hallmark of a native Env conformation and a potential Achilles' heel that can be exploited for bNAb recognition and vaccine design.
Subject(s)
HIV Envelope Protein gp120/metabolism , HIV Envelope Protein gp41/metabolism , HIV-1/metabolism , Animals , Antibodies, Neutralizing/immunology , CHO Cells , Cricetulus , Glycosylation , HEK293 Cells , HIV Envelope Protein gp120/chemistry , HIV Envelope Protein gp120/immunology , HIV Envelope Protein gp41/chemistry , HIV Envelope Protein gp41/immunology , HIV-1/immunology , Humans , Models, Molecular , Polysaccharides/metabolism , Protein Structure, Quaternary , Structure-Activity RelationshipABSTRACT
The envelope spike of HIV-1 employs a 'glycan shield' to protect itself from antibody-mediated neutralization. Paradoxically, however, potent broadly neutralizing antibodies (bnAbs) that target this shield have been isolated. The unusually high glycan density on the gp120 subunit limits processing during biosynthesis, leaving a region of under-processed oligomannose-type structures, which is a primary target of these bnAbs. Here we investigate the contribution of individual glycosylation sites in the formation of this so-called intrinsic mannose patch. Deletion of individual sites has a limited effect on the overall size of the intrinsic mannose patch but leads to changes in the processing of neighbouring glycans. These structural changes are largely tolerated by a panel of glycan-dependent bnAbs targeting these regions, indicating a degree of plasticity in their recognition. These results support the intrinsic mannose patch as a stable target for vaccine design.