Antigenic variations in the CD4 induced sites of the CCR5-tropic, pathogenic SHIVsf162p3 gp120 variants.

In vivo passage of non-pathogenic, CCR5-tropic simian/human immunodeficiency virus (SHIV) - SHIVsf162 resulted in a pathogenic isolate, SHIVsf162p3. In an attempt to characterize envelope (Env)-mediated properties that may contribute to its pathogenicity, major (P3 major) and minor (P3 minor) Env gp120 variants were cloned from the plasma of a SHIVsf162p3-infected animal, and expressed in the context of luciferase reporter viruses. Entry mediated by these envelopes and susceptibility to neutralization by CD4 induced-site (CD4i) antibodies (MAbs) was analyzed in comparison to parental SF162. Sequence analysis revealed that the P3 major and minor variant Envs contained 14 and 17 amino acid changes, respectively, compared with SF162. The rank order of entry mediated by the three envelopes was P3 major > SF162 > P3 minor, whereas the reverse order was observed for susceptibility to neutralization by CD4i MAbs. Since CD4i epitopes overlap the coreceptor (CoR) binding site, these findings suggest that the amino acid changes accumulated upon in vivo passage of SHIVsf162 result in Env gp120 structural rearrangements that modulate the exposure and/or conformation of the CoR binding site. This, in turn, led to increased entry and infectivity of the P3 major variant and may be responsible, in part, for the enhanced pathogenicity of SHIVsf162p3.

Infection of macaques with a molecular clone, SHIVSF33A2, provides evidence for tissue specific variants.

Infection of rhesus macaques with chimeric simian-human immunodeficiency viruses (SHIV) is an established model to study acquired immunodeficiency syndrome (AIDS) pathogenesis. Such a controlled system allows for detailed analysis of the molecular determinants of viral pathogenesis in addition to studying host-specific immune responses that modulate disease progression. Furthermore, the use of a pathogenic molecular clone affords the opportunity to study both viral evolution within a host and to examine the generation of tissue specific variants. In this report we describe viral diversification within tissues of two rhesus macaques infected intravenously with the CXCR4-specific molecular clone SHIVSF33A2. Heteroduplex tracking analysis (HTA) was used to determine the complexity of viral DNA within distinct lymphoid tissues. Not surprising, heterogeneity of the proviral quasispecies in tissues obtained during the acute infection was limited. However, tissues obtained at necropsy harbored a more diverse and often different population of env variants. As the inoculating virus is a molecular clone, the variants generated are likely due to the presence of tissue specific selective forces rather than a founder's effect.

Human T cell leukemia virus type 1 Tax associates with a molecular chaperone complex containing hTid-1 and Hsp70.

Tax, an oncogenic viral protein encoded by human T cell leukemia virus type 1 (HTLV-1), induces cellular transformation of T lymphocytes by modulating a variety of cellular gene expressions [1]. Identifying cellular partners that interact with Tax constitutes the first step toward elucidating the molecular basis of Tax-induced transformation. Here, we report a novel Tax-interacting protein, hTid-1. hTid-1, a human homolog of the Drosophila tumor suppressor protein Tid56, was initially characterized based on its interaction with the HPV-16 E7 oncoprotein [2]. hTid-1 and Tid56 are members of the DnaJ family [2,3], which contains a highly conserved signature J domain that regulates the activities of heat shock protein 70 (Hsp70) by serving as cochaperone [4-6]. In this context, the molecular chaperone complex is involved in cellular signaling pathways linked to apoptosis, protein folding, and membrane translocation and in modulation of the activities of tumor suppressor proteins, including retinoblastoma, p53, and WT1[7-12]. We find that expression of hTid-1 inhibits the transformation phenotype of two human lung adenocarcinoma cell lines. We show that Tax interacts with hTid-1 via a central cysteine-rich domain of hTid-1 while a signature J domain of hTid-1 mediates its binding to Hsp70 in HEK cells. Importantly, Tax associates with the molecular chaperone complex containing both hTid-1 and Hsp70 and alters the cellular localization of hTid-1 and Hsp70. In the absence of Tax, expression of the hTid-1/Hsp70 molecular complex is targeted to perinuclear mitochondrial clusters. In the presence of Tax, hTid-1 and its associated Hsp70 are sequestered within a cytoplasmic "hot spot" structure, a subcellular distribution that is characteristic of Tax in HEK cells.

Evidence for similar recognition of the conserved neutralization epitopes of human immunodeficiency virus type 1 envelope gp120 in humans and macaques.

We compared the immune responses to the human immunodeficiency virus type 1 (HIV-1) envelope glycoproteins in humans and macaques with the use of clade A and clade B isogenic V3 loop glycan-possessing and -deficient viruses. We found that the presence or absence of the V3 loop glycan affects to similar extents immune recognition by a panel of anti-HIV human and anti-simian/human immunodeficiency virus (anti-SHIV) macaque sera. All sera tested neutralized the glycan-deficient viruses, in which the conserved CD4BS and CD4i epitopes are more exposed, better than the glycan-containing viruses. The titer of broadly neutralizing antibodies appears to be higher in the sera of macaques infected with glycan-deficient viruses. Collectively, our data add legitimacy to the use of SHIV-macaque models for testing the efficacy of HIV-1 Env-based immunogens. Furthermore, they suggest that antibodies to the CD4BS and CD4i sites of gp120 are prevalent in human and macaque sera and that the use of immunogens in which these conserved neutralizing epitopes are more exposed is likely to increase their immunogenicity.

Antibody protects macaques against vaginal challenge with a pathogenic R5 simian/human immunodeficiency virus at serum levels giving complete neutralization in vitro.

A major unknown in human immunodeficiency virus (HIV-1) vaccine design is the efficacy of antibodies in preventing mucosal transmission of R5 viruses. These viruses, which use CCR5 as a coreceptor, appear to have a selective advantage in transmission of HIV-1 in humans. Hence R5 viruses predominate during primary infection and persist throughout the course of disease in most infected people. Vaginal challenge of macaques with chimeric simian/human immunodeficiency viruses (SHIV) is perhaps one of the best available animal models for human HIV-1 infection. Passive transfer studies are widely used to establish the conditions for antibody protection against viral challenge. Here we show that passive intravenous transfer of the human neutralizing monoclonal antibody b12 provides dose-dependent protection to macaques vaginally challenged with the R5 virus SHIV(162P4). Four of four monkeys given 25 mg of b12 per kg of body weight 6 h prior to challenge showed no evidence of viral infection (sterile protection). Two of four monkeys given 5 mg of b12/kg were similarly protected, whereas the other two showed significantly reduced and delayed plasma viremia compared to control animals. In contrast, all four monkeys treated with a dose of 1 mg/kg became infected with viremia levels close to those for control animals. Antibody b12 serum concentrations at the time of virus challenge corresponded to approximately 400 (25 mg/kg), 80 (5 mg/kg), and 16 (1 mg/kg) times the in vitro (90%) neutralization titers. Therefore, complete protection against mucosal challenge with an R5 SHIV required essentially complete neutralization of the infecting virus. This suggests that a vaccine based on antibody alone would need to sustain serum neutralizing antibody titers (90%) of the order of 1:400 to achieve sterile protection but that lower titers, around 1:100, could provide a significant benefit. The significance of such substerilizing neutralizing antibody titers in the context of a potent cellular immune response is an important area for further study.

Pathogenic determinants of the mucosally transmissible CXCR4-specific SHIV(SF33A2) map to env region.

Infection of rhesus macaques with chimeric simian-human immunodeficiency viruses (SHIV) is an established method to study AIDS pathogenesis and is increasingly used to assess the efficacy of vaccine and antiviral candidates. For these reasons, a detailed understanding of those molecular determinants, which confer pathogenic potential to SHIV viruses, should assist in both rational experimental design and interpretation of results. In this report, we describe the development and in vivo characterization of a pathogenic molecular clone, SHIVSF33A2, which contains an envelope sequence derived from the CXCR4-dependent isolate, HIV-1SF33. Proviral DNA, amplified from a rhesus macaque infected with the pathogenic isolate SHIVSF33A, was substituted into the corresponding region of the parental, nonpathogenic SHIVSF33 genome creating the molecular clone SHIVSF33A2. Coreceptor specificity of SHIVSF33A2 was determined to be CXCR4 specific. Naive rhesus macaques were productively infected after a single exposure to cell-free SHIVSF33A2 by either the intravenous (IV) or intravaginal (IVAG) routes. Animals infected with SHIVSF33A2 suffered a severe loss of peripheral CD4+ T cells and high acute plasma viremia with development of simian AIDS 9 months after inoculation. Sequence analysis identified 25 discreet amino acid changes within the V1-V5 regions of the envelope protein when compared with the nonpathogenic parental virus. These data indicate that domains within the HIV-1 envelope protein are sufficient to define pathogenic potential in the context of the SIVmac239 genome.

Mucosal transmission and induction of simian AIDS by CCR5-specific simian/human immunodeficiency virus SHIV(SF162P3).

Nonhuman primate models are increasingly used in the screening of candidate AIDS vaccine and immunization strategies for advancement to large-scale human trials. The predictive value of such macaque studies is largely dependent upon the fidelity of the model system in mimicking human immunodeficiency virus (HIV) type 1 infection in terms of viral transmission, replication, and pathogenesis. Herein, we describe the efficient mucosal transmission of a CCR5-specific chimeric simian/human immunodeficiency virus, SHIV(SF162P3). Female rhesus macaques were infected with SHIV(SF162P3) after a single atraumatic application to the cervicovaginal mucosa. The disease course of SHIV(SF162P3)-infected monkeys is similar and as varied as natural HIV infection in terms of viral replication, gradual loss of CD4(+) peripheral blood mononuclear cells, and the development of simian AIDS-defining opportunistic infections. The SHIV(SF162P3)/macaque model should facilitate direct preclinical assessment of HIV vaccine strategies in addition to antiviral compounds directed towards envelope target cell interactions. Furthermore, this controlled model provides the setting to investigate immunologic responses and putative host-specific susceptibility factors that alter viral transmission and subsequent disease progression.

The N-terminal V3 loop glycan modulates the interaction of clade A and B human immunodeficiency virus type 1 envelopes with CD4 and chemokine receptors.

We investigated the underlying mechanism by which the highly conserved N-terminal V3 loop glycan of gp120 conferred resistance to neutralization of human immunodeficiency virus type 1 (HIV-1). We find that the presence or absence of this V3 glycan on clade A and B viruses accorded various degrees of susceptibility to neutralization by antibodies to the CD4 binding site, CD4-induced epitopes, and chemokine receptors. Our data suggest that this carbohydrate moiety on gp120 blocks access to the binding site for CD4 and modulates the chemokine receptor binding site of phenotypically diverse clade A and clade B isolates. Its presence also contributes to the masking of CD4-induced epitopes on clade B envelopes. These findings reveal a common mechanism by which diverse HIV-1 isolates escape immune recognition. Furthermore, the observation that conserved functional epitopes of HIV-1 are more exposed on V3 glycan-deficient envelope glycoproteins provides a basis for exploring the use of these envelopes as vaccine components.

Age-dependent changes in T cell homeostasis and SIV load in sooty mangabeys.

Sooty mangabeys (Cercocebus atys) showed age-dependent changes in T cell regeneration. Younger animals had a high percentage of CD4+ CD45RA + T cells and a high concentration of T cell receptor excisional circles (TRECs) in peripheral blood, which indicated active thymopoiesis. In contrast, older animals had an increased T cell turnover, which suggested that most T cell production occurred in the periphery. In addition, the number of peripheral CD4+ T cells naturally decreased with age. Non-pathogenic SIVsm infection did not significantly change the T cell proliferation rate or the TREC concentration, though it did cause a moderate loss of peripheral CD4 + T cells. The viral load correlated negatively with age, which could be accounted for by the reduced availability of CD4 + target cells in older mangabeys. Thus, the number of susceptible target cells may be a limiting factor in natural SIV infection.

Human immunodeficiency virus type 1 envelope epitope-specific CD4(+) T lymphocytes in simian/human immunodeficiency virus-infected and vaccinated rhesus monkeys detected using a peptide-major histocompatibility complex class II tetramer.

A tetrameric recombinant major histocompatibility complex (MHC) class II-peptide complex was used to quantitate human immunodeficiency virus type 1 (HIV-1) envelope (Env)-specific CD4(+) T cells in vaccinated and in simian/human immunodeficiency virus (SHIV)-infected rhesus monkeys. A rhesus monkey MHC class II DR molecule, Mamu-DR*W201, and an HIV-1 Env peptide (p46) were employed to construct this tetrameric complex. A p46-specific proliferative response was seen in sorted, tetramer-binding, but not nonbinding, CD4(+) T cells, directly demonstrating that this response was mediated by the epitope-specific lymphocytes. Although staining of whole blood from 10 SHIV-infected Mamu-DR*W201(+) rhesus monkeys failed to demonstrate tetramer-binding CD4(+) T cells (<0.02%), p46-stimulated peripheral blood mononuclear cells (PBMCs) from 9 of these 10 monkeys had detectable p46 tetramer-binding cells, comprising 0.5 to 15.2% of the CD4(+) T cells. p46-stimulated PBMCs from 7 of 10 Mamu-DR*W201(+) monkeys vaccinated with a recombinant canarypox virus-HIV-1 env construct also demonstrated p46 tetramer-binding cells, comprising 0.9 to 7.2% of the CD4(+) T cells. Thus, Env p46-specific CD4(+) T cells can be detected by tetrameric Mamu-DR*W201-p46 complex staining of PBMCs in both SHIV-infected and vaccinated rhesus monkeys. These epitope-specific cell populations appear to be present in peripheral blood at a very low frequency.

Generation and structural analysis of soluble oligomeric gp140 envelope proteins derived from neutralization-resistant and neutralization-susceptible primary HIV type 1 isolates.

We generated DNA constructs expressing soluble truncated forms of the envelope of SF162, a neutralization-resistant primary human immunodeficiency virus type 1 isolate, and SF162AV2, a neutralization-susceptible virus derived from SF162 after the deletion of 30 amino acids from the V2 loop. The constructs express the entire gp120 subunit and the extracellular region of the gp41 subunit, with either the presence ("cleaved" forms, designated gp140C) or the absence ("fused" forms, designated gp140F) of the gp120-gp41 cleavage site. Both gp140 forms derived from SF162 and SF162deltaV2 are secreted in the cell medium and are recognized by the oligomer-specific anti-gp41 MAb T4. As is the case for the corresponding virion-associated envelope molecules, the CD4-binding region is occluded within both gp140F and gp140C forms. However, structural differences exist between these two forms. The gp140F proteins are less efficiently recognized than the gp140C proteins by antibodies present in the sera of HIV-infected patients with neutralizing activities against SF162 and SF162AV2. Also, the V3 loop is more exposed on gp140F than gp140C. As is the case for intact virions, on CD4 binding both the gp140F and gp140C proteins undergo conformational changes that result in the exposure of the epitope recognized by MAb 17b, which has been implicated in coreceptor binding. In contrast, during these structural changes the exposure of specific V3 loop epitopes is not increased on either gp140C or gp140F. Taken together, our data indicate that although these gp140 forms differ structurally from the native envelope, their similarities, in particular that of gp140C, outweigh their differences.

Normal T-cell turnover in sooty mangabeys harboring active simian immunodeficiency virus infection.

Sooty mangabeys naturally infected with simian immunodeficiency virus (SIV) remain healthy though they harbor viral loads comparable to those in rhesus macaques that progress to AIDS. To assess the immunologic basis of disease resistance in mangabeys, we compared the effect of SIV infection on T-cell regeneration in both monkey species. Measurement of the proliferation marker Ki-67 by flow cytometry showed that mangabeys harbored proliferating T cells at a level of 3 to 4% in peripheral blood irrespective of their infection status. In contrast, rhesus macaques demonstrated a naturally high fraction of proliferating T cells (7%) that increased two- to threefold following SIV infection. Ki-67(+) T cells were predominantly CD45RA(-), indicating increased proliferation of memory cells in macaques. Quantitation of an episomal DNA product of T-cell receptor alpha rearrangement (termed alpha1 circle) showed that the concentration of recent thymic emigrants in blood decreased with age over a 2-log unit range in both monkey species, consistent with age-related thymic involution. SIV infection caused a limited decrease of alpha1 circle numbers in mangabeys as well as in macaques. Dilution of alpha1 circles by T-cell proliferation likely contributed to this decrease, since alpha1 circle numbers and Ki-67(+) fractions correlated negatively. These findings are compatible with immune exhaustion mediated by abnormal T-cell proliferation, rather than with early thymic failure, in SIV-infected macaques. Normal T-cell turnover in SIV-infected mangabeys provides an explanation for the long-term maintenance of a functional immune system in these hosts.

A method of video-assisted thoracoscopic surgery for collection of thymic biopsies in rhesus monkeys (Macaca mulatta).

To support an infectious disease study, we developed a surgical procedure to collect serial thymic biopsies in rhesus monkeys (Macaca mulatta). In many instances in which thymic tissue is required from living animals, open surgical approaches (thoracotomies) are used, which result in greater postoperative pain and longer recovery periods than those associated with thoracoscopic procedures. Our intent was to develop a surgical procedure that allowed serial biopsy of the thymus with minimal surgical morbidity. We modified a previously published experimental method of thoracoscopic total thymectomy in the dog to collect thymic biopsies in M. mulatta. Of the 15 animals evaluated, 8 underwent two biopsy procedures separated by a 5- to 6-week interoperative interval. The other seven animals underwent a single biopsy procedure. Thymic tissue was collected successfully during all procedures, with an average surgical time of 15 min. No significant intra- or postoperative complications were noted, and the animals recoveries from the surgical procedures were uneventful. Minimally invasive thoracoscopic surgical techniques can be used successfully to collect thymic tissue from adult and juvenile rhesus monkeys with minimal surgical morbidity.

In vivo adaptation of SHIV(SF162): chimeric virus expressing a NSI, CCR5-specific envelope protein.

The chemokine receptor CCR5 is known to be a critical determinant of human immunodeficiency virus (HIV) transmission and pathogenesis in the human host. Towards the development of a macaque model to evaluate the efficacy of vaccines and therapeutics against infection with CCR5-specific viruses, and to delineate the pathogenic properties of such viruses, we constructed a chimeric simian human immunodeficiency virus, SHIV(SF162), containing the env, tat, rev, and vpu genes from HIV-1(SF162) (R5, MT/NSI) in the context of the molecular clone simian immunodeficiency virus, SIV(mac239). Virus generated from this molecular clone was used to intravenously infect two juvenile macaques, followed by three consecutive serial blood/bone marrow transfusions. Animals infected with parental SHIV(SF162) (P1) had detectable levels of viral replication (as determined by p27(gag) production) within days of infection; however, viral set-points fell below detection by Week 3. Late passage animals (P3 and P4) had a two-log increase in the level of plasma p27(gag) antigen. These results demonstrate that in vivo serial passage of the R5-specific SHIV(SF162) enhanced its replicative capacity.

Activation of the PAK-related kinase by human immunodeficiency virus type 1 Nef in primary human peripheral blood lymphocytes and macrophages leads to phosphorylation of a PIX-p95 complex.

Human immunodeficiency virus type 1 (HIV-1) Nef enhances virus replication in both primary T lymphocytes and monocyte-derived macrophages. This enhancement phenotype has been linked to the ability of Nef to modulate the activity of cellular kinases. We find that despite the reported high-affinity interaction between Nef and the Src kinase Hck in vitro, a Nef-Hck interaction in the context of HIV-1-infected primary macrophages is not detectable. However, Nef binding and activation of the PAK-related kinase and phosphorylation of its substrate could be readily detected in both infected primary T lymphocytes and macrophages. Furthermore, we show that this substrate is a complex composed of the recently characterized PAK interacting partner PIX (PAK-interacting guanine nucleotide exchange factor) and its tightly associated p95 protein. PAK and PIX-p95 appear to be differentially activated and phosphorylated depending on the intracellular environment in which nef is expressed. These results identify the PIX-p95 complex as a novel effector of Nef in primary cells and suggest that the regulation of the PAK signaling pathway may differ in T cells and macrophages.

Fatal immunopathogenesis by SIV/HIV-1 (SHIV) containing a variant form of the HIV-1SF33 env gene in juvenile and newborn rhesus macaques.

SIV/HIV-1 (SHIV) chimeric clones, constructed by substituting portions of the pathogenic molecular clone SIVmac239 with counterpart portions from HIV-1 clones, provide a means to analyze functions of selected HIV-1 genes in vivo in nonhuman primates. Our studies focused on SHIVSF33, which contains the vpu, tat, rev, and env genes of the cytopathic, T-cell line tropic clone HIV-1sf33 (subtype-B); this clone has a premature stop codon in the vpu gene. In three juvenile macaques inoculated intravenously with SHIVSF33, low-level persistent infection was established; no disease was observed for a period of >2 years. However, at approximately 16 months p.i., one of four SHIVSF33-infected juvenile macaques exhibited an increase in virus load, depletion of CD4(+) T cells in peripheral blood and lymph nodes, and other symptoms of simian AIDS (SAIDS). Virus recovered from this animal in the symptomatic stage was designated SHIVSF33a (A, adapted); this virus displayed multiple amino acid sequence changes throughout the HIV-1 env gene compared with the input SHIVSF33 clone. Additionally, a mutation in all clones from SHIVSF33a restored the open reading frame for the vpu gene. In vitro evaluations in tissue-culture systems revealed that SHIVSF33a replicated to higher levels and exhibited greater cytopathicity than SHIVSF33. Furthermore cloned env genes for SHIVSF33a were more fusogenic in a cell-fusion assay compared with the env gene of the SHIVSF33. Intravenous inoculation of SHIVsf33a into juvenile and newborn macaques resulted in a rapid decline in CD4(+) T cells to very low levels and development of a fatal AIDS-like disease. A cell-free preparation of this pathogenic chimeric virus also established persistent infection when applied to oral mucosal membranes of juvenile macaques and produced a fatal AIDS-like disease. These studies on pathogenic SHIVSF33a establish the basis for further investigations on the role of the HIV-1 env gene in virus adaptation and in mechanism(s) of immunodeficiency in primates; moreover, the chimeric virus SHIVSF33a can play a role in elucidating mucosal membrane transmission and development of antiviral vaccines in newborns as well as juvenile and adult macaques.

Selection for neutralization resistance of the simian/human immunodeficiency virus SHIVSF33A variant in vivo by virtue of sequence changes in the extracellular envelope glycoprotein that modify N-linked glycosylation.

We previously reported on the in vivo adaptation of an infectious molecular simian/human immunodeficiency virus (SHIV) clone, SHIVSF33, into a pathogenic biologic viral variant, designated SHIVSF33A. In the present study, we show that SHIVSF33A is resistant to neutralization by human immunodeficiency virus (HIV) and SHIV antisera. Multiple amino acid substitutions accumulated over time throughout the env gene of SHIVSF33A; some of them coincided with the acquisition of the neutralization resistance of the virus. Of interest are changes that resulted in the removal, repositioning, and addition of potential glycosylation sites within the V1, V2, and V3 regions of envelope gp120. To determine whether potential glycosylation changes within these principal neutralization domains of HIV type 1 formed the basis for the resistance to serum neutralization of SHIVSF33A, mutant viruses were generated on the backbone of parental SHIVSF33 and tested for their neutralization sensitivity. The mutations generated did not alter the in vitro replication kinetics or cytopathicity of the mutant viruses in T-cell lines. However, the removal of a potential glycosylation site in the V1 domain or the creation of such a site in the V3 domain did allow the virus to escape serum neutralization antibodies that recognized parental SHIVSF33. The combination of the V1 and V3 mutations conferred an additive effect on neutralization resistance over that of the single mutations. Taken together, these data suggest that (i) SHIV variants with changes in the Env SU can be selected in vivo primarily by virtue of their ability to escape neutralizing antibody recognition and (ii) carbohydrates play an important role in conferring neutralization escape, possibly by altering the structure of envelope gp120 or by shielding principal neutralization sites.

Distinct pathogenic sequela in rhesus macaques infected with CCR5 or CXCR4 utilizing SHIVs.

Infection of macaques with chimeric simian-human immunodeficiency virus (SHIV) provides an excellent in vivo model for examining the influence of envelope on HIV-1 pathogenesis. Infection with a pathogenic CCR5 (R5)-specific enveloped virus, SHIVSF162P, was compared with infection with the CXCR4 (X4)-specific SHIVSF33A.2. Despite comparable levels of viral replication, animals infected with the R5 and X4 SHIV had distinct pathogenic outcomes. SHIVSF162P caused a dramatic loss of CD4+ intestinal T cells followed by a gradual depletion in peripheral CD4+ T cells, whereas infection with SHIVSF33A.2 caused a profound loss in peripheral T cells that was not paralleled in the intestine. These results suggest a critical role of co-receptor utilization in viral pathogenesis and provide a reliable in vivo model for preclinical examination of HIV-1 vaccines and therapeutic agents in the context of the HIV-1 envelope protein.

In vitro infection of primate PBMC with simian/human immunodeficiency virus, SHIV(SF33A): correlation to in vivo outcome.

The macaque/SIV animal system is an important model for studying AIDS pathogenesis and for evaluating the efficacy of vaccines and anti-viral therapeutics. However, differences between HIV-1 and SIV envelope proteins exist that render the SIV/macaque model of limited value when examining envelope determinants of retroviral pathogenesis. To overcome this problem, we utilized a chimeric virus, SHIV(SF33), containing the env gene from HIV-1SF33 in the context of the molecular clone SIVmac239, in the macaque animal model. In this study SHIV(SF33A), a pathogenic virus that evolved in vivo from a rhesus macaque infected intravenously with the molecular clone SHIV(SF33) was used in both in vitro and in vivo studies. By using a cell culture system, we examined the biological properties of our parental and animal-adapted chimeric viruses and compared in vitro susceptibility to in vivo studies.