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).

Analysis of the rhesus cytomegalovirus immediate-early gene promoter.

A cytomegalovirus (CMV) isolate has been recovered from a rhesus macaque (Macaca mulatta) experimentally infected with simian immunodeficiency virus. The full-length immediate-early gene (IE) was cloned from a genomic library of this primary rhesus CMV isolate (RhCMV) using the African green monkey (AGM) CMV IE gene as probe. The promoter region and the first non-coding exon of the RhCMV IE gene have been sequenced. Nucleotide sequence comparisons from positions -733 to +625 (relative to the start site of transcription at +1) reveal 70 and 48% sequence homology with the AGM CMV IE and the human CMV (HCMV) IE genes, respectively. A region that includes the TATA box, the cis repression signal and the first exon in the RhCMV IE gene sequence is 91 and 76% homologous with the AGM CMV and HCMV IE genes, respectively. In permissive MRC-5 cells infected with RhCMV, synthesis of RNA from the IE gene peaks at 4-8 hr post infection. These studies provide a basis for elucidating molecular mechanisms regulating expression of the RhCMV IE gene and viral replication.

Identification of the simian foamy virus transcriptional transactivator gene (taf).

Simian foamy virus type 1 (SFV-1), a member of spumavirus subfamily of retroviruses, encodes a transcriptional transactivator that functions to strongly augment gene expression directed by the viral long terminal repeat (LTR). The objective of this study was to identify the viral gene responsible for transactivation. Nucleotide sequences between the env gene and the LTR of SFV-1 were determined. The predicted amino acid sequence revealed two large open reading frames (ORFs), designated ORF-1 (311 amino acids) and ORF-2 (422 amino acids). In the corresponding region of the human foamy virus, three ORFs (bel-1, bel-2, and bel-3) have been identified (R. M. Flugel, A. Rethwilm, B. Maurer, and G. Darai, EMBO J. 6:2077-2084, 1987). Pairwise comparisons of the ORF-1 and ORF-2 with bel-1 and bel-2 show small clusters of homology; less than 39% overall homology of conserved amino acids is observed. A counterpart for human foamy virus bel-3 is not present in the SFV-1 sequence. Three species of viral RNA have been identified in cells infected with SFV-1; an 11.5-kb RNA representing full-length transcripts, a 6.5-kb RNA representing the env message, and a 2.8-kb RNA from the ORF region. Analysis of a cDNA clone encoding the ORF region of SFV-1 reveals that the 2.8-kb message is generated by complex splicing events involving the 3' end of the env gene. In transient expression assays in cell lines representing several species. ORF-1 was shown to be necessary and sufficient for transactivating viral gene expression directed by the SFV-1 LTR. The target for transactivation is located in the U3 domain of the LTR, upstream from position - 125 (+ 1 represents the transcription initiation site). We propose that OFF-1 of SFV-1 be designated the transcriptional transactivator of foamy virus (taf).

Cellular factors regulate transactivation of human immunodeficiency virus type 1.

It is hypothesized that the immediate-early (IE) gene products of human cytomegalovirus (CMV) and the transactivator (TAT) of human immunodeficiency virus type 1 (HIV-1) regulate HIV-1 gene expression through mechanisms involving host cell factors. By using transient transfection assays with the gene for chloramphenicol acetyltransferase (CAT) under the transcriptional control of the HIV-1 long terminal repeat (LTR), we examined transactivation of the LTR by plasmids that express either the HIV-1 gene for TAT or human CMV IE. The ratio of the level of transactivation by CMV IE to the level of transactivation by TAT varied up to 1,000-fold between cell types. The difference in the activities of these transactivators in various cell types was not a consequence of differential expression of the transactivator gene. Analysis of RNA species initiated in the HIV-1 LTR supports the conclusion that cellular factors regulate the level of elongation of the transcription complex on the LTR. Furthermore, evidence that in some cell types the predominant mechanism of transactivation by HIV-1 TAT involves posttranscriptional processes is presented.

Simian foamy virus type 1 is a retrovirus which encodes a transcriptional transactivator.

Simian foamy viruses, members of the spumavirus subfamily of retroviruses, are found in a variety of nonhuman primates and, as yet, remain to be characterized with respect to genetic structure and regulation of viral gene expression. The genome of simian foamy virus type 1 (SFV-1), an isolate from rhesus macaques, has been molecularly cloned, and the role of the viral long terminal repeat (LTR) in transcriptional control has been investigated. The SFV-1 LTR is 1,621 base pairs long, and sequence comparisons with human foamy virus revealed a pattern of clustered homology. A cap site in the LTR was identified by analysis of SFV-1 transcripts in infected cells. Transient expression assays in cell lines representing several species and different cell types showed that the SFV-1 LTR has low basal activity in uninfected cells, whereas LTR-directed expression is greatly increased in cells infected with SFV-1. This transactivation is mediated by a mechanism involving increases in steady-state levels of viral transcripts. Thus, the SFV-1 genome encodes a transactivator that functions on the LTR at the transcriptional level.

Cytomegalovirus activates transcription directed by the long terminal repeat of human immunodeficiency virus type 1.

Proteins encoded by a variety of DNA viruses activate gene expression from the promoter within the long terminal repeat (LTR) of the human immunodeficiency virus type 1 (HIV-1). The mechanism by which immediate-early (IE) gene products of human cytomegalovirus (CMV) activate expression from the HIV-1 LTR was examined in transient expression assays in cultures of human cells by using plasmids containing the LTR linked to the bacterial chloramphenicol acetyltransferase (CAT) gene and a plasmid expressing the CMV IE gene. Analysis of clustered site mutations within the HIV-1 LTR revealed that sequences from nucleotides -6 to +20 (relative to the start site of transcription) are critical for responsiveness to transactivation by CMV IE gene products. This region partially overlaps the trans-acting response element (+19 to +42) required for function of the HIV-1 transactivator. The CMV IE gene was shown to increase the steady-state levels of both prematurely terminated and full-length transcripts initiated within the LTR. These results support a model in which CMV IE gene products act through a specific regulatory element in the HIV-1 LTR to increase viral transcription.

cis-acting regulatory regions in the long terminal repeat of simian foamy virus type 1.

Simian foamy virus type 1 (SFV-1), a member of the Spumavirinae subfamily of retroviruses, encodes a transcriptional transactivator (taf) that strongly augments gene expression directed by the viral long terminal repeat (LTR) (A. Mergia, K. E. S. Shaw, E. Pratt-Lowe, P. A. Barry, and P. A. Luciw, J. Virol. 65:2903-2909, 1991). This report describes cis-acting regulatory elements in the LTR that control viral gene expression. A series of LTR mutants and hybrid promoter constructs have been analyzed in transient expression assays for responsiveness to Taf. The targets for transactivation have been mapped to two regions of the U3 domain of the LTR, between positions -1196 and -880 and between positions -403 and -125 (+1 represents the transcription initiation site). No significant nucleotide sequence homology between these two regions is noted; thus, the SFV-1 taf gene acts through at least two distinct sequence elements in the LTR. The target contained between positions -403 and -125 acts independently of orientation, in different cell types and species, and in the context of a heterologous promoter. Thus, the target element between positions -403 and -125 has properties of a transcriptional enhancer. The observation that two distinct elements in the SFV-1 LTR are targets for transcriptional transactivation is novel with respect to observations for other retroviral systems. The R-U5 region of the SFV-1 LTR down-regulates transactivation by severalfold. Computer analysis of the R-U5 region revealed a secondary structure with a free-energy level of -74 kcal (ca. -310,000 J); this structural feature may account for the inhibitory effect on gene expression directed by the LTR. Taf of SFV-1 had no effect on gene expression directed by the LTR of the related human foamy virus, whereas Taf transactivates gene expression directed by the LTRs of the human and simian immunodeficiency viruses. Comparative functional analysis of Taf on homologous and heterologous LTRs may facilitate elucidation of the mechanism of transactivation of foamy viruses.

Persistent infection of rhesus macaques with T-cell-line-tropic and macrophage-tropic clones of simian/human immunodeficiency viruses (SHIV).

To elucidate the functions of human immunodeficiency virus type 1 (HIV-1) genes in a nonhuman primate model, we have constructed infectious recombinant viruses (chimeras) between the pathogenic molecular clone of simian immunodeficiency virus (SIV) SIVmac239 and molecular clones of HIV-1 that differ in phenotypic properties controlled by the env gene. HIV-1SF33 is a T-cell-line-tropic virus which induces syncytia, and HIV-1SF162 is a macrophage-tropic virus that does not induce syncytia. A DNA fragment encoding tat, rev, and env (gp160) of SIVmac239 has been replaced with the counterpart genetic region of HIV-1SF33 and HIV-1SF162 to derive chimeric recombinant simian/human immunodeficiency virus (SHIV) strains SHIVSF33 and SHIVSF162, respectively. In the acute infection stage, macaques inoculated with SHIVSF33 had levels of viremia similar to macaques infected with SIVmac239, whereas virus loads were 1/10th to 1/100th those in macaques infected with SHIVSF162. Of note is the relatively small amount of virus detected in lymph nodes of SHIVSF162-infected macaques. In the chronic infection stage, macaques infected with SHIVSF33 also showed higher virus loads than macaques infected with SHIVSF162. Virus persists for over 1 year, as demonstrated by PCR for amplification of viral DNA in all animals and by virus isolation in some animals. Antiviral antibodies, including antibodies to the HIV-1 env glycoprotein (gp160), were detected; titers of antiviral antibodies were higher in macaques infected with SHIVSF33 than in macaques infected with SHIVSF162. Although virus has persisted for over 1 year after inoculation, these animals have remained healthy with no signs of immunodeficiency. These findings demonstrate the utility of the SHIV/macaque model for analyzing HIV-1 env gene functions and for evaluating vaccines based on HIV-1 env antigens.

Molecular interactions of cytomegalovirus and the human and simian immunodeficiency viruses.

In HuT 78 cells chronically infected with SIV, super-infection with rhesus cytomegalovirus (rhCMV) stimulated an increase in SIV replication. Utilizing transient expression assays with the SIV long terminal repeat (LTR) driving expression of the chloramphenicol acetyltransferase (CAT) reporter gene, the increase in SIV replication, by coinfection with CMV, was due to transactivation of the SIV LTR by the immediate early gene products (IE) of rhesus CMV. Similarly, IE of human CMV stimulated expression from both the SIV and HIV LTRs.

The nef gene of simian immunodeficiency virus SIVmac1A11.

The role of the simian immunodeficiency virus (SIV) nef gene in viral replication was investigated in several tissue culture systems. SIVmac1A11 is a molecularly cloned virus which replicates in both peripheral blood mononuclear cells (PBMC) and macrophages, although no disease is observed in infected rhesus macaques. In this report, we demonstrate that SIVmac1A11 contains a full open reading frame for nef which specifies a 37-kDa protein. To investigate the effects of nef on viral replication, a 70-bp deletion was introduced into the nef gene of SIVmac1A11. Analysis of infected cell extracts by immunoblotting revealed that both SIVmac1A11 and nef deletion virus SIVmac1A11 delta nef produced the same viral proteins, except that Nef was absent in the mutant virus. The deletion mutation did not affect viral replication in PBMC, in monocyte-derived and alveolar macrophages obtained from rhesus macaques, and in human cell lines HUT-78 and CEMx-174. In addition, SIVmac1A11 and SIVmac1A11 delta nef exhibited similar patterns of cytopathologic changes and ultrastructural appearances in infected cells. SIVmac1A11 and SIVmac1A11 delta nef did not infect human tumor macrophage cell line U937, GCT, THP-1, or HL-60 cells, although virus was produced after these cells were transfected with either wild-type or nef mutant viral DNA. Similar levels of virus were recovered from U937 and THP-1 cells transfected with mutant and parental proviral DNAs. In transient expression assays in a T-cell line and a macrophage line, the nef protein of SIVmac1A11 did not significantly suppress or enhance expression of the chloramphenicol acetyltransferase reporter gene linked to the SIVmac long terminal repeat. Thus, abrogation of nef did not affect several in vitro properties of SIVmac1A11, including patterns of viral infection in rhesus PBMC, rhesus macrophages, or human T-cell lines.

Detection of simian immunodeficiency virus DNA in macrophages from infected rhesus macaques.

We have examined the frequency of infection of monocyte-derived and alveolar macrophages isolated from rhesus macaques inoculated with simian immunodeficiency virus (SIVmac) utilizing a semiquantitative PCR methodology. Animals were inoculated with either pathogenic (SIVmac239) or nonpathogenic (SIVmac1A11) molecularly cloned viruses of SIVmac, or with uncloned pathogenic SIVmacBIOL. The frequency of SIV DNA in macrophages was highest early after infection and at terminal stages of disease, whereas during the asymptomatic period, SIV DNA was present at very low levels in macrophages.