Demonstration of biological activity and nucleotide sequence of an in vitro synthesized clone of the Moloney murine sarcoma virus mos gene

v-mos protein produced by in vitro translation has protein kinase activity

The v-mos protein, termed p37v-mos, has a closely associated serine/threonine protein kinase activity. To provide further information about its protein kinase activity, we tested the activity of p37v-mos produced in a cell-free translation system from transcripts generated from a cloned v-mos gene. Anti-mos(37-55) immunoprecipitates of in vitro-produced p37v-mos were found to possess serine/threonine protein kinase activity, whereas those obtained with anti-mos(260-271), known to block v-mos autophosphorylation, lacked kinase activity. The phosphorylated products were identical in size to p37v-mos and p43v-mos produced in protein kinase assays from Moloney murine sarcoma virus-infected cells expressing authentic p37v-mos. These results provide further proof that the protein kinase activity associated with p37v-mos is an intrinsic property of the v-mos gene product. This translation system also provides a useful experimental model to study the activation of the mos protein kinase. Thus, protein kinase assays performed on [35S]methionine-labeled p37v-mos produced p43v-mos at the expense of p37v-mos. Phosphatase treatment removed the p43v-mos species, resulting in increase of the p37v-mos-sized protein, confirming our previous interpretation that p43v-mos is a hyperphosphorylated form of p37v-mos.

Two domains distantly related to protein-tyrosine kinases in the vesicular stomatitis virus polymerase

We have carried out an exhaustive search for amino acid sequence similarities between vesicular stomatitis virus (VSV) proteins and database entries. Unexpectedly, we found that the L polymerase protein contains two blocks of sequence (residues 725-1102 and 1291-1671) with distant but statistically significant similarity to the catalytic domain of tyrosine-specific protein kinases. The first kinase-like region is most similar to members of the Abl subfamily, Fes and Fps (26.6% and 27.3% identity, respectively), whereas the second region is closest to members of the platelet-derived growth factor receptor (PDGFR) subfamily, PDGFR and Kit (30.4% and 25.9% identity, respectively). Multiple alignment of the catalytic domain of these kinases to all three rhabdovirus L protein sequences available (VSV Indiana, VSV New Jersey, and rabies) revealed that the polymerases contain many but not all residues well conserved in the protein kinase family. Similarity was highest for VSV Indiana and lowest for rabies. We conclude that the kinase-like regions in the rhabdoviral L proteins are probably very distantly related to the protein kinase family. The similarities could either reflect contemporary protein kinase activity or represent some other function(s) associated with these large multifunctional polymerase proteins. Our findings also shed new light on questions of the origins and evolution of RNA viruses.

Biologically active mutants with deletions in the v-mos oncogene assayed with retroviral vectors

We have constructed retroviral expression vectors by manipulation of the Moloney murine leukemia virus genome such that an exogenous DNA sequence may be inserted and subsequently expressed when introduced into mammalian cells. A series of N-terminal deletions of the v-mos oncogene was constructed and assayed for biological activity with these retroviral expression vectors. The results of the deletion analysis demonstrate that the region of p37mos coding region upstream of the third methionine codon is dispensable with respect to transformation. However, deletion mutants of v-mos which allow initiation of translation at the fourth methionine codon have lost the biological activity of the parental v-mos gene. Furthermore, experiments were also carried out to define the C-terminal limit of the active region of p37mos by the construction of premature termination mutants by the insertion of a termination oligonucleotide. Insertion of the oligonucleotide just 69 base pairs upstream from the wild-type termination site abolished the focus-forming ability of v-mos. Thus, we have shown the N-terminal limit of the active region of p37mos to be between the third and fourth methionines, while the C-terminal limit is within the last 23 amino acids of the protein.

The primary structure of the putative oncogene pim-1 shows extensive homology with protein kinases

We have shown previously that the putative oncogene pim-1 is frequently activated by provirus insertion in murine leukemia virus-induced T cell lymphomas. Here we describe the structure of the pim-1 gene as determined by sequencing genomic and cDNA clones. The gene has an open reading frame, encoding a protein of 313 amino acids, extending over six exons and preceded and followed by stop codons in all reading frames. Proviruses always integrate outside the protein-encoding domain, showing a high preference for a small region in the 3'-terminal exon; integration in the 3' exon results in relatively high levels of pim-1 mRNA. Computer search reveals homology between pim-1 and protein kinases: all the domains characteristic of protein kinases are conserved in the pim-1 amino acid sequence. The highest homologies were observed with the protein-serine kinases.

Molecular basis underlying phenotypic revertants of Moloney murine sarcoma virus MuSVts110

We examined the molecular basis for phenotypic reversion in cells infected with a transformation mutant of murine sarcoma virus, MuSVts110. In MuSVts110-infected NRK cells (6m2 cells), the manifestation of the transformed phenotype at 33 degrees C and the normal phenotype at 39 degrees C is governed by thermosensitive splicing of the MuSVts110 primary transcript, a 4.0-kilobase (kb) RNA which contains the gag and mos genes joined out of frame. At 33 degrees C, selectively, the 4.0-kb RNA is processed to a spliced 3.5-kb RNA in which the gag and mos genes are rejoined in a continuous open reading frame, thus allowing synthesis of the P85gag-mos-transforming protein. In contrast, the MuSVts110 revertant cell lines (designated 54-5A4 and 204-3) appear transformed at all growth temperatures from 33 to 39 degrees C and express a P100gag-mos-transforming protein from an apparently unprocessed 4.0-kb viral RNA. In the current study we established both by S1 nuclease analysis and primer extension sequencing that the revertant 54-5A4 and 204-3 4.0-kb viral RNAs suffered a 5-base deletion at the intron-exon border of the 3' splice site. The effect of this deletion is twofold. First, because of the damage to the 3' splice site, the revertant viral 4.0-kb RNAs cannot be processed to the spliced 3.5-kb RNA and, consequently, cannot be translated to P85gag-mos. Second, the 5-base deletion excises an in-frame stop codon positioned at the intron-exon border in the parental RNA and restores the original mos gene reading frame. The net effect is to produce a continuous open reading frame from the gag, alternate mos, and authentic mos gene reading frames which are fused together in the revertant 4.0-kb RNA. This continuous open reading frame can be translated into the P100gag-mos-transforming protein at any growth temperature.

Lysine residue 121 in the proposed ATP-binding site of the v-mos protein is required for transformation

The transforming gene product encoded by Moloney murine sarcoma virus clone 124, p37mos, contains a lysine residue (lysine-121) that is conserved among all members of the protein kinase family. This lysine has been shown to be part of a conserved ATP-binding site in both the catalytic subunit of the cAMP-dependent protein kinase and p60v-src. We wished to determine whether this lysine is required for the transforming activity of p37mos. Two site-specific mutations were therefore constructed, which result in the substitution of an aspartic acid or arginine codon in place of the codon for lysine-121. Both mutations abolished the ability of the mos gene to transform cells. These results show that lysine-121 is required for the ability of p37mos to transform cells and provide evidence for an ATP-binding site in p37mos. Furthermore, these results suggest that the conserved lysine residue is specifically involved in the catalytic activity of protein kinases in general.

Biologically active mutants with deletions in the v-mos oncogene assayed with retroviral vectors

We have constructed retroviral expression vectors by manipulation of the Moloney murine leukemia virus genome such that an exogenous DNA sequence may be inserted and subsequently expressed when introduced into mammalian cells. A series of N-terminal deletions of the v-mos oncogene was constructed and assayed for biological activity with these retroviral expression vectors. The results of the deletion analysis demonstrate that the region of p37mos coding region upstream of the third methionine codon is dispensable with respect to transformation. However, deletion mutants of v-mos which allow initiation of translation at the fourth methionine codon have lost the biological activity of the parental v-mos gene. Furthermore, experiments were also carried out to define the C-terminal limit of the active region of p37mos by the construction of premature termination mutants by the insertion of a termination oligonucleotide. Insertion of the oligonucleotide just 69 base pairs upstream from the wild-type termination site abolished the focus-forming ability of v-mos. Thus, we have shown the N-terminal limit of the active region of p37mos to be between the third and fourth methionines, while the C-terminal limit is within the last 23 amino acids of the protein.

Comparison of myeloproliferative sarcoma virus with Moloney murine sarcoma virus variants by nucleotide sequencing and heteroduplex analysis

The myeloproliferative sarcoma virus (MPSV) was derived by passage of Moloney sarcoma virus (Mo-MuSV) in adult mice. Mo-MuSV variants transform fibroblasts. However, MPSV also affects erythroid, myeloid, and hematopoietic stem cells. The MPSV proviral genome, two temperature-sensitive mutants derived from it, Mo-MuSV variant M1, and Moloney murine leukemia virus (Mo-MuLV) were compared by heteroduplex mapping. MPSV wild type was found to have 1 kilobase pair deleted from the pol gene and to contain v-mos-related sequences. The 3' end of MPSV, including the oncogene-helper junctions, the v-mos gene, and the 3' long terminal repeat, was sequenced and compared with sequences of Mo-MuLV, MSV-124, and the mouse oncogene c-mos. From these data, MPSV appears to be either closely related to the original Mo-MuSV or an independent recombinant of Mo-MuLV and c-mos. Five possible explanations of the altered specificity of MPSV are considered. (i) The MPSV mos protein has properties inherent in c-mos but lost by other Mo-MuSV mos proteins. (ii) The MPSV mos protein has altered characteristics due to amino acid changes. (iii) Due to a frameshift, MPSV codes for a mos protein truncated at the amino terminal and also a novel peptide. (iv) A second novel peptide may be encoded from the 3' env region. (v) MPSV has long terminal repeats and an enhancer sequence more like Mo-MuLV than Mo-MuSV, with a consequently altered target cell specificity.

Molecular cloning and characterization of a leukemia-inducing myeloproliferative sarcoma virus and two of its temperature-sensitive mutants

The myeloproliferative sarcoma virus (MPSV) induces extensive hematopoietic changes, including spleen foci in adult mice, and transforms fibroblasts in vitro. NRK nonproducer cell lines of MPSV and ts temperature-sensitive mutants were analyzed by restriction enzyme digestion and Southern blotting. EcoRI fragments containing the proviral DNAs of MPSV and two temperature-sensitive mutants and rat cellular sequences homologous to c-mos were molecularly cloned. By comparing restriction enzyme cleavage sites, it was shown that the MPSV genome consists only of sequences related either to Moloney murine leukemia virus or to the c-mos mouse oncogenic sequences. Two regions of fragment heterogeneity were observed: (i) in the defective pol gene, where MPSV and the two cloned temperature-sensitive mutants were different from Moloney murine sarcoma virus and from each other, although MPSV wild-type retained more of the pol gene than any of the Moloney murine sarcoma virus isolates; (ii) in the area 3' to the mos gene, which was identical in MPSV and its temperature-sensitive mutants but different from other Moloney murine sarcoma virus variants. Transfection of cloned MPSV DNA in RAT4 cells and virus rescue on infection with Friend murine leukemia virus yielded MPSV which transformed fibroblasts in vitro and also induced spleen foci in adult mice, thus proving that both properties are coded by the same viral genome.

Onc genes and other new targets for cancer chemotherapy

Recent advances in molecular biology have raised the hope that understanding of human cancer might progress rapidly and that improvements in therapy might result (Bishop 1983a, b; Busch 1962; Busch 1976; Duesberg 1983). With the development of gene cloning, DNA sequence analysis and improved hybridization methods, it became possible to evaluate whether cancer results from alteration in gene dosage, point or multiple mutation of genes, translocations, deletions, insertions, inversions, cis or trans altered promoters, amplification, and a variety of other genetic factors, including enhancer elements that alter rates of readouts of particular mRNA species. "Onc genes" are under intensive study because they offer manageable probes for evaluation of these various possibilities and also because the study of their cellular analogs may further understanding of the molecular biology of normal fetal and malignant cells. Despite the excessive enthusiasm of some proponents of this field and the negativism of its critics (Bishop 1983 a, b; Duesberg 1983), it is clear that analytical tools and new information will be of value in further studies on experimental cancer, regardless of whether cellular oncogenes (c-onc genes) have anything to do with human cancer or not. In the meantime, studies on enzymes, proteins and epitopes involved in growth processes, have opened new avenues for inhibition of human cancer by quantitative reduction of biosynthetic reactions.

Molecular lesions in cancer

Newer methods of identifying biochemical events associated with cancer include recombinant DNA technology, monoclonal antibodies and improved analysis of nuclear and other cell functions to determine specific events which occur commonly in cancer cells. 'Onc-gene' products offer potential opportunities for new approaches to cancer treatment and the hope of inducing differentiation of cancer cells toward their normal counterparts. Studies on antigens which react with monoclonal antibodies offer the opportunity for 'epitope attack' which may be effected by improved drugs or by design of totally new drugs to bind to specific reactive sites. The complexity and pleiomorphism of cancer do not permit predictions as to whether these approaches will be more effective than the empirical approach to cancer treatment.

In vitro methylation of specific regions of the cloned Moloney sarcoma virus genome inhibits its transforming activity

The transforming activity of cloned Moloney sarcoma virus (MSV) proviral DNA was inhibited by in vitro methylation of the DNA at cytosine residues, using HpaII and HhaI methylases before transfection into NIH 3T3 cells. The inhibition of transforming activity due to HpaII methylation was reversed by treatment of the transfected cells with 5-azacytidine, a specific inhibitor of methylation. Analysis of the genomic DNA from the transformed cells which resulted from the transfection of methylated MSV DNA revealed that the integrated MSV proviral DNA was sensitive to HpaII digestion in all cell lines examined, suggesting that loss of methyl groups was necessary for transformation. When cells were infected with Moloney murine leukemia virus at various times after transfection with methylated MSV DNA, the amount of transforming virus produced indicated that the loss of methyl groups occurred within 24 h. Methylation of MSV DNA at HhaI sites was as inhibitory to transforming activity as methylation at HpaII sites. In addition, methylation at both HpaII and HhaI sites did not further reduce the transforming activity of the DNA. These results suggested that; whereas methylation of specific sites on the provirus may not be essential for inhibiting the transforming activity of MSV DNA, methylation of specific regions may be necessary. Thus, by cotransfection of plasmids containing only specific regions of the MSV provirus, it was determined that methylation of the v-mos gene was more inhibitory to transformation than methylation of the viral long terminal repeat.

The transforming protein of Moloney murine sarcoma virus is a soluble cytoplasmic protein

The transforming gene, v-mos, of Moloney murine sarcoma virus (M-MuSV) encodes a 37,000-dalton phosphoprotein, p37mos. Since the biochemical function of this protein is unknown, we have determined the subcellular location of p37mos in M-MuSV 124-transformed cells. Using two different methods of cell lysis and fractionation, we found that newly synthesized as well as mature p37mos is a soluble cytoplasmic protein. In agreement with these results, immunofluorescent staining of cells acutely infected with M-MuSV 124, using an antiserum directed against a synthetic v-mos peptide, produced a diffuse cytoplasmic pattern. Gel filtration experiments and glycerol gradient sedimentation analysis suggest that the bulk of p37mos exists as a monomer and is not involved in a specific association with other cellular proteins. These properties of p37mos are different from those of other characterized retroviral transforming proteins.

Analysis of FBJ-MuSV provirus and c-fos (mouse) gene reveals that viral and cellular fos gene products have different carboxy termini

The complete nucleotide sequence of the FBJ-MuSV proviral DNA and the cellular homolog (c-fos) of its oncogene (v-fos) have been determined. The 4026 nucleotide long FBJ-MuSV proviral DNA contains two long terminal repeats, a substitution of 1639 nucleotides of mouse cellular DNA (v-fos) and the 3' end of the env gene derived from FBJ-MuLV. The sequences of the parental FBJ-MuLV and the cellular c-fos (mouse) gene share five of five nucleotides at the 5' end and ten of 11 nucleotides at the 3' end of the v-fos substitution. When compared with the v-fos sequences, the c-fos gene contains four discontinuous regions, three of which are flanked by sequences characteristic of introns. Direct sequence analysis of c-fos (mouse) RNA by primer extension demonstrates that the fourth discontinuity is due to a 104 bp deletion in the v-fos gene. As a consequence of the deletion, the predicted v-fos and c-fos gene products differ at their C termini.

In vitro methylation of specific regions of the cloned Moloney sarcoma virus genome inhibits its transforming activity

The transforming activity of cloned Moloney sarcoma virus (MSV) proviral DNA was inhibited by in vitro methylation of the DNA at cytosine residues, using HpaII and HhaI methylases before transfection into NIH 3T3 cells. The inhibition of transforming activity due to HpaII methylation was reversed by treatment of the transfected cells with 5-azacytidine, a specific inhibitor of methylation. Analysis of the genomic DNA from the transformed cells which resulted from the transfection of methylated MSV DNA revealed that the integrated MSV proviral DNA was sensitive to HpaII digestion in all cell lines examined, suggesting that loss of methyl groups was necessary for transformation. When cells were infected with Moloney murine leukemia virus at various times after transfection with methylated MSV DNA, the amount of transforming virus produced indicated that the loss of methyl groups occurred within 24 h. Methylation of MSV DNA at HhaI sites was as inhibitory to transforming activity as methylation at HpaII sites. In addition, methylation at both HpaII and HhaI sites did not further reduce the transforming activity of the DNA. These results suggested that; whereas methylation of specific sites on the provirus may not be essential for inhibiting the transforming activity of MSV DNA, methylation of specific regions may be necessary. Thus, by cotransfection of plasmids containing only specific regions of the MSV provirus, it was determined that methylation of the v-mos gene was more inhibitory to transformation than methylation of the viral long terminal repeat.

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.

Recombinational junctions of variants of Moloney murine sarcoma virus: generation and divergence of a mammalian transforming gene

Different variants of Moloney murine sarcoma virus (MSV) were examined by nucleotide sequencing to compare the junctions between the acquired cellular sequence, v-mos, and the adjacent virus-derived sequences. These variants included 124-MSV, m1-MSV, and HT1-MSV and also the purportedly independent isolate Gazdar MSV. These four strains have an identical 5' junction between the murine leukemia virus env gene and the v-mos gene. This junction lies within the sixth codon of the chimeric env-mos coding region that encodes the transforming gene product. In contrast, at the 3' junction between the v-mos gene and the murine leukemia virus env gene, the three variants examined here were all different. A small deletion was found in the COOH-terminal portion of the m1-MSV env-mos coding region, indicating that the COOH terminus of this transforming gene product must be different from that of 124-MSV or HT1-MSV. The data presented here are consistent with the thesis that a virus closely related to HT1-MSV was the primordial Moloney MSV, and that all other related strains evolved from it by deletion or rearrangement. The variability observed in the Moloney MSV family is discussed in terms of possible mechanisms for the initial capture of mos sequences by the parental retrovirus and also in comparison with other transforming retrovirus families, such as Abelson murine leukemia virus and Rous sarcoma virus.

Detection of a transforming gene product in cells transformed by Moloney murine sarcoma virus

We identified, in cells transformed by Moloney murine sarcoma virus (M-MuSV clone 124), a protein encoded by the M-MuSV transforming gene, v-mos. An antiserum against a synthetic peptide corresponding to the C terminus of a protein predicted from the v-mos nucleotide sequence specifically recognizes a protein doublet of approximately 37,000 daltons from 35S-methionine-labeled M-MuSV 124-transformed producer cells. By peptide mapping, this protein is almost identical to the 37 kd in vitro translation product from the M-MuSV v-mos gene. Immunoprecipitates from 32P-labeled cells contain a single v-mos-specific phosphoprotein, which has at least six sites of phosphorylation containing phosphoserine. Pulse-chase experiments show that the lower band in the 35S-methionine-labeled doublet is the primary translation product, which is modified, probably by phosphorylation, to yield the upper band. A similar mos protein is immunoprecipitated from HT1-MuSV-transformed cells, but not from uninfected NIH/3T3 cells. These mos proteins are present at very low levels in transformed cell lines. Cells acutely infected with M-MuSV 124, however, transiently contain much higher levels of the mos protein. These high levels coincide with extensive cell mortality.

Analysis of v-mos encoded proteins in cells transformed by several related murine sarcoma viruses

We have used antisera against synthetic peptides to identify and characterize a 37,000 dalton v-mos encoded protein (p37mos) in cells transformed by M-MuSV 124. p37mos, a phosphoprotein, comprises only about 0.0005% of total cellular protein in cell lines transformed by M-MuSV 124. NIH 3T3 cells acutely infected with M-MuSV 124, however, contain 30-100-fold more p37mos. These elevated levels of p37mos correlate with striking morphological changes and cell death in the acutely infected cell population. Using the antipeptide antisera, we have extended the analysis of v-mos proteins to include several other MuSV variants that contain a similar v-mos gene to M-MuSV 124. With the exception of P85, the gag-mos fusion protein from ts110 MuSV, the v-mos gene of these variants is expressed as a 35,000-37,000 dalton protein (size depending on the particular virus).