The simian immunodeficiency virus envelope open reading frame located after the termination codon is expressed in vivo in infected animals

Features of the SIVmac transmembrane glycoprotein cytoplasmic domain that are important for Env functions

The cytoplasmic domain (CD) of the SIVmac transmembrane protein (TM) can affect viral infectivity by modulating several Env functions, notably fusogenic capacity and incorporation into virions. In addition, envelopes with a truncated CD are counterselected in primary cells in culture and in vivo in rhesus macaques, suggesting a role for this domain in viral persistence. Here, we have used mutagenesis to examine specific features of the SIVmac TM CD, including the conserved C-terminal alpha helix and the overall length of the CD. Several mutations dramatically reduced and/or delayed virus infectivity in lymphoid cell lines. Detailed analysis of mutants revealed defects in envelope stability, fusogenic capacity, and virion incorporation. The primary defect associated with an envelope containing a 64-residue CD was rapid degradation. A mutant Env lacking the C-terminal alpha helix but encoding an exceptionally long CD (373 residues) was highly fusogenic but inefficiently incorporated into virions. A third mutant, containing amino acid substitutions designed to alter the charge density of the C-terminal helix, retained cytopathic properties and showed enhanced fusogenic capacity but replicated with delayed kinetics. Taken together, these results demonstrate that CD sequence variation entails functional "tradeoffs" that can involve optimization of certain Env functions at the expense of others.

Genetic and biological comparisons of pathogenic and nonpathogenic molecular clones of simian immunodeficiency virus (SIVmac)

Simian immunodeficiency virus (SIV) is a designation for a group of related but unique lentiviruses identified in several primate species. A viral isolate from a rhesus macaque (i.e., SIVmac) causes a fatal AIDS-like disease in experimentally infected macaques, and several infectious molecular clones of this virus have been characterized. This report presents the complete nucleotide sequence of molecularly cloned SIVmac1A11, and comparisons are made with the sequence of molecularly cloned SIVmac239. SIVmac1A11 has delayed replication kinetics in lymphoid cells but replicates as well as uncloned SIVmac in macrophage cultures. Macaques infected with virus from the SIVmac1A11 clone develop antiviral antibodies, but virus does not persist in peripheral blood mononuclear cells and no disease signs are observed. SIVmac239 infects lymphoid cells, shows restricted replication in cultured macrophages, and establishes a persistent infection in animals that leads to a fatal AIDS-like disease. Both viruses are about 98% homologous at the nucleotide sequence level. In SIVmac1A11, the vpr gene as well as the transmembrane domain of env are prematurely truncated, whereas the nef gene of SIVmac239 is prematurely truncated. Sequence differences are also noted in variable region 1 (V1) in the surface domain of the env gene. The potential implications of these and other sequence differences are discussed with respect to the phenotypes of both viruses. This animal model is critically important for investigating the roles of specific viral genes in viral/host interactions that cannot be studied in individuals infected with the human immunodeficiency virus (HIV).

The human immunodeficiency virus type 2 vpr gene is essential for productive infection of human macrophages

The human immunodeficiency virus (HIV) genetic determinant(s) responsible for tropism in human T cells or macrophages are not well defined. We studied the role of the HIV type 2 (HIV-2) nef and vpr genes in viral tropism. HIV-2 mutants, lacking either vpr or nef genes, or both vpr and nef, were obtained by site-specific mutagenesis of a biologically active HIV-2 proviral clone (HIV-2sbl/isy), which is infectious in both human T cells and macrophages. Viral progeny carrying mutations of nef, vpr, or of both nef and vpr genes replicated more efficiently than the parental virus in primary human peripheral blood cells and in the human Hut 78 T-cell line. In contrast, the HIV-2 nef- mutant infected human macrophages as efficiently as the parental virus, whereas viruses lacking the vpr gene either alone or in conjunction with the lack of the nef gene did not replicate in macrophages. Thus, some lack of nef in HIV-2 enhances viral replication in T cells and does not interfere with viral replication in primary macrophages, whereas vpr is essential for replication of HIV-2 in human macrophages. Because the parental HIV-2sbl/isy cloned virus also infects rhesus macaques, the use in animal studies of these HIV-2 mutants with differences in cell tropism and rates of replication will be highly useful in understanding the mechanism of viral infectivity and possibly pathogenicity in vivo.

Significance of premature stop codons in env of simian immunodeficiency virus

The location of the translational termination codon for the transmembrane protein (TMP) varies in three infectious molecular clones of simian immunodeficiency virus from macaques (SIVmac). The SIVmac251 and SIVmac142 infectious clones have premature stop signals that differ in location by one codon; transfection of these DNAs into human HUT-78 cells yielded virus with a truncated TMP (28 to 30 kilodaltons [kDa]). The SIVmac239 infectious clone does not have a premature stop codon in its TMP-coding region. Transfection of HUT-78 cells with this clone initially yielded virus with a full-length TMP (41 kDa). At 20 to 30 days posttransfection, SIVmac239 virus with a 41-kDa TMP gradually disappeared coincident with the emergence of a virus with a 28-kDa TMP. Virus production dramatically increased in parallel with the emergence of a virus with a 28-kDa TMP. Sequence analysis of viral DNAs from these cultures showed that premature stop codons arising by point mutation were responsible for the change in size of the TMP with time. A similar selective pressure for truncated forms of TMP was observed when the SIVmac239 clone was transfected into human peripheral blood lymphocytes (PBL). In contrast, no such selective pressure was observed in macaque PBL. When the SIVmac239 clone was transfected into macaque PBL and the resultant virus was serially passaged in macaque PBL, the virus replicated very well and maintained a 41-kDa TMP for 80 days in culture. Macaque monkeys were infected with SIVmac239 having a 28-kDa TMP; virus subsequently recovered from T4-enriched lymphocytes of peripheral blood showed only the 41-kDa form of TMP. These results indicate that the natural form of TMP in SIVmac is the full-length 41-kDa TMP, just as in human immunodeficiency virus type 1. Viruses with truncated forms of TMP appear to result from mutation and selection during propagation in unnatural human cells.

An African primate lentivirus (SIVsm) closely related to HIV-2

The ancestors of the human immunodeficiency viruses (HIV-1 and HIV-2) may have evolved from a reservoir of African nonhuman primate lentiviruses, termed simian immunodeficiency viruses (SIV). None of the SIV strains characterized so far are closely related to HIV-1. HIV-2, however, is closely related to SIV (SIVmac) isolated from captive rhesus macaques (Macaca mulatta). SIV infection of feral Asian macaques has not been demonstrated by serological surveys. Thus, macaques may have acquired SIV in captivity by cross-species transmission from an SIV-infected African primate. Sooty mangabeys (Cercocebus atys), an African primate species indigenous to West Africa, however, are infected with SIV (SIVsm) both in captivity and in the wild (P. Fultz, personal communication). We have molecularly cloned and sequenced SIVsm and report here that it is closely related to SIVmac and HIV-2. These results suggest that SIVsm has infected macaques in captivity and humans in West Africa and evolved as SIVmac and HIV-2, respectively.

Identification of the fusion peptide of primate immunodeficiency viruses

Membrane fusion induced by the envelope glycoproteins of human and simian immunodeficiency viruses (HIV and SIVmac) is a necessary step for the infection of CD4 cells and for the formation of syncytia after infection. Identification of the region in these molecules that mediates the fusion events is important for understanding and possibly interfering with HIV/SIVmac infection and pathogenesis. Amino acid substitutions were made in the 15 NH2-terminal residues of the SIVmac gp32 transmembrane glycoprotein, and the mutants were expressed in recombinant vaccinia viruses, which were then used to infect CD4-expressing T cell lines. Mutations that increased the overall hydrophobicity of the gp32 NH2-terminus increased the ability of the viral envelope to induce syncytia formation, whereas introduction of polar or charged amino acids in the same region abolished the fusogenic function of the viral envelope. Hydrophobicity in the NH2-terminal region of gp32 may therefore be an important correlate of viral virulence in vivo and could perhaps be exploited to generate a more effective animal model for the study of acquired immunodeficiency syndrome.

Molecular and biological characterization of a replication competent human immunodeficiency type 2 (HIV-2) proviral clone

We obtained complete genomic clones of human immunodeficiency virus type 2 (HIV-2) from the DNA of the neoplastic human cell line HUT 78 freshly infected with a HIV-2 isolate, strain SBL6669. The recombinant phage DNA was transfected into the lymphocytes of CD4-positive HUT 78 cell line to test the replication competence of the proviral DNA. One genomic clone, designated HIV-2SBL/ISY, yielded retroviral particles after a few weeks of culture of the transfected cells. The HIV-2SBL/ISY clone contained a complete provirus and cellular flanking sequence. We obtained the DNA sequence of the provirus and compared it with the published sequence of two other HIV-2 isolates. The degree of variability among HIV-2 isolates is comparable to that observed among African HIV-1 isolates sequenced to date. Immunologically, HIV-2SBL/ISY is similar to the parental virus (HIV-2SBL6669) but differs in the envelope transmembrane protein that is truncated (gp32-34) in the parental virus and not in HIV-2SBL/ISY (gp41). Both the parental and the cloned viruses are infectious and cytopathic for some human T-cell lines, induce syncytia, and infect a human macrophage cell line (U937) in vitro. The availability of a biologically active HIV-2 clone provides the means to study the role and interaction of HIV-2 genes in vitro as well as to assess the functional similarities among HIV-1 and HIV-2 genes. Since HIV-2SBL/ISY cloned virus infects fresh peripheral blood T cells from Rhesus macaques in vitro and infects the same animal in vivo, its use in animals may represent a model for functional study of viral genes in vivo as well as for development of experimental approaches to prevent and cure retroviral infection in humans.