Molecular cloning of the Fujinami sarcoma virus genome and its comparison with sequences of other related transforming viruses

Expression of multiple oncogenes in human esophageal carcinomas

To study the oncogenesis of human esophageal carcinoma, the expression of a variety of oncogenes was studied in 10 esophageal carcinoma cell lines and 16 pairs of tumor and nontumor tissues removed from patients with esophageal carcinoma. Northern blot analyses using 11 different oncogene probes revealed that 5 oncogenes, i.e. c-myc, c-H-ras, c-sis, c-raf, and c-fos, were expressed. Among them, a variant c-sis mRNA transcript of 2.7 kilobase (kb) was expressed in 7 of 10 cell lines and in 9 of 16 tumor tissues. Furthermore, an overexpression and an amplification of c-myc gene was observed in some cell lines. These results suggest that multiple oncogene expression may be required for the induction, maintenance, and progression of esophageal carcinoma. The expression of a 2.7-kb transcript, of c-sis and overexpression of c-myc gene may play some role in the carcinogenesis of esophageal carcinoma.

Syrian hamster embryo cell lines useful for detecting transforming genes in mouse tumours: detection of transforming genes in X-ray-related mouse tumours

The Syrian hamster embryo cell lines, SHOK and MC-1, were used as recipient cells for DNA transfection assay to detect transforming genes in experimental mouse tumours. A mouse repeat sequence was utilised to check whether each transformed focus included mouse genomic DNA in the Hamster background. We investigated five mouse tumours that are related to X-ray radiation, and detected activated c-K-ras, c-mos, and c-cot oncogenes which induced foci of hamster cells. These results show that SHOK and MC-1 cells have unique properties for detecting transforming genes in experimental mouse tumours.

Genetic changes in skin tumor progression: correlation between presence of a mutant ras gene and loss of heterozygosity on mouse chromosome 7

Initiation of tumorigenesis in mouse skin can be accomplished by mutagenesis of the H-ras gene by treatment with chemical carcinogens. A mouse model system has been developed to study the additional genetic events that take place during tumor progression. Skin carcinomas were induced in F1 hybrid mice exhibiting restriction fragment length polymorphisms at multiple chromosomal loci. Analysis of loss of heterozygosity in such tumors showed that imbalance of alleles on mouse chromosome 7, on which the H-ras gene is located, occurs very frequently in skin carcinomas. The chromosomal alterations detected, which included both nondisjunction and mitotic recombination events, were only seen in tumors that have activated ras genes. We conclude that gross chromosomal alterations that elevate the copy number of mutant H-ras and/or lead to loss of normal H-ras are a consistent feature of mouse skin tumor development.

Establishment of a human malignant meningioma cell line with amplified c-myc oncogene

A new cell line (KT21-MG1) has been established from a human malignant meningioma transplanted into nude mice. The cultured cells showed epithelial cell-like morphology and were positive immunohistochemically for vimentin as the original tumor. They have been grown continuously in vitro for more than 2 years. The population doubling time was about 24 hours at the 30th passage. The cells are capable of proliferating in soft agar medium and produced tumors in nude mice, the histologies of which were similar to the original patient-derived tumor. Analysis of cellular oncogenes showed that myc and fps were amplified approximately tenfold and threefold, respectively, in this cell line, whereas N-myc, L-myc, N-ras, K-ras, H-ras, abl, erbB2, Blym, src, raf-1, myb, and sis were not changed significantly. The amplification of myc was accompanied by an enhanced expression. Chromosome studies of cultured cells showed the monosomy of chromosome 22 that has been reported to be a specific abnormality in meningiomas.

Avian retroviral long terminal repeats bind CCAAT/enhancer-binding protein

DNA-protein interactions involving enhancer and promoter sequences within the U3 regions of several avian retroviral long terminal repeats (LTRs) were studied by DNase I footprinting. The rat CCAAT/enhancer-binding protein, C/EBP, bound to all four viral LTRs examined. The Rous sarcoma virus binding site corresponded closely to the 5' limit of the LTR enhancer; nucleotides -225 to -188 were protected as a pair of adjacent binding domains. The Fujinami sarcoma virus LTR bound C/EBP at a single site at nucleotides -213 to -195. C/EBP also bound to the promoter region of the enhancerless Rous-associated virus-0 LTR at nucleotides -77 to -57. The avian myeloblastosis virus LTR bound C/EBP at three sites: nucleotides -262 to -246, -154 to -134, and -55 to -39. We have previously observed binding of C/EBP to an enhancer in the gag gene of avian retroviruses. A heat-treated nuclear extract from chicken liver bound to all of the same retroviral sequences as did C/EBP. Alignment of the avian retroviral binding sequences with the published binding sites for C/EBP in two CCAAT boxes and in the simian virus 40, polyoma, and murine sarcoma virus enhancers suggested TTGNNGCTAATG as a consensus sequence for binding of C/EBP. When two bases of this consensus sequence were altered by site-specific mutagenesis of the Rous sarcoma virus LTR, binding of the heat-stable chicken protein was eliminated.

Avian retroviral long terminal repeats bind CCAAT/enhancer-binding protein

DNA-protein interactions involving enhancer and promoter sequences within the U3 regions of several avian retroviral long terminal repeats (LTRs) were studied by DNase I footprinting. The rat CCAAT/enhancer-binding protein, C/EBP, bound to all four viral LTRs examined. The Rous sarcoma virus binding site corresponded closely to the 5' limit of the LTR enhancer; nucleotides -225 to -188 were protected as a pair of adjacent binding domains. The Fujinami sarcoma virus LTR bound C/EBP at a single site at nucleotides -213 to -195. C/EBP also bound to the promoter region of the enhancerless Rous-associated virus-0 LTR at nucleotides -77 to -57. The avian myeloblastosis virus LTR bound C/EBP at three sites: nucleotides -262 to -246, -154 to -134, and -55 to -39. We have previously observed binding of C/EBP to an enhancer in the gag gene of avian retroviruses. A heat-treated nuclear extract from chicken liver bound to all of the same retroviral sequences as did C/EBP. Alignment of the avian retroviral binding sequences with the published binding sites for C/EBP in two CCAAT boxes and in the simian virus 40, polyoma, and murine sarcoma virus enhancers suggested TTGNNGCTAATG as a consensus sequence for binding of C/EBP. When two bases of this consensus sequence were altered by site-specific mutagenesis of the Rous sarcoma virus LTR, binding of the heat-stable chicken protein was eliminated.

Spontaneous progression of hyperplastic outgrowths of the D1 lineage to mammary tumors: expression of mouse mammary tumor virus and cellular proto-oncogenes

Mammary cancer in mice is characterized by progression through defined stages of preneoplasia, with the most common preneoplastic stage being the hyperplastic alveolar nodule (HAN). We determined the relative levels of RNA expression of various cellular proto-oncogenes and endogenous mouse mammary tumor virus genes in outgrowths and tumors of three sublines of the transplantable D1 HAN preneoplastic outgrowth line. The three sublines differed in relative tumor-producing capabilities. Subline D1B produced a high incidence of tumors with short latency periods, whereas sublines D1C and D1D produced low incidences of tumors with long latency periods. No consistent alteration in proto-oncogene expression correlated with relative tumorigenicity, although tumors frequently contained higher levels of one or more proto-oncogene transcripts as compared with preneoplastic tissue. Slightly elevated (2- to 6-fold) levels of different oncogene transcripts were detected in 13 of 17 tumors as compared with outgrowth tissue, including abl (2 tumors), fps (5 tumors), Ha-ras (6 tumors), and Ki-ras (8 tumors). One tumor contained 45 times more Ki-ras-specific RNA than outgrowth tissue because of a comparable amplification of Ki-ras DNA sequences. Elevated levels of Ha-ras occurred more frequently in tumors of a high-incidence subline than in a less-aggressive subline (5/10 vs 1/7), but this difference was not statistically significant. However, consistent changes in MMTV expression accompanied progression from preneoplastic tissues to mammary tumors. All 17 tumors displayed reduced levels of the MMTV-specific long terminal repeat (LTR) transcript (1.6 kb) as compared with HAN tissue; tumors with moderate levels of LTR transcript expressed the 3.8-kb envelope message as well, one not detected in HANs. Expression of the LTR transcript is apparently influenced by factors in addition to the methylation status of endogenous mouse mammary tumor virus genes, which was similar in outgrowths and tumors. As the survey of representative proto-oncogenes failed to identify a uniform change between HAN and tumors, it is likely that other genes are involved in tumor progression in the mammary gland.

cis-acting regulatory elements within gag genes of avian retroviruses

A cis-acting enhancer element has been detected within the gag gene of several avian retroviruses, including Rous sarcoma virus, Fujinami sarcoma virus, and the endogenous Rous-associated virus-0. A consensus enhancer core sequence, GTGGTTTG, is present in all of these viral genomes, approximately 900 bases downstream from the site of initiation of transcription. When an internal fragment derived from the gag gene of any of these viruses (spanning nucleotides 533 to approximately 1149) was inserted into a plasmid containing the chloramphenicol acetyltransferase (cat) gene under control of the simian virus 40 promoter, 9- or 21-fold enhancement of CAT expression was observed after transfection into mouse L cells and chicken embryo fibroblasts, respectively. This enhancement was not dependent on the position of insertion of the gag fragment into the plasmid. However, there was a strong dependence on orientation, with higher levels of CAT expression in constructs in which the 5' end of the gag fragment was nearest to the promoter, suggesting a possible negative regulatory element at the 3' end of this fragment. Deletion of the 3' end of the insert resulted in a gag fragment, containing nucleotides 533 to 1017, which enhanced expression equally in either orientation. When the gag fragment was inserted into a plasmid containing the cat gene under the control of an intact Rous sarcoma virus long terminal repeat, it induced a two- to threefold increase in CAT activity and CAT mRNA levels. Translation of the gag fragment did not appear to be necessary for the observed enhancement, since two insertional mutations resulting in frameshifts in the gag insert did not affect CAT expression. However, deletion of a 330-base internal fragment from the gag insert restored a basal level of CAT activity. These results suggest that retroviruses have regulatory elements within their genes distinct from those in the long terminal repeats that flank the genes.

Genetic determinants of neoplastic diseases induced by a subgroup F avian leukosis virus

Two subgroup F avian leukosis viruses, ring-necked pheasant virus (RPV) and RAV-61, were previously shown to induce a high incidence of a fatal proliferative disorder in the lungs of infected chickens. These lung lesions, termed angiosarcomas, appear rapidly (4 to 5 weeks after infection), show no evidence of proto-oncogene activation by proviral integration, and are not induced by avian leukosis viruses belonging to other subgroups. To identify the viral sequences responsible for induction of these tumors, we constructed recombinant viruses by exchanging genomic segments of molecularly cloned RPV with those of a subgroup A leukosis virus, UR2AV. The ability to induce rapid lung tumors segregated only with the env sequences of RPV; the long terminal repeat of RPV was not required. However, recombinants carrying both env and long terminal repeat sequences of RPV induced lung tumors with a shorter latency. In several cases, recombinant viruses exhibited pathogenic properties differing from those of either parental virus. Recombinants carrying the gag-pol region of RPV and the env gene of UR2AV induced a high incidence of a muscle lesion termed infiltrative intramuscular fibromatosis. One recombinant, EU-8, which carries the gag-pol and LTR sequences of RPV, and the env gene of UR2AV, induced lymphoid leukosis after an unusually short latent period. The median time of death from lymphoid leukosis was 6 to 7 weeks after infection with EU-8 compared with approximately 5 months for UR2AV.

Isolation of chicken cellular DNA sequences with homology to the region of viral oncogenes that encodes the tyrosine kinase domain

A library of chicken genomic DNA was screened for sequences that could hybridize to a cloned DNA fragment containing the transforming gene (v-fps) of Fujinami sarcoma virus. In addition to c-fps, two unique chicken cellular DNA sequences were isolated that hybridized weakly to v-fps. These sequences hybridized with many other viral oncogenes encoding tyrosine kinases. Sequence analysis of the region where homology was detected revealed a region that is highly conserved among the tyrosine kinases both at the nucleotide and amino acid levels. Although we were unable to detect expression of either chicken cellular DNA sequence in a variety of avian tissues, the data suggest the existence of additional members of the tyrosine kinase gene family. Screening genomic libraries for sequences that hybridize weakly to functional regions of other genes may prove useful for the isolation and characterization of additional members of other gene families.

cis-acting regulatory elements within gag genes of avian retroviruses

A cis-acting enhancer element has been detected within the gag gene of several avian retroviruses, including Rous sarcoma virus, Fujinami sarcoma virus, and the endogenous Rous-associated virus-0. A consensus enhancer core sequence, GTGGTTTG, is present in all of these viral genomes, approximately 900 bases downstream from the site of initiation of transcription. When an internal fragment derived from the gag gene of any of these viruses (spanning nucleotides 533 to approximately 1149) was inserted into a plasmid containing the chloramphenicol acetyltransferase (cat) gene under control of the simian virus 40 promoter, 9- or 21-fold enhancement of CAT expression was observed after transfection into mouse L cells and chicken embryo fibroblasts, respectively. This enhancement was not dependent on the position of insertion of the gag fragment into the plasmid. However, there was a strong dependence on orientation, with higher levels of CAT expression in constructs in which the 5' end of the gag fragment was nearest to the promoter, suggesting a possible negative regulatory element at the 3' end of this fragment. Deletion of the 3' end of the insert resulted in a gag fragment, containing nucleotides 533 to 1017, which enhanced expression equally in either orientation. When the gag fragment was inserted into a plasmid containing the cat gene under the control of an intact Rous sarcoma virus long terminal repeat, it induced a two- to threefold increase in CAT activity and CAT mRNA levels. Translation of the gag fragment did not appear to be necessary for the observed enhancement, since two insertional mutations resulting in frameshifts in the gag insert did not affect CAT expression. However, deletion of a 330-base internal fragment from the gag insert restored a basal level of CAT activity. These results suggest that retroviruses have regulatory elements within their genes distinct from those in the long terminal repeats that flank the genes.

Single amino acid substitution, from Glu1025 to Asp, of the fps oncogenic protein causes temperature sensitivity in transformation and kinase activity

We have sequenced 2.7 kilobases of v-fps DNA encoding the transforming protein, p140, of the temperature-sensitive (ts) FL-15 clone of avian Fujinami sarcoma virus. Ten single nucleotide differences were found when compared with the v-fps sequence of the temperature-resistant (tr) clone, FSV-2. Of these differences, five encoded altered amino acids within the 5' fps domain, only one encoded an altered amino acid in the 3' kinase domain, and four were silent. Among the five amino acid changes in the 5' fps domain, four were identical to the corresponding residues of c-fps, and the remaining one, a change from His to Arg at amino acid number 559, was located in the middle of a stretch of five consecutive histidine residues. These sequence comparisons suggested that only two amino acid changes, His to Arg at amino acid 559 and Glu to Asp at amino acid 1025, were likely to be responsible for the temperature sensitivity of the v-fps protein. Two recombinants, pFL-11 containing the 5' alterations and pFL-12 containing the single 3' mutation, were constructed in vitro to determine the precise ts lesion. It was found that both the recombinant pFL-12 and the parental pFL-5 were ts by three criteria: cell morphology, colony formation, and kinase activity. In contrast, the recombinant pFL-11 was ts in morphology, but not in colony formation, and was partially ts in kinase activity. pFSV 2-2 itself was temperature resistant by these criteria. We conclude that, first, the mutation of Glu to Asp at amino acid number 1025 can cause a complete ts phenotype, implying that this residue is located at a critical position of the v-fps oncogenic protein. Secondly, the change from His to Arg at amino acid position 559 results in a partial temperature sensitivity, providing the genetic evidence for a second functional domain of the v-fps oncogenic protein.

Transduction of c-src coding and intron sequences by a transformation-defective deletion mutant of Rous sarcoma virus

The mechanism of cellular src (c-src) transduction by a transformation-defective deletion mutant, td109, of Rous sarcoma virus was studied by sequence analysis of the recombinational junctions in three td109-derived recovered sarcoma viruses (rASVs). Our results show that two rASVs have been generated by recombination between td109 and c-src at the region between exons 1 and 2 defined previously. Significant homology between td109 and c-src sequences was present at the sites of recombination. The viral and c-src sequence junction of the third rASV was formed by splicing a cryptic donor site at the 5' region of env of td109 to exon 1 of c-src. Various lengths of c-src internal intron 1 sequences were incorporated into all three rASV genomes, which resulted from activation of potential splice donor and acceptor sites. The incorporated intron 1 sequences were absent in the c-src mRNA, excluding its being the precursor for recombination with td109 and implying that initial recombinations most likely took place at the DNA level. A potential splice acceptor site within the incorporated intron 1 sequences in two rASVs was activated and was used for the src mRNA synthesis in infected cells. The normal env mRNA splice acceptor site was used for src mRNA synthesis for the third rASV.

Sequential expression of protooncogenes during lectin-stimulated mitogenesis of normal human lymphocytes

The proliferation of non-neoplastic T lymphocytes is regulated, in part, by the coordinated expression of genes encoding T-cell growth factor (interleukin 2, IL2), IL2 receptors (IL2R), and transferrin receptors (TFR). In addition to growth factors and their receptors, protooncogenes may regulate lymphocyte proliferation. We used cloned cDNAs homologous to 21 different protooncogenes to screen for their expression at the mRNA level in human peripheral blood mononuclear cells (PBMC) stimulated with the mitogenic lectin phytohemagglutinin (PHA), and we compared the time course of accumulation of mRNAs for these protooncogenes to that of mRNAs for the IL2, IL2R, TFR, and histone H3 genes. mRNAs for c-abl, c-ets, c-yes, and N-ras were present in unstimulated PBMC. After stimulation of PBMC by PHA, we detected marked increases within 10 min in the levels of mRNA for c-fos and c-myc; within 6 hr for IL2 and IL2R mRNAs; within 14 hr for c-myb, p53, N-ras, and TFR mRNAs; and within 24-36 hr for H3 mRNA. Expression of c-abl, c-ets, and c-yes increased gradually following stimulation with PHA. None of the other protooncogenes tested was expressed in PBMC. Addition of the protein synthesis inhibitor cycloheximide, before the addition of PHA to cultures, abolished the PHA-induced accumulation of mRNAs for c-myb, N-ras, and TFR, but not of mRNAs for c-fos, c-myc, IL2, and IL2R. These data indicate that c-fos, c-myc, IL2, and IL2R belong to a group of genes expressed early, whereas c-myb, N-ras, and TFR belong to a group of genes expressed later in PHA-activated PBMC, and that the products of the c-fos and c-myc protooncogenes are not required for expression of IL2 or IL2R genes. Addition of purified IL2 augmented the expression of the later-expressed genes c-myb, p53, N-ras, and TFR in PHA-stimulated cultures of PBMC, as well as of the early genes c-myc and IL2R, but not of c-fos and IL2, thus suggesting that PHA and IL2 stimulate the expression of overlapping, but nonidentical, sets of genes in PBMC.

Isolation of chicken cellular DNA sequences with homology to the region of viral oncogenes that encodes the tyrosine kinase domain

A library of chicken genomic DNA was screened for sequences that could hybridize to a cloned DNA fragment containing the transforming gene (v-fps) of Fujinami sarcoma virus. In addition to c-fps, two unique chicken cellular DNA sequences were isolated that hybridized weakly to v-fps. These sequences hybridized with many other viral oncogenes encoding tyrosine kinases. Sequence analysis of the region where homology was detected revealed a region that is highly conserved among the tyrosine kinases both at the nucleotide and amino acid levels. Although we were unable to detect expression of either chicken cellular DNA sequence in a variety of avian tissues, the data suggest the existence of additional members of the tyrosine kinase gene family. Screening genomic libraries for sequences that hybridize weakly to functional regions of other genes may prove useful for the isolation and characterization of additional members of other gene families.

Expression of proto-oncogenes in normal and papovavirus-transformed or -infected rat fibroblasts

Dot blot hybridization was used to determine the transcript levels of 10 cellular oncogenes in Fischer rat fibroblasts transformed or infected in tissue culture by polyoma virus or SV40. The level of these messages was compared to that determined for nontransformed, noninfected control cells. The analysis includes the oncogenes myc, sis, mos, erbB, erbA, Ha-ras, Ki-ras, src, fps, and abl. For all the oncogenes tested, except for mos, detectable expression was observed in all cell lines studied including the normal control cells; when normal and transformed or infected cells were compared, no significant difference in transcript level was found for any of the oncogenes except one. A slight elevation of sis message was observed for some transformants. The results of this study apply to six polyoma and seven SV40 transformants which were chosen with the purpose of analyzing transformants displaying a variety of properties. Thus, the polyoma-transformed cell lines varied in their expression of the transformed phenotype as judged by anchorage-independent growth and cell morphology, in their coding capacity for and expression of early gene products, and included two classes of rat fibroblasts transformed by ts-a mutants: those with a temperature-insensitive transformed phenotype, and those with a temperature-sensitive phenotype, A-type and N-type, respectively. Concerning the latter two types, no differences in oncogene expression were observed between cells grown at low and those grown at high temperatures, or between the two groups of cells at either temperature.

Construction and biological analysis of deletion mutants of Fujinami sarcoma virus: 5'-fps sequence has a role in the transforming activity

Fujinami sarcoma virus (FSV) genome codes for the gag-fps fusion protein FSV-P130. The amino acid sequence of the 3' one-third portion in v-fps is partially homologous to the 3' half of pp60src, or the kinase domain, but the sequence of the 5' portion is unique to v-fps. To identify a possible domain structure in the v-fps sequence responsible for cell transformation, we constructed various deletion mutants of FSV with molecularly cloned viral DNA. Their transforming activities were assayed by measuring focus formation on chicken embryo fibroblasts and rat 3Y1 cells and tumor formation in chickens. The mutants carrying a deletion at the 3' portion in v-fps, the kinase domain, lost transforming activity. The mutants carrying an approximately 1-kilobase deletion within the 5' portion of the v-fps sequence retained focus-forming activity and tumorigenicity in the chicken system, but the efficiency of focus formation was about 10 times lower than that of the wild type. The morphology of these transformed cells was distinct from that observed in cells infected with wild-type FSV. Furthermore, these mutants could not transform rat 3Y1 cells, although wild-type FSV DNA transformed rat 3Y1 cells at a high frequency. The mutants carrying a larger deletion in the 5' portion of fps completely lacked the transforming activity. These results suggest that the 3' portion of the v-fps sequence is necessary but not sufficient for cell transformation and that the 5' portion of v-fps has a role in the transforming activity.

Deletion in the 3' pol sequence correlates with aberration of RNA expression in certain replication-defective avian sarcoma viruses

The RNA expression of a series of replication-defective recovered avian sarcoma viruses (rASVs) were studied. Abnormal-sized viral RNAs, both larger and smaller than the genome, were observed in the nonproducer cells infected with rASVs containing env and pol deletions. Each nonproducer clone contained a single provirus integrated at a unique site and expressed a unique RNA pattern. Upon rescuing of the sarcoma virus with a helper virus and subsequent cloning, the RNA pattern of individual nonproducer clones again displayed variation according to the integration sites. This was not seen in nondefective rASV or in rASVs containing only an env deletion. The aberrant RNA expression did not result from the lack of reverse transcriptase activity per se, since neither nonconditional nor temperature-sensitive mutants of RSV expressed abnormal viral RNAs in the absence of a functional reverse transcriptase. The abnormal RNA patterns could not be corrected in trans by helper virus functions. The unusual-sized RNAs in env- pol- rASV-infected cells are not due to splicing to alternative acceptor sites for src mRNA because there are no extra viral sequences between the 5' leader and the src sequences; instead, they are due to the presence of extra sequences, most likely of cellular origin, at the 3' ends of the viral RNAs. Based upon the extent of deletions in the viral genomes, the data suggest that deletion in the 3' pol region of those rASVs results in a cis effect on the transcription and processing of the 3' ends of viral RNAs. The unusual-sized viral RNAs are most likely due to read-through transcription from the right-hand terminus of provirus into downstream cellular sequences, followed by cleavage and polyadenylation at multiple sites of the 3' region of the RNA transcripts. The extent of read-through transcription appears to depend on the chromosomal location of the provirus.

Molecular cloning of the PRCII sarcoma viral genome and the chicken proto-oncogene c-fps

The class II avian sarcoma viruses comprise PRCII, PRCIIp, PRCIV, URI, 16L, and Fujinami. The members of this class are all replication-defective viruses containing various amounts of a transforming sequence called v-fps. PRCII contains the smallest amount of fps-specific sequences, transforms fibroblasts in tissue culture, but is only weakly tumorigenic. As a first step in understanding variations in pathogenicity among the class II avian sarcoma viruses and the mechanism by which the oncogene of these viruses was transduced from a single cellular locus, we have molecularly cloned the viral genome of PRCII, its related helper PRCII-AV, and the chicken proto-oncogene (c-fps) from which v-fps derived. The fps-specific region within the cloned PRCII genome was shown to be 0.8-1.0 kb smaller than that of the Fujinami fps-specific region, in agreement with previous studies. Transfection of the cloned DNAs into primary chicken cells demonstrated that both clones (PRCII and PRCII-AV) are biologically active. The cloned PRCII genome is helper dependent and produces a gag-fusion phosphoprotein (P105) which is phosphorylated on a tyrosine residue. The cloned PRCII-AV genome produces infectious virus and can function as a helper for the cloned PRCII genome in transfection assays. Three overlapping recombinant lambda clones homologous to v-fps from a chicken genomic library have been isolated. One of these, lambda-c-fps(2), contains all of the cellular sequences homologous to v-fps. In the aggregate, the three molecular clones may represent the entirety of c-fps.

Transcriptional activity of avian retroviral long terminal repeats directly correlates with enhancer activity

Retroviral long terminal repeats (LTRs) contain elements responsible for the control of proviral transcription and gene expression. Molecular clones of the LTR region of a number of avian retroviruses have been isolated, and DNA sequence analysis of these clones reveals the existence of a related, but heterogeneous, family of LTRs. To examine the functional significance of the observed sequence differences, we have directly tested the abilities of several different avian retrovirus LTRs to act as promoters and enhancers of mRNA transcription. Our results indicate that large differences in LTR transcriptional activity exist and that these differences in gene expression directly correlate with LTR enhancer activity. In particular, we show that the LTR of Fujinami sarcoma virus is intermediate in both transcriptional and enhancer activity when compared with the very active LTRs of the exogenous viruses RAV-2 and Schmidt-Ruppin B and the much less active LTRs of the endogenous virus RAV-0 and its provirus ev-2. These results suggest that LTR enhancer activity may be the primary determinant of avian retroviral LTR transcriptional activity and, hence, oncogenic potential.

Induction of tumors and generation of recovered sarcoma viruses by, and mapping of deletions in, two molecularly cloned src deletion mutants

td108 , a transformation-defective (td) deletion mutant of the Schmidt-Ruppin strain of Rous sarcoma virus of subgroup A (SR-A), was molecularly cloned. Two isolates of td viruses, td108 -3b and td108 -4a, obtained by transfection of the molecularly cloned td108 DNAs into chicken embryo fibroblasts, were tested for their ability to induce tumors and generate recovered avian sarcoma viruses ( rASVs ) in chickens. Both td viruses were able to induce tumors with a latency and frequency similar to those observed previously with biologically purified td mutants of SR-A. rASVs were isolated from most of the tumors examined. The genomic RNAs of those newly obtained rASVs were analyzed by RNase T1 oligonucleotide fingerprinting. The results showed that they had regained the deleted src sequences and contained the same set of marker src oligonucleotides as those of rASVs analyzed previously. The src oligonucleotides of rASVs are distinguishable from those present in SR-A. We conclude that those rASVs must have been generated by recombination between the molecularly cloned td mutants and the c-src sequence. The deletions in the td mutants were mapped by restriction enzyme analysis and nucleotide sequencing. td108 -3b was found to contain an internal src deletion of 1,416 nucleotides and to retain 57 and 105 nucleotides of the 5' and 3' src coding sequences, respectively. td108 -4a contained a src deletion of 1,174 nucleotides and retained 180 and 225 nucleotides of the 5' and 3' src sequences, respectively. Comparison of sequences in the 5' src and its upstream region of td108 -3b with those of SR-A, rASV1441 (a td108 -derived rASV analyzed previously), and c-src suggested that the 5' recombination between td108 and c-src occurred from 7 to 20 nucleotides upstream from the beginning of the src coding sequence.

Molecular cloning and characterization of avian sarcoma virus UR2 and comparison of its transforming sequence with those of other avian sarcoma viruses

Avian sarcoma virus UR2 and its associated helper virus, UR2AV , were molecularly cloned into lambda gtWES X lambda B by using unintegrated viral DNAs. One UR2 and several UR2AV clones were obtained. The UR2 DNA was subsequently cloned into pBR322. Both UR2 and UR2AV DNAs were tested for their biological activity by transfection onto chicken embryo fibroblasts. When cotransfected with UR2AV DNA, UR2 DNA was able to induce transformation of chicken embryo fibroblasts with a morphology similar to that of parental UR2 . UR2 -specific protein with kinase activity and UR2 -specific RNA were detected in the transfected cells. Transforming virus, UR2 ( UR2AV ), was produced from the doubly transfected cells. Five of the six UR2AV clones tested were also shown to be biologically active. The insert of the UR2 DNA clone is 3.4 kilobases in length and contains two copies of the long terminal repeat. Detailed restriction mapping showed that UR2 DNA shared with UR2AV DNA 0.8 kilobases of 5' sequence, including a portion of 5' gag, and 1.4 kilobases of 3' sequence, including a portion of 3' env. The UR2 transforming sequence, ros, is ca. 1.2 kilobases. No significant homology was found between v-ros and the conserved regions of v-src, v-yes, or v- abl . By contrast, a significant homology was found between v-ros and v-fps. The v-fps-related sequence was mapped within a 300-base-pair sequence in the middle of ros.

Monoclonal antibodies to the transforming protein of Fujinami avian sarcoma virus discriminate between different fps-encoded proteins

Two monoclonal antibodies have been obtained that recognize antigenic determinants within the C-terminal fps-encoded region of P140gag-fps, the transforming protein of Fujinami avian sarcoma virus (FSV). The hybridomas which secrete these antibodies (termed 88AG and p26C) were isolated after the fusion of NS-1 mouse myeloma cells with B lymphocytes from Fischer rats that had been immunized with FSV-transformed rat-1 cells. FSV P140gag-fps immunoprecipitated by either antibody is active as a tyrosine-specific kinase and is able to autophosphorylate and to phosphorylate enolase in vitro. The fps-encoded proteins of all FSV variants, including the gag- p91fps protein of F36 virus, are recognized by both monoclonal antibodies. However, the product of the avian cellular c-fps gene. NCP98, and the transforming proteins of the recently isolated fps-containing avian sarcoma viruses 16L and UR1 are recognized only by the p26C antibody. The 88AG antibody therefore defines an epitope specific for FSV fps, whereas the epitope for p26C is conserved between cellular and viral fps proteins. The P105gag-fps protein of the PRCII virus is not precipitated by p26C (nor by 88AG), presumably as a consequence of the deletion of N-terminal fps sequences. These data indicate that the fps-encoded peptide sequences of 16L P142gag-fps and UR1 P150gag-fps are more closely related to NCP98 than that of FSV P140gag-fps. This supports the view that 16L and UR1 viruses represent recent retroviral acquisitions of the c-fps oncogene. The P85gag-fes transforming protein of Snyder-Theilen feline sarcoma virus is not precipitated by either monoclonal antibody but is recognized by some antisera from FSV tumor-bearing rats, demonstrating that fps-specific antigenic determinants are conserved in fes-encoded proteins.

The avian sarcoma virus PRCII lacks 1020 nucleotides of the fps transforming gene

Fujinami sarcoma virus (FSV) and PRCII avian sarcoma virus both encode gag-fps transforming proteins associated with tyrosine-specific protein kinase activity; however, PRCII has a lower oncogenic potential than does FSV. In this study, the genomes of PRCII and FSV have been compared. By hybridization of PRCII [32P]RNA to FSV DNA on Southern blots, a large internal deletion in the 5' half of the fps gene in PRCII has been mapped. To determine the exact size and location of the deletion in PRCII, dideoxy sequencing of PRCII RNA with FSV DNA fragments as primers was used. The FSV sequence corresponding to the deletion in PRCII was flanked by 6-base direct repeats ( AGCTGG ) at 1614-1619 and 2634-2639 nucleotides. One copy of the direct repeat was retained in the PRCII genome. The length of the deleted region was 1020 nucleotides. The deletion in fps did not alter the kinase domain or ATP-binding site of the P105 transforming protein of PRCII. It was shown that the specific kinase activity of P105 was as high as that of FSV P130 . The sequence deleted from PRCII was found to encode part of a large hydrophilic domain. In the accompanying paper [J. Woolford and K. Beemon (1984) Virology 135, 168-180], evidence that the PRCII and FSV proteins have different subcellular locations and solubility properties, possibly due to the loss of this domain, is presented. These alterations in the structure and location of the PRCII protein may prevent it from phosphorylating certain substrates involved in oncogenic transformation.

Revertants and partial transformants of rat fibroblasts infected with Fujinami sarcoma virus

Fifteen revertants were isolated from three independent clones of rat fibroblasts transformed by Fujinami sarcoma virus (FSV). Three revertant clones resulted from the deletion of the one copy of the FSV provirus, and one encoded an enzymatically inactive, transformation-defective protein. The remaining revertant clones were characterized by a transcriptional block of the provirus. Digestion of chromosomal DNA with MspI and HpaII revealed that the FSV provirus was hypermethylated in these revertants, whereas proviral DNA of their spontaneous retransformants was hypomethylated. Furthermore, the revertants had lost DNase I-hypersensitive sites in and around the FSV provirus. The effect of transcriptional regulation of the FSV provirus was further analyzed in clones showing various degrees of phenotypic transformation. We quantitated v-fps mRNA levels in these cells by liquid hybridization and found that increasing levels of viral RNA correlated with a more pronounced transformed phenotype. These results suggest that transcription of FSV proviral DNA is under both viral and cellular control and that transformation by FSV is a function of the dosage of v-fps mRNA.

Nucleotide sequence of v-fps in the PRCII strain of avian sarcoma virus

PRCII is an avian retrovirus whose oncogene (v-fps) induces fibrosarcomas in birds. The viral gene v-fps arose by transduction of an undetermined portion of a cellular gene known as c-fps. PRCII is weakly oncogenic when compared with Fujinami sarcoma virus, another transforming virus containing v-fps. As a first step in the elucidation of the molecular basis for the decreased virulence of PRCII, we have determined the entire nucleotide sequence of v-fps in the PRCII genome. The v-fps domain in PRCII encodes a polypeptide with a molecular weight of ca. 60,500 fused to a portion of the polyprotein encoded by the viral structural gene gag. The hybrid gag-fps polyprotein of PRCII would have a molecular weight of ca. 98,100, in accord with results of previous studies of the protein encoded by the PRCII genome. The leftward junctions between fps and gag in Fujinami sarcoma virus and PRCII are located at the same position in fps, but at different positions in gag. A sequence of 1,020 nucleotides, bounded by direct repeats of 6 nucleotides, is present in v-fps of Fujinami sarcoma virus but absent from PRCII. Our data should permit further explorations of the relationship between structure and function in the transforming protein encoded by v-fps.

A fps gene without gag gene sequences transforms cells in culture and induces tumors in chickens

From molecularly cloned DNAs of Fujinami sarcoma virus (FSV) and the Schmidt-Ruppin-A strain of Rous sarcoma virus (SRA), viral DNA was constructed in which fps-specific sequences encoded in FSV replaced the src gene of SRA. A 3' fragment of FSV DNA, from an ATG methionine coding sequence 148 base pairs downstream from the gag-fps junction through the long terminal repeat, was joined to cloned SRA DNA at the translation start site for the src gene. The resultant DNA clone contained the splice acceptor site for src mRNA processing in SRA, but contained no src coding sequences from SRA nor any gag sequences from FSV. All genes for the replication of SRA were retained. Transfection of this cloned viral DNA genome into chicken embryo fibroblasts induced morphological transformation of the cells in culture. However, the morphology of the transformed cells was distinct from that observed in cells infected with wild-type FSV. The transformed cells produced a nondefective transforming virus called F36 which contained a hybrid FSV-SRA long terminal repeat. F36-infected cells produced a protein with the expected molecular weight of 91,000, which had an associated protein kinase activity and was immunoprecipitated by antibodies raised against fps gene determinants but not by antibodies raised against gag or src proteins. Injection of F36 virus into 8-day-old chicks produced tumors at the site of inoculation, detectable within 7 days. These results demonstrated that the gag portion of the gag-fps fusion protein of FSV is not required for transformation or tumorigenesis.

The low tumorigenic potential of PRCII, among viruses of the Fujinami sarcoma virus subgroup, corresponds to an internal (fps) deletion of the transforming gene

The avian sarcoma viruses FSV, PRCII, PRCIIp, and PRCIV share a related class of hybrid onc genes (delta gag-fps) defined by a specific nucleotide sequence fps and by delta gag-fps proteins of different sizes. Among these viruses, PRCII appears to have a lower tumorigenic potential than the others. Here we have compared fibroblast-transforming function and onc gene structure of these viruses. The fibroblast transforming ability of PRCII was lower than those of FSV, PRCIIp, and PRCIV. By gel electrophoresis the genomic RNA of PRCII measured 3.5 kb and those of FSV, PRCIIp, and PRCIV 4.5 kb; the delta gag-fps protein of PRCII measured 105 kilodaltons (kd), that of FSV 140 kd, and those of PRCIIp and PRCIV about 150 kd. By fingerprinting viral RNAs hybridized with molecularly cloned viral DNA the delta gag regions of PRCII and PRCIIp were defined to be 1.45 kb and that of FSV to be 1.3 kb. Fingerprint analysis of viral RNA-proto fps DNA hybrids showed the fps regions (approximately 2.8 kb) of FSV and PRCIIp to be isogenic. Compared to FSV and PRCIIp, the fps sequence of PRCII lacked a 1-kb region which maps between 0.3 and 1.3 kb from the 5' end of fps in FSV and PRCIIp. Based on oligonucleotide analysis, the shared fps complements of PRCII and PRCIIp were indistinguishable while that of FSV differed from those of the PRC viruses in scattered point mutations amounting to 1-2% of the RNA. Since all other regions of PRCII are isogenic with those of the highly tumorigenic variants PRCIIp, PRCIV, and FSV, it is concluded that the low fibroblast-transforming and oncogenic potential of PRCII reflects the internal fps deletion. Since the fps deletion reduces but does not eliminate transforming function, we suggest that the complete onc genes of viruses in the FSV subgroup include either several functional, or a regulatory and a functional fibroblast transforming domain. It has been reported that the 3' domains of the onc genes of viruses in the Fujinami subgroup and the onc genes of certain feline sarcoma viruses are distantly related. Since full transforming potential of the avian viruses depends on the 5' fps region not shared with the feline sarcoma viruses, we suggest that despite their structural homology, the avian and feline onc genes must have functionally different domains.

Genetic mapping of the mouse oncogenes c-Ha-ras-1 and c-fes to chromosome 7

The mouse homologs of the cellular oncogenes c-Ha-ras-1 of Harvey sarcoma virus and c-fes of feline sarcoma virus were both mapped to chromosome 7 by Southern blot analysis of hamster-mouse somatic cell hybrid DNAs.

Mapping of multiple phosphorylation sites within the structural and catalytic domains of the Fujinami avian sarcoma virus transforming protein

The phosphorylation sites of the P140gag-fps gene product of Fujinami avian sarcoma virus have been identified and localized to different regions of this transforming protein. FSV P140gag-fps isolated from transformed cells is phosphorylated on at least three distinct tyrosine residues and one serine residue, in addition to minor phosphorylation sites shared with Pr76gag. Partial proteolysis with virion protease p15 or with Staphylococcus aureus V8 protease has been used to generate defined peptide fragments of P140gag-fps and thus to map its phosphorylation sites. The amino-terminal gag-encoded region of P140gag-fps contains a phosphotyrosine residue in addition to normal gag phosphorylation sites. The two major phosphotyrosine residues and the major phosphorserine residue are located in the carboxy-terminal portion of the fps-encoded region of P140gag-fps. P140gag-fps radiolabeled in vitro in an immune complex kinase reaction is phosphorylated at only one of the two C-terminal tyrosine residues phosphorylated in vivo and weakly phosphorylated at the gag-encoded tyrosine and at a tyrosine site not detectably phosphorylated in vivo. Thus, the in vitro tyrosine phosphorylation of P140gag-fps is distinct from that seen in the transformed cell. A comparative tryptic phosphopeptide analysis of the gag-fps proteins of three Fujinami avian sarcoma virus variants showed that the phosphotyrosine-containing peptides are invariant, and this high degree of sequence conservation suggests that these sites are functionally important or lie within important regions. The P105gag-fps transforming protein of PRCII avian sarcoma virus lacks one of the C-terminal phosphotyrosine sites found in Fujinami avian sarcoma virus P140gag-fps. Partial trypsin cleavage of FSV P140gag-fps immunoprecipitated with anti-gag serum releases C-terminal fragments of 45K and 29K from the immune complex that retain an associated tyrosine-specific protein kinase activity. This observation, and the localization of the major P140gag-fps phosphorylation sites to the C-terminal fps region, indicate that the kinase domain of P140gag-fps is located at its C terminus. The phosphorylation of P140gag-fps itself is complex, suggesting that it may itself interact with several protein kinases in the transformed cell.

Cytoplasmic localization of the transforming protein of Fujinami sarcoma virus: salt-sensitive association with subcellular components

Fujinami sarcoma virus (FSV) encodes a transforming protein of 130,000 daltons (P130) which is associated with a tyrosine-specific protein kinase activity. To elucidate mechanisms involved in cell transformation by FSV, we have studied the intracellular location of P130 in rat cells nonproductively infected with FSV. Immunofluorescent staining of several FSV-transformed rat cell lines with a tumor regressor antiserum specific against the fps sequences of P130 showed that the major staining was localized in the cytoplasm. Staining was also seen in cell ruffles and in some cases at areas of cell contact. The cytoplasmic location of P130 staining in cells infected with temperature-sensitive mutants of FSV was unchanged when they were grown at permissive or nonpermissive temperature. Cell fractionation of FSV-transformed cells under various conditions showed that the ionic strength used during cell fractionation had a striking effect on the distribution of P130. At 10 mM NaCl, 70% of P130 sedimented in the large granule fraction, whereas at 500 mM NaCl 70 to 90% of P130 was recovered in the cytosol fraction. Furthermore, a combination of ionic and nonionic detergents that effectively solubilized subcellular membranes was insufficient to solubilize P130 unless the salt concentration was raised. We conclude that the majority of P130 and its associated protein kinase activity are localized in the cytoplasm and that P130 is not an integral membrane protein.

Nucleotide sequence of Fujinami sarcoma virus: evolutionary relationship of its transforming gene with transforming genes of other sarcoma viruses

We determined the entire nucleotide sequence of the molecularly cloned DNA of Fujinami sarcoma virus (FSV). The sequence of 1182 amino acids was deduced for the FSV transforming protein P130, the product of the FSV gag-fps fused gene. The P130 sequence was highly homologous to the amino acid sequence obtained for the gag-fes protein of feline sarcoma virus, supporting the view that fps and fes were derived from a cognate cellular gene in avian and mammalian species. In addition, FSV P130 and p60src of Rous sarcoma virus were 40% homologous in the region of the carboxyterminal 280 amino acids, which includes the phosphoacceptor tyrosine residue. These results strongly suggest that the 3' region of fps/fes and src originated from a common progenitor sequence. A portion (the U3 region) of the long terminal repeat of FSV DNA appears to be unusual among avian retroviruses in its close similarity in sequence and overall organization to the same region of the endogenous viral ev1 DNA.

A cellular protein is immunologically crossreactive with and functionally homologous to the Fujinami sarcoma virus transforming protein

We obtained a regressing-tumor antiserum specific for the unique sequence of the transforming protein P140 of Fujinami sarcoma virus by injecting Fischer rats with syngeneic embryo cells transformed with Fujinami sarcoma virus. This serum is capable of immunoprecipitating a protein of 98,000 daltons from cell extracts of normal, uninfected chicken bone marrow cells. This normal cellular protein (NCP98) was shown to be structurally related to P140, sharing the majority of 35S-methionine-labeled tryptic peptides with the viral gene product P140. NCP98 is a phosphoprotein in vivo, with an associated in vitro protein kinase activity, capable of phosphorylating specifically at tyrosine residues of NCP98 itself and alpha-casein, an externally added substrate. This kinase activity is biochemically indistinguishable from the kinase activity associated with P140 by all criteria tested. Moreover, in vitro-phosphorylated NCP98 and P140 shared the same phosphopeptides. The expression of NCP98 is tissue-specific. It is readily detectable in bone marrow cells and detectable to a lesser extent in liver and lung cells from 6--18 day old chickens.

Localization and characterization of phosphorylation sites of the Fujinami avian sarcoma virus and PRCII virus transforming proteins

Fujinami sarcoma virus (FSV) and PRCII are avian sarcoma viruses which share cellularly derived v-fps transforming sequences. The FSV P140gag-fps gene product is phosphorylated on three distinct tyrosine residues in transformed cells or in an in vitro kinase reaction. Three variants of FSV, and the related virus PRCII which lacks about half of the v-fps sequence found in FSV, encode gene products which are all phosphorylated at tyrosine residues contained within identical tryptic peptides. This indicates a stringent conservation of amino acid sequence at the tyrosine phosphorylation sites which presumably reflects the importance of these sites for the biologic activity of the transforming proteins. Under suitable conditions the proteolytic enzymes p15 and V8 protease each introduce one cut into FSV P140, p15 in the N-terminal gag-encoded region and V8 protease in the middle of the fps-encoded region. Using these enzymes we have mapped the major site of tyrosine phosphorylation to the C-terminal end of the fps region of FSV P140gag-fps. A second tyrosine phosphorylation site is found in the fps region of FSV P140 isolated from transformed cells, and a minor tyrosine phosphorylation site is found in the N-terminal gag-encoded region. Our results suggest that the C-terminal fps-encoded region is required for expression of the tyrosine-specific protein kinase activity.