Electron microscopic analysis of ts1 10 Moloney mouse sarcoma virus, a variant of wild-type virus with two RNAs containing large deletions

A subset of Pr65gag is nucleus associated in murine leukemia virus-infected cells

Nuclei of cells infected with Moloney murine leukemia virus (MoMuLV) were examined for the presence of gag proteins. This analysis was performed in conjunction with other studies suggesting a possible role for gag proteins in regulating nuclear events relating to processing and/or transport of viral genomic RNA. We detected Pr65gag and a p30-related protein in a nuclear fraction of infected cells. We also found evidence that a highly conserved amino acid sequence, which is shared by p30 and U1 small nuclear ribonucleoprotein 70-kDa protein, is a component of the nuclear targeting sequence for Pr65gag. Immunoelectron microscopy studies with a monoclonal anti-p12 antibody established that approximately 18% of gag-containing proteins of MoMuLV are located in the nucleus. Such gag-containing proteins from a mutant MoMuLV that lacks N-terminal myristic acid had greater affinity for the nucleus, suggesting that fatty acid acylation of Pr65gag plays a role in overcoming the proposed nuclear transport signal. The possible roles that nuclear gag proteins may play in retroviral replication are discussed.

Regulation of the efficiency and thermodependence of murine sarcoma virus MuSVts110 RNA splicing by sequences in both exons

Efficient splicing of MuSVts110 RNA is restricted to temperatures of 33 degrees or lower. Previously, we have shown that this conditional splicing event is mediated, in part, by cis-acting intronic sequences. We have now examined the role of exon sequences in MuSVts110 RNA splicing. We found that deletion of all but 36 nucleotides of the gag exon (E1) yielded a transcript incapable of supporting splicing. However, inefficient, growth temperature-dependent splicing was recovered after restoration of the 300 nucleotides of E1 proximal to the 5' splice site (5' ss). Increasingly efficient splicing was observed as more E1 was restored. Hence, although MuSVts110 E1 sequences were required for splicing, they were not involved in its thermodependence. Similarly, removal of all but 88 nucleotides of the mos exon (E2) abolished splicing at the usual 3' splice site (3' ss). In contrast to E1, restoration of the 200 nucleotides of E2 adjacent to the 3' ss reactivated efficient, temperature-independent splicing. Thermodependent splicing, however, reappeared with the replacement of E2 sequences located more than 400 nucleotides distal to the 3' splice site. In MuSVts110 mutants containing the minimum amounts of both E1 and E2 which would support splicing, splicing was both far more efficient than predicted and temperature-independent, suggesting that cooperation between E1 and E2 may help to regulate MuSVts110 splicing.

Moloney murine sarcoma virus MuSVts110 DNA: cloning, nucleotide sequence, and gene expression

We have cloned Moloney murine sarcoma virus (MuSV) MuSVts110 DNA by assembly of polymerase chain reaction (PCR)-amplified segments of integrated viral DNA from infected NRK cells (6m2 cells) and determined its complete sequence. Previously, by direct sequencing of MuSVts110 RNA transcribed in 6m2 cells, we established that the thermosensitive RNA splicing phenotype uniquely characteristic of MuSVts110 results from a deletion of 1,487 nucleotides of progenitor MuSV-124 sequences. As anticipated, the sequence obtained in this study contained precisely this same deletion. In addition, several other unexpected sequence differences were found between MuSVts110 and MuSV-124. For example, in the noncoding region upstream of the gag gene, MuSVts110 DNA contained a 52-nucleotide tract typical of murine leukemia virus rather than MuSV-124, suggesting that MuSVts110 originated as a MuSV-helper murine leukemia virus recombinant during reverse transcription rather than from a straightforward deletion within MuSV-124. In addition, both MuSVts110 long terminal repeats contained head-to-tail duplications of eight nucleotides in the U3 region. Finally, seven single-nucleotide substitutions were found scattered throughout MuSVts110 DNA. Three of the nucleotide substitutions were in the gag gene, resulting in one coding change in p15 and one in p30. All of the remaining nucleotide changes were found in the noncoding region between the 5' long terminal repeat and the gag gene. In NIH 3T3 cells transfected with the cloned MuSVts110 DNA, the pattern of viral RNA expression conformed with that observed in cells infected with authentic MuSVts110 virus in that viral RNA splicing was 30 to 40% efficient at growth temperatures between 28 and 33 degrees C but reduced to trace levels above 37 degrees C.

Regulation of RNA splicing in gag-deficient mutants of Moloney murine sarcoma virus MuSVts110

We investigated whether the MuSVts110 gag gene product (P58gag) can regulate the novel growth temperature dependence of MuSVts110 RNA splicing. MuSVts110 mutants with either frameshifts or deletions in the gag gene were tested for their ability to maintain the MuSVts110 splicing phenotype. Only small decreases in splicing efficiency and no changes in the thermosensitivity of viral RNA splicing were observed in MuSVts110 gag gene frameshift mutants. Deletions within the gag gene, however, variably decreased MuSVts110 splicing efficiency but had no effect on its thermosensitivity. Another class of MuSVts110 splicing mutants generated by treatment of MuSVts110-infected cells with NiCl2 was also examined. In these "nickel revertants," P58gag is made, but splicing of the viral transcript is nearly complete at all growth temperatures. The splicing of "tagged" viral RNA transcribed from a modified MuSVts110 DNA introduced into nickel revertant cells remained thermosensitive, arguing against trans effects of viral gene products on splicing efficiency. These experiments indicated that neither the MuSVts110 P58gag protein nor any other viral gene product acts in trans to regulate MuSVts110 splicing.

Reversion of thermosensitive splicing defect of Moloney murine sarcoma virus ts110 by oversplicing of viral RNA

Moloney murine sarcoma virus ts110 possesses a thermosensitive splicing defect. By continuously growing nonproducer cells at the nonpermissive temperature, a new class of revertant cells, termed 6m3, that had lost the thermosensitive splicing defect was produced, and six distinct clones were selected. These cell clones were transformed at either permissive or restrictive temperatures. Unlike parental 6m2 cells, which contain two virus-specific RNA species of 4.0 and 3.5 kilobases (kb) at temperatures permissive for transformation, the 3.5-kb RNA was the only virus-specific RNA species detected in 6m3 clones. No new v-mos-containing DNA fragment was observed in Southern blot analysis of these cell clones compared with parental 6m2 cells, indicating that the 3.5-kb RNA was a splicing product rather than a direct transcript. Moreover, these cells expressed P85gag-mos but not P58gag at any temperature. The reversion of the phenotype in 6m3 cell clones appears to be the result of a selective loss of the temperature sensitivity of the splicing reaction, without affecting the thermosensitivity of the protein kinase activity. This change also appears to alter the mechanism regulating the efficiency of the genomic RNA-splicing reaction.

Vimentin phosphorylation by p37mos protein kinase in vitro and generation of a 50-kDa cleavage product in v-mos-transformed cells

Previous studies have shown that vimentin, an intermediate filament protein, is reduced in amount in cells acutely infected with Moloney mouse sarcoma virus (Mo-MuSV). In this report, we provide evidence for specific alteration of vimentin in Mo-MuSV-transformed cells and demonstrate specific phosphorylation of vimentin by the p37mos protein kinase in vitro. Specificity of the phosphorylation reaction was demonstrated by using viral mos proteins encoded by various isolates of Mo-MuSV and p37mos produced in yeast. A phosphotransfer domain mutant lacking the ability to autophosphorylate p37mos failed to phosphorylate vimentin. Similarly, vimentin was not phosphorylated by the temperature-sensitive P85gag-mos kinase derived from infected cells maintained at the restrictive temperature. In ts110 MuSV-transformed NRK cells, vimentin was phosphorylated at both the permissive and nonpermissive temperatures for transformation. However, at the permissive temperature, an altered form of vimentin (about 50 kDa) with a more basic isoelectric point and lower apparent molecular weight was detected. This 50-kDa product was highly phosphorylated as compared to the bulk of the normal 55-kDa form of vimentin. On the basis of its mobility in two-dimensional gels, the 50-kDa form of vimentin should lack the carboxy terminus. This type of alteration could conceivably modulate the function of vimentin filaments in the transformed cell.

Exploitation of a thermosensitive splicing event to study pre-mRNA splicing in vivo

The spliced form of MuSVts110 viral RNA is approximately 20-fold more abundant at growth temperatures of 33 degrees C or lower than at 37 to 41 degrees C. This difference is due to changes in the efficiency of MuSVts110 RNA splicing rather than selective thermolability of the spliced species at 37 to 41 degrees C or general thermosensitivity of RNA splicing in MuSVts110-infected cells. Moreover, RNA transcribed from MuSVts110 DNA introduced into a variety of cell lines is spliced in a temperature-sensitive fashion, suggesting that the structure of the viral RNA controls the efficiency of the event. We exploited this novel splicing event to study the cleavage and ligation events during splicing in vivo. No spliced viral mRNA or splicing intermediates were observed in MuSVts110-infected cells (6m2 cells) at 39 degrees C. However, after a short (about 30-min) lag following a shift to 33 degrees C, viral pre-mRNA cleaved at the 5' splice site began to accumulate. Ligated exons were not detected until about 60 min following the initial detection of cleavage at the 5' splice site, suggesting that these two splicing reactions did not occur concurrently. Splicing of viral RNA in the MuSVts110 revertant 54-5A4, which lacks the sequence -AG/TGT- at the usual 3' splice site, was studied. Cleavage at the 5' splice site in the revertant viral RNA proceeded in a temperature-sensitive fashion. No novel cryptic 3' splice sites were activated; however, splicing at an alternate upstream 3' splice site used at low efficiency in normal MuSVts110 RNA was increased to a level close to that of 5'-splice-site cleavage in the revertant viral RNA. Increased splicing at this site in 54-5A4 viral RNA is probably driven by the unavailability of the usual 3' splice site for exon ligation. The thermosensitivity of this alternate splice event suggests that the sequences governing the thermodependence of MuSVts110 RNA splicing do not involve any particular 3' splice site or branch point sequence, but rather lie near the 5' end of the intron.

Activation of thermosensitive RNA splicing and production of a heat-labile P85gag-mos kinase by the introduction of a specific deletion in murine sarcoma virus-124 DNA

Murine sarcoma virus ts110 (MuSVts110) is a conditionally transformation-defective MuSV mutant lacking 1,487 bases found in its wild-type parent, MuSV-349 (MuSV-124). Expression of the MuSVts110 v-mos gene product, P85gag-mos, requires splicing of the viral transcript to align the gag and mos genes in frame. However, this splice event is restricted to growth temperatures of 33 degrees C or lower. No splicing of the viral RNA, no production of P85gag-mos, and, hence, no cell transformation is observed at growth temperatures above 33 degrees C. To determine whether thermosensitive splicing is an intrinsic property of To determine whether thermosensitive splicing is an intrinsic property of MuSVts110 RNA specified by the 1,487-base deletion or a result of a cellular defect, we examined an "equivalent" or MuSVts110 DNA (designated ts32 DNA) constructed by combining wild-type MuSV-124 DNA fragments with a synthetic oligonucleotide to yield an otherwise wild-type viral DNA containing the same 1,487-base deletion as authentic MuSVts110. As observed in control cells (6m2 cells) infected with the authentic MuSVts110 virus, NIH 3T3 cells transfected with ts32 DNA appeared morphologically transformed when grown at 33 degrees C, but were converted to a more normal, flattened shape within a few hours of a shift to 39 degrees C. In concert with these morphological changes, both the processing of the ts32 RNA transcripts and the production of ts32 p85gag-mos kinase were found to be optimal at growth temperatures from 28 to 33 degrees C, but dramatically reduced at 37 to 41 degrees C. Like authentic P85gag-mos, the ts32 P85gag-mos kinase activity was rapidly inactivated by brief exposure to 39 degrees C. These results suggested that the MuSVts110 equivalent is functionally indistinguishable from authentic MuSVts110 and that the novel temperature-sensitive splicing of MuSVts110 transcripts is specified by an intrinsic property of the viral RNA.

The histidine-221 to tyrosine substitution in v-mos abolishes its biological function and its protein kinase activity

The viral mos gene encodes a cytoplasmic transforming protein termed p37mos. Evidence gathered from a number of experimental approaches is consistent with p37mos having a serine/threonine protein kinase activity. To gain further understanding of the p37mos-associated biochemical activity, we constructed a mutation in the v-mos gene by oligonucleotide-directed mutagenesis yielding a histidine to tyrosine substitution at residue 221 in p37mos. Based upon nucleotide sequences, the histidine residue at the corresponding position is conserved in all the serine/threonine protein kinases from yeast to man, and is absent in protein-tyrosine kinases. The mutant p37mos (Tyr-221) was expressed in yeast and assayed for kinase activity. The mutant protein was inactive as judged by a loss of autophosphorylation activity in vitro, thus providing further support for the conclusion that p37mos is a protein kinase. When the mutant v-mos gene was introduced into a retroviral vector, pDD102, and assayed for focus-forming ability on NIH/3T3 cells, it was found to be inactive at both 37 and 30 degrees. In contrast, the wild-type v-mos had transforming activity at both temperatures. These results extend our earlier findings on the correlation between transforming ability and protein kinase activity. A histidine to tyrosine substitution at the corresponding position of the v-mos protein and the yeast CDC28 gene product causes a similar effect on the kinase activity. Therefore, this residue and/or the sequence near the N-terminal side of the conserved predicted phosphate transfer domain, near the middle of the complete catalytic domain, might be specifically involved in the catalytic activity of serine/threonine protein kinases in general.

Exploitation of a thermosensitive splicing event to study pre-mRNA splicing in vivo

The spliced form of MuSVts110 viral RNA is approximately 20-fold more abundant at growth temperatures of 33 degrees C or lower than at 37 to 41 degrees C. This difference is due to changes in the efficiency of MuSVts110 RNA splicing rather than selective thermolability of the spliced species at 37 to 41 degrees C or general thermosensitivity of RNA splicing in MuSVts110-infected cells. Moreover, RNA transcribed from MuSVts110 DNA introduced into a variety of cell lines is spliced in a temperature-sensitive fashion, suggesting that the structure of the viral RNA controls the efficiency of the event. We exploited this novel splicing event to study the cleavage and ligation events during splicing in vivo. No spliced viral mRNA or splicing intermediates were observed in MuSVts110-infected cells (6m2 cells) at 39 degrees C. However, after a short (about 30-min) lag following a shift to 33 degrees C, viral pre-mRNA cleaved at the 5' splice site began to accumulate. Ligated exons were not detected until about 60 min following the initial detection of cleavage at the 5' splice site, suggesting that these two splicing reactions did not occur concurrently. Splicing of viral RNA in the MuSVts110 revertant 54-5A4, which lacks the sequence -AG/TGT- at the usual 3' splice site, was studied. Cleavage at the 5' splice site in the revertant viral RNA proceeded in a temperature-sensitive fashion. No novel cryptic 3' splice sites were activated; however, splicing at an alternate upstream 3' splice site used at low efficiency in normal MuSVts110 RNA was increased to a level close to that of 5'-splice-site cleavage in the revertant viral RNA. Increased splicing at this site in 54-5A4 viral RNA is probably driven by the unavailability of the usual 3' splice site for exon ligation. The thermosensitivity of this alternate splice event suggests that the sequences governing the thermodependence of MuSVts110 RNA splicing do not involve any particular 3' splice site or branch point sequence, but rather lie near the 5' end of the intron.

Moloney murine sarcoma virus encoded p37mos expressed in yeast has protein kinase activity

We describe the expression of the Moloney murine sarcoma virus env-mos protein (p37mos) in yeast under the control of the yeast GAL1 promoter. Consistent with our previous results concerning the p37mos protein kinase made in virus infected mouse cells, p37mos produced in yeast possesses autophosphorylation activity in an immune complex kinase assay using anti-mos (37-35) serum.

Antibodies against small nuclear ribonucleoproteins immunoprecipitate complexes containing ts110 Moloney murine sarcoma virus genomic and messenger RNAs

Small nuclear ribonucleoproteins (snRNPs) are believed to play a role in processing premessenger RNAs. In this study, snRNPs were immunoprecipitated from extracts of cells infected with ts110 Moloney murine sarcoma virus (ts110 MoMuSV). Both the unspliced 4.0 kb and the spliced 3.5-kb ts110 MoMuSV specific RNA species were found in the immunoprecipitates obtained with monoclonal antibody anti-Sm and polyclonal anti-Sm, anti-(U1) RNP and anti-La sera. Although only a portion of the total ts110 RNAs was present in these immunoprecipitates, immune recognition by the anti-snRNPs was specific and not due to contaminating anti-RNA (at least for the anti-Sm sera) or, to anti-viral protein activities. Genomic 8.3-kb RNA and subgenomic 3.0-kb spliced env mRNA from Moloney murine leukemia virus (MoMuLV) infected cells as well as the cellular actin mRNA were also detected in immunoprecipitates obtained with the same antisera. The fact that pre-mRNAs and mature mRNAs of different origin can be recovered from immunoprecipitates formed with anti-snRNP sera establishes their tight association and confirms the role of snRNPs in mRNA processing.

Temperature-sensitive splicing defect of ts110 Moloney murine sarcoma virus is virus encoded

ts110 Moloney murine sarcoma virus (Mo-MuSV)-nonproductively infected cells (6m2) have a transformed phenotype at 28 to 33 degrees C and a normal phenotype at 39 degrees C. At temperatures permissive for transformation, 6m2 cells contain P58gag produced from the 4.0-kilobase (kb) viral RNA genome and P85gag-mos translated from a 3.5-kb spliced mRNA. At 39 degrees C, only the 4.0-kb RNA and its product P58gag are detected. Two temperature-sensitive defects have been observed in ts110-infected 6m2 cells: (i) the splicing of the 4.0-kb RNA to the 3.5-kb RNA; and (ii) the thermolability of P85gag-mos and its kinase activity relative to the wild-type revertant protein, termed P100gag-mos (R.B. Arlinghaus, J. Gen. Virol. 66:1845-1853, 1985). In the present study, we examined the mos gene products of two cell lines (204-2F6 and 204-2F8) obtained by infection of normal rat kidney cells with ts110 Mo-MuSV as a simian sarcoma-associated virus pseudotype to see whether the temperature-sensitive splicing defect could be transferred by viral infection. Southern blot analysis of these two cell lines showed that viral DNAs containing restriction fragments from cellular DNA are different from those in 6m2 cells, indicating that 204-2F6 and 204-2F8 cells have different ts110 provirus integration sites from those of 6m2 cells. Northern blots, S1 mapping analyses, and immunoprecipitation experiments showed unequivocally that the splicing defect of ts110 Mo-MuSV is virus encoded and is independent of host cell factors.

Serine kinase activity associated with Maloney murine sarcoma virus-124-encoded p37mos

An antiserum directed against amino acid residues 37-55 [anti-mos (37-55) serum] of the predicted v-mos sequence was used to precipitate p37mos from Moloney murine sarcoma virus-124 (Mo-MuSV-124) acutely infected 3T3 cells. Proteins with sizes ranging from p37mos to 43 kDa (p43) were found to be phosphorylated when anti-mos (37-55) immune complexes containing p37mos were incubated with [gamma-32P]ATP and Mn2+. The phosphorylation of p37mos and p43 could be specifically blocked when the anti-mos (37-55) serum was incubated with 37-55 cyclic mos peptide prior to immunoprecipitation, but not if the serum was preincubated with an unrelated peptide representing amino acids of the myc protein sequence. Anti-mos (37-55) immune complexes from uninfected 3T3 cells did not produce any phosphorylated proteins the size of p37mos or p43. However, a 50-kDa protein (p50) was phosphorylated in both unblocked and mos peptide-blocked anti-mos (37-55) immune complexes from infected 3T3 cells, and in immune complexes from uninfected cells. Quercetin, an inhibitor of some protein kinases, inhibited the kinase phosphorylating p50 but not the kinase phosphorylating p37mos and p43. Preabsorption of the cell extract prior to immunoprecipitation with an excess of formalin-fixed Staphylococcus aureus, complexed with preimmune normal rabbit serum IgG, specifically removed the kinase phosphorylating p50. The amount of in vitro phosphorylated p37mos and p43 in the immune-complex kinase assay reached a maximum in extracts of 3T3 cells 2-3 days postinfection with Mo-MuSV 124 but decreased to trace levels after 5 days. Metabolically and in vitro phosphorylated p37mos generated an identical pattern of phosphopeptides upon partial V8 protease digestion. Based on peptide mapping and a kinetic analysis of the in vitro phosphorylation reaction, p37mos appears to be a precursor to the p43 phosphorylated species. Phosphoamino acid analyses revealed only phosphoserine in in vitro phosphorylated p37mos and p43mos. It was concluded that p37mos is closely associated with a serine kinase activity and that the in vitro phosphorylation of p37mos may lead to formation of a highly modified mos protein (p43) by way of superphosphorylation.

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)

Temperature-sensitive viral RNA expression in Moloney murine sarcoma virus ts110-infected cells

We examined the mos-specific intracellular RNA species in 6m2 cells, an NRK cell line nonproductively infected with the ts110 mutant of Moloney murine sarcoma virus. These cells present a normal phenotype at 39 degrees C and a transformed phenotype at 28 or 33 degrees C, expressing two viral proteins, termed P85gag-mos and P58gag, at 28 to 33 degrees C, whereas only P58gag is expressed at 39 degrees C. It has been previously shown that 6m2 cells contain two virus-specific RNA species, a 4.0-kilobase (kb) RNA coding for P58gag and a 3.5-kb RNA coding for P85gag-mos. Using both Northern blot and S1 nuclease analyses, we show here that the 3.5-kb RNA is the predominant viral RNA species in 6m2 cells grown at 28 degrees C, whereas only the 4.0-kb RNA is detected at 39 degrees C. During temperature shift experiments, the 3.5-kb RNA species disappears after a shift from 28 to 39 degrees C and is detected again after a shift back from 39 to 28 degrees C. By Southern blot analysis, we have detected only one ts110 proviral DNA in the 6m2 genome. This observation, as well as previously published heteroduplex and S1 nuclease analyses which showed that the 3.5-kb RNA species lacks about 430 bases found at the gag gene-mos gene junction in the 4.0-kb RNA, suggests that the 3.5-kb RNA is a splicing product of the 4.0-kb RNA. The absence of the 3.5-kb RNA when 6m2 cells are grown at 39 degrees C indicates that the splicing reaction is thermosensitive. The splicing defect of the ts110 Moloney murine sarcoma virus viral RNA in 6m2 cells cannot be complemented by acute Moloney murine leukemia virus superinfection, since no 3.5-kb ts110 RNA was detected in acutely superinfected 6m2 cells maintained at 39 degrees C. The spliced Moloney murine leukemia virus env mRNA, however, is found in acutely infected cells maintained at 39 degrees C, suggesting that the lack of ts110 viral RNA splicing at 39 degrees C is not due to an obvious host defect. In sharp contrast, however, 6m2 cells chronically superinfected with Moloney murine leukemia virus produce a 3.5-kb RNA species at 39 degrees C as well as at 28 degrees C and contain proviral DNAs corresponding to the two viral RNA species.(ABSTRACT TRUNCATED AT 400 WORDS)

The gag-mos hybrid protein of ts110 Moloney murine sarcoma virus: variation of gene expression with temperature

A NRK cell clone (6m2 cells) infected with ts110 Moloney murine sarcoma virus (MuSV) produce a gag-mos protein, P85gag-mos, and a truncated gag protein of Mr 58,000d termed P58gag. The gag-mos protein is produced from a 3.5-kb mRNA whereas the gag protein is made from a 4.0-kb mRNA. It has been proposed that the 3.5-kb RNA is produced from the 4.0-kb RNA by a splicing mechanism (R. P. Junghans, E. C. Murphy, Jr., and R. B. Arlinghaus (1982) J. Mol. Biol. 161, 229-255). The results presented here provide further support for this model. The expression of the 3.5-kb RNA and the gag-mos protein increased as the temperature at which 6m2 cells were maintained was lowered from 39 to 28 degrees. This increase coincided with a decrease in both the 4.0-kb RNA and its product P58gag. The optimum temperature for syntheses of both the gag-mos mRNA and its protein was found to be 28 degrees. Consistent with the increase in the level of the gag-mos protein is the increase in the protein kinase activity associated with P85gag-mos and the degree of morphological transformation of 6m2 cells. Thus, the level of P85gag-mos within 6m2 cells is directly proportional to the degree of cell transformation and the amount of the kinase activity associated with the gag-mos protein, providing convincing evidence that P85gag-mos plays a direct role in the neoplastic transformation of these cells.

Further characterization of the P85gag-mos -associated protein kinase activity

The gag-mos hybrid protein encoded by ts110 MoMuSV was shown to have an associated protein kinase activity which phosphorylated both P85gag-mos and P58gag when [gamma-32P]ATP and a manganese cofactor were added to an immune complex containing P85gag-mos. Immunoprecipitation and removal of P85gag-mos from the reaction mixture by either an anti-mos or anti-gag serum resulted in a subsequent elimination of in vitro P85gag-mos and P58gag phosphorylation. This kinase activity was shown to be either an intrinsic property of P85gag-mos or else a tightly bound cellular enzyme activity resistant to elution with 2.0 M NaCl, 0.5% deoxycholate, and 0.1% SDS. A correlation was made between the amount of kinase activity and the concentration of P85gag-mos. Viral gag antisera were also used to show immune complex phosphorylation of another gag-mos hybrid protein termed P100gag-mos, derived from a revertant of ts110. In vitro phosphorylation experiments derived from v-mos transformed MuSV 124 cells using viral gag antisera were completely negative which shows that the gag-mos kinase in 6m2 cells is not merely a gag-associated kinase that phosphorylates MuSV coded gag gene products. When shifting 6m2 cells from a permissive temperature to the nonpermissive temperature of 39 degrees for 2-4 hr, a noticeable change toward a more normal morphology occurs. NRK 54-5A4 cells infected with a revertant of ts110 with wild-type phenotype, showed little change in morphology between permissive and nonpermissive temperatures. In addition to the ts defect affecting P85gag-mos production previously reported, a second ts defect in ts110 is reported here which is functional in nature; it can be detected within 5 min after shift to 39 degrees by the heat lability of the P85-associated kinase activity. The P100gag-mos protein kinase from the wild-type revertant cells did not exhibit this heat sensitivity under similar conditions. The thermal inactivation of the P85 kinase was shown to precede events that occur as cells are shifted to the restricted temperature including morphological reversion to the normal phenotype, and the decrease in P85gag-mos concentration. Based on all of these observations, it is suggested that the P85-associated kinase activity is not merely an adherent cellular kinase, but actually a function of the gag-mos gene product.

S1 nuclease mapping of viral RNAs from a temperature-sensitive transformation mutant of murine sarcoma virus

The structures of murine sarcoma virus (MuSV) ts110 viral RNA and intracellular RNA present in MuSV ts110-infected cells (6m2 cells) have been examined by S1 nuclease analysis. A previous study involving heteroduplex analysis of MuSV ts110 viral RNAs hybridized to wild-type DNA revealed the presence of two MuSV ts110 RNAs, 4.0 and 3.5 kilobases (kb) in length, containing overlapping central deletions relative to wild-type MuSV 124 viral RNA (Junghans et al., J. Mol. Biol. 161:229-255, 1982). Here we show that the deletion (termed delta 1) in the 4.0-kb RNA has a 5' border located at about nucleotide 2409 (using the numbering system of Van Beveren et al., Cell 27:97-108, 1981), a position 63 bases upstream of the junction of the p30 and p10 coding sequences. The 3' border of the delta 1 deletion is found 1,473 bases downstream at approximately nucleotide 3883, 10 nucleotides downstream of the first mos gene initiation codon. In the 3.5-kb MuSV ts110 RNA, the 5' border of the deleted central region (termed delta 2) is located in a splice consensus donor site at approximately nucleotide 2017, 330 bases downstream from the junction of the p12 and p30 coding sequences, and extends about 1,915 bases in the downstream direction to nucleotide 3935, found in a splice consensus acceptor site about 55 nucleotides downstream of the first mos gene initiation codon and 30 bases upstream of the second initiation codon. No alteration of polyadenylate addition sites was observed in either MuSV ts110 RNA species, as compared with MuSV 349 RNA. The observation that the 5' and 3' borders of the deletion in the 3.5-kb RNA are within in-frame splice donor and acceptor sites suggests strongly that the 3.5-kb RNA is derived from the 4.0-kb RNA by a temperature-sensitive splice mechanism. Data presented here show unequivocally that formation of the 3.5-kb MuSV ts110 RNA from which the P85gag-mos polypeptide is translated is temperature sensitive. At 33 degrees C, with S1 analysis, the 3.5-kb RNA is found readily in 6m2 cells. Within 4 h of a shift to 39 degrees C, however, only trace amounts of this RNA can be found. Moreover, reshifting 6m2 cells to 33 degrees C permits the reappearance of the 3.5-kb RNA at its original level.

Incorporation of lipids into variants of Moloney sarcoma virus which produce gag-mos fusion proteins

Several transforming gene products of mammalian retroviruses undergo post-translational addition of fatty acids. This report demonstrates that gag-mos fusion proteins from variant strains of murine sarcoma viruses incorporate both myristate and palmitate. However, the inefficiency of palmitate incorporation, as well as incorporation of that fatty acid into gag proteins, suggest that palmitate is metabolized to myristate before becoming bound to virus proteins. Furthermore, no detectable post-translational processing event is apparently required for addition of myristate, suggesting that such an event is unnecessary for association of gag-mos proteins with cell membranes.

Gag-mos Polyproteins encoded by variants of the Moloney strain of mouse sarcoma virus

Two revertants of ts110 Moloney murine sarcoma virus (MuSV) with wild-type MuSV phenotype were examined for the presence of mos gene products, ts110 MuSV has a temperature-sensitive defect in a function required to maintain the transformed phenotype. The nonproducer 6m2 cell clone transformed by ts110 produces an 85,000-Da gag-mos protein (P85gag-mos) and a 58,000-Da gag protein (P58gag). A spontaneous revertant (clone 54-5A4) of the 6m2 cell clone produces a 100,000-Da protein (P100) recognized by antisera raised against murine leukemia virus p15, p12, and p30 but lacks determinants of p10, reverse transcriptase, and gp70. P100 was specifically recognized by antisera (anti-C3) prepared against a synthetic peptide representing the predicted C-terminal 12 amino acids of Moloney MuSV v-mos gene. Normal sera or anti-C3 blocked with excess synthetic peptide did not recognize P100. Thus, P100 is a product of the gag and mos genes. P100 was found to be phosphorylated. A second wild-type revertant (clone 204-3) was obtained by superinfection of ts110 nonproducer cells with Simian sarcoma associated virus (SSAV); it was also found to contain a phosphorylated P100gag-mos protein. The 204-3 cell clone also contained two gag polyproteins (Pr60gag and Pr55gag) of the size and antigenic properties of those found in SSAV-infected cells. These results provide two examples of P100 gag-mos proteins both derived from the P85gag-mos producing 6m2 cell clone. The P100 gag-mos polyproteins are made in amounts that are easily detected by radiolabeling experiments using [3H]leucine. The intracellular viral RNAs present in 6m2 cells and the two revertant clones were also examined. All three cell clones contained a 4.0 kb RNA hybridizing to v-mos sequences but only the 6m2 clone contained a 3.5 kb mos-containing RNA. Our findings indicate that the 3.5 kb RNA codes for P85gag-mos in cell-free translation experiments (Junghans et al., 1982, J. Mol. Biol. 161, 229). These findings as they relate to the mechanism that produces P100gag-mos instead of P85gag-mos are discussed.

P85: a gag-mos polyprotein encoded by ts110 Moloney murine sarcoma virus

Antibody to a synthetic peptide (anti-C3 serum) with the predicted sequence of the C terminus of the Moloney murine sarcoma virus (strain 124) v-mos gene was used in immunoprecipitation experiments with cytoplasmic extracts of a clone of NRK cells infected with ts110 Moloney murine sarcoma virus, termed 6m2 cells. ts110 Moloney murine sarcoma virus codes for two viral proteins of 85,000 and 58,000 M(r), termed P85 and P58, respectively, in nonproducer 6m2 cells maintained at 33 degrees C. Anti-C3 serum specifically recognized [(3)H]leucine-labeled P85, but not P58, from infected cells maintained at 33 degrees C, whereas antiserum prepared against murine leukemia virus p12 recognized both proteins. Normal serum and anti-C3 serum pretreated with excess C3 peptide did not precipitate P85. Immunoprecipitation experiments after metabolic labeling of 6m2 cells with (32)P(i) showed that P85 is phosphorylated. Both anti-C3 and anti-p12 sera specifically detected (32)P-labeled P85. Cell-free translation of ts110 murine sarcoma virus/murine lukemia virus RNA produces P85, P58, and helper virus protein Pr63(gag). Anti-C3 serum specifically precipitated P85 but neither P58 nor Pr63(gag). We conclude from these studies that P85 is a product of both the gag and mos genes of ts110 murine sarcoma virus, and, therefore, it is referred to as P85(gag-mos). We have not detected any other v-mos gene product in ts110-infected cells.

Detection of an 85,000-dalton phosphoprotein in ts110 murine sarcoma virus-infected cells with antiserum against a v-mos peptide

We have used an antiserum directed against a synthetic v-mos peptide (anti-C3 serum) to screen ts110 murine sarcoma virus (MuSV)-infected cells for the presence of v-mos-encoded proteins. Anti-C3 serum specifically recognized an 85,000-dalton protein doublet (P85) from [35S]methionine-labeled ts110 MuSV-infected producer cells grown at 32 degrees C, the permissive temperature for transformation. The P85 doublet was also recognized by an antiserum directed against the viral gag protein p15. P85 was present but at 2- to 10-fold-lower levels in ts110 MuSV-infected producer cells grown at 39 degrees C, the restrictive temperature for transformation. The P85gag-mos fusion product was the only v-mos protein reproducibly detected in this ts110 MuSV-transformed cell line. Immunoprecipitation of 32P-labeled cells with anti-C3 serum revealed that the upper band of the P85 doublet is phosphorylated, containing mostly phosphoserine and some phosphothreonine. Cells acutely infected with ts110 MuSV contained slightly higher levels of P85 than did the ts110 MuSV-infected producer cell line. Anti-C3 serum specifically recognized a 33,000-dalton protein (p33) in the acutely infected cells labeled with [35S]methionine. p33 was present in trace amounts and may represent a previously unidentified ts110 MuSV-encoded v-mos protein.