Significance of macrophage tropism of SIV in the macaque model of HIV disease

A SIV molecular clone that targets the CNS and induces neuroAIDS in rhesus macaques

Despite effective control of plasma viremia with the use of combination antiretroviral therapies (cART), minor cognitive and motor disorders (MCMD) persist as a significant clinical problem in HIV-infected patients. Non-human primate models are therefore required to study mechanisms of disease progression in the central nervous system (CNS). We isolated a strain of simian immunodeficiency virus (SIV), SIVsm804E, which induces neuroAIDS in a high proportion of rhesus macaques and identified enhanced antagonism of the host innate factor BST-2 as an important factor in the macrophage tropism and initial neuro-invasion of this isolate. In the present study, we further developed this model by deriving a molecular clone SIVsm804E-CL757 (CL757). This clone induced neurological disorders in high frequencies but without rapid disease progression and thus is more reflective of the tempo of neuroAIDS in HIV-infection. NeuroAIDS was also induced in macaques co-inoculated with CL757 and the parental AIDS-inducing, but non-neurovirulent SIVsmE543-3 (E543-3). Molecular analysis of macaques infected with CL757 revealed compartmentalization of virus populations between the CNS and the periphery. CL757 exclusively targeted the CNS whereas E543-3 was restricted to the periphery consistent with a role for viral determinants in the mechanisms of neuroinvasion. CL757 would be a useful model to investigate disease progression in the CNS and as a model to study virus reservoirs in the CNS.

Despite effective control of plasma viremia with the use of combination antiretroviral therapies, neurologic disease resulting from HIV-infection of the central nervous system (CNS) persists as a significant clinical problem. Non-human primate models are therefore required to study mechanisms of disease progression in the CNS. We generated an infectious molecular clone (CL757) of an SIV isolate from the brain of a macaque with neuroAIDS. This cloned virus induced neurological disorders in 50% of rhesus macaques infected but without rapid disease progression often seen in other commonly used animal models. Molecular analysis of tissues from macaques infected with CL757 revealed that the variants isolated from the CNS and the periphery became genetically distinct from one another. When co-inoculated with an AIDS-inducing, non-neurovirulent clone (E543-3), CL757 targeted the CNS consistent with its neurovirulence. CL757 would be a useful model to investigate disease progression in the CNS and as a model to study virus reservoirs in the CNS.

Derivation and Characterization of a CD4-Independent, Non-CD4-Tropic Simian Immunodeficiency Virus

CD4 tropism is conserved among all primate lentiviruses and likely contributes to viral pathogenesis by targeting cells that are critical for adaptive antiviral immune responses. Although CD4-independent variants of human immunodeficiency virus (HIV) and simian immunodeficiency virus (SIV) have been described that can utilize the coreceptor CCR5 or CXCR4 in the absence of CD4, these viruses typically retain their CD4 binding sites and still can interact with CD4. We describe the derivation of a novel CD4-independent variant of pathogenic SIVmac239, termed iMac239, that was used to derive an infectious R5-tropic SIV lacking a CD4 binding site. Of the seven mutations that differentiate iMac239 from wild-type SIVmac239, a single change (D178G) in the V1/V2 region was sufficient to confer CD4 independence in cell-cell fusion assays, although other mutations were required for replication competence. Like other CD4-independent viruses, iMac239 was highly neutralization sensitive, although mutations were identified that could confer CD4-independent infection without increasing its neutralization sensitivity. Strikingly, iMac239 retained the ability to replicate in cell lines and primary cells even when its CD4 binding site had been ablated by deletion of a highly conserved aspartic acid at position 385, which, for HIV-1, plays a critical role in CD4 binding. iMac239, with and without the D385 deletion, exhibited an expanded host range in primary rhesus peripheral blood mononuclear cells that included CCR5(+) CD8(+) T cells. As the first non-CD4-tropic SIV, iMac239-ΔD385 will afford the opportunity to directly assess the in vivo role of CD4 targeting on pathogenesis and host immune responses.

IMPORTANCE

CD4 tropism is an invariant feature of primate lentiviruses and likely plays a key role in pathogenesis by focusing viral infection onto cells that mediate adaptive immune responses and in protecting virions attached to cells from neutralizing antibodies. Although CD4-independent viruses are well described for HIV and SIV, these viruses characteristically retain their CD4 binding site and can engage CD4 if available. We derived a novel CD4-independent, CCR5-tropic variant of the pathogenic molecular clone SIVmac239, termed iMac239. The genetic determinants of iMac239's CD4 independence provide new insights into mechanisms that underlie this phenotype. This virus remained replication competent even after its CD4 binding site had been ablated by mutagenesis. As the first truly non-CD4-tropic SIV, lacking the capacity to interact with CD4, iMac239 will provide the unique opportunity to evaluate SIV pathogenesis and host immune responses in the absence of the immunomodulatory effects of CD4(+) T cell targeting and infection.

Macaque species susceptibility to simian immunodeficiency virus: increased incidence of SIV central nervous system disease in pigtailed macaques versus rhesus macaques

Immune pressure exerted by MHC class I-restricted cytotoxic T cells drives the development of viral escape mutations, thereby regulating HIV disease progression. Nonetheless, the relationship between host immunity and HIV central nervous system (CNS) disease remains poorly understood. The simian immunodeficiency virus (SIV) macaque model recapitulates key features of HIV infection including development of AIDS and CNS disease. To investigate cell-mediated immunity regulating SIV CNS disease progression, we compared the incidence of SIV encephalitis and the influence of MHC class I allele expression on the development of CNS disease in rhesus macaques (Macaca mulatta) versus pigtailed macaques (Macaca nemestrina). After inoculation with the immunosuppressive swarm SIV/DeltaB670 and the neurovirulent molecular clone SIV/17E-Fr, pigtailed macaques progressed more rapidly to AIDS, had higher plasma and cerebrospinal fluid (CSF) viral loads, and were more likely to progress to SIV-associated encephalitis (SIVE) compared to rhesus macaques. In addition, MHC class I alleles were neuroprotective in both species (Mamu-A*001 in rhesus macaques and Mane-A1*084:01:01 in pigtailed macaques); animals expressing these alleles were less likely to develop SIV encephalitis and correspondingly had lower viral replication in the brain. Species-specific differences in susceptibility to SIV disease demonstrated that cell mediated immune responses are critical to SIV CNS disease progression.

Nonhuman primate models of NeuroAIDS

Human Immunodeficiency virus (HIV), the virus that causes acquired immunodeficiency syndrome (AIDS), also manifests neurological complications. HIV-associated dementia (HAD) is the most severe form of HIV-induced neurocognitive disorders. HIV encephalitis (HIVE), the pathological correlate of HAD, is characterized by the formation of multinucleated giant cells and microglial nodules, astrocytosis, and neuronal damage and loss. Pathological evaluation of HAD disease progression in humans is not possible, with the only data collected being from individuals who have succumbed to the disorder, a snap shot of end-stage disease at best. Therefore, pertinent animal models have been developed to alleviate this gap of knowledge in the field of neurovirology and neuroinflammation. In general, the most widely used animal models are the simian immunodeficiency virus (SIV) and the chimeric simian/human immunodeficiency virus (SHIV) macaque model systems. Although both SIV and SHIV model systems are able to potentiate neuroinvasion and the concomitant neuropathology similar to that seen in the human syndromes, the innate differences between the two in disease pathogenesis and progression make for two separate, yet effective, systems for the study of HIV-associated neuropathology.

The Nef protein of HIV-1 induces loss of cell surface costimulatory molecules CD80 and CD86 in APCs

The Nef protein of HIV-1 is essential for its pathogenicity and is known to down-regulate MHC expression on infected cell surfaces. We now show that Nef also redistributes the costimulatory molecules CD80 and CD86 away from the cell surface in the human monocytic U937 cell line as well as in mouse macrophages and dendritic cells. Furthermore, HIV-1-infected U937 cells and human blood-derived macrophages show a similar loss of cell surface CD80 and CD86. Nef colocalizes with MHC class I (MHCI), CD80, and CD86 in intracellular compartments, and binds to both mouse and human CD80 and CD86. Some Nef mutants defective in MHCI down-modulation, including one from a clinical isolate, remain capable of down-modulating CD80 and CD86. Nef-mediated loss of surface CD80/CD86 is functionally significant, because it leads to compromised activation of naive T cells. This novel immunomodulatory role of Nef may be of potential importance in explaining the correlations of macrophage-tropism and Nef with HIV-1 pathogenicity and immune evasion.

Development and characterization of positively selected brain-adapted SIV

HIV is found in the brains of most infected individuals but only 30% develop neurological disease. Both viral and host factors are thought to contribute to the motor and cognitive disorders resulting from HIV infection. Here, using the SIV/rhesus monkey system, we characterize the salient characteristics of the virus from the brain of animals with neuropathological disorders. Nine unique molecular clones of SIV were derived from virus released by microglia cultured from the brains of two macaques with SIV encephalitis. Sequence analysis revealed a remarkably high level of similarity between their env and nef genes as well as their 3' LTR. As this genotype was found in the brains of two separate animals, and it encoded a set of distinct amino acid changes from the infecting virus, it demonstrates the convergent evolution of the virus to a unique brain-adapted genotype. This genotype was distinct from other macrophage-tropic and neurovirulent strains of SIV. Functional characterization of virus derived from representative clones showed a robust in vitro infection of 174xCEM cells, primary macrophages and primary microglia. The infectious phenotype of this virus is distinct from that shown by other strains of SIV, potentially reflecting the method by which the virus successfully infiltrates and infects the CNS. Positive in vivo selection of a brain-adapted strain of SIV resulted in a near-homogeneous strain of virus with distinct properties that may give clues to the viral basis of neuroAIDS.

Simian immunodeficiency viruses from multiple lineages infect human macrophages: implications for cross-species transmission

Zoonotic transfer of simian immunodeficiency virus (SIV) from chimpanzees and sooty mangabeys to humans has been documented on at least seven occasions. Several recently identified SIV isolates have also been shown to replicate efficiently in human peripheral blood mononuclear cells (PBMCs) in vitro, indicative of the potential for additional cross-species transmission via T cell infection. Although SIV predominantly uses the macrophage-tropic HIV chemokine coreceptor CCR5, little is known about the ability of SIV to infect human macrophages. In this study, 16 SIV isolates belonging to five different primate lentivirus lineages were tested for their ability to infect human monocyte-derived macrophages (MDMs). Twelve of the viruses were capable of infecting MDMs, and 11 of these were also able to replicate in human PBMCs. The replication capacity of the isolates differed within and between the various families and was dependent on particular donor macrophages. Our results suggest that most simian lentiviruses characterized to date not only have the ability to infect primary human T lymphocytes but also replicate efficiently in macrophages, thereby increasing the potential for cross-species transmission into the human population. Comparative studies using these isolates may facilitate the identification of characteristics that contribute to virus infectivity and pathogenicity.

Differences between T cell epitopes recognized after immunization and after infection

Evidence suggests that cellular immune responses play a crucial role in the control of HIV and SIV replication in infected individuals. Several vaccine strategies have therefore targeted these CD8(+) and CD4(+) responses. Whether vaccination induces the same repertoire of responses seen after infection is, however, a key unanswered question in HIV vaccine development. We therefore compared the epitope specificity induced by vaccination to that present postchallenge in the peripheral blood. Intracellular cytokine staining of PBMC stimulated with overlapping 15/20-mer peptides spanning the proteins of SIV were measured after DNA/modified vaccinia Ankara vaccination of eight rhesus macaques. Lymphocytes from 8 animals recognized a total of 39 CD8 epitopes and 41 CD4 epitopes encoded by the vaccine. T cell responses were again monitored after challenge with SIVmac239 to investigate the evolution of these responses. Only 57% of all CD8(+) T cell responses and 19% of all CD4(+) T cell responses present after vaccination were recalled after infection as measured in the peripheral blood. Interestingly, 29 new CD8 epitopes and 5 new CD4 epitopes were recognized by PBMC in the acute phase. These new epitopes were not detected after vaccination, and only some of them were maintained in the chronic phase (33% of CD8 and no CD4 responses). Additionally, 24 new CD8 epitopes and 7 new CD4 epitopes were recognized by PBMC in the chronic phase of infection. The repertoire of the immune response detected in the peripheral blood after immunization substantially differed from the immune response detected in the peripheral blood after infection.

Neuropathogenesis of lentiviral infection in macaques: roles of CXCR4 and CCR5 viruses and interleukin-4 in enhancing monocyte chemoattractant protein-1 production in macrophages

Neurological disease associated with lentiviral infection occurs mainly as a consequence of primary replication of the virus or a combination of the virus infection and replication of opportunistic pathogens in the central nervous system. Recent studies have shown that whereas the disease can be caused by CCR5 tropic viruses alone, its induction by CXCR4 (X4) tropic viruses occurred usually in association with infections caused by opportunistic pathogens and in the presence of a Th2 cytokine, interleukin (IL)-4.(1,2) Further, X4-mediated neurological disease developed preferentially in rhesus compared to pig-tailed macaques. Because macrophages are the target cells for lentiviral infection in the brain and because macrophage chemoattractant protein (MCP)-1 is one of the major chemokines that is closely associated with acquired immune deficiency syndrome (AIDS) dementia, we tested for correlations between MCP-1 production and virus tropism in macrophages from the two species of macaques. The studies showed that the higher susceptibility of rhesus macaques to X4 virus-mediated encephalitis correlated with heightened production of virus and MCP-1 in cultured macrophages from this species and that these effects were further enhanced with treatment with IL-4. However, the latter effect was restricted to macrophages infected with X4 viruses. IL-4 may therefore be a basic requirement for X4 viruses to cause central nervous system disease.

Innate differences between simian-human immunodeficiency virus (SHIV)(KU-2)-infected rhesus and pig-tailed macaques in development of neurological disease

Neurological disease associated with HIV infection results from either primary replication of the virus or a combination of virus infection and replication of opportunistic pathogens in the CNS. Recent studies indicate that the primary infection is mediated mainly by viruses that utilize CCR5 as the coreceptor; it is not known whether the syndrome can be mediated by viruses that use the CXCR4 coreceptor. The macaque model of the disease using simian immunodeficiency virus (SIV) has confirmed that CCR5-using viruses such as SIV(mac)251 can cause primary disease in the CNS. In this report we have examined the role of simian-human immunodeficiency virus (SHIV)(KU-2), a CXCR4 virus which replicates productively in rhesus macrophages, in causing CNS disease. A survey of archival brain tissues from SHIV(KU-2)-infected rhesus and pig-tailed macaques that succumbed to AIDS showed productive viral replication in the CNS of 10 of 14 rhesus animals. Eight of these 10 had additional infections with opportunistic pathogens. In contrast, 21 of 22 pig-tailed macaques had no evidence of productive viral infection in the brain. In an earlier study we had shown that inoculation of SHIV-infected rhesus macaques with eggs of Schistosoma mansoni, a potent inducer of IL-4, resulted in enhanced replication of the virus in tissue macrophages. In the present study, we compared the replication of the virus in macrophages from normal rhesus and pig-tailed macaques and determined further whether exogenous IL-4 could cause enhancement of virus replication in these cells. These studies showed that the virus replicated productively in rhesus macrophages, and this was enhanced significantly after recombinant macaque IL-4 was added to the medium. IL-4 also caused enhancement of virus production in macrophages isolated from virus-infected animals. In contrast, the virus replicated only minimally in pig-tailed macaque macrophages and supplemental IL-4 had negligible effects. The data thus suggested that failure of pig-tailed macaques to develop encephalitis was due to the innate resistance of macrophages from this species of macaque to support replication of SHIV(KU-2). The ability of the virus to replicate in the brains of rhesus macaques was dependent on coinfection in the brain with opportunistic pathogens which presumably induced both macrophages and IL-4 in the CNS microenvironment. A supportive role for IL-4 in the CNS disease was suggested by the presence of IL-4 RNA in the encephalitic brains of rhesus macaques and reduced levels of this cytokine in the brains from pig-tailed macaques.

Early expression of IFN-alpha/beta and iNOS in the brains of Venezuelan equine encephalitis virus-infected mice

To investigate the roles of type I interferon (IFN-alpha/beta) and other mediators of innate immune responses (e.g., inducible nitric oxide synthase [iNOS]) in early dissemination of Venezuelan equine encephalitis virus (VEE) infection, we used mice with targeted deletions in either their IFN-alpha/beta-receptor (IFNAR-1-/-) or interferon regulatory factor 2 (IRF-2-/-) genes. Following footpad infection, both IFNAR-1-/- and IRF-2-/- mice were more susceptible than control mice to VEE. The IFNAR-1-/- mice also exhibit accelerated VEE dissemination to serum, spleen, and brain, and compared with control mice, they evidenced faster kinetics in the upregulation of proinflammatory genes. In contrast, in IRF-2-/- mice, iNOS gene induction was completely absent following peripheral virulent VEE infection. In evaluating the role of cells involved in iNOS production, primary microglial cell cultures were found to be highly permissive to VEE infection. Moreover, VEE infection increased levels of nitric oxide (NO) in resting microglial cultures but decreased NO production in IFN-gamma-stimulated microglia. Thus, these findings suggest that reactive nitrogen species play an important contributory role in VEE dissemination and survival of the host. Our results further suggest the necessity for a carefully balanced host response that follows a middle course between immunopathology and insufficient inflammatory response to VEE infection.

Neuropathogenesis of simian immunodeficiency virus in neonatal rhesus macaques

Neonatal human immunodeficiency virus (HIV) infection usually occurs intrapartum or postpartum and results in a higher incidence of neurological dysfunction than is seen in adults. To explore the neuropathogenesis of neonatal HIV infection, we infected neonatal macaques with simian immunodeficiency virus (SIV) and followed the course of infection focusing on early time points. Infected neonates had decreased brain growth and mild histological changes in brain that resembled those seen in pediatric AIDS, including perivascular infiltrates of mononuclear cells, mineralization of vessels in the basal ganglia, and gliosis. The perivascular lesions and gliosis were associated with the presence of occasional infected cells that required in situ hybridization with radiolabeled riboprobes for detection. Using this technique, SIV-infected cells were detected in the brain parenchyma within 7 days of infection. These findings were confirmed by nested PCR for SIVgag DNA in brain and RT-PCR for viral RNA in cerebrospinal fluid. Together, these techniques revealed SIV infection of the CNS in 12 of 13 neonates infected with SIVmac239, 3 of 3 infected with SIVmac251, and 2 of 2 infected with SIVmac239/316. The prevalence of CNS infection was indistinguishable from that of older animals infected with the same dose and stock of virus, but neonates appeared to have fewer infected cells in the CNS and detecting them required more sensitive techniques. This observation was true regardless of inoculum and despite the fact that neonates had equal or greater viral loads in the periphery compared with older animals. These data suggest that maturation-dependent host factors have a major impact on the neuropathogenesis of pediatric AIDS.

SIV-associated nephropathy in rhesus macaques infected with lymphocyte-tropic SIVmac239

We examined the renal pathology and viral genetic changes following inoculation of six rhesus macaques with lymphocyte-tropic SIVmac239. Portions of the renal cortex were sieved into glomerular and tubulointerstitial (TI) fractions and examined for SIVmac sequences by PCR and for p27 core antigen. SIVmac sequences were detected in renal tissue from five of six macaques (three of five glomerular and five of five TI fractions were positive for SIV by PCR). Glomerulosclerosis (segmental and global) was evident in two macaques that were positive for env sequences in the glomerular fractions. Diffuse mesangial hyperplasia and matrix expansion were present in all three animals with glomerular SIV, as was an increase in glomerular collagen I and collagen IV. Tubulointerstitial inflammation was evident in all virus-inoculated macaques. The TI infiltration of CD68+ cells was most pronounced in the animals with SIVmac present in the glomerulus. All SIVmac-infected macaques exhibited increased glomerular deposition of IgM and to a lesser extent IgG, but no C3 or IgA was evident. Sequence analyses of the viral env gene (gp120) isolated from the glomerular and TI fractions of a macaque that developed glomerulopathy revealed the presence of specific viral variants in glomerular and TI fractions. In addition, chimeric viruses constructed with glomerular but not tubulointerstitial gp120 sequences were converted to a macrophage-tropic phenotype. These results indicate that infection by lymphocyte-tropic SIVmac239 is primarily associated with immunoglobulin deposition in the glomerulus and suggests that when glomerulosclerosis develops there is selection of viral variants that are macrophage tropic in nature.