Early SIV encephalopathy

SIV encephalopathy was studied in rhesus macaques early after intracerebral (IC) or intravenous (IV) inoculation. Although SIV was detected in the brain of all IC-inoculated animals, the CNS showed moderate neuropathological changes. IV-inoculated animals presented a spectrum of brain changes ranging from perivascular infiltrates to multinucleated giant cells. CNS infection was detected as early as seven days post-IV-inoculation, mostly in a perivascular localization. Using combined immunohistochemistry and in situ hybridization, infected cells were shown to express macrophage markers.     

Nef genes of SIV

Molecular clones of SIVmac were constructed that differed only in sequences within the nef gene. DEAE-transfection of viral DNA containing an open from of nef yielded virus that replicated with similar kinetics and to a similar extent in macaque peripheral blood lymphocyte (PBL) cultures as virus with a deletion or stop codon within nef. Rhesus monkeys that received each kind of molecularly cloned virus became infected. Our results additionally suggest that mutant forms of virus are selected in vitro while open, functional forms are selected in vivo. In animals infected with virus containing a stop codon within nef, reversion of the stop codon to a coding codon was demonstrated in five of five clones analyzed. These results indicate that nef is playing some role crucial to the virus life cycle in vivo.     

SIV Infection of Lung Macrophages

HIV-1 depletes CD4+ T cells in the blood, lymphatic tissues, gut and lungs. Here we investigated the relationship between depletion and infection of CD4+ T cells in the lung parenchyma. The lungs of 38 Indian rhesus macaques in early to later stages of SIVmac251 infection were examined, and the numbers of CD4+ T cells and macrophages plus the frequency of SIV RNA+ cells were quantified. We showed that SIV infected macrophages in the lung parenchyma, but only in small numbers except in the setting of interstitial inflammation where large numbers of SIV RNA+ macrophages were detected. However, even in this setting, the number of macrophages was not decreased. By contrast, there were few infected CD4+ T cells in lung parenchyma, but CD4+ T cells were nonetheless depleted by unknown mechanisms. The CD4+ T cells in lung parenchyma were depleted even though they were not productively infected, whereas SIV can infect large numbers of macrophages in the setting of interstitial inflammation without depleting them. These observations point to the need for future investigations into mechanisms of CD4+ T cell depletion at this mucosal site, and into mechanisms by which macrophage populations are maintained despite high levels of infection. The large numbers of SIV RNA+ macrophages in lungs in the setting of interstitial inflammation indicates that lung macrophages can be an important source for SIV persistent infection.     

Apoptosis in SIV infection

Pathogenic human immunodeficiency virus (HIV)/Simian immunodeficiency virus (SIV) infection is associated with increased T-cell apoptosis. In marked contrast to HIV infection in humans and SIV infection in macaques, the SIV infection of natural host species is typically nonpathogenic despite high levels of viral replication. In these nonpathogenic primate models, no observation of T-cell apoptosis was observed, suggesting that either SIV is less capable of directly inducing apoptosis in natural hosts (likely as a result of coevolution/coadaptation with the host) or, alternatively, that the indirect T-cell apoptosis plays the key role in determining the HIV-associated T-cell depletion and progression to acquired immune deficiency syndrome (AIDS). Understanding the molecular and cellular mechanisms responsible for the disease-free equilibrium in natural hosts for SIV infection, including those determining the absence of high levels of T-cell apoptosis, is likely to provide important clues regarding the mechanisms of AIDS pathogenesis in humans.     

Postexposure immunotherapy of simian immunodeficiency virus (SIV) infected rhesus with an SIV immunogen

An inactivated whole simian immunodeficiency virus (SIV) immunogen given to healthy, seropositive rhesus macaques 4 months after infection had no effect on the humoral immune response to SIV, the presence of antigenemia, cell-associated viremia, or disease course. Further immunotherapeutic trials in this highly susceptible animal model should be carried out sooner after exposure, before significant loss of CD4 cells has occurred. The SIV infected macaque model will continue to serve an essential role in development and testing of anti-AIDS drugs and immunogens.     

Comparison of protection from homologous cell-free vs cell-associated SIV challenge afforded by inactivated whole SIV vaccines

This study attempted to determine if SIV vaccines could protect against challenge with peripheral blood mononuclear cells (PBMCs) from an SIV infected rhesus monkey. Mature Macaca mulatta were vaccinated four times with formalin inactivated SIV_mac32H administered in MDP adjuvant (n = 8) or SIV_mac32H ISCOM vaccine (n = 8). Controls included animals vaccinated with measles virus in MDP adjuvant (n = 4) or ISCOM (n = 4) preparations. Of each group, half were challenged intravenously (IV) with ten MID₅₀ of the cell-free SIV_mac32H (11-88) SIV stock and half were challenged with ten MID₃₀ of PBMCs from the SIV_mac32H infected macaque 1XC. All SIV vaccinated animals challenged with the 11-88 cell free stock of SIV_mac32H were protected, whereas only half of the SIV vaccinated monkeys receiving the same infectious dose of the 1XC cell stock were protected.     

Protection of Macaca nemestrina from disease following pathogenic simian immunodeficiency virus (SIV) challenge: utilization of SIV nucleocapsid mutant DNA vaccines with and without an SIV protein boost

Molecular clones were constructed that express nucleocapsid (NC) deletion mutant simian immunodeficiency viruses (SIVs) that are replication defective but capable of completing virtually all of the steps of a single viral infection cycle. These steps include production of particles that are viral RNA deficient yet contain a full complement of processed viral proteins. The mutant particles are ultrastructurally indistinguishable from wild-type virus. Similar to a live attenuated vaccine, this approach should allow immunological presentation of a full range of viral epitopes, without the safety risks of replicating virus. A total of 11 Macaca nemestrina macaques were inoculated with NC mutant SIV expressing DNA, intramuscularly (i.m.) in one study and i.m. and subcutaneously in another study. Six control animals received vector DNA lacking SIV sequences. Only modest and inconsistent humoral responses and no cellular immune responses were observed prior to challenge. Following intravenous challenge with 20 animal infectious doses of the pathogenic SIV(Mne) in a long-term study, all control animals became infected and three of four animals developed progressive SIV disease leading to death. All 11 NC mutant SIV DNA-immunized animals became infected following challenge but typically showed decreased initial peak plasma SIV RNA levels compared to those of control animals (P = 0.0007). In the long-term study, most of the immunized animals had low or undetectable postacute levels of plasma SIV RNA, and no CD4(+) T-cell depletion or clinical evidence of progressive disease, over more than 2 years of observation. Although a subset of immunized and control animals were boosted with SIV(Mne) proteins, no apparent protective benefit was observed. Immunization of macaques with DNA that codes for replication-defective but structurally complete virions appears to protect from or at least delay the onset of AIDS after infection with a pathogenic immunodeficiency virus. With further optimization, this may be a promising approach for vaccine development.     

Cortico-cortical relations of cat somatosensory areas SIV and SV

Sensory cortex is characterized by multiple representations of a given modality which are generally highly interconnected and hierarchically arranged. The cat cerebral cortex contains at least five major areas dedicated to somatosensory processing, yet aside from areas SI and SII, little is known regarding the interconnectivity of the other, higher-level regions, such as SIV and SV. Therefore, this investigation examined the anatomical relationship of somatosensory areas SIV and SV to each other. In adult cats, wheatgerm agglutinin-horseradish peroxidase (WGA-HRP) injected into SIV produced retrogradely labeled neurons in SV in a bilaminar pattern. When biotinylated dextran amine (BDA) was injected into SV, orthogradely labeled axon terminals were found in SIV across all laminae but predominated in supragranular locations. In the reciprocal direction, neurons located in both the supra- and infragranular layers of SIV projected across all laminae of SV, but also in a manner that favored the supragranular layers. Because local inhibitory circuits are critical for specific somatosensory response properties, the distribution of GABA-ergic neurons and their co-localized markers calbindin (CB), calretinin (CR) and parvalbumin (PV) was also compared for SIV and SV using immunocytochemical techniques. Although fundamental differences in laminar arrangement were observed between the different GABA-ergic subtypes, the distribution for each subtype was essentially the same in both SIV and SV. Collectively, these connectional, cytoarchitectonic and organizational similarities indicate that SIV and SV are reciprocally connected and share many somatosensory processing and connectional features.     

Serial pathogenesis study of SIV brain infection

A serial study of early SIV brain infection revealed initial involvement of leptomeninges, followed by perivascular infection of brain parenchyma. Severity of SIV encephalitis correlated with severity of systemic disease rather than with length of infection. Diffuse white matter disease was not observed, and there was little evidence of SIV infection of brain endothelial cells. SIV infection of leptomeninges is separate from infection of the brain, which appears to be due to transvascular spread of infected monocytes/macrophages.     

SIV vaccine protection of rhesus monkeys.

Rhesus macaques (M. mulatta), immunized with an inactivated whole SIVmac vaccine and muramyl dipeptide or Freund's incomplete adjuvant, were protected against IV challenge infection with 10 animal infectious doses of the homologous virus. The protection in these animals appeared to be complete, with no breakthrough of latent virus infection over a 10-month period. Vaccine protection in this model was correlated generally with a high level of SIVmac envelope antibody by ELISA and immunoblot, high titers of syncytial inhibiting antibody, and, more specifically, with the presence of antibodies binding to a putative V3 loop synthetic peptide of the SIVmac outer envelope. This model can now be used for further identification of the protective epitopes and protective host immune responses as well as for development of novel and better AIDS vaccines.     

SIV envelope acquires a nefarious habit

Deletion of the nef gene from macaque simian immunodeficiency virus (SIVmac) attenuates its ability to cause disease. Pathogenic viruses occasionally emerge in macaques infected with Nef-deleted SIVmac, with some genetic determinants mapping to the envelope (env) gene. An intriguing new study shows that these changes endow Env with a Nef-like ability to counteract tetherin/BST2 (Serra-Moreno et?al., 2011).     

Protection of Macaques with Diverse MHC Genotypes against a Heterologous SIV by Vaccination with a Deglycosylated Live-Attenuated SIV

HIV vaccine development has been hampered by issues such as undefined correlates of protection and extensive diversity of HIV. We addressed these issues using a previously established SIV-macaque model in which SIV mutants with deletions of multiple gp120 N-glycans function as potent live attenuated vaccines to induce near-sterile immunity against the parental pathogenic SIVmac239. In this study, we investigated the protective efficacy of these mutants against a highly pathogenic heterologous SIVsmE543-3 delivered intravenously to rhesus macaques with diverse MHC genotypes. All 11 vaccinated macaques contained the acute-phase infection with blood viral loads below the level of detection between 4 and 10 weeks postchallenge (pc), following a transient but marginal peak of viral replication at 2 weeks in only half of the challenged animals. In the chronic phase, seven vaccinees contained viral replication for over 80 weeks pc, while four did not. Neutralizing antibodies against challenge virus were not detected. Although overall levels of SIV specific T cell responses did not correlate with containment of acute and chronic viral replication, a critical role of cellular responses in the containment of viral replication was suggested. Emergence of viruses with altered fitness due to recombination between the vaccine and challenge viruses and increased gp120 glycosylation was linked to the failure to control SIV. These results demonstrate the induction of effective protective immune responses in a significant number of animals against heterologous virus by infection with deglycosylated attenuated SIV mutants in macaques with highly diverse MHC background. These findings suggest that broad HIV cross clade protection is possible, even in hosts with diverse genetic backgrounds. In summary, results of this study indicate that deglycosylated live-attenuated vaccines may provide a platform for the elucidation of correlates of protection needed for a successful HIV vaccine against diverse isolates.     

Mucosal challenge of Macaca nemestrina with simian immunodeficiency virus (SIV) following SIV nucleocapsid mutant DNA vaccination

A simian immunodeficiency virus (SIV)(Mne) DNA clone was constructed that produces viruses containing a four amino acid deletion in the second zinc finger of the nucleocapsid (NC) domain of the Gag polyprotein. Viruses produced from this clone, although non-infectious both in vitro and in vivo, complete a majority of the steps in a single retroviral infection cycle. Eight pig-tailed macaques (Macaca nemestrina) were inoculated intramuscularly and subcutaneously three times over the course of 24 weeks with the NC mutant expressing DNA. These macaques, and four controls, were then challenged mucosally (intrarectally) with the homologous virus (SIV Mne CL E11S) and monitored for evidence of infection and clinical disease. Prior to challenge, a measurable humoral immune response was noted in four of eight immunized macaques. After challenge, all 12 macaques became infected, although four immunized animals greatly restricted their viral replication, and one immunized animal that controlled replication remains antibody negative. No disease has been evidence during the 46-week period of monitoring after challenge.     

Theoretical and functional analysis of the SIV fusion peptide.

The fusion domain of simian immunodeficiency virus (SIV) envelope glycoproteins is a hydrophobic region located at the amino-terminal extremity of the transmembrane protein (gp32). Assuming an alpha helical structure for the SIV fusogenic domain of gp32 in a lipid environment, theoretical studies have predicted that the fusion peptide would insert obliquely in the lipid bilayer. This oblique insertion could be an initial step of the fusion process by disorganizing locally the structure of the lipid bilayer. We have tested this hypothesis by selectively mutagenizing the SIV gp160 expressed via a vaccinia virus vector, to alter the theoretical angle of insertion of the fusion peptide. The fusogenic activity of the wild-type and mutant glycoproteins was tested after infection of T4 lymphocytic cell lines by the recombinant vaccinia virus, and measure of syncytia formation. Mutations that modified the oblique orientation reduced the fusogenic activity. In contrast, mutations that conserve the oblique orientation did not alter the fusogenic properties. Our results support the hypothesis that oblique orientation is important for fusogenic activity.     

Identification of multiple simian immunodeficiency virus (SIV)-specific CTL epitopes in sooty mangabeys with natural and experimentally acquired SIV infection

Host immune responses to SIV infection in sooty mangabeys are likely to be an important determinant of how such nonhuman primate species maintain asymptomatic lentivirus infection. We have previously described two patterns of asymptomatic SIV infection in sooty mangabeys: low viral loads with vigorous SIV-specific CTL activity in SIVmac239-infected sooty mangabeys, and high viral loads with generally weak or absent SIV-specific CTL activity in naturally infected sooty mangabeys. To define the specificity of the CTL response in SIV-infected mangabeys, we characterized CTL epitopes in two naturally infected and three SIVmac239-infected sooty mangabeys. Compared with that in SIVmac239-infected mangabeys, the yield of SIV-specific CTL clones was significantly lower in naturally infected sooty mangabeys. All CTL clones were phenotypically CD3+ CD8+, and lysis was MHC restricted. Seven SIV CTL epitopes were identified in five sooty mangabeys: one in Gag and three each in Nef and Envelope (Env). The CTL epitopes mapped to conserved regions in the SIV genome and were immunodominant. Several similar or identical CTL epitopes were recognized by both naturally infected and SIVmac239-infected mangabeys that shared class I MHC alleles. To our knowledge, this is the first report of SIV-specific CTL epitopes in sooty mangabeys. Longitudinal studies of viral load and sequence variation in CTL epitopes may provide useful information on the role of CTL in control or persistence of SIV infection in sooty mangabeys.     

NK细胞与HIV/SIV感染相关性的研究进展

NK细胞作为天然免疫系统的重要组成部分,其在HIV/SIV感染后的免疫机制及如何发挥抗病毒作用成为近几年艾滋病研究的热点之一。研究中发现,伴随HIV/SIV的感染,NK细胞亚群比例发生改变同时伴有功能缺陷,这种变化与HIV/SIV慢性感染阶段病毒复制水平有显著相关性。并且由于归巢受体表达的改变引起NK细胞在HIV/SIV感染者体内不同组织间的重新分布。NK细胞表面的受体KIR3DL1和KIR3DS也表现出对HIV感染的抵抗作用。这些发现为我们进一步研究NK细胞的抗HIV/SIV病毒感染的免疫机制提供了新的思路和方向。     

Immunization of Macaca fascicularis with inactivated SIV preparations: Challenge with human- or monkey-derived SIV and the effects of a longer immunization schedule

In cynomolgus monkeys, we compared two human-derived SIV_mac251 whole virus vaccines, a long vs short immunization schedule, and two different challenge viruses. Both vaccines induced protection after challenge with human-derived SIV_mac251/32H. There was no difference between the two schedules of immunization. Seven monkeys, five of which were protected following the first challenge, were reboosted and rechallenged with monkey-derived SIV_mac251, but no protection was observed. The titers of anti-human cell or -SIV neutralizing antibodies were not related to protection.     

Correlates of SIV encephalitis in rhesus monkeys.

Necropsy records from 204 SIV-infected rhesus monkeys that had been inoculated with various strains of SIV and had died of SIV-related disease were reviewed. The relationship of SIV encephalitis with other parameters was evaluated. Encephalitis was associated with the presence of syncytial cells in other tissues, with persistent or early recurrent antigenemia, with a selective decrease in CD4+CD29+ blood lymphocytes, and with a shortened time of survival. Monkeys whose lymphocytes produced high levels of virus in culture also had a higher incidence of encephalitis. SIV was more frequently isolated from the brains of animals with encephalitis. No other clear associations were detected.