Inoculation of baboons and macaques with simian immunodeficiency virus/Mne, a primate lentivirus closely related to human immunodeficiency virus type 2

Intrarectal inoculation of macaques by the simian immunodeficiency virus, SIVmne E11S: CD4+ depletion and AIDS

Macaca nemestrina and Macaca fascicularis were inoculated with various doses of a single-cell clone of SIVmne-infected HuT 78 cells (E11S) by both the intravenous and intrarectal routes. Animals inoculated intravenously at each dose seroconverted and virus was isolated from peripheral blood mononuclear cells, but only the high-dose intrarectally exposed macaques became viremic and seroconverted. However, some seronegative, virus isolation negative intrarectally inoculated macaques showed evidence of infection and disease.

Pathogenic diversity of simian immunodeficiency viruses

The SIV family is a diverse group of viruses that vary considerably in pathogenesis and virulence in their natural host species or macaques. Although the disease induced by the SIVsm subtype in particular is remarkably similar to human AIDS, it must be remembered that this is an experimental animal model. Therefore, although the pathogenesis of SIVsm (and other viruses) in macaques offers an relevant animal model for pathogenesis and vaccine trials, the interactions of these viruses in their natural host, and virus-, or host-specific effects have been poorly characterized. This animal model offers a unique opportunity to study the details of the pathogenesis of immunodeficiency and to define host and viral factors responsible for disease progression.

Analysis of cytotoxic T lymphocyte responses to SIV proteins in SIV-infected macaques using antigen-specific stimulation with recombinant vaccinia and fowl poxviruses

Methods to analyze CD8+ CTL responses to simian immunodeficiency virus (SIV)-encoded proteins are essential to understand lentivirus immunopathogenesis and protective immune responses. Recombinant infectious shuttle vectors are useful for analyzing CTL responses to many viruses, including HIV. Therefore, CTL responses in SIV-infected Macaca fascicularis to SIV env and SIV gag/pol were evaluated using specific antigen stimulation with recombinant vaccinia (rVV) and fowl poxviruses (rFPV) containing SIV genes. Peripheral blood mononuclear cells from SIV-infected animals were stimulated with autologous cells infected with rVV expressing SIV env/gag/pol, and CTLs specific for SIV env and for SIV gag/pol were detected by testing for lytic activity in target cells expressing these genes separately. Lymphocyte subset purifications from the effector population demonstrated that the CTL response was mediated by CD8+ cells, and the use of brefeldin A to selectively block antigen presentation in association with MHC class I products affirmed this cytolytic activity was class I restricted. The use of rVV to analyze responses to SIV genes is potentially problematic in hosts immunized to vaccinia. Fowl poxvirus is an alternative virus that has many of the molecular advantages of vaccinia virus but is genomically distinct. Therefore, the ability of rFPV to expand and detect SIV-specific CTLs was evaluated. Although there was no cytopathic effect following infection with rFPV, macaque cells infected with this vector did express rFPV gene products, and could be used as stimulator and target cells to detect SIV-specific CD8+ CTLs. The results suggest that these recombinant viral vectors can be used to specifically stimulate CD8+, MHC class I-restricted CTLs reactive to SIV proteins, and should facilitate evaluating CTL responses in both SIV-infected animals and animals vaccinated against SIV.

Viral genetic determinants in SIVsmmPBj pathogenesis

A variant simian immunodeficiency virus (SIV) from sooty mangabeys, SIVsmmPBj, induces an acutely lethal disease in pigtailed macaques (Macaca nemestrina). This study further characterizes the viral genetic determinants involved in this acutely lethal disease. We have generated chimeric molecular clones constructed between SIVsmmPBj and either SIVsmH4 or SIVsmm9 to analyze the role of the 5' half of the genome and the envelope gene in the induction of acute disease. These studies suggest that the gag and gp40 of SIVsmmPBj are required for the development of lethal disease, and an additional determinant in the central regulatory gene region of the SIVsmmPBj genome is also required.

Infectivity of titered doses of simian immunodeficiency virus clone E11S inoculated intravenously into rhesus macaques (Macaca mulatta)

The macaque infectious dose (MID) of a single-cell clone of simian immunodeficiency virus isolated from a pig-tailed macaque (SIV/Mne clone E11S) was determined in rhesus macaques (Macaca mulatta). Twenty-one macaques were inoculated with 10-fold dilutions of the virus stock (three or four animals per dose). The virologic and clinical status of these animals was monitored for 26 weeks. The 25% MID (MID25) occurred at a 10(5)-fold dilution of the viral stock.

T-cell activation influences initial DNA synthesis of simian immunodeficiency virus in resting T lymphocytes from macaques

The relationship between T-cell activation and early events in the replication cycle of simian immunodeficiency virus (SIV) was analyzed in resting T lymphocytes from macaques. We used the polymerase chain reaction to detect an early product of reverse transcription (R/U5) and almost complete viral DNA (long terminal repeat/gag). We found that SIV can enter resting T lymphocytes and initiate replication but that the reverse transcription process is not efficient and proceeds slowly in resting cells. Cross-linking the CD3/T-cell receptor complex with monoclonal antibodies, unlike cross-linking either the CD28 or CD2 accessory receptor and like phorbol myristate acetate, induced a rapid increase in viral R/U5 DNA detected within 3 to 6 h postinfection. Anti-CD3 or phorbol myristate acetate induced replication of full-length viral DNA within 6 to 9 h postinfection, but full-length SIV DNA was not detectable at earlier time points. We then compared various inhibitors of T-cell activation for their effects on viral initiation and complete replication. Cyclosporin A, an inhibitor of a distal step in T-cell activation, blocked anti-CD3-induced T-cell proliferation and completion of SIV DNA replication but had no effect on induced increases in SIV R/U5 DNA. By contrast, initial SIV DNA synthesis was partially blocked by inhibitors of very early steps in T-cell activation, including herbimycin A, an inhibitor of protein tyrosine kinases, and by two different inhibitors of protein kinase C, H7 and staurosporine. Since resting T cells do not efficiently complete SIV DNA synthesis and cyclosporin A can block the formation of complete viral DNA induced in activated T cells, a cellular factor(s) present in activated T cells appears to be required for the formation of full-length SIV DNA.

Simian immunodeficiency virus infection of the gastrointestinal tract of rhesus macaques. Functional, pathological, and morphological changes

Gastrointestinal dysfunction and wasting are frequent complications of human immunodeficiency virus (HIV) infection. Nutrient malabsorption, decreased digestive enzymes and HIV transcripts have been documented in jejunal mucosa of HIV-infected patients; however, the pathogenesis of this enteropathy is not understood. Rhesus macaques infected with simian immunodeficiency virus (SIV) also exhibit diarrhea and weight loss; therefore, we investigated the use of this animal model to study HIV-associated intestinal abnormalities. A retrospective study of intestinal tissues from 15 SIV-infected macaques was performed to determine the cellular targets of the virus and examine the effect of SIV infection on jejunal mucosal morphology and function. Pathological and morphological changes included inflammatory infiltrates, villus blunting, and crypt hyperplasia. SIV-infected cells were detected by in situ hybridization in stomach, duodenum, jejunum, ileum, cecum, and colon. Using combined immunohistochemistry and in situ hybridization, the cellular targets were identified as T lymphocytes and macrophages. The jejunum of SIV-infected animals had depressed digestive enzyme activities and abnormal morphometry, suggestive of a maturational defect in proliferating epithelial cells. Our results suggest that SIV infection of mononuclear inflammatory cells in intestinal mucosa may alter development and function of absorptive epithelial cells and lead to jejunal dysfunction.

Early phenotypic and functional alterations in lymphocytes from simian immunodeficiency virus infected macaques

Phenotypic and functional changes in lymphocytes from rhesus monkeys (Macaca mulatta) were investigated during the first 6 months after infection with SIV mac 32H. Animals preimmunized with keyhole limpet hemocyanin (KLH) were sacrificed 1, 3, 6, 12, and 24 weeks post infection. Subset composition and function of lymphocytes from blood, spleen, lymph node and thymus were analysed. In addition to a rapid decline in CD4/CD8 ratios, a massive reduction in CD29+ CD4+ cells was seen in the periphery. Although depletion of this subset was observed throughout the course of this experiment, the loss of proliferative T cell responses was most pronounced very early after infection and partially recovered after Month 3. Polyclonal cytotoxic responses were only slightly affected. In the thymus, a gradual, but moderate loss of CD4+CD8+ immature thymocytes, and a relative increase in both CD4+ and CD8+ mature subsets was observed. Infectious virus was readily recovered from homogenates of lymph node and spleen, but not of thymus tissue. Interestingly, however, virus was detected in thymocytes from all infected animals by cocultivation with a simian immunodeficiency virus (SIV) susceptible cell line.

Prevention of transmission of simian immunodeficiency virus from vaccinated macaques that developed transient virus infection following challenge

Macaque immunization with a mixture of four SIV peptides from conserved hydrophilic envelope regions has been shown to prevent virus persistence following challenge with SIVmne/E11s. Data shown here demonstrate that lymph node cells from all vaccinated monkeys and peripheral blood lymphocytes from one of the vaccinees were positive in a SIV-pol 'nested' polymerase chain reaction (PCR) amplification analysis. However, by 37 months after infection, all immunized monkeys were healthy while two of three controls had died and the remaining animal was virus culture-positive and had declining CD4+ lymphocytes. Viable lymph node cells and peripheral lymphoid cells in blood were transferred from the three immunized macaques to individual susceptible macaques. As a control for the transfer, one of the vaccine experiment controls that was actively producing virus in its peripheral blood was used. None of the recipients of cells from the vaccinated macaques seroconverted and all were virus coculture- and PCR-negative 25 weeks post-transfer (p.t.). The recipient of cells from the control infected macaque became positive in these tests by 2-3 weeks p.t. These results suggest that, while peptide-vaccinated macaques permitted some level of SIV replication following challenge, the vaccine prevented disease progression and virus transmission.

Induction of mucosal and systemic immunity to a recombinant simian immunodeficiency viral protein

Heterosexual transmission through the cervico-vaginal mucosa is the principal route of human immunodeficiency virus (HIV) infection in Africa and is increasing in the United States and Europe. Vaginal immunization with simian immunodeficiency virus (SIV) had not yet been studied in nonhuman primates. Immune responses in macaques were investigated by stimulation of the genital and gut-associated lymphoid tissue with a recombinant, particulate SIV antigen. Vaginal, followed by oral, administration of the vaccine elicited three types of immunity: (i) gag protein p27-specific, secretory immunoglobulin A (IgA) and immunoglobulin G (IgG) in the vaginal fluid, (ii) specific CD4+ T cell proliferation and helper function in B cell p27-specific IgA synthesis in the genital lymph nodes, and (iii) specific serum IgA and IgG, with CD4+ T cell proliferative and helper functions in the circulating blood.

HIV and skin disease: the molecular biology of the human immunodeficiency virus

The human immunodeficiency virus (HIV) is a member of a family of retroviruses that cause chronic persistent infections in animals and in humans. The structure of this virus resembles that of other retroviruses but also contains important and complex regulatory elements. The expression of HIV can be influenced by the action of exogenous agents and cytokines. HIV has been isolated from a number of cell types, including cells in the skin, using sensitive detection methods such as the polymerase chain reaction and in situ hybridization. This article is a basic overview of the molecular biology of HIV and its presence in skin.

Infection of Macaca nemestrina by human immunodeficiency virus type-1

After observations that Macaca nemestrina were exceptionally susceptible to simian immunodeficiency virus and human immunodeficiency virus type-2 (HIV-2), studies of HIV-1 replication were initiated. Several strains of HIV-1, including a recent patient isolate, replicated in vitro in peripheral blood mononuclear cells (PBMCs) and in CD4-positive M. nemestrina lymphocytes in a CD4-dependent fashion. Eight animals were subsequently inoculated with either cell-associated or cell-free suspensions of HIV-1. All animals had HIV-1 isolated by cocultivation, had HIV-1 DNA in their PBMCs as shown by polymerase chain reaction, and experienced sustained seroconversion to a broad spectrum of HIV-1 proteins. Macaca nemestrina is an animal model of HIV-1 infections that provides opportunities for evaluating the pathogenesis of acute HIV-1 replication and candidate vaccines and therapies.

Primary cultures of endothelial cells from the human liver sinusoid are permissive for human immunodeficiency virus type 1

Human endothelial cells isolated from hepatic sinusoids were infected in vitro with human immunodeficiency virus type 1 (HIV-1). An early sign of infection occurring in the culture was the formation of multinucleated cells. By double-labeling immunofluorescence, 5-15% of the cells recognized as endothelial cells owing to the presence of von Willebrand factor were found to contain HIV p24 and gp120 antigens after 2 weeks. Reverse transcriptase activity was released into the medium, and different steps in the process of viral budding were observed by electron microscopy. The virus produced by the endothelial cells was found to be infectious for CEM cells, a human T-cell line. CD4 molecules are present at the surface of the endothelial cells, as demonstrated by immunogold-silver staining and backscattered electron imaging. Treatment with an anti-CD4 antibody abolished productive infection of the sinusoidal endothelial cells. The possibility that endothelial cells of the liver sinusoid are infected in vivo with HIV remains to be clearly shown.

Pathologic features of SIV-induced disease and the association of macrophage infection with disease evolution

Since the original isolation of simian immunodeficiency virus (SIV) from a macaque with an AIDS-like disease, numerous studies have demonstrated the close biologic and genetic relationship of the SIVs to the HIVs. Probably most important, the clinical spectrum of disease associated with SIVmac/SIVsmm infection in rhesus monkeys is strikingly similar to AIDS in HIV-1-infected human beings. Herein are summarized the pathologic features of SIVmac-induced disease in a cohort of rhesus monkeys, with special reference to the role of infected macrophages in the development of AIDS-related manifestations.

Protection of macaques against SIV infection by subunit vaccines of SIV envelope glycoprotein gp160

Simian immunodeficiency virus (SIV) is a primate lentivirus related to human immunodeficiency viruses and is an etiologic agent for acquired immunodeficiency syndrome (AIDS)-like diseases in macaques. To date, only inactivated whole virus vaccines have been shown to protect macaques against SIV infection. Protective immunity was elicited by recombinant subunit vaccines. Four Macaca fascicularis were immunized with recombinant vaccinia virus expressing SIVmne gp160 and were boosted with gp160 produced in baculovirus-infected cells. All four animals were protected against an intravenous challenge of the homologous virus at one to nine animal-infectious doses. These results indicate that immunization with viral envelope antigens alone is sufficient to elicit protective immunity against a primate immunodeficiency virus. The combination immunization regimen, similar to one now being evaluated in humans as candidate human immunodeficiency virus (HIV)-1 vaccines, appears to be an effective way to elicit such immune responses.

Lentivirus-induced pulmonary lesions in rhesus monkeys (Macaca mulatta) infected with simian immunodeficiency virus

Necropsy reports from 28 rhesus monkeys that had been experimentally infected with simian immunodeficiency virus (SIV) and that were free of cytomegalovirus were reviewed. Lung sections from 24 of these monkeys that had no etiologic agent other than SIV detected in the lung were studied in detail by histopathologic, immunohistochemical, and electron microscopic examination and by in situ hybridization. Fourteen of the monkeys were part of a serial euthanasia study, while others were euthanatized after they became moribund. The following lesions were detected: perivascular inflammation, vasculitis, interstitial pneumonia, syncytial cells, hemorrhage, fibrin exudation, and pleural fibrosis. Perivascular inflammation was the most frequent lesion and occurred as early as 2 weeks after inoculation. Severe pneumonia and numerous syncytial cells were seen only in animals euthanatized because they had become moribund. The lesions appeared to be directly due to SIV infection. SIV antigens, RNA, and virions were detected in syncytial cells and macrophages by immunohistochemical examination, in situ hybridization, and transmission electron microscopic examination, respectively. The amount of virus present was correlated with the severity of the lesions. The SIV-induced lesions were different from those of the lymphocytic interstitial pneumonia, which occurs in human immunodeficiency virus-infected children and in ovine lentivirus-infected sheep and goats.

Localization of simian immunodeficiency virus in the central nervous system of rhesus monkeys

Simian immunodeficiency virus (SIV), like the human immunodeficiency virus (HIV), is a lentivirus that is both immunosuppressive and neurovirulent. Rhesus macaques (Macaca mulatta) inoculated with SIV often develop a giant cell encephalitis similar to that seen in humans infected with HIV. The authors examined SIV expression by immunohistochemistry and RNA in situ hybridization in the cerebrum, cerebellum, choroid plexus, and spinal cord from five macaques with and two macaques without giant cell encephalitis. Selected portions of the central nervous system (CNS) also were examined by electron microscopy. Simian immunodeficiency virus was detected in the CNS of all seven monkeys whether or not they had giant cell encephalitis. Both SIV antigen and RNA were present in all levels of the CNS examined. Macrophage/giant cell lesions always contained viral RNA and antigen and were the only sites where viral particles were detected by electron microscopy. However, SIV antigen and RNA also were commonly associated with small vessels, the choroid plexus, and meninges; these were the only locations where virus was detected in animals without giant cell encephalitis. Immunophenotyping showed that the cellular infiltrates consisted primarily of monocyte/macrophages and occasional CD8-positive T cells. Macrophages and T cells also were present in the stroma of the choroid plexus and were intimately associated with vessels in the CNS of SIV-infected but not uninfected macaques. Simian immunodeficiency virus infection of the macaque CNS provides an excellent model for studying the pathogenesis, treatment, and prevention of HIV-1-encephalitis.

Protection of macaques with a simian immunodeficiency virus envelope peptide vaccine based on conserved human immunodeficiency virus type 1 sequences

This report describes the vaccination of rhesus macaques with peptides selected from regions of the simian immunodeficiency virus (SIV) envelope that are hydrophilic, immunoreactive, and highly homologous with corresponding conserved envelope sequences of the human immunodeficiency virus (HIV). The peptides, produced as beta-galactosidase fusion proteins, induced virus-neutralizing and peptide-specific antibodies. After challenge with virulent virus, controls became virus positive and developed gradually rising antibody titers to SIV over 63 weeks. Immunized macaques developed a postchallenge anamnestic response to SIVenv antigens within 3-6 weeks followed by a gradual, fluctuating decline in SIV antibody titers and partial or total suppression of detectable SIV. Virus suppression correlated with prechallenge neutralizing antibody titers. Although the average CD4+ cell count in the blood of immunized macaques remained constant, the control macaques exhibited a progressive decrease developing about week 55 after challenge. The conserved nature of the HIV and SIV peptides and the similar humoral immunoreactivity in the respective hosts suggest that homologous HIV peptides may be important components of a successful immunization strategy.

Isolation of a simian immunodeficiency virus related to human immunodeficiency virus type 2 from a west African pet sooty mangabey

Two of 25 healthy pet sooty mangabey (SM) monkeys (Cercocebus atys) living in West Africa were seropositive by immunoblot when surveyed for antibody to simian immunodeficiency virus of macaques (SIVmac). SIVsmLIB1 was isolated from one of the pet sooty mangabeys. Nucleotide sequence data showed that this isolate is a member of the SIVsm/human immunodeficiecy virus type 2 (HIV-2)/SIVmac group of primate lentiviruses. Furthermore, sequence comparisons revealed extensive genetic diversity among SIVsm isolates similar to that observed previously in SIV isolates from naturally infected African green monkeys. These observations provide additional evidence for monkey-human cross-species transmission of SIVsm as the source of HIV-2 infection of human.

Viral and cellular gene expression in CD4+ human lymphoid cell lines infected by the simian immunodeficiency virus, SIV/Mne

Our laboratory has undertaken an analysis of cellular and viral gene expression in CD4+ human lymphoid cell lines infected by the human and simian immunodeficiency viruses, HIV-1 and SIV/Mne, respectively. The purpose of the current study was to: (i) examine the effects of SIV/Mne infection on host macromolecular synthesis and compare the results to those in the HIV-1 system; and (ii) investigate the mechanisms responsible for the restriction of SIV/Mne infection in CD4 positive lymphoid cells which are readily infected by HIV-1. First we determined that SIV does not impose selective blocks on host macromolecular synthesis, unlike HIV-1, which induces both the selective inhibition of cellular protein synthesis and the degradation of cellular mRNAs (Agy, M., Wambach, M., Foy, K., and Katze, M. G., 1990, Virology 177, 251-258). No such selective reduction in cellular mRNA stability or protein synthesis was observed in cells infected by SIV/Mne. Additional differences between SIV and HIV-1 were observed using a panel of CD4+ human cell lines. While HIV-1-infected all cell lines. SIV/Mne efficiently infected only the MT-4, C8166, and 174 x CEM cell lines. Repeated efforts to infect CEM or Jurkat cells were unsuccessful as determined by PCR analysis of viral DNA. HUT 78 cells supported a limited infection detectable only by PCR analysis. These data suggest the block in viral replication in the nonsusceptible cell lines is at an early step. Interestingly, all the SIV susceptible cells were virally transformed, C8166 and MT-4 by HTLV-1, and 174 x CEM by Epstein-Barr virus. Furthermore FACS analysis revealed that all susceptible cells expressed two B cell associated markers, B7/BB1 and CD40. These observations taken together highlight differences between the HIV and SIV viruses, and suggest that for efficient replication, SIV/Mne may require an additional cell surface molecule, cofactors provided by transforming viruses, or a complex interplay between the two.

Generation of a chimeric human and simian immunodeficiency virus infectious to monkey peripheral blood mononuclear cells

We constructed five chimeric clones between human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency virus (SIVMAC) and four SIVMAC mutants by recombinant DNA techniques. Three chimeric clones and all mutants with an alteration in either the vif, vpx, vpr, or nef gene were infectious to human CD4-positive cell lines. The susceptibility of macaque monkey peripheral blood mononuclear cells (PBMC) to infection by these mutants and chimeras was examined in vitro. Macaque PBMC supported the replication of wild-type and vpx, vpr, and nef mutant SIVMAC strains. A chimera carrying the long terminal repeats (LTRs), gag, pol, vif, and vpx of SIVMAC and tat, rev, vpu, and env of HIV-1 was also replication competent in PBMC. In contrast, HIV-1, the vif mutant of SIVMAC, a chimera containing rev and env of SIVMAC, and a chimera containing vpx, vpr, tat, rev, and env of SIVMAC did not grow in PBMC. Western immunoblotting analysis of the replicating chimera in PBMC confirmed the hybrid nature of the virus. These data strongly suggested that the sequence important for macaque cell tropism lies within the LTR, gag, pol, and/or vif sequences of the SIVMAC genome.

The inhibitory activity of a peptide derivative against the growth of simian immunodeficiency virus in C8166 cells

The peptide derivative Ro 31-8959 is a potent and selective inhibitor of the aspartic proteinases encoded by HIV-1 and HIV-2 and it arrests the growth of both viruses in cell culture. We have demonstrated similar effects against the simian immunodeficiency virus SIVmac251 in the human T-cell line, C8166 (ED50 = 6nM) with a therapeutic index of 4,500. The antiviral activity of Ro 31-8959 was 250 and 22 times greater than that of ddI and ddC, respectively. The mode of action was confirmed by accumulation of the polyprotein p55 with concomitant reduction of the cleavage product, p27, and by the production of immature virions.

Neurobiology of simian and feline immunodeficiency virus infections

Experimental and clinical evidence indicates that all lentiviruses of animals and humans are neurotropic and potentially neurovirulent. The prototypic animal lentiviruses, visna virus in sheep and caprine arthritis encephalitis virus in goats have been known for decades to induce neurologic disease. More recently, infection of the brain with the human immunodeficiency virus (HIV) has been linked to an associated encephalopathy and cognitive/motor complex. While the visna virus and caprine arthritis encephalitis virus are important models of neurologic disease they are not optimal for the study of HIV encephalitis because immune deficiency is only a minor component of the disease they induce. By contrast, the recently isolated lentiviruses from monkeys and cats, the simian and feline immunodeficiency viruses (SIV and FIV respectively), are profoundly immunosuppressive as well as neurotropic. SIV infection of the central nervous system of macaques now provides the best animal model for HIV infection of the human brain due to the close evolutionary relationship between monkeys and man, the genetic relatedness of their respective lentiviruses, and the similarities in the neuropathology. This chapter will compare and contrast the neurobiology of SIV and FIV with HIV.

Simian immunodeficiency virus infection of macaque bone marrow macrophages correlates with disease progression in vivo

The pathogenesis of hematopoietic abnormalities associated with infection of susceptible hosts with either simian immunodeficiency virus (SIV) or human immunodeficiency virus (HIV) is not fully understood. To determine if bone marrow cells are infected with SIV and if the pattern of viral infection is correlated with the severity of disease and abnormalities in hematopoiesis, 23 SIV-infected rhesus monkeys were examined by immunohistochemistry and in situ hybridization. By immunohistochemistry, only four monkeys were positive for SIV core protein p27, while in situ hybridization revealed viral RNA in the bone marrow of 15 monkeys. Simian immunodeficiency virus RNA was consistently expressed in the bone marrow from monkeys with severe lymphoid depletion (11 of 11), but less so in monkeys with follicular hyperplasia (0 of 2) or mild lymphoid depletion (4 of 10). In animals with mild lymphoid depletion, bone marrow cells infected with SIV were mainly mononuclear cells that appeared to be of myelomonocytic lineage. In contrast, monkeys with severe lymphoid depletion had SIV RNA localized to larger mononuclear cells with abundant cytoplasm often located in small lucent areas of the stroma. These SIV RNA-positive mononuclear cells were positive for the macrophage determinant CD68 as demonstrated by immunohistochemistry. Furthermore the stage of simian acquired immune deficiency syndrome, as indicated by lymphoid morphology, and SIV localization in the bone marrow were correlated with the incidence of anemia, bone marrow hyperplasia, and abnormal distribution of macrophages in the bone marrow. These results indicate that, in common with other animal lentiviral infections, the macrophage is a major target of SIV infections in the bone marrow.

Nonhuman primate models for evaluation of AIDS therapy

Infection of macaque monkeys with simian immunodeficiency virus (SIV) has been established as an excellent animal model system for studying the pathogenesis of an HIV-like virus and for evaluating newly developed antiretroviral drugs and vaccines. Based on their genetic, antigenic, and biologic properties, the simian immunodeficiency viruses are the closest known relatives of the human AIDS viruses, and experimental infection of macaque monkeys results in a disease that is remarkably similar to human AIDS. Infected macaques show diarrhea, weight loss, hematologic abnormalities including lymphopenia and thrombocytopenia, lymphadenopathy/lymphoid hyperplasia that progresses to lymphoid depletion, immunosuppression with marked reduction in CD4+ cells and in the CD4+/CD8+ cell ratio, and opportunistic infections. A majority of such macaques die from an AIDS-like disease within one to three years of infection. An acutely lethal variant of SIV has been identified that results in death in susceptible macaques within 7-12 days of infection. Preliminary prophylactic treatment trials with AZT in macaque monkeys exposed to the acutely lethal SIV variant indicate that some protection is provided when AZT treatment is initiated within 24 hours of virus exposure. Other studies with the more chronic SIV infection model, however, failed to show any prophylactic efficacy of CS-87, AZT, D4T, or FDT.

Generation and characterization of infectious chimeric clones between human immunodeficiency virus type 1 and simian immunodeficiency virus from an African green monkey

A series of chimeric clones of human immunodeficiency virus type 1 and simian immunodeficiency virus isolated from an African green monkey was constructed in vitro. In transient transfection experiments, all clones produced virion-associated reverse transcriptase, gag proteins, and env proteins. Eight out of 10 chimeric viruses clearly grew in the human CD4+ cell line C8166. Susceptibility of other CD4+ cell lines, MT-4, A3.01, and Molt4 clone 8, to infection with these viruses was also demonstrated.

In vitro screening for antiretroviral agents against simian immunodeficiency virus (SIV)

Simian immunodeficiency virus (SIV), which causes an acquired immunodeficiency syndrome in macaques, is a lentivirus that is morphologically, antigenically, genetically, and biologically similar to the human immunodeficiency virus (HIV). Because of these similarities, the SIV model represents a unique opportunity for in vitro and in vivo testing of antiretroviral agents. Since antiretroviral agents may exhibit different properties in different cells in vitro, more than one cell line may be necessary to evaluate the efficacy and modes of action of an antiretroviral agent. Initially we tested ten cell lines for their permissiveness to five SIV isolates. One B-cell line (AA-2) and one T-cell line (HuT 78) were selected to test antiretroviral agents since both were extremely permissive for SIVmac251, an isolate with a high rate of infectivity. Using this optimized in vitro testing protocol, we screened ten antiretroviral agents for their ability to inhibit SIV replication. Six of the compounds completely inhibited SIV viral antigen expression. Based on the selectivity index, 3'-azido-3'-dideoxythymidine, 3'-azido-2',3'-dideoxyuridine, and 3'-fluoro-3'-deoxythymidine appear to be the most efficacious antiretroviral agents against SIVmac251. Several different assays for determining viral antigen inhibition were conducted and the results of these assays were comparable. Our results demonstrate that the SIV in vitro model is a valuable screening tool for determining the efficacy and toxicity of new antiretroviral agents.

Induction of AIDS in rhesus monkeys by molecularly cloned simian immunodeficiency virus

Better understanding of the pathogenesis of acquired immunodeficiency syndrome (AIDS) would be greatly facilitated by a relevant animal model that uses molecularly cloned virus of defined sequence to induce the disease. Such a system would also be of great value for AIDS vaccine research. An infectious molecular clone of simian immunodeficiency virus (SIV) was identified that induces AIDS in common rhesus monkeys in a time frame suitable for laboratory investigation. These results provide another strong link in the chain of evidence for the viral etiology of AIDS. More importantly, they define a system for molecular dissection of the determinants of AIDS pathogenesis.

Complete nucleotide sequence of a simian immunodeficiency virus from African green monkeys: a novel type of intragroup divergence

We have determined the entire nucleotide sequence of a full-length molecular clone, termed SIVagm3, which is infectious in vitro and in vivo. The genomic organization was found to be similar to other immunodeficiency viruses of human and simian origin. Comparison of SIVagm3 with SIVagmTYO-1, the only other completely sequenced molecular SIVagm clone, revealed a novel type of intragroup divergence, which is characterized by (1) an unusually high degree of variability in pol in relation to gag and env and (2) a high degree of divergence in the rev and tat genes. Thus, since SIVagm3 and SIVagmTYO-1 evolved from their common ancestor, they diverged in a different manner than human immunodeficiency viruses. Hypervariable regions in env were defined and shown to be relatively restricted in comparison to HIV-1 and HIV-2.

Molecularly cloned simian immunodeficiency virus SIVagm3 is highly divergent from other SIVagm isolates and is biologically active in vitro and in vivo

Simian immunodeficiency viruses have been isolated from African green monkeys originating from Ethiopia. A molecular clone, termed SIVagm3, was found to be highly divergent from SIVagmTYO-1 in terms of its restriction map and partial nucleotide sequence. A premature stop codon present in the transmembrane protein of SIVagm TYO-1 was absent in SIVagm3. SIVagm3 was biologically active in vitro and in vivo and displayed characteristics reminiscent of the wild-type virus. Biological activity was demonstrated by seroconversion of juvenile African green monkeys and Macaca nemestrina after inoculation. In contrast to antibody reactivity mainly directed against env proteins in naturally infected African green monkeys. African green monkeys and M. nemestrina infected with the cloned virus showed antibody reactivity directed against all major proteins as demonstrated by immunoblot analysis. The availability of a biologically fully competent molecular clone of SIVagm allows us now to address various pertinent questions in an animal model system which should help to understand features of human immunodeficiency virus infection in human beings.