Nucleotide sequence analysis of the long terminal repeat of integrated caprine arthritis encephalitis virus

Characterization of a new 5' splice site within the caprine arthritis encephalitis virus genome: evidence for a novel auxiliary protein

BACKGROUND

Lentiviral genomes encode multiple structural and regulatory proteins. Expression of the full complement of viral proteins is accomplished in part by alternative splicing of the genomic RNA. Caprine arthritis encephalitis virus (CAEV) and maedi-visna virus (MVV) are two highly related small-ruminant lentiviruses (SRLVs) that infect goats and sheep. Their genome seems to be less complex than those of primate lentiviruses since SRLVs encode only three auxiliary proteins, namely, Tat, Rev, and Vif, in addition to the products of gag, pol, and env genes common to all retroviruses. Here, we investigated the central part of the SRLV genome to identify new splice elements and their relevance in viral mRNA and protein expression.

RESULTS

We demonstrated the existence of a new 5' splice (SD) site located within the central part of CAEV genome, 17 nucleotides downstream from the SD site used for the rev mRNA synthesis, and perfectly conserved among SRLV strains. This new SD site was found to be functional in both transfected and infected cells, leading to the production of a transcript containing an open reading frame generated by the splice junction with the 3' splice site used for the rev mRNA synthesis. This open reading frame encodes two major protein isoforms of 18- and 17-kDa, named Rtm, in which the N-terminal domain shared by the Env precursor and Rev proteins is fused to the entire cytoplasmic tail of the transmembrane glycoprotein. Immunoprecipitations using monospecific antibodies provided evidence for the expression of the Rtm isoforms in infected cells. The Rtm protein interacts specifically with the cytoplasmic domain of the transmembrane glycoprotein in vitro, and its expression impairs the fusion activity of the Env protein.

CONCLUSION

The characterization of a novel CAEV protein, named Rtm, which is produced by an additional multiply-spliced mRNA, indicated that the splicing pattern of CAEV genome is more complex than previously reported, generating greater protein diversity. The high conservation of the SD site used for the rtm mRNA synthesis among CAEV and MVV strains strongly suggests that the Rtm protein plays a role in SRLV propagation in vivo, likely by competing with Env protein functions.

tRNAs promote nuclear import of HIV-1 intracellular reverse transcription complexes

Infection of non-dividing cells is a biological property of HIV-1 crucial for virus transmission and AIDS pathogenesis. This property depends on nuclear import of the intracellular reverse transcription and pre-integration complexes (RTCs/PICs). To identify cellular factors involved in nuclear import of HIV-1 RTCs, cytosolic extracts were fractionated by chromatography and import activity examined by the nuclear import assay. A near-homogeneous fraction was obtained, which was active in inducing nuclear import of purified and labeled RTCs. The active fraction contained tRNAs, mostly with defective 3' CCA ends. Such tRNAs promoted HIV-1 RTC nuclear import when synthesized in vitro. Active tRNAs were incorporated into and recovered from virus particles. Mutational analyses indicated that the anticodon loop mediated binding to the viral complex whereas the T-arm may interact with cellular factors involved in nuclear import. These tRNA species efficiently accumulated into the nucleus on their own in a energy- and temperature-dependent way. An HIV-1 mutant containing MLV gag did not incorporate tRNA species capable of inducing HIV-1 RTC nuclear import and failed to infect cell cycle-arrested cells. Here we provide evidence that at least some tRNA species can be imported into the nucleus of human cells and promote HIV-1 nuclear import.

Retroviral sequences in rheumatoid arthritis synovium

There are several relationships between retroviruses and cellular transformation, as well as retroviruses being involved in the development of autoimmune diseases. Retroviruses have been discussed as etiologic agents modulating or triggering certain pathways in the pathogenesis of rheumatoid arthritis (RA). However, none of the currently known retroviruses has been identified as specific for RA. Due to the unique properties of retroviruses, distinct experimental approaches can be used to detect retroviral activity in cells and tissues. Current research in RA using state-of-the-art molecular biology techniques includes both the search for exogenous and endogenous retroviral gene sequences in synovium of patients with RA.

Defective viral particles in caprine arthritis encephalitis virus infection

Attempts to isolate full-length unintegrated circular forms of the caprine arthritis encephalitis virus (CAEV) genome yielded only a large number of molecules with deletions. The 3' borders of most of these deletions were near the U3 region of the long terminal repeat whereas the 5' edges were found at various upstream sites within pol or env. With one exception, gag sequences were always present. Analysis of molecular clones derived from integrated proviral CAEV genomes from the same infected cells showed a similar spectrum of deletions. The presence of transcriptionally active elements within the U3 domain of the defective genomes, as well as cis-acting elements within the leader sequences known to be required for efficient encapsidation of viral RNA, suggested that the defective viral DNA genomes could be transcribed into defective RNA molecules which could then be packaged into virions. Isopycnic density gradient centrifugation of supernatants of infected cell cultures indicated the presence of particles with densities less than that expected for intact virions (1.16 g/cc). Northern analysis revealed the presence of smaller viral-specific RNAs that lacked env sequences. These data, along with the structures of the molecular clones, suggest that CAEV stocks contain particles with defective genomes. The role of these particles in influencing the course of virus infection remains to be determined.

rev-like transcripts of caprine arthritis encephalitis virus

The pattern of expression of the caprine arthritis encephalitis virus genome (CAEV) in acutely infected tahr lung cells was found to be complex and temporally regulated. Employing Northern analysis, five CAEV-specific transcripts, 9, 6.5, 5.0, 2.5, and 1.4 kb, were detected. Nucleotide sequence analysis established the genetic structure of two species of cDNA, isolated from a library of CAEV-infected tahr cells, and suggested that they represent rev-like transcripts. One of these cDNA species was composed of three exons--the leader, an exon derived from the 5' region of env, and an exon which spanned the 3' orf. The second cDNA species consisted of four exons--three of which were identical with those of the former species. The additional exon (the second) was located at the 3' end of pol. These transcripts could potentially encode three proteins--a Rev-like protein, which is a fusion of 38 amino acids derived from the N-terminus of env and 91 residues from the 3' orf; a truncated form of the env transmembrane protein, and a novel protein, designated X composed of 73 amino acids. Thus, CAEV, like other lentiviruses, displays a complex pattern of gene expression, characterized by alternative splicing and the production of potentially polycistronic transcripts.

Identification of sequences encoding the equine infectious anemia virus tat gene

Equine infectious anemia virus (EIAV), a lentivirus, encodes a trans-activator (tat) which stimulates gene expression directed by the viral long terminal repeat (LTR). This function has been previously shown by us and others to be encoded by sequences within the middle region of the EIAV genome in which two short open reading frames, S1 and S2, reside. In the present study, by using in vitro mutagenesis, we show that disruption of S1, but not S2, completely abolished trans-activation. Addition of oligonucleotides complementary to S1 to cells transfected with a tat expression vector resulted in inhibition of trans-activation. EIAV cDNAs were isolated from a library of EIAV-infected cells constructed by using a eukaryotic expression vector. One cDNA clone which contained S1 sequences was able to trans-activate the EIAV LTR. Sequence analysis of this cDNA clone revealed that, in addition to S1, two other open reading frames were present. The cDNA still retained its activity when the latter two sequences were deleted.

Analysis of regulatory elements of the equine infectious anemia virus and caprine arthritis-encephalitis virus long terminal repeats

We analyzed the equine infectious anemia virus (EIAV) long terminal repeat (LTR) for sequences that influence its promoter activity and ability to be trans-activated by the EIAV tat gene product. A series of LTR deletion mutants and recombinants between LTR and simian virus 40 (SV40) regulatory sequences were used for these studies. We were able to identify the EIAV promoter region and showed that sequences within the U3 region significantly inhibited LTR-directed transcription. However, when placed in a heterologous context (SV40 promoter) these U3 sequences functioned as an enhancer. trans-activation of the EIAV LTR was found to depend upon sequences downstream of the transcription initiation site and also within U3. Deletion mutagenesis experiments showed that the major downstream element was present in a 46-nucleotide stretch (+4 to +50). An SV40 promoter construct containing these sequences could be trans-activated in cells expressing the EIAV tat gene product. For comparative purposes we also examined the LTR of another animal lentivirus, caprine arthritis-encephalitis virus (CAEV), for positive and negative transcriptional regulatory elements and demonstrated the presence of an enhancer within its U3 sequence. There is evidence that trans-activation of the CAEV LTR requires U3 sequences. When the EIAV U3 region was replaced by the CAEV U3 sequence, the promoter activity of the EIAV LTR was markedly elevated, but the responsiveness to the EIAV trans-activator could not be restored.

Localization of sequences responsible for trans-activation of the equine infectious anemia virus long terminal repeat

We used the Escherichia coli chloramphenicol acetyltransferase gene (cat) to study sequences that influence expression of the equine infectious anemia virus (EIAV) genome. The EIAV long terminal repeat (LTR) directed CAT activity in a canine cell line, but at levels much lower than those achieved with other eucaryotic viral promoters. In the same cells infected with EIAV or cotransfected with molecularly cloned EIAV genomic DNA, LTR-directed activity was markedly enhanced. Comparison of cat mRNA and protein levels in these cells indicated that this trans-activating effect could be accounted for by a bimodal mechanism in which both transcriptional and posttranscriptional events are enhanced. trans-Activation but not promoter activity was abolished by deletion of the R-U5 region of the EIAV LTR. EIAV sequences responsible for the trans-activating function could be localized to a region encompassing the 3' and 5' termini of the pol and env genes, respectively (nucleotides 4474 to 5775). Interestingly, this stretch harbors a short open reading frame with some amino acid sequence similarity to the human immunodeficiency virus type I tat gene product.

Nucleotide sequence analysis of equine infectious anemia virus proviral DNA

The nucleotide sequence of the integrated form of the genome of the equine infectious anemia virus was determined. By comparison with LTR sequences of other retroviruses, signals for the control of viral gene transcription and translation could be identified in the EIAV LTR. Open reading frames for gag and pol genes were identified and their sequences matched very closely to those determined previously by others. However, in the present study, the pol gene reading frame was open throughout its entire length. The open reading frame for the env gene product was constructed from the sequences of two independent EIAV clones. Thus, a noninfectious genomic-length clone was shown to contain a frameshift mutation approximately in the middle of the presumed env gene coding sequence, whereas the sequence of another clone was open in this region. The deduced amino acid sequences of the EIAV gag and pol products showed closer evolutionary relationships to those of known lentiviruses than to other retroviruses. There was also partial sequence homology between predicted env gene products of EIAV, visna virus, and HTLV-III/LAV. Sequences analogous to the sor region of other lentiviruses could not be identified in our EIAV clone. A short open reading frame at the 3' end of the genome that overlapped env but not the 3' LTR was present but lacked significant sequence similarity to the 3' open reading frames of other lentiviruses. Thus, the sequence and general structure of EIAV most closely resemble those of known lentiviruses.