HIV-specific Abs Research Articles

Update on Fc-Mediated Antibody Functions Against HIV-1 Beyond Neutralization.

Antibodies (Abs) are the major component of the humoral immune response and a key player in vaccination. The precise Ab-mediated inhibitory mechanisms leading to in vivo protection against HIV have not been elucidated. In addition to the desired viral capture and neutralizing Ab functions, complex Ab-dependent mechanisms that involve engaging immune effector cells to clear infected host cells, immune complexes, and opsonized virus have been proposed as being relevant. These inhibitory mechanisms involve Fc-mediated effector functions leading to Ab-dependent cellular cytotoxicity, phagocytosis, cell-mediated virus inhibition, aggregation, and complement inhibition. Indeed, the decreased risk of infection observed in the RV144 HIV-1 vaccine trial was correlated with the production of non-neutralizing inhibitory Abs, highlighting the role of Ab inhibitory functions besides neutralization. Moreover, Ab isotypes and subclasses recognizing specific HIV envelope epitopes as well as pecular Fc-receptor polymorphisms have been associated with disease progression. These findings further support the need to define which Fc-mediated Ab inhibitory functions leading to protection are critical for HIV vaccine design. Herein, based on our previous review Su & Moog Front Immunol 2014, we update the different inhibitory properties of HIV-specific Abs that may potentially contribute to HIV protection.

A replicating Adenovirus-SIV recombinant prime/protein boost regimen induces SIVspecific T and B cell responses in lymph nodes associated with humoral immunity in the genital mucosa of female Rhesus macaques

Abstract The efficacy of HIV vaccines relies on potent antibody (Ab) responses at major transmission sites such as the female genital tract (FGT). CD4+ T follicular helper (TFH) cells, specialized in providing B cell help in germinal centers (GCs) of secondary lymphoid organs, play an important role in initial stages of HIV-specific Ab responses. Here we investigated SIV-specific T and B cell responses and FGT immunity in Rhesus macaques following mucosal priming with Ad5hr-SIV(Env/gag/nef) vectors at wks 0 & 13 and intramuscular boosting with SIV gp120 in alum at wks 26 & 38. Lymph nodes (LNs) were collected pre-vaccination and 3–4 days post-2nd prime and post-2nd boost. Vaginal washes were obtained prior to and 3 wks post-immunizations. GC TFH and B cell frequencies positively correlated post-2nd prime (p=0.04; r=0.6) suggesting an effect of early TFH cells in GCs. GC SIV-specific TFH cells were significantly enhanced post-2nd boost (p=0.01). BCL6 upregulation was also seen in GC-TFH cells at this time, confirming the GC phenotype of TFH cells. GC SIV-specific memory B cell levels were higher post-2nd boost compared to post-prime (p=0.03) indicating efficient SIV-specific B cell generation. GC B cells post-2nd prime and boost strongly associated with SIV-specific IgG levels in vaginal washes (p=0.03, r=0.7; p=0.002, r=0.8). GC centrocytes are critical for long-lasting Ab secreting cells. GC centrocytes post 2nd prime and boost tended to correlate with vaginal wash SIV-specific IgG levels (p=0.06, p=0.05; r=0.6 for both). Overall, our vaccine regimen elicited GC T and B cell responses that supported SIV-specific humoral immunity in the FGT suggesting further development of replicating mucosal Ad-vaccines is warranted for females as well as males.

Phagocytosis of a Model Human Immunodeficiency Virus Target by Human Breast Milk Leukocytes Is Predominantly Granulocyte-Driven When Elicited by Specific Antibody.

Studies demonstrate a protective effect of antibodies (Abs) in breast milk (BM) against mother-to-child transmission (MTCT) of human immunodeficiency virus (HIV). Contribution of the BM cellular component has been overlooked. The only clinical HIV vaccine trial to demonstrate efficacy, RV144, correlated protection with Abs mediating functions through the constant immunoglobulin region-the crystallizable fragment (Fc). These data support induction of vaccine Abs triggering antiviral activities by leukocytes through Fc receptors (FcRs). To measure Ab-dependent cellular phagocytosis (ADCP), an essential Fc-mediated response, by BM phagocytes. Cells were isolated from five human BM samples obtained at 7-183 days postpartum and analyzed for ADCP. Fluorescent beads coated with HIV envelope (Env) epitopes were used as targets. Sixty-seven to 100 mL of milk was utilized. Total cell concentrations per milliliter were 16,083-222,857, with 1.6-12.3% being CD45+ leukocytes. ADCP activity was measurable using the HIV-specific Ab 830A. Use of the actin inhibitor cytochalasin D and FcR blocker indicated that ADCP was actin dependent and required FcR engagement. ADCP scores were variable, but largely consistent, across the samples studied, exhibiting <4-fold difference from lowest to highest activity for CD45+ cells. Of the CD45+ ADCP, significantly more activity was granulocyte derived (72-95%), while the remaining activity was monocyte driven. The data indicate that BM phagocytes can manifest antiviral activities in the presence of specific Abs and therefore may contribute to reduction of MTCT of HIV.

Primary Human Neutrophils Exhibit a Unique HIV-Directed Antibody-Dependent Phagocytosis Profile

The only clinical HIV vaccine trial to demonstrate efficacy, RV144, correlated protection with the antibodies (Abs) mediating function via the “constant” immunoglobulin region, the crystallizable fragment (Fc). These data have supported a focus on the induction of Abs by vaccines that trigger antiviral activities by relevant leukocytes via Fc receptors (FcRs). Neutrophils are phagocytes that comprise > 50% of leukocytes and display unique FcRs. We sought to compare the Ab-dependent cellular phagocytosis (ADCP) activity of human neutrophils to the commonly assayed THP-1 cell line. HIV-specific Abs were employed to elicit ADCP of beads coated with HIV envelope protein. Overall, trends were noted among neutrophil donors and the ADCP profile was different from that of THP-1 cells. mAb ELISA titers correlated with ADCP by THP-1 cells but not neutrophils. Monoclonal (m)Abs were also tested with primary monocytes. Donor-to-donor variation was high, and hindered the analysis of this dataset, but it was, in itself, an important finding. This study illustrates the concept that the assessment of FcR-mediated Ab activity with a frequently used cell line such as THP-1 is not necessarily indicative of relevant Ab functionality in vivo, and this calls for in-depth study of the properties of the HIV antibodies best-suited to eliciting antiviral activities by primary cells.

HIV-antibody complexes enhance production of type I interferon by plasmacytoid dendritic cells.

Type I IFN production is essential for innate control of acute viral infection; however, prolonged high-level IFN production is associated with chronic immune activation in HIV-infected individuals. Although plasmacytoid DCs (pDCs) are a primary source of IFN, the mechanisms that regulate IFN levels following the acute phase are unknown. We hypothesized that HIV-specific Ab responses regulate late IFN production. We evaluated the mechanism through which HIV-activated pDCs produce IFN as well as how both monoclonal HIV-specific Abs and Abs produced in natural HIV infection modulated normal pDC sensing of HIV. We found that HIV-induced IFN production required TLR7 signaling, receptor-mediated entry, fusion, and viral uncoating, but not endocytosis or HIV life cycle stages after uncoating. Abs directed against the HIV envelope that do not interfere with CD4 binding markedly enhanced the IFN response, irrespective of their ability to neutralize CD4+ T cell infection. Ab-mediated enhancement of IFN production required Fc γ receptor engagement, bypassed fusion, and initiated signaling through both TLR7 and TLR9, which was not utilized in the absence of Ab. Polyclonal Abs isolated from HIV-infected subjects also enhanced pDC production of IFN in response to HIV. Our data provide an explanation for high levels of IFN production and immune activation in chronic HIV infection.

Antibody Functional Assays as Measures of Fc Receptor-Mediated Immunity to HIV - New Technologies and their Impact on the HIV Vaccine Field.

Background:There is now intense interest in the role of HIV-specific antibodies and the engagement of FcγR functions in the control and prevention of HIV infection. The analyses of the RV144 vaccine trial, natural progression cohorts, and macaque models all point to a role for Fc-dependent effector functions, such as cytotoxicity (ADCC) or phagocytosis (ADCP), in the control of HIV. However, reliable assays that can be reproducibly used across different laboratories to measure Fc-dependent functions, such as antibody dependent cellular cytotoxicity (ADCC) are limited.Method:This brief review highlights the importance of Fc properties for immunity to HIV, particular-ly via FcγR diversity and function. We discuss assays used to study FcR mediated functions of HIV-specific Ab, including our recently developed novel cell-free ELISA using homo-dimeric FcγR ecto-domains to detect functionally relevant viral antigen-specific antibodies.Results:The binding of these dimeric FcγR ectodomains, to closely spaced pairs of IgG Fc, mimics the engagement and cross-linking of Fc receptors by IgG opsonized virions or infected cells as the es-sential prerequisite to the induction of Ab-dependent effector functions. The dimeric FcγR ELISA reli-ably correlates with ADCC in patient responses to influenza. The assay is amenable to high throughput and could be standardized across laboratories.Conclusion:We propose the assay has broader implications for the evaluation of the quality of anti-body responses in viral infections and for the rapid evaluation of responses in vaccine development campaigns for HIV and other viral infections.

Enhanced FCGR2A and FCGR3A signaling by HIV viremic controller IgG

HIV-1 viremic controllers (VC) spontaneously control infection without antiretroviral treatment. Several studies indicate that IgG Abs from VCs induce enhanced responses from immune effector cells. Since signaling through Fc-γ receptors (FCGRs) modulate these Ab-driven responses, here we examine if enhanced FCGR activation is a common feature of IgG from VCs. Using an infected cell-based system, we observed that VC IgG stimulated greater FCGR2A and FCGR3A activation as compared with noncontrollers, independent of the magnitude of HIV-specific Ab binding or virus neutralization activities. Multivariate regression analysis showed that enhanced FCGR signaling was a significant predictor of VC status as compared with chronically infected patients (CIP) on highly active antiretroviral therapy (HAART). Unsupervised hierarchical clustering of patient IgG functions primarily grouped VC IgG profiles by enhanced FCGR2A, FCGR3A, or dual signaling activity. Our findings demonstrate that enhanced FCGR signaling is a common and significant predictive feature of VC IgG, with VCs displaying a distinct spectrum of FCGR activation profiles. Thus, profiling FCGR activation may provide a useful method for screening and distinguishing protective anti-HIV IgG responses in HIV-infected patients and in monitoring HIV vaccination regimens.

Toward a cure for HIV--Seeking effective therapeutic vaccine strategies.

This review article focuses on the rationale and evaluation of therapeutic vaccines against HIV. This strategy has been developed in order to restore or restimulate HIV-specific immunity in patients treated with antiretroviral therapies. Despite the lack of good candidate vaccines against HIV, two objectives have been targeted during the past 15 years. Therapeutic immunization was first proposed to help control virus relapses during treatment interruptions. More recently, the concept of therapeutic immunization has been boosted by efforts to reach HIV remission or cure, in combination to HIV reactivating agents, to help purge HIV reservoirs in a "shock and kill" strategy. This review analyses the rationales for these strategies and the results of the most widely therapeutic vaccines designed to generate T-cell immunity, i.e. recombinant viral vectors and dendritic cell-based strategies, while extremely few strategies targeted HIV-specific Abs. Only marginal control of HIV was obtained with cellular-based strategies, suggesting that approaches targeting or using broadly neutralizing Abs, should be of benefit for future efforts of therapeutic immunization against HIV in the quest toward a cure for HIV.

Which Antibody Functions are Important for an HIV Vaccine?

HIV antibody (Ab) functions capable of preventing mucosal cell-free or cell-to-cell HIV transmission are critical for the development of effective prophylactic and therapeutic vaccines. In addition to CD4+ T cells, other potential HIV-target cell types including antigen-presenting cells (APCs) (dendritic cells, macrophages) residing at mucosal sites are infected. Moreover, the interactions between APCs and HIV lead to HIV cell-to-cell transmission. Recently discovered broadly neutralizing antibodies (NAbs) are able to neutralize a broad spectrum of HIV strains, inhibit cell-to-cell transfer, and efficiently protect from infection in the experimentally challenged macaque model. However, the 31% protection observed in the RV144 vaccine trial in the absence of detectable NAbs in blood samples pointed to the possible role of additional Ab inhibitory functions. Increasing evidence suggests that IgG Fcγ receptor (FcγR)-mediated inhibition of Abs present at the mucosal site may play a role in protection against HIV mucosal transmission. Moreover, mucosal IgA Abs may be determinant in protection against HIV sexual transmission. Therefore, defining Ab inhibitory functions that could lead to protection is critical for further HIV vaccine design. Here, we review different inhibitory properties of HIV-specific Abs and discuss their potential role in protection against HIV sexual transmission.

Transient Antibody-Mucin Interactions Produce a Dynamic Molecular Shield against Viral Invasion

Given the difficulty in finding a cure for HIV/AIDS, a promising prevention strategy to reduce HIV transmission is to directly block infection at the portal of entry. The recent Thai RV144 trial offered the first evidence that an antibody-based vaccine may block heterosexual HIV transmission. Unfortunately, the underlying mechanism(s) for protection remain unclear. Here we theoretically examine a hypothesis that builds on our recent laboratory observation: virus-specific antibodies (Ab) can trap individual virions in cervicovaginal mucus (CVM), thereby reducing infection in vivo. Ab are known to have a weak—previously considered inconsequential—binding affinity with the mucin fibers that constitute CVM. However, multiple Ab can bind to the same virion at the same time, which markedly increases the overall Ab-mucin binding avidity, and creates an inheritable virion-mucin affinity. Our model takes into account biologically relevant length and timescales, while incorporating known HIV-Ab affinity and the respective diffusivities of viruses and Ab in semen and CVM. The model predicts that HIV-specific Ab in CVM leads to rapid formation and persistence of an HIV concentration front near the semen/CVM interface, far from the vaginal epithelium. Such an HIV concentration front minimizes the flux of HIV virions reaching target cells, and maximizes their elimination upon drainage of genital secretions. The robustness of the result implies that even exceedingly weak Ab-mucin affinity can markedly reduce the flux of virions reaching target cells. Beyond this specific application, the model developed here is adaptable to other pathogens, mucosal barriers, and geometries, as well as kinetic and diffusional effects, providing a tool for hypothesis testing and producing quantitative insights into the dynamics of immune-mediated protection.

Neutralizing antibodies inhibit HIV-1 transfer from primary dendritic cells to autologous CD4 T lymphocytes

AbstractDendritic cells (DCs) support only low levels of HIV-1 replication, but have been shown to transfer infectious viral particles highly efficiently to neighboring permissive CD4 T lymphocytes. This mode of cell-to-cell HIV-1 spread may be a predominant mode of infection and dissemination. In the present study, we analyzed the kinetics of fusion, replication, and the ability of HIV-1–specific Abs to inhibit HIV-1 transfer from immature DCs to autologous CD4 T lymphocytes. We found that neutralizing mAbs prevented HIV-1 transfer to CD4 T lymphocytes in trans and in cis, whereas nonneutralizing Abs did not. Neutralizing Abs also significantly decreased HIV-1 replication in DCs, even when added 2 hours after HIV-1 infection. Interestingly, a similar inhibition of HIV-1 replication in DCs was detected with some nonneutralizing Abs and was correlated with DC maturation. We suggest that the binding of HIV-1-specific Abs to FcγRs leads to HIV-1 inhibition in DCs by triggering DC maturation. This efficient inhibition of HIV-1 transfer by Abs highlights the importance of inducing HIV-specific Abs by vaccination directly at the mucosal portal of HIV-1 entry to prevent early dissemination after sexual transmission.

Selection of human anti-HIV broadly neutralizing antibodies occurs within the context of frozen 1F7-idiotypic repertoire

Most HIV-infected individuals develop HIV-specific antibodies (Abs) exhibiting a common idiotype designated as 1F7. Expression of this idiotype establishes idiotypic-driven repertoire freeze, maintaining antibody responses ineffective at controlling autologous contemporaneous viruses. As such, this study investigated the temporal dynamics of 1F7-idiotype expression, as well as the role of this idiotype in the selection of HIV-specific broadly neutralizing antibodies (BnAbs). This study investigated the timing of appearance and persistence of 1F7-idiotypic HIV-specific Abs by screening plasma samples from individuals followed longitudinally starting in primary HIV infection. The expression of 1F7 on HIV-specific BnAbs was also investigated to determine whether their development occurs within the context of 1F7-idiotypic repertoire freeze. The 1F7 idiotype was detected on gp120, gp41 and membrane proximal external region (MPER) peptide-specific Abs using an enzyme-linked immunosorbent assay (ELISA). HIV-specific Abs in longitudinal plasma samples from six patients and six BnAbs were tested for the presence of the 1F7 idiotype. The idiotype was expressed on HIV-specific Abs within 3 months of infection, with the magnitude of 1F7 detection increasing with time from infection. The 1F7 idiotype was also expressed on all BnAbs tested. These results demonstrate that HIV-specific antibody responses are restricted within the 1F7 idiotype from early infection onwards, and that six well characterized BnAbs developed within the context of 1F7-idiotypic repertoire freeze. Future research should evaluate the necessity of the 1F7 idiotype for broad neutralization, and determine if vaccines should target Abs within or outside this idiotypic space.

Rapid Degranulation of NK Cells following Activation by HIV-Specific Antibodies

Ab-dependent cellular cytotoxicity (ADCC) Abs stimulate NK cell effector functions and play a role in protecting from and controlling viral infections. We characterized ADCC Abs in a cross-sectional cohort of 80 HIV-infected subjects not on antiretroviral therapy. We analyzed ADCC response by killing fluorescently labeled target cells, as well as expression of IFN-gamma and the degranulation marker CD107a from activated NK cells as measured by a novel intracellular cytokine assay. HIV-specific ADCC directed toward Envelope proteins were present in the majority of 80 untreated HIV-infected individuals measured by killing function. Similarly, most subjects had HIV-specific Abs that mediated degranulation or cytokine expression by NK cells. Interestingly, there was a poor correlation between ADCC-mediated killing of fluorescently labeled whole Envelope protein-pulsed cell lines and Ab-mediated expression of IFN-gamma by NK cells. However, in contrast to healthy donor NK cells, autologous patient NK cells more effectively degranulated granzyme B in response to ADCC activation. Activation of NK cells in response to stimulation by HIV-specific Abs occurs at least as rapidly as activation of Gag-specific CTLs. Our studies highlight the complexity of ab-mediated NK cell activation in HIV infection, and suggest new avenues toward studying the utility of ADCC in controlling HIV infection.

Role for CD21 in the Establishment of an Extracellular HIV Reservoir in Lymphoid Tissues

Follicular dendritic cells (FDC) represent a major extracellular reservoir for HIV. A better understanding of the mechanisms of virion attachment to FDC may offer new avenues for reducing viral burdens in infected individuals. We used a murine model to investigate the establishment of extracellular HIV reservoirs in lymph nodes (LN). Consistent with findings in human tissues, CD21 was required for trapping of HIV to LN cells, as evidenced by significantly reduced virion binding when mice were pretreated with a C3 ligand-blocking anti-CD21 mAb and absence of virion trapping in CD21 knockout mice. Also consistent with findings in human tissues, the majority of HIV virions were associated with the FDC-enriched fraction of LN cell preparations. Somewhat surprisingly, HIV-specific Abs were not essential for HIV binding to LN cells, indicating that seeding of the FDC reservoir may begin shortly after infection and before the development of HIV-specific Abs. Finally, the virion-displacing potential for anti-CD21 mAbs was investigated. Treatment of mice with anti-CD21 mAbs several days after injection of HIV significantly reduced HIV bound to LN cells. Our findings demonstrate a critical role for CD21 in HIV trapping by LN cells and suggest a new therapeutic avenue for reducing HIV reservoirs.

Selection of HIV-Specific Immunogenic Epitopes by Screening Random Peptide Libraries with HIV-1-Positive Sera

Efforts to develop a protective HIV-1 vaccine have been hindered by difficulties in identifying epitopes capable of inducing broad neutralizing Ab responses. In fact, the high mutation rate occurring in HIV-1 envelope proteins and the complex structure of gp120 as an oligomer associated with gp41 result in a high degree of antigenic polymorphism. To overcome these obstacles, we screened random peptide libraries using sera from HIV-infected subjects to identify antigenic and immunogenic mimics of HIV-1 epitopes. After extensive counterscreening with HIV-negative sera, we isolated peptides specifically recognized by Abs from HIV-1-infected individuals. These peptides behaved as antigenic mimics of linear or conformational HIV-1 epitopes generated in vivo in infected subjects. Consistent with these findings, sera of simian HIV-infected monkeys also recognized the HIV-specific epitopes. The selected peptides were immunogenic in mice, where they elicited HIV-specific Abs that effectively neutralized HIV-1 isolates. These results demonstrate that pools of HIV-1 mimotopes can be selected from combinatorial peptide libraries by taking advantage of the HIV-specific Ab repertoire induced by the natural infection.