In vitro translation of Harvey murine sarcoma virus RNA.

The viral RNA of the Harvey strain of murine sarcoma virus (Ha-SV), which does not encode for any known viral structural polypeptides, has been translated in a nuclease-digested, cell-free system. The major protein product of the in vitro translation reaction has a molecular weight of 21,000 and is initiated faithfully with [35S]formylmethionine from formyl-[35S]methionyl-tRNAFMET. This polypeptide is clearly distinct from the RNA of the Moloney strain of type C helper virus used to pseudotype the Ha-SV. The intensity of the 21,000-dalton polypeptide on gels correlates well to the concentration of Ha-SV RNA in different viral RNA preparations. These experiments indicate that a polypeptide marker for Ha-SV is now available for the first time. The possibility that this protein is the product of the rat portion of the Ha-SV genome is discussed.     

Radiation-enhanced murine sarcoma virus genome rescue activity.

Although the doses of X-ray (312-2,500 R) used for irradiation of cells caused impairment of DNA synthesis and cell replication, co-cultivation of X-irradiated MuLV- carrier cells with un-irradiated nonproducer cells of MSV-induced tumour resulted in as much as 20-fold increase in MSV retrieval compared with the un-irradiated control. The enhancement was apparent also as a 3-fold increase in the number of cells producing MSV (infectious centers) in the co-cultivation plate. This suggested that the MSV genome rescue efficiency in terms of MSV per cell, as well as the number of cells producing MSV, increased markedly. By uridine-3H-labeling and focus assay experiments, evidence was presented which suggested that an increase in MSV/MuLV ratio in the culture fluid of co-cultivation plates was obtained when the MuLV-carrier cells were pre-irradiated. By contrast, X-irradiation of the nonproducer cells prior to co-cultivation caused only reductions of MSV genome rescue efficiency. However, use of X-irradiated MuLV-carrier cells for co-cultivation with X-irradiated nonproducer cells restored this efficiency to some extent. The dose-survival curve of the nonproducer cells was not much different from those of the MuLV-carrier cells after X-irradiation. It was suggested that the viability of nonproducer cells was required for replication of MuLV transferred from the carrier cells and for subsequent MSV genome rescue.     

An altered DNA sequence encompassing the ras gene of Harvey murine sarcoma virus.

The DNA fragment encompassing the ras gene of Harvey murine sarcoma virus was sequenced and assigned the coding region of a transforming protein, p21, to the sequence. Examination of nucleotide sequence, taken together with the result of analysis of the ras mRNAs (1), has revealed that p21 is encoded from a continuous coding region starting with the 5' proximal initiation codon but not a processed protein. However, there were found several differences between the sequence published by Dhar et. al. (2) and ours, including 9 deletions, 7 substitutions and 2 insertions of nucleotides in the published sequence of 997 nucleotides in length. Among these, one of the substitutions occurring in the coding region resulted in amino acid replacement of glycine by alanine at position 122 of p21. The evidences are presented with some of actual gel autoradiographs.     

Dual evolutionary origin for the rat genetic sequences of Harvey murine sarcoma virus.

Detailed restriction endonuclease maps were developed for Harvey murine sarcoma virus (Ha-MuSV) DNA (clone H-1), molecularly closed at its unique EcoRI site in pBR322, for three nonoverlapping subgenomic HindIII clones which together span the entire H-1 clone and for a molecularly cloned DNA copy of a portion of rat 30S RNA (which represents the majority of the rat genetic sequences in Ha-MuSV). Molecular hybridization of the 30S clone to small restriction fragments of clone H-1 revealed a 0.9-to-1.0-kilobase pair region in the 5' half of the Ha-MuSV genome not homologous to the 30S clone, although the 30S clone did contain related sequences in Ha-MuSV on both sides of this nonhomologous region. By using cloned sequences from a segment of the Ha-MuSV nonhomology region as a probe for hybridization to Southern blots of DNA from rat, mouse, bat, and chicken cells, one to three bands were detected in DNA of each species. By contrast, the 30S clone DNA was highly related to many sequences in rat DNA, partially related to fewer mouse DNA sequences, and homologous only to one to three bands in bat and chicken DNA. Earlier work had shown that the 5' half of the Ha-MuSV genome coded for transformation and for the viral p21 protein (Chang et al., J. Virol. 35: 76--92, 1980; Wei et al., Proc. Natl. Acad. Sci. U.S.A., in press). We used two subgenomic HindIII clones whose shared HindIII site mapped within the 5' region of clone H-1 nonhomologous to the 30S clone to test whether the nonhomologous segment might encode the transforming and p21 functions. Although neither of the subgenomic HindIII fragments by themselves induced transformation, ligation of these two nontransforming DNAs to each other did restore p21-mediated transformation. A conclusion consistent with these results is that a region in the 5' half of the Ha-MuSV genome evolutionarily distinct from and not present in rat 30S RNA is essential for transformation and for p21 encoding.     

Comparison of the genomic organization of Kirsten and Harvey sarcoma viruses.

Current studies were undertaken to compare the genomes of Kirsten murine sarcoma virus (Ki-MuSV), Harvey murine sarcoma virus (Ha-MuSV), and the replication-defective endogenous rat virus to understand the function of these viral RNAs. Genome organization and sequence homology were studied by fingerprinting large RNase T1-resistant oligonucleotides and by cross-protecting homologous oligonucleotides against RNase A and T1 digestion with complementary DNA prepared from each of the other viral RNA. Ki-MuSV and Ha-MuSV were found to share an extensive series of rat-derived oligonucleotides begining ca. 1 kilobase (kb) from the 3' end and extending to within 1.5 kb of the 5'end of Ki-MuSV RNA. The total map distance covered in ca. 5.5 kb. The eight oligonucleotides covering the 1.5 kb at the 5' end of Ki-MuSV RNA were not found in Ha-MuSV RNA. Five out of these eight oligonucleotides, however, could be designated with certainty to be of rat virus origin. Since Ha-MuSV is 6.5 kb in size and Ki-MuSV is 8 kb in size, the major difference between them is the 1.5 kb from the replication-defective endogenous rat virus sequences at the 5' end of Ki-MuSV not present in Ha-MuSV. Consistent with the difference in the genome structure, these two sarcoma viral RNA'S yielded distinct major translation products in cell-free systems, I.E., A 50,000-dalton polypeptide (P50) from Ki-MuSV and a 22,000-dalton polypeptide (p22) from Ha-MuSV. These polypeptides may provide the necessary protein makers for identifying in vivo virus-coded proteins.     

Functional analysis of the murine sarcoma virus RNA packaging sequence

We investigated the features of the Moloney murine sarcoma virus leader sequence necessary for RNA packaging function by using a deletion analysis approach. We found that sequences that extend beyond those characterized genetically in previous reports are important for optimal packaging efficiency. A fragment covering a minimum of four potential stem-loop structures is required for the shortest packaging element compatible with gene transfer. Our results reveal the extent to which each of the segments of the packaging sequence contribute to packaging efficiency.     

Enhanced transformation by a simian virus 40 recombinant virus containing a Harvey murine sarcoma virus long terminal repeat.

We have constructed a recombinant simian virus 40 (SV40) DNA containing a copy of the Harvey murine sarcoma virus long terminal repeat (LTR). This recombinant viral DNA was converted into an infectious SV40 virus particle and subsequently infected into NIH 3T3 cells (either uninfected or previously infected with Moloney leukemia virus). We found that this hybrid virus, SVLTR1, transforms cells with 10 to 20 times the efficiency of SV40 wild type. Southern blot analysis of these transformed cell genomic DNAs revealed that simple integration of the viral DNA within the retrovirus LTR cannot account for the enhanced transformation of the recombinant virus. A restriction fragment derived from the SVLTR-1 virus which contains an intact LTR was readily identified in a majority of the transformed cell DNAs. These results suggest that the LTR fragment which contains the attachment sites and flanking sequences for the proviral DNA duplex may be insufficient by itself to facilitate correct retrovirus integration and that some other functional element of the LTR is responsible for the increased transformation potential of this virus. We have found that a complete copy of the Harvey murine sarcoma virus LTR linked to well-defined structural genes lacking their own promoters (SV40 early region, thymidine kinase, and G418 resistance) can be effectively used to promote marker gene expression. To determine which element of the LTR served to enhance the biological activity of the recombinant virus described above, we deleted DNA sequences essential for promoter activity within the LTR. SV40 virus stocks reconstructed with this mutated copy of the Harvey murine sarcoma virus LTR still transform mouse cells at an enhanced frequency. We speculate that when the LTR is placed more than 1.5 kilobases from the SV40 early promoter, the cis-acting enhancer element within the LTR can increase the ability of the SV40 promoter to effectively operate when integrated in a murine chromosome. These data are discussed in terms of the apparent cell specificity of viral enhancer elements.     

Identification of proteins encoded by the Gazdar murine sarcoma virus genome by in vitro translation and comparison with Moloney murine sarcoma virus 124.

The gene products of Gazdar murine sarcoma virus (Gz-MuSV) were identified by in vitro translation of Gz-MuSV virion RNA. An overlapping set of proteins with approximate molecular weights of 37,000 (37K), 33K, 24K, and 18K were synthesized from the transforming gene of Gz-MuSV, v-mosGz. In addition, Gz-MuSV-specific RNA directed the in vitro synthesis of a 62K gag gene protein and a 37.5K env gene-related product. The Gz-MuSV-specific in vitro translation products were compared with the in vitro translation products of M-MuSV 124, an independent isolate with a similar v-mos gene. This analysis showed that the 62K Gz-MuSV gag gene protein and the 37K, 33K, 24K, and 18K v-mosGz proteins were almost identical to the M-MuSV 124 62K (gag) and 37K, 33K, 24K, and 18K (v-mosMo) proteins that we previously identified and characterized. The 37.5K env gene product from Gz-MuSV does not have a correlate in the M-MuSV 124 translation products. These results were analyzed in the context of expectations based on similarities and differences in genetic organization of these two viral genomes.     

Helper-independent transformation by unintegrated Harvey sarcoma virus DNA.

We have studied the unintegrated infectious DNA of Harvey sarcoma virus (Ha-SV) and Moloney leukemia virus (Mo-MuLV). The source of infectious viral DNA was the Hirt supernatant fraction from cells acutely infected with Ha-SV and Mo-MuLV. To obtain a direct quantitative assay for infectious viral DNA, recipient mouse cells were first exposed to calcium phosphate-precipitated viral DNA and then treated with dimethyl sulfoxide. Infectivity was monitored by focus formation for Ha-SV and XC plaque formation for Mo-MuLV. The viral DNA titration pattern followed single-hit kinetics for both foci and plaques, indicating that a single molecule carried information for each function. Focus-forming and plaque-forming activity were present in different molecules, since these two biological activities could be separated from each other by agarose gel electrophoresis. The focus-forming molecule was linear DNA with a molecular weight of about 4 x 10(6) daltons. The focus-forming activity of the viral DNA was sensitive to EcoRI and resistant to XhoI restriction endonucleases, whereas the plaque-forming activity was resistant to EcoRI and sensitive to XhoI. The generation of helper-independent foci indicates that Ha-SV DNA can transform mouse cells in the absence of helper virus or its proteins.     

Harvey sarcoma virus genome contains no extensive sequences unrelated to those of other retroviruses except ras.

The Harvey murine sarcoma virus genome contains two rat-derived sets of genetic information recombined with the Moloney mouse leukemia virus. The rat sequences represent a ras oncogene and a rat VL30 element. The VL30 sequences have several discrete regions of similarity with retroviral sequences which were detected by searching a protein database for similarities with predicted polypeptide sequences from the VL30 regions. On the 5' side, the most similar sequences were those of feline sarcoma viruses; on the 3' side, murine leukemia viruses were the most similar. Some of the regions of similarity could also be detected directly by searching a nucleic acid sequence database with the viral DNA sequences. The most extensive region of similarity was that which corresponded to the endonuclease in the pol gene of a murine leukemia virus. The majority of the rat-derived sequences present in the Harvey sarcoma virus genome can now be attributed exclusively to ras or retrovirus- or retrotransposon-related sequences.     

Further genetic localization of the transforming sequences of the p21 v-ras gene of Harvey murine sarcoma virus.

The sequences encoding the 21-kilodalton transforming protein (p21 ras) of Harvey murine sarcoma virus have previously been localized genetically to a 1.3-kilobase segment of the viral DNA (E. H. Chang, R. W. Ellis, E. M. Scolnick, and D. R. Lowy, Science 210:1249-1251, 1980). Within this segment, DNA sequence analysis has found a single open reading frame large enough to encode the viral p21 (R. Dhar, R. W. Ellis, T. Y. Shih, S. Oroszlan, B. Shapiro, J. Maizel, D. Lowy, and E. M. Scolnick, Science 217:934-937, 1982). There are three potential in-frame ATG initiation codons at the 5' end of this open reading frame. By constructing a mutant of Harvey murine sarcoma virus DNA from which the first two ATG codons of this open reading frame have been deleted, we now show by transfection of the mutant viral DNA into NIH 3T3 cells that only the third ATG codon is necessary and sufficient for synthesis of the viral p21 and for cellular transformation.     

Base sequence differences between the RNA components of Harvey sarcoma virus.

The 50 to 70S RNA of the Harvey sarcoma-Moloney leukemia virus (MLV) complex consists of 30 to 40S RNA subunits of two different size classes and contains sequences homologous to Moloney mouse leukemia virus and to information contained in a C-type rat virus, termed NRK virus. We have isolated by preparative gel electrophoresis the large (component 1) and the small (component 2) 30 to 40S RNA species from the Harvey sarcoma-MLV complex. Harvey RNA component 1 was completely complementary to DNA transcribed from MLV RNA and showed no homology to DNA transcribed from NRK virus when annealed under conditions of DNA excess. Harvey RNA component 2 was about 65% complementary to MLV DNA and about 33% complementary to NRK virus DNA. Approximately 60 to 80% of the MLV-specific sequences in RNA component 2 is either a distinct molecular species or is part of a hydrid molecular including NRK virus- and MLV-specific sequences. The rest of the MLV sequences in component 2 could be accounted for by degraded component 1 co-purifying with component 2. The possible role of these sequences in the ability of the virus to transform cells is discussed.     

Development and analysis of a transformation-defective mutant of Harvey murine sarcoma tk virus and its gene product.

The Harvey murine sarcoma virus has been cloned and induces focus formation on NIH 3T3 cells. Recombinants of this virus have been constructed which include the thymidine kinase gene of herpes simplex virus type 1 in a downstream linkage with the p21 ras gene of Harvey murine sarcoma virus. Harvey murine sarcoma tk virus rescued from cells transfected with this construct is both thymidine kinase positive and focus inducing in in vitro transmission studies. The hypoxanthine-aminopterin-thymidine selectability of the thymidine kinase gene carried by this virus has been exploited to develop three mutants defective in the p21 ras sequence. All three are focus negative and thymidine kinase positive when transmitted to suitable cells. Of these, only one encodes a p22 that is immunologically related to p21. This mutant has been used to explore the relationship between the known characteristics of p21 and cellular transformation. Data presented herein indicate that the p21 of Harvey murine sarcoma virus consists of at least two domains, one which specifies the guanine nucleotide-binding activity of p21 and the other which is involved in p21-membrane association in transformed cells.     

Harvey murine sarcoma virus p21 ras protein: biological and biochemical significance of the cysteine nearest the carboxy terminus.

Previous studies of premature chain termination mutants and in frame deletion mutants of the p21 ras transforming protein encoded by the transforming gene of Harvey murine sarcoma virus (Ha-MuSV) have suggested that the C terminus is required for cellular transformation, lipid binding, and membrane localization. We have now further characterized the post-translational processing of these mutants and have also studied two C-terminal v-rasH point mutants: one encodes serine in place of cysteine-186, the other threonine for valine-187. The Thr-187 mutant was transformation-competent, and its p21 protein was processed normally, as was the p21 encoded by a transformation-competent deletion mutant from which amino acids 166-175 had been deleted. The Ser-186 mutant was defective for transformation. The p21s encoded by the Ser-186 mutant and by the previously described transformation-defective mutants did not undergo the posttranslational processing common to biologically active ras proteins: their electrophoretic migration rate did not change, they remained in the cytosol, and they failed to bind lipid. Since the cell-encoded ras proteins also contain this cysteine, we conclude that this amino acid residue is required for all ras proteins.     

Functional characterization of the dimer linkage structure RNA of Moloney murine sarcoma virus

Several determinants that appear to promote the dimerization of murine retroviral genomic RNA have been identified. The interaction between these determinants has not been extensively examined. Previously, we proposed that dimerization of the Moloney murine sarcoma virus genomic RNAs relies upon the concentration-dependent interactions of a conserved palindrome that is initiated by separate G-rich stretches (H. Ly, D. P. Nierlich, J. C. Olsen, and A. H. Kaplan, J. Virol. 73:7255-7261, 1999). The cooperative action of these two elements was examined using a combination of genetic and antisense approaches. Dimerization of RNA molecules carrying both the palindrome and G-rich sequences was completely inhibited by an oligonucleotide complementary to the palindrome; molecules lacking the palindrome could not dimerize in the presence of oligomers that hybridize to two G-rich sequences. The results of spontaneous dimerization experiments also demonstrated that RNA molecules lacking either of the two stretches of guanines dimerized much more slowly than the full-length molecule which includes the dimer linkage structure (DLS). However, the addition of an oligonucleotide complementary to the remaining stretch of guanines restored the kinetics of dimerization to wild-type levels. The ability of this oligomer to rescue the kinetics of dimerization was dependent on the presence of the palindrome, suggesting that interactions within the G-rich regions produce changes in the palindrome that allow dimerization to proceed with maximum efficiency. Further, unsuccessful attempts to produce heterodimers between constructs lacking various combinations of these elements indicate that the G-rich regions and the palindrome do not interact directly. Finally, we demonstrate that both of these elements are important in maintaining efficient viral replication. Modified antisense oligonucleotides targeting the DLS were found to reduce the level of viral vector titer production. The reduction in viral titer is due to a decrease in the efficiency of viral genomic RNA encapsidation. Overall, our data support a dynamic model of retroviral RNA dimerization in which discrete dimerization elements act in a concerted fashion.     

Physical map of biologically active Harvey sarcoma virus unintegrated linear DNA.

BALB/c JLS V9 cells recently infected with Harvey sarcoma virus-murine leukemia virus (HSV-MuLV) complex contained unintegrated HSV linear DNA of 6.0-kilobase pair mass. The cells also contained two HSV closed circular DNA species along with MuLV-encoded linear and closed circular DNA species. HSV 6.0-kilobase pair linear DNA induced focal transformation upon transfection of NIH 3T3 mouse fibroblasts, and the biological activity of HSV DNA did not require helper MuLV functions. A physical map of restriction endonuclease cleavage sites along HSV 6.0-kilobase pair linear DNA was derived. Comparison of this map with one for Moloney MuLV DNA showed that the HSV and Moloney MuLV genomes are identical near their viral RNA 3' ends.