Praveen K. Amancha

Spatial Alterations between CD4+ T Follicular Helper, B, and CD8+ T Cells during Simian Immunodeficiency Virus Infection: T/B Cell Homeostasis, Activation, and Potential Mechanism for Viral Escape

HIV/SIV infections induce chronic immune activation with remodeling of lymphoid architecture and hypergammaglobulinemia, although the mechanisms leading to such symptoms remain to be fully elucidated. Moreover, lymph nodes have been highlighted as a predilection site for SIV escape in vivo. Following 20 rhesus macaques infected with SIVmac239 as they progress from pre-infection to acute and chronic infection, we document for the first time, to our knowledge, the local dynamics of T follicular helper (TFH) cells and B cells in situ. Progression of SIV infection was accompanied by increased numbers of well-delineated follicles containing germinal centers (GCs) and TFH cells with a progressive increase in the density of programmed death-1 (PD-1) expression in lymph nodes. The rise in PD-1+ TFH cells was followed by a substantial accumulation of Ki67+ B cells within GCs. However, unlike in blood, major increases in the frequency of CD27+ memory B cells were observed in lymph nodes, indicating increased turnover of these cells, correlated with increases in total and SIV specific Ab levels. Of importance, compared with T cell zones, GCs seemed to exclude CD8+ T cells while harboring increasing numbers of CD4+ T cells, many of which are positive for SIVgag, providing an environment particularly beneficial for virus replication and reservoirs. Our data highlight for the first time, to our knowledge, important spatial interactions of GC cell subsets during SIV infection, the capacity of lymphoid tissues to maintain stable relative levels of circulating B cell subsets, and a potential mechanism for viral reservoirs within GCs during SIV infection.

Sustained virologic control in SIV+ macaques after antiretroviral and α4β7 antibody therapy

Antibodies sustain viral control For many infected individuals, antiretroviral therapy (ART) means that an HIV-1 diagnosis is no longer a death sentence. But the virus persists in treated individuals, and complying with the intense drug regimen to keep virus loads down can be challenging for patients. Seeking an alternative, Byrareddy et al. treated ART-suppressed monkeys with antibodies targeting α4β7 integrin. When ART was halted in the antibody-treated animals, viral loads stayed undetectable, and normal CD4 T cell counts were maintained for over 9 months—and persisted—even after stopping the antibody therapy. Science, this issue p. 197 Update: An Editorial Expression of Concern has been published here Combining short-term antiretroviral therapy with specific anti-integrin treatment sustains low viral loads in monkeys. Antiretroviral drug therapy (ART) effectively suppresses replication of both the immunodeficiency viruses, human (HIV) and simian (SIV); however, virus rebounds soon after ART is withdrawn. SIV-infected monkeys were treated with a 90-day course of ART initiated at 5 weeks post infection followed at 9 weeks post infection by infusions of a primatized monoclonal antibody against the α4β7 integrin administered every 3 weeks until week 32. These animals subsequently maintained low to undetectable viral loads and normal CD4+ T cell counts in plasma and gastrointestinal tissues for more than 9 months, even after all treatment was withdrawn. This combination therapy allows macaques to effectively control viremia and reconstitute their immune systems without a need for further therapy.

Whole-body immunoPET reveals active SIV dynamics in viremic and antiretroviral therapy–treated macaques

The detection of viral dynamics and localization in the context of controlled HIV infection remains a challenge and is limited to blood and biopsies. We developed a method to capture total-body simian immunodeficiency virus (SIV) replication using immunoPET (antibody-targeted positron emission tomography). The administration of a poly(ethylene glycol)-modified, 64Cu-labeled SIV Gp120–specific antibody led to readily detectable signals in the gastrointestinal and respiratory tract, lymphoid tissues and reproductive organs of viremic monkeys. Viral signals were reduced in aviremic antiretroviral-treated monkeys but detectable in colon, select lymph nodes, small bowel, nasal turbinates, the genital tract and lung. In elite controllers, virus was detected primarily in foci in the small bowel, select lymphoid areas and the male reproductive tract, as confirmed by quantitative reverse-transcription PCR (qRT-PCR) and immunohistochemistry. This real-time, in vivo viral imaging method has broad applications to the study of immunodeficiency virus pathogenesis, drug and vaccine development, and the potential for clinical translation.

Early Lymphoid Responses and Germinal Center Formation Correlate with Lower Viral Load Set Points and Better Prognosis of Simian Immunodeficiency Virus Infection

We have investigated the dynamics of germinal center (GC) formation in lymphoid tissues following acute SIV infection. SIV induces a marked follicular hyperplasia, associated with an aberrant accumulation of nonproliferating T follicular helper cells within GCs, but with an abundance of cells producing IL-21, demonstrating that the mechanisms involved for these two events appear independent. IL-21–stimulated T follicular helper cells are considered a critical element for GC formation, a physiological process that seems dysregulated and excessive during HIV/SIV infection, contributing to lymphoid pathogenesis. However, the data suggest that the kinetics by which such GCs are formed may be an important predictor of the host–pathogen equilibrium, as early GC hyperplasia was associated with better control of viral replication. In contrast, monkeys undergoing fast disease progression upon infection exhibited an involution of GCs without local IL-21 production in GCs. These results provide important clues regarding GC-related hyperimmune responses in the context of disease progression within various individuals during HIV/SIV infection and may open novel therapeutic avenues to limit lymphoid dysfunction, postinfection.

Immune Cell Dynamics in Rhesus Macaques Infected with a Brazilian Strain of Zika Virus.

Zika virus (ZIKV) is a mosquito-borne and sexually transmitted flavivirus that is associated with fetal CNS-damaging malformations during pregnancy in humans. This study documents the viral kinetics and immune responses in rhesus macaques infected with a clinical ZIKV Brazilian isolate. We evaluated the viral kinetics and immune responses induced after an i.v. infection with a Brazilian ZIKV clinical isolate (HS-2015-BA-01) in rhesus macaques for up to 142 d. ZIKV-specific Ab-secreting cells, germinal center reactions, and monocyte, dendritic cell, NK, and T cell frequencies were monitored. ZIKV loads were readily detected in plasma (until day 5 or 7), semen and urine (until days 7 and 14), and saliva (until day 42), but the viremia was rapidly controlled. No detectable clinical manifestations were observed. However, lymph node hyperplasia was clearly visible postviremia but was associated with low frequencies of ZIKV-specific Ab-secreting cells in lymph nodes and bone marrow, correlating with low Ab titers. CD14+/CD16− monocytes and myeloid CD11chi dendritic cells decreased in blood, whereas NK and T cell numbers were only marginally altered during the course of the study. ZIKV infection caused a significant lymphoid tissue activation but limited induction of ZIKV-specific B cells, suggesting that these parameters need to be considered for ZIKV vaccine design.

Early initiation of antiretroviral treatment postSIV infection does not resolve lymphoid tissue activation

Objective: Germinal center resident follicular helper T (TFH) cells in lymphoid follicles are a potential sanctuary for HIV/simian immunodeficiency virus (SIV) replication. But the dynamics of germinal centers upon early initiation of antiretroviral therapy (ART) and their potential role in the formation of viral sanctuaries post-SIV infection are not fully understood. Design: Sequential lymph node biopsies (n = 10) were collected from SIVmac239-infected rhesus macaques before infection, at 5 weeks postinfection/pre-ART, 6 and 12 weeks following ART initiation. These tissues and cells were analyzed for frequencies of TFH cells and assignment of germinal center scores. Results: Modest but significant increases in TFH cells and hyperplastic follicles with large germinal centers were noted during the acute phase of SIV infection (week 5/pre-ART). However, 6 weeks after ART initiation, substantial increases in germinal center TFH cells, germinal center B cells, hyperplastic follicles with large germinal centers, and abundant local IL-21 production were observed, whereas levels of SIV RNA and DNA of lymph nodes had decreased to barely detectable values along with barely detectable levels of SIV antibody-producing cells. An additional 6 weeks of ART did not appreciably decrease germinal center TFH or germinal center scores. Conclusion: Thus, although early ART rapidly controls SIV replication, it does not regulate early lymphoid activation, which may contribute to the seeding and magnitude of viral reservoirs.

Up-regulation of Tim-3 on T cells during acute simian immunodeficiency virus infection and on antigen specific responders.

Objective:Understanding the role of T-cell immunoglobulin and mucin domain-containing molecule 3 (Tim-3) on T cells and dendritic cells during the course of simian immunodeficiency virus (SIV) infection. Design:Sequentially collected PBMCs from uninfected and SIVmac239-infected rhesus macaques were evaluated for Tim-3 expression by flow cytometry and antigen-specific responses. Results:Blood innate immune cells (dendritic cells) and B cells showed high constitutive expression of Tim-3, whereas, compared to humans, only a minority of macaque T cells did. However, TIM-3 expression was transiently up-regulated on both CD4+ and CD8+ T cells during acute SIV infection, correlating with plasma viral loads, CD4+ cell counts, and Ki67 expression up to 6 weeks postinfection and returned to baseline values by 8 weeks postinfection. Upon antigen-specific stimulation, most Tim-3+ T cells produced various cytokines, suggesting that this marker is up-regulated on effector antigen-specific T cells and not associated with T-cell exhaustion. Among myeloid dendritic cells (mDCs), a clear separation was seen between blood mDCs expressing Tim-3 and those expressing PD-L2 – a ligand for inhibitory receptor programmed death 1. Conclusion:Rhesus macaques show constitutive expression of Tim-3 primarily on innate immune cells, but markedly lower levels on T cells compared to humans. Nevertheless, Tim-3 expression on T cells is transiently up-regulated during acute, but not chronic, SIV infection, and appears to be a marker of antigen-specific effector cells. The exact role and contribution of Tim-3 to the modulation of antiviral responses in vivo will require additional investigation.

In vivo characterization of macrophage-tropic simian immunodeficiency virus molecular clones in rhesus macaques

Macrophages are a major target of HIV/SIV infection and play an important role in pathogenesis by serving as viral reservoirs in the central nervous system. Previously, a unique early SIVmac251 envelope (Env) variant, deSIV147 was cloned from blood of a rhesus macaque with rapid disease progression and SIV-associated encephalitis. Here, we show that infectious molecular clone deSIV147 caused systemic infection in rhesus macaques following intravenous or intrarectal exposure. Next, we inoculated deSIV147 into macaques depleted of CD4+ T cells and found that animals were SIV-positive, with high plasma and CSF viral loads. These macaques also showed SIVp17-positive macrophages in brain, lymph nodes, colon, lung, and liver. Furthermore, accumulation of perivascular macrophages, multinucleated giant cells, and microgliosis was detected. These findings suggest that the neurotropic deSIV147 clone will be useful to study macrophage infection in HIV/SIV-associated neurocognitive disorders, gain insights into myeloid cell reservoirs in brain and other anatomical sites, as well as test strategies for eradication.