Efficient transformation by Prague A Rous sarcoma virus plasmid DNA requires the presence of cis-acting regions within the gag gene.

A region in addition to and outside the long terminal repeats (LTRs) in the gag gene of the Prague A strain of Rous sarcoma virus was found to be essential in cis for efficient cell transformation by cloned viral DNA. Transformation in chicken embryo fibroblasts, which requires infectious virus production and reinfection, was facilitated in cis by sequences between nucleotides 630 and 1659. Efficient transformation of NIH 3T3 cells in which secondary spread of virus is not necessary (as it is in chicken embryo fibroblasts) required sequences between nucleotides 630 and 1149. A src cDNA clone which also lacks this region demonstrated low transformation efficiency, indicating that the role of the cis element cannot be attributed to interference with RNA splicing. The gag gene segment required in cis for transformation, between nucleotides 630 and 1149, could substitute for the simian virus 40 enhancer in either orientation, and cells transfected with Rous sarcoma virus LTR-driven plasmids containing the gag cis element had a two- to threefold increase in steady-state viral RNA levels compared with plasmids lacking this region. Thus, additional cis-acting regulatory elements located outside the viral LTRs may modulate viral gene expression and contribute to the efficiency of cell transformation.     

Small deletion in src of Rous sarcoma virus modifying transformation phenotypes: identification of 207-nucleotide deletion and its smaller product with protein kinase activity.

Partial deletion in the src gene and the gene product were characterized in a deletion mutant, dl5, isolated from the Prague strain of Rous sarcoma virus. The mutant induced fusiform-like transformed cells, unlike the parental Prague strain, which induced round transformed cells. Determination of the total nucleotide sequences of src in dl5 and the Prague strain of Rous sarcoma virus demonstrated that in the former two deletions of 196 and 11 nucleotides had occurred at positions 403 and 696, respectively, from the 5' end of src. A protein with a molecular weight of 52,000 (p52src) was detected in cells infected with dl5, as predicted from the deletion size in src. From the nucleotide sequence, it was predicted that p52src had two deletions of 65 and 4 amino acids at positions 135 and 232, respectively, from the N-terminal methionine of p60src and also had 33 amino acid changes between these two deletion sites due to alteration of the reading frame. p52src, which contained deletions and alterations of amino acids near the N-terminus, showed protein kinase activity similar to that of p60src and functioned in the infected cells. These results strongly suggest that changes in the N-terminal region of p60src modified its transforming ability, causing induction of the fusiform-like transformation phenotype.     

Cloning and nucleotide sequences of cDNAs spanning the splice junctions of Rous sarcoma virus mRNAs.

The cDNAs corresponding to the 5' ends of the mRNAs coding for the envelope protein precursor (gPr92env) of the B77 strain and the transforming protein (pp60src) of the Prague B strain of Rous sarcoma virus were cloned into pBR322, and the nucleotide sequences surrounding the splice junctions were determined. Both mRNAs are products of single splicing events from a common donor splice site at nucleotide 398 from the 5' end of the RNA to acceptor splice sites at nucleotides 5078 and 7054 for the env and src mRNAs, respectively. These results confirm and extend previous conclusions based on peptide mapping and single-strand nuclease mapping. Compared with the sequence of the Prague C genome RNA, the B77 strain contains a 6-nucleotide deletion in the sequence corresponding to the hydrophobic portion of the signal peptide of the envelope protein precursor.     

Nucleotide sequence of rous sarcoma virus

We present the 9312 nucleotide sequence of the Prague C (Pr-C) strain of Rous sarcoma virus (RSV). A comparison of known protein sequences with the nucleotide sequence allows assignment of the coding regions for the gag, pol, env and src genes. The gag gene is terminated by an amber stop codon and is contained within a different reading frame than is the pol gene. The pol and env genes overlap. The sequences surrounding the src gene in the PrC and Schmidt-Ruppin (SR-A) strains of RSV have been compared, and they reveal that an element, E, of approximately 153 nucleotides is present on the 3′ side of the src gene in Pr-C, and on the 5′ side in SR-A. We hypothesize that E was part of a duplicated region of over 250 nucleotides flanking the src gene in an ancestral RSV, and that differential deletion of one copy of E led to its positional difference in Pr-C and SR-A.     

Transduction of the cellular src gene and 3'' adjacent sequences in avian sarcoma virus PR2257.

When injected into chickens, a transformation-defective mutant of the Prague C strain of Rous sarcoma virus induced tumors at low incidence and after a long latency. One such tumor released a replication-defective virus designated PR2257. We molecularly cloned and sequenced the proviral DNA from quail fibroblasts transformed by PR2257. Comparison of PR2257 sequence with that of Prague C, cellular src, and 3' adjacent cellular DNA showed that the spliced version of the c-src gene and about 950 base pairs (bp) of 3'-flanking cellular DNA were transduced into PR2257. This transduction eliminated nearly all replicative genes, since the gag gene splice donor site was linked to the splice acceptor site of the src gene and, on the 3' side, recombination occurred in the end of env gene. Insertion of two extra cytosines 23 bp before and 19 bp after the c-src stop codon resulted in an extension of the coding portion up to 587 amino acids, divergence of sequences after Pro-525 and replacement of Tyr-527 by a valine residue. In addition, it appears that the 5' and 3' untranslated regions of PR2257 result from multiple recombinations between exogenous and endogenous virus genomes. Limited digestion of p66src encoded by PR2257 with Staphylococcus aureus V8 protease yielded a V2 peptide (C-terminal moiety) with an apparent molecular mass of 31 kilodaltons, consistent with the 5.7-kilodalton increase expected from the DNA sequence. The structure of PR2257 suggests that the first step in the capture of c-src gene by avian lymphomatosis viruses is the trans splicing of the viral leader mRNA to exon 1 of c-src.     

Two base changes restore infectivity to a noninfectious molecular clone of Moloney murine leukemia virus (pMLV-1).

The complete nucleotide sequence of a molecular clone of Moloney murine leukemia virus (pMLV-1) has previously been reported (Shinnick et al., Nature [London] 293:543-548, 1981). However, pMLV-1 does not generate infectious virus after transfection into cells (Berns et al., J. Virol. 36:254-263, 1980). The lesion in pMLV-1 has been localized by determining the biological activity of recombinants containing DNA from an infectious clone of Moloney murine leukemia virus (pMLV-48) and pMLV-1. Replacement of a 1.0-kilobase pair region which spans the gag-pol junction of pMLV-1 with the corresponding DNA fragment from the infectious clone restores its infectivity. Nucleotide sequence analysis of this fragment obtained from the infectious clone (pMLV-48) and pMLV-1 reveals two single base pair changes, one in the p30gag gene and the other in the 5' end of the pol gene. The mutation in the pol gene does not affect the production of infectious virus but renders them XC negative, whereas the mutation in the gag gene appears to be lethal. The complete nucleotide sequence of an infectious clone of Moloney murine leukemia virus can now be deduced.     

马传染性贫血病毒驴白细胞弱毒疫苗gag基因的序列测定及分析

以马传染性贫血病毒（ＥＬＡＶ）驴白细胞弱毒疫苗株（ＤＬＡ）病毒基因组ＲＮＡ为材料,用ＲＴ－ＰＣＲ方法扩增出ＥＩＡＶ ｇａｇ基因,以平端针其克隆到质粒载体ｐＵＣ１９中,由于疫苗不是克隆株,因此通过５次单独克隆与测序,推导出ＥＩＡＶ－ＤＬＡ ｇａｇ基因的优势序列。ｇａｇ基因全长１４５８个碱基,编码一４８６个氨基酸残基的前体蛋白。与美国ＥＩＡＶ Ｗｙｏｍｉｎｇ１３６９株比较,核苷酸同源性为８０％,氨基酸     

DNA sequence of the viral and cellular src gene of chickens. II. Comparison of the src genes of two strains of avian sarcoma virus and of the cellular homolog

The nucleotide sequence of the src gene and flanking regions of the Schmidt-Ruppin strain of Rous sarcoma virus (SR-A) was determined. The src region of SR-A was very homologous to that of recovered avian sarcoma virus (rASV1441), with only 17 differences among 1,578 nucleotides. The size of the predicted protein was 526 amino acids in both viruses, of which 6 amino acids were different. The differences in nucleotides and amino acids between the two viruses localized within the 5' two-thirds of the src coding region. There were also viruses localized within the 5' two-thirds of the src coding region. There were also some differences in the region flanking the 5' end of src. Since rASVs are considered to be recombinatns between deletion mutants of SR-A and cellular-src (c-src) sequences, several segments of c-src DNA were also sequenced to understand the molecular basis for the recombination. At 14 of 17 bases where SR-A and rASV1441 differed, rASV1441 had the same sequence as c-src. Three of these sequences corresponded to sequences of oligonucleotides which were previously identified in RNAs of nearly all isolates of rASV but which were absent in SR-A RNA. In the 5'-flanking sequences of the src gene, c-src was more similar to rASV1441 than to SR-A. These results confirm the cellular origin of the src sequences of rASVs and provide information about the possible sites of the recombination.     

Sequence of the Long Terminal Repeat and Adjacent Segments of the Endogenous Avian Virus Rous-Associated Virus 0

Rous-associated virus 0 (RAV-0), an endogenous chicken virus, does not cause disease when inoculated into susceptible domestic chickens. An infectious unintegrated circular RAV-0 DNA was molecularly cloned, and the sequence of the long terminal repeat (LTR) and adjacent segments was determined. The sequence of the LTR was found to be very similar to that of replication-defective endogenous virus EV-1. Like the EV-1 LTR, the RAV-0 LTR is smaller (278 base pairs instead of 330) than the LTRs of the oncogenic members of the avian sarcoma virus-avian leukosis virus group. There is, however, significant homology. The most striking differences are in the U(3) region of the LTR, and in this region there are a series of small segments present in the oncogenic viruses which are absent in RAV-0. These differences in the U(3) region of the LTR could account for the differences in the oncogenic potential of RAV-0 and the avian leukosis viruses. I also compared the regions adjacent to the RAV-0 LTR with the available avian sarcoma virus sequences. A segment of approximately 200 bases to the right of the LTR (toward gag) is almost identical in RAV-0 and the Prague C strain of Rous sarcoma virus. The segment of RAV-0 which lies between the end of the env gene and U(3) is approximately 190 bases in length. Essentially this entire segment is present between env and src in the Schmidt-Ruppin A strain of Rous sarcoma virus. Most of this segment is also present between env and src in Prague C; however, in Prague C there is an apparent deletion of 40 bases in the region adjacent to env. In Schmidt-Ruppin A, but not in Prague C, about half of this segment is also present between src and the LTR. This arrangement has implications for the mechanism by which src was acquired. The region which encoded the gp37 portion of env appears to be very similar in RAV-0 and the Rous sarcoma viruses. However, differences at the very end of env imply that the carboxy termini of RAV-0, Schmidt-Ruppin A, and Prague C gp37s are significantly different. The implications of these observations are considered.     

Murine sarcoma virus ts110 RNA transcripts: origin from a single proviral DNA and sequence of the gag-mos junctions in both the precursor and spliced viral RNAs

Our previous studies have argued persuasively that in murine sarcoma virus ts110 (MuSVts110) the gag and mos genes are fused out of frame due to a approximately 1.5-kilobase (kb) deletion of wild-type murine sarcoma virus 349 (MuSV-349) viral information. As a consequence of this deletion, infected cells grown at 39 degrees C appear morphologically normal, producing a 4-kb viral RNA and a truncated gag gene product, P58gag. At 33 degrees C, however, MuSVts110-infected cells appear transformed, producing two viral RNAs, about 4 and 3.5 kb in length, and two viral proteins, P58gag and P85gag-mos. Recent S1 nuclease analyses (Nash et al., J. Virol. 50:478-488, 1984) suggested strongly that at 33 degrees C about 430 bases surrounding the out-of-frame gag-mos junction and bounded by consensus splice donor and acceptor sites are excised from the 4-kb RNA to form the 3.5-kb RNA. As a result of this apparent splicing event, the gag and mos genes seemed to be fused in frame and allowed the translation of P85gag-mos. In the present study, DNA primers hybridizing to the MuSVts110 4- and 3.5-kb RNAs just downstream of the gag-mos junction points were used to sequence these junctions by the primer extension method. We observed that, relative to wild-type MuSV-349 5.2-kb RNA, the MuSVts110 4-kb RNA had suffered a 1,488-base deletion as a result of the fusion of wild-type gag gene nucleotide 2404 to wild-type mos gene nucleotide 3892. This gag-mos junction is out of frame, containing both TAG and TGA termination codons in the reading frame 42 and 50 bases downstream of the gag-mos junction, respectively. Thus, the MuSVts110 4-kb RNA can only be translated into a truncated gag precursor containing an additional C-terminal 14 amino acid residues derived from an alternate mos gene reading frame. Similar analyses of the MuSVts110 3.5-kb RNA showed a further loss of both gag and mos sequences over those deleted in the original 1,488-base deletion. In the MuSVts110 3.5-kb RNA, we found that gag nucleotide 2017 was fused to mos nucleotide 3936 (nucleotide 2449 in the MuSVts110 4-kb genome). This 431-base excised fragment is bounded exactly by in-frame consensus splice donor and acceptor sequences. As a consequence of this splice event, the TAG codon is excised and the restoration of the original mos gene reading frame allows the TGA codon to be bypassed.(ABSTRACT TRUNCATED AT 400 WORDS)     

Nucleotide sequence of AKV murine leukemia virus.

AKV is an endogenous, ecotropic murine leukemia virus that serves as one of the parents of the recombinant; oncogenic mink cell focus-forming viruses that arise in preleukemic AKR mice. I report the 8,374-nucleotide-long sequence of AKV, as determined from the infectious molecular clone AKR-623. The 5'-leader sequence of AKV extends to nucleotide 639, after which lies a long open reading frame encoding the gag and pol gene products. The reading frame is interrupted by a single amber codon separating the gag and pol genes. The pol gene overlaps the env gene within the 3' region of the AKV genome. The nucleotide sequence of the 5' region of AKV reveals the following features. (i) The 5'-leader sequence lacks any AUG codon to initiate translation of gPr80gag, suggesting that gPr80gag is not required for the replication of AKV. (ii) A short portion of the leader region diverges in sequence from the closely related Moloney murine leukemia virus and appears to be related to a sequence highly repeated in eucaryotic genomes. (iii) As in Moloney murine leukemia virus, there is a potential RNA secondary structure flanking the amber codon that separates the gag and pol genes. This structure might function as a regulatory protein binding site that controls the relative levels of synthesis of the gag and pol precursors. The nucleotide sequence of the 3' region of AKV is compared with sequences reported previously from both infectious and noninfectious molecular clones of AKV.     

Comparison of Rous sarcoma virus RNA processing in chicken and mouse fibroblasts: evidence for double-spliced RNA in nonpermissive mouse cells.

Rous sarcoma virus, an avian retrovirus, transforms but does not replicate in mammalian cells. To determine to what extent differences in RNA splicing might contribute to this lack of productive infection, cloned proviral DNA derived from the Prague A strain of Rous sarcoma virus was transfected into mouse NIH 3T3 cells, and the viral RNA was compared by RNase protection with viral RNA from transfected chicken embryo fibroblasts by using a tandem antisense riboprobe spanning the three major splice sites. The levels of viral RNA in NIH 3T3 cells compared with those in chicken embryo fibroblasts were lower, but the RNA was spliced at increased efficiency. The difference in the ratio of unspliced to spliced RNA levels was not due to the increased lability of unspliced RNA in NIH 3T3 cells. Although chicken embryo fibroblasts contained equal levels of src and env mRNAs, spliced viral mRNAs in NIH 3T3 cells were almost exclusively src. In NIH 3T3 cells the env mRNA was further processed by using a cryptic 5' splice site located within the env coding sequences and the normal src 3' splice site to form a double-spliced mRNA. This mRNA was identical to the src mRNA, except that a 159-nucleotide sequence from the 5' end of the env gene was inserted at the src splice junction. Smaller amounts of single-spliced RNA were also present in which only the region between the cryptic 5' and src 3' splice sites was spliced out. The aberrant processing of the viral env mRNA in NIH 3T3 cells may in part explain the nonpermissiveness of these cells to productive Rous sarcoma virus infection.     

A nucleotide substitution in the gag N terminus of the endogenous ecotropic DBA/2 virus prevents Pr65gag myristylation and virus replication.

The endogenous ecotropic provirus Emv-3 present in DBA/2 mice is poorly expressed in the animal, as well as in cell cultures. Transfection of proviral DNA into NIH 3T3 cells localized the expression defect to the 5' region of the viral genome, spanning the untranslated region and the N-terminal part of the gag gene. Comparison of the nucleotide sequence of the Emv-3 provirus with the sequence of the highly infectious Akv murine leukemia virus revealed three nucleotide differences within the gag coding region. One of these differences was found in codon 3 of the gag polyprotein, where a Gln codon is seen in Akv and a Pro codon is differences was found in codon 3 of the gag polyprotein, where a Gln codon is seen in Akv and a Pro codon is seen in Emv-3. By site-directed mutagenesis, we showed that the defect of Emv-3 expression indeed is localized to codon 3 of the gag gene. The gag polyprotein of mammalian type C retrovirus contains myristic acid covalently linked to the N-terminal glycine. This myristylation is not seen in the Emv-3-coded gag polyprotein. We showed that the in vitro-mutagenized Emv-3 genome containing a Gln codon at position 3 of the gag gene yields a myristylated gag polyprotein. Thus, it seems most likely that the defect of expression of the Emv-3 provirus is due to the presence of a proline is position 3 of the gag polyprotein, preventing the myristylation.     

Polymorphism of avian sarcoma virus src proteins.

The src gene products of seven different avian sarcoma viruses were compared. In vitro translation of virion RNA yielded products identified unambiguously as p60src in the case of two stocks of the Schmidt-Ruppin strain, three stocks of the Prague strain, the Bryan strain, and the Bratislava 77 strain of avian sarcoma virus. Differences in the electrophoretic mobility of these seven p60src proteins in sodium dodecyl sulfate-polyacrylamide gels, corresponding to variation in the apparent molecular weights ranging from 56,000 to 60,500, were observed. Antigenic variability was also found; only three of the seven viruses tested encoded a p60src, which was precipitated by antisera derived from rabbits bearing tumors induced by the Schmidt-Ruppin strain of Rous sarcoma virus. Examination of the methionine-containing tryptic peptides of the seven ;60src proteins by two-dimensional mapping revealed four common peptides but marked variability in the five to eight other peptides in each protein. Clear differences in the peptide maps of p60src were observed, both between different strains of virus and within strains. In the three cases examined, p60src synthesized in transformed cells was found to be essentially identical to that synthesized in vitro. We conclude that there is significant polymorphism in the p60src proteins of the avian sarcoma viruses.     

A 3' UTR sequence stabilizes termination codons in the unspliced RNA of Rous sarcoma virus

Eukaryotic cells target mRNAs to the nonsense-mediated mRNA decay (NMD) pathway when translation terminates within the coding region. In mammalian cells, this is presumably due to a downstream signal deposited during pre-mRNA splicing. In contrast, unspliced retroviral RNA undergoes NMD in chicken cells when premature termination codons (PTCs) are present in the gag gene. Surprisingly, deletion of a 401-nt 3' UTR sequence immediately downstream of the normal gag termination codon caused this termination event to be recognized as premature. We termed this 3' UTR region the Rous sarcoma virus (RSV) stability element (RSE). The RSE also stabilized the viral RNA when placed immediately downstream of a PTC in the gag gene. Deletion analysis of the RSE indicated a smaller functional element. We conclude that this 3' UTR sequence stabilizes termination codons in the RSV RNA, and termination codons not associated with such an RSE sequence undergo NMD.