The Gag proteins of Rous sarcoma virus and human immunodeficiency virus (HIV) each contain a function involved in a late step in budding, defects in which result in the accumulation of these molecules at the plasma membrane. In the Rous sarcoma virus Gag protein (Pr76 gag), this assembly domain is associated with a PPPY motif, which is located at an internal position between the MA and CA sequences. This motif is not contained anywhere within the HIV Gag protein (Pr55 gag), and the MA sequence is linked directly to CA. Instead, a late assembly function of HIV has been associated with the p6 sequence situated at the C terminus of Gag. Here we demonstrate the remarkable finding that the late assembly domains from these two unrelated Gag proteins are exchangeable between retroviruses and can function in a positionally independent manner.
The salient features of this model for oncornavirus assembly are that uncleaved precursor molecules to the internal virus polypeptides possess specific recognition sites both for viral envelope constituents already inserted in the cell membrane and for the viral RNA. After orderly alignment of these components at the budding site, virus maturation proceeds through specific proteolytic cleavage of the precursor components and association of the resultant molecules into the characteristic type C virion substructures revealed by electron microscopy.
Comparisons of peptide and oligonucleotide maps of glycoproteins and RNA from nine isolates of equine infectious anemia virus (EIAV) that were generated during parallel infections of two Shetland ponies revealed that each isolate was structurally unique. Each EIAV isolate contained a unique subset of variant peptides, oligonucleotides, or both, indicating that structural variation in EIAV is a random and noncumulative process and that a large spectrum of possible EIAV variants can be generated in infected animals.
The utilization of predicted splice donor and acceptor sites in generating equine infectious anemia virus (EIAV) transcripts in fetal donkey dermal cells (FDD) was examined. A single splice donor site identified immediately upstream of the gag coding region joins the viral leader sequence to all downstream exons of spliced EIAV transcripts. The predominant 3.5-kb transcript synthesized in EIAV-infected FDD cells appears to be generated by a single splicing event which links the leader sequence to the first of two functional splice acceptor sites near the 5' end of the Si open reading frame (ORF). The translation products encoded by the 3.5-kb transcript were examined by producing in vitro transcripts from a cDNA corresponding to this RNA followed by in vitro translation in wheat germ extracts. These transcripts directed the synthesis of three proteins: the virus trans-activator protein (EIAV Tat) encoded by ORF S1, a protein of unknown function encoded by ORF S2, and the virus envelope glycoprotein. When transfected into FDD cells, this cDNA also directed expression of EIAV Tat. Amino-terminal sequence analysis of the in vitro-synthesized Si protein supports the suggestion that translation of EIAV Tat is initiated at a CUG codon within the virus leader region. Both in vitro-synthesized S2 protein and synthetic peptides corresponding to S2 are shown to react positively with sera obtained from EIAV-infected horses, providing the first direct evidence of expression of this protein in infected animals.
Defined segments of the transmembrane envelope glycoprotein (gp45) of equine infectious anemia virus were expressed as TrpLE fusion proteins and examined for their reactivity in Western immunoblots against a diverse panel of equine immune sera. The most immunogenic region of gp45 was localized to its amino terminus, positioned between the hydrophobic fusion and the transmembrane domains. A series of overlapping synthetic peptides were used in enzyme-linked immunosorbent assays to define an immunodominant epitope within this region. In contrast, the carboxy-terminal half of gp45 displayed both weak and variable immunoreactivity with equine immune sera.
The two glycoproteins, gp85 and gp35, of Rous-associated virus type 61 (RAV-61), were isolated from radiolabeled virions by gel electrophoresis and digested with trypsin. The chromatographic profile of the gp35 digest revealed no peaks in common with that of gp85; therefore, the smaller glycoprotein is not a cleavage product of gp85. The stoichiometry ofradiolabeled RAV-61 proteins was studied by quantitative gel filtration and gel electrophoresis. Among the 11 polypeptides identified were 4 minor ones, including the f8(p91) and a(p64) chains of reverse transcriptase and two unidentified chains, p76 and p35; the latter two were unmasked by removing the virions' surface glycoproteins with a protease, bromelain. Virions contained some 15 to 30 molecules of reverse transcriptase.
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