Inverse Correlation of Telomerase Activity/Proliferation of CD4+ T Lymphocytes and Disease Progression in Simian Immunodeficiency Virus–Infected Nonhuman Primates:

Divergent Annexin A1 expression in periphery and gut is associated with systemic immune activation and impaired gut immune response during SIV infection

HIV-1 disease progression is paradoxically characterized by systemic chronic immune activation and gut mucosal immune dysfunction, which is not fully defined. Annexin A1 (ANXA1), an inflammation modulator, is a potential link between systemic inflammation and gut immune dysfunction during the simian immunodeficiency virus (SIV) infection. Gene expression of ANXA1 and cytokines were assessed in therapy-naïve rhesus macaques during early and chronic stages of SIV infection and compared with SIV-negative controls. ANXA1 expression was suppressed in the gut but systemically increased during early infection. Conversely, ANXA1 expression increased in both compartments during chronic infection. ANXA1 expression in peripheral blood was positively correlated with HLA-DR+CD4+ and CD8+ T-cell frequencies, and negatively associated with the expression of pro-inflammatory cytokines and CCR5. In contrast, the gut mucosa presented an anergic cytokine profile in relation to ANXA1 expression. In vitro stimulations with ANXA1 peptide resulted in decreased inflammatory response in PBMC but increased activation of gut lymphocytes. Our findings suggest that ANXA1 signaling is dysfunctional in SIV infection, and may contribute to chronic inflammation in periphery and with immune dysfunction in the gut mucosa. Thus, ANXA1 signaling may be a novel therapeutic target for the resolution of immune dysfunction in HIV infection.

Pathogenic and apathogenic courses of SIV infection are associated with distinct and characteristic regulatory patterns of G1/S and G2/M cell cycle checkpoints in CD4+ T cells

Dysregulation of both the cell cycle within the CD4(+) T cells and T cell responses is characteristic for pathogenic HIV infection in humans and experimental SIV infection in rhesus macaques. However, SIV infection in sooty mangabeys does not lead to either an AIDS-like disease or such CD4(+) T cell dysregulation. A previous study has highlighted a potential role for cell cycle regulatory proteins in these distinct clinical outcomes. This study was performed to characterize the effect of SIV infection on the expression of cell cycle-related molecules in CD4(+) T cells of rhesus macaques and sooty mangabeys in attempts to define activation-induced gene expression patterns associated with disease resistance or susceptibility. First, T cell receptor (TCR)-mediated cell activation induced gene expression profiles that were unique to CD4(+) T cells from SIV-naive sooty mangabeys and rhesus macaques. More importantly, distinct and reproducible gene expression patterns were detected in CD4(+) T cells as a result of in vivo SIV infection in animals from each of the two species. In addition, SIV infection in both species showed significant differential effects on TCR activation-induced expression with a reproducible alteration of 10 genes highlighted by discordant effects on expression of Cyclin D3, Cyclin B, and RAD17. Therefore SIV infection in rhesus macaques and sooty mangabeys exhibits distinct and reproducible effects on cell cycle regulation in CD4(+) T cells during T cell activation that may be the basis for disease susceptibility vs. resistance in these two species, respectively.

Autoimmunity, anergy, lentiviral immunity and disease

Autoimmune antibodies and autoimmune responses have been characterized in both human HIV infection and the rhesus macaque (RM) non-human primate model of SIV infection and reasoned to contribute to the pathogenesis of AIDS. Many theories for the induction and maintenance of such responses have been entertained including molecular mimicry between HIV proteins and self molecules, CD4+ T cell loss accompanied by loss of normal immune regulation that dictate self-non-self-reactivity, defective negative/positive selection of T cells to name a few. The precise mechanisms that lead to such immune dysfunction is difficult to study in humans. Our lab has been studying such autoimmune responses in both SIV-infected RM and sooty mangabeys (SM), a species from Africa that are naturally infected with SIV but do not display any detectable signs of immune deficiency or autoimmunity. We submit that this model is an important model since it allows for narrowing down those mechanisms and pathways that are a result of lentiviral infection per se from those that specifically cause disease including autoimmunity. During the course of these studies, we have ruled out a role for plasma and cellular viral loads, anti-viral humoral responses and a variety of cell signaling pathways. We have identified select pathways that appear to play roles in the pathogenesis of lentiviral infection and disease. These include pathways involved in innocent bystander killing by apoptosis of CD4+ T cells, role for differential regulation of the cell cycle, and a role for distinct host proteins that get incorporated by the virions as they are assembled and either bud out of CD4+ T cells or exit the cells in the form of multi-vesicular endosomal particles from monocytes/macrophages from SIV-infected disease susceptible RM and disease-resistant SM. We present our current working model and hypotheses that are designed to elucidate differences that are responsible for such distinct outcomes of lentiviral infection, autoimmunity and disease. We believe that such findings have important implications for the design of vaccines against human HIV infection.

Co-immunization of rhesus macaques with plasmid vectors expressing IFN-gamma, GM-CSF, and SIV antigens enhances anti-viral humoral immunity but does not affect viremia after challenge with highly pathogenic virus

To investigate the adjuvant capacity of granulocyte-macrophage colony-stimulating factor (GM-CSF) and interferon (IFN-gamma), we cloned these rhesus cytokines into a mammalian expression vector. Two groups of six rhesus macaques (Macaca mulatta) received intradermal immunizations of plasmid DNA coding for SIV Eng and Gag, and influenza virus nucleoprotein (Flu-NP), with or without the co-administration of plasmid DNA coding for these cytokines. Humoral immune responses to antigens of both of these viruses and SIV specific T cell proliferative responses were significantly enhanced by co-immunization with the cytokines. These twelve monkeys, and a group of six naive controls, were challenged by the oral mucosal route with the uncloned and highly pathogenic SIVmac251. All monkeys became infected. The early CD4 decline was reduced in the group co-immunized with cytokine and viral plasmids. Unexpectedly, plasma viremia set points were not different in this co-immunized group and the non-immunized control group. On the other hand, monkeys vaccinated with equivalent amounts of empty vector plasmid (i.e. no cytokine inserts) along with plasmids expressing viral antigens demonstrated a slight but significant decrease in acute viremia compared to non-immunized controls (P<0.02). However, viral loads at set points were not significantly different between both the immunized and the non-immunized control group. Thus, although the cytokine vectors demonstrated detectable enhancement of the immune response to different viral antigens, such enhanced response did not translate into better anti-viral control in our experiment. These results underscore the need for further testing of cytokines as vaccine adjuvants in relevant animal models.

Relative resistance in the development of T cell anergy in CD4+ T cells from simian immunodeficiency virus disease-resistant sooty mangabeys

Despite high viral loads, T cells from sooty mangabey (SM) monkeys that are naturally infected with SIV but remain clinically asymptomatic, proliferate and demonstrate normal Ag-specific memory recall CD4(+) T cell responses. In contrast, CD4(+) T cells from rhesus macaques (RM) experimentally infected with SIV lose Ag-specific memory recall responses and develop immunological anergy. To elucidate the mechanisms for these distinct outcomes of lentiviral infection, highly enriched alloreactive CD4(+) T cells from humans, RM, and SM were anergized by TCR-only stimulation (signal 1 alone) and subsequently challenged with anti-CD3/anti-CD28 Abs (signals 1 + 2). Whereas alloreactive CD4(+)T cells from humans and RM became anergized, surprisingly, CD4(+) T cells from SM showed marked proliferation and IL-2 synthesis after restimulation. This resistance to undergo anergy was not secondary to a global deficiency in anergy induction of CD4(+) T cells from SM since incubation of CD4(+) T cells with anti-CD3 alone in the presence of rapamycin readily induced anergy in these cells. The resistance to undergo anergy was reasoned to be due to the ability of CD4(+) T cells from SM to synthesize IL-2 when incubated with anti-CD3 alone. Analysis of phosphorylated kinases involved in T cell activation showed that the activation of CD4(+) T cells by signal 1 in SM elicited a pattern of response that required both signals 1 + 2 in humans and RM. This function of CD4(+) T cells from SM may contribute to the resistance of this species to SIV-induced disease.