Neoplastic transformation by E26 leukemia virus is mediated by a single protein containing domains of gag and myb genes.

The genome of avian leukemia virus E26 shares homology with v-myb, the oncogene of avian myeloblastosis virus, and encodes a protein with an Mr of 135,000. Analyses of tryptic oligopeptides show that this protein is related to the proteins encoded by gag (Pr76gag) as well as v-myb (p45v-myb[AMV] ) and c-myb (p75c-myb). We found no evidence for the existence of additional myb-related proteins or subgenomic species of myb-related RNA in myeloblasts transformed by strain E26.     

Identification of a ribosome-binding site for a leader peptide encoded by Rous sarcoma virus RNA.

A new method for identifying ribosome-binding sites was developed to determine whether AUG codons in the 5'-terminal RNA sequence of Rous sarcoma virus were used to initiate protein synthesis. We found that when translation is inhibited, the major ribosome-binding site on Rous sarcoma virus RNA is at the 5'-proximal AUG codon, even though the primary translational product from this RNA, Pr76gag, is encoded behind the fourth AUG codon 331 bases downstream from the observed initiation site. These results suggest that ribosomes can initiate translation on Rous sarcoma virus RNA at more than one site, thereby producing a seven-amino-acid peptide, as well as the gag gene polyprotein precursor of Mr 76,000.     

Protein-coding potential of mouse mammary tumor virus genome RNA as examined by in vitro translation.

The protein-coding capacity of the mouse mammary tumor virus genome has been examined by in vitro translation of genome length and polyadenylated subgenomic fragments of viral RNA. Intact genome RNA of about 35S programmed synthesis of the Pr77gag, Pr110gag and Pr160gag/pol precursors seen in infected cells in vivo. Polyadenylated RNA fragments of 18 to 28S encoded products whose tryptic peptide maps resembled those of the nonglycosylated precursor to the envelope glycoproteins, confirming the gene order 5'-gag-pol-env-3'. Translation of polyadenylated RNA fragments smaller than 18S yielded a series of related proteins whose peptide maps bore no resemblance to any of the virion structural proteins. Thus, a region of the mouse mammary tumor virus genome distal to the env gene appears to have an open reading frame sufficient to encode at least 36,000 daltons of protein as of yet unknown function.     

Translation of bovine leukemia virus virion RNAs in heterologous protein-synthesizing systems.

Bovine leukemia virus 60 to 70S RNA was heat denatured, the polyadenylic acid-containing species were separated by velocity sedimentation, and several size classes were translated in a micrococcal nuclease-treated cell-free system from rabbit reticulocytes. The major RNA species sedimented at 38S and migrated as a single component of molecular weight 2.95 x 10(6) when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The predominant polypeptides of the in vitro translation of bovine leukemia virus 38S RNA were products with molecular weights of 70,000 and 45,000; minor components with molecular weights of 145,000 and 18,000 were also observed. Two lines of evidence indicate that the 70,000- and 45,000-molecular weight polypeptides represent translation products of the gag gene of the bovine leukemia virus genome (Pr70gag and Pr45gag). First, they are specifically precipitated by a monospecific antiserum to the major internal protein, p24, and second, they are synthesized and correctly processed into virion proteins p24, p15, and p10 in Xenopus laevis oocytes microinjected with bovine leukemia virus 38S RNA. The 145,000-molecular weight polypeptide was immunoprecipitated by the anti-p24 serum and not by an antiserum to the major envelope glycoprotein, gp60. It contained all the tryptic peptides of Pr70gag and additional peptides unique to it, and thus represents in elongation product of Pr70gag in an adjacent gene, presumably the pol gene. The 18,000-molecular weight product was antigenically unrelated to p24 and gp60 and shared no peptides in common with Pr70gag, Pr45gag, or the 145,000-molecular weight polypeptide. It was maximally synthesized on a polyadenylic acid-containing virion 16 to 18S RNA, and we present evidence that this RNA is a 3' end-derived subgenomic fragment of the bovine leukemia virus genome rather than a contaminating cellular RNA.     

The genome and the intracellular RNAs of avian myeloblastosis virus

Avian myeloblastosis virus (AMV) is an acute leukemia virus which causes a myeloblastic leukemia in birds and transforms myeloid hematopoietic cells in vitro. We have analyzed RNA from AMV virions and from AMV-transformed producer and nonproducer cells by gel electrophoresis followed by transfer to chemically activated paper and hybridization to several complementary DNA (cDNA) probes. Using a cDNA probe specific for AMV, we identified two RNA species of 7.2 and 2.3 kb, which were present in all AMV-transformed cells and in all AMV virion preparations examined. The 7.2 kb species, which is presumably the genome of AMV, appears to contain the entire retroviral gag gene and at least part of the pol gene, but lacks much (or all) of the env gene. Thus AMV differs from other acute leukemia viruses described to date, since the latter have genomes of 5.5 to 5.6 kb, have only part of the gag gene and lack pol sequences. The smaller RNA does not contain gag-, pol- or env-specific nucleotide sequences but does carry nucleotide sequences from both the 5' and 3' termini of the genome, suggesting that it may be a subgenomic mRNA. Both the 7.2 and 2.3 kb species were associated with the 70S RNA complex in virions. These results suggest that AMV, unlike other acute leukemia viruses, does not express its transforming gene via a gag-related "fusion" protein but rather as a (so far unidentified) protein translated from a subgenomic mRNA.     

The Parodi-Irgens feline sarcoma virus and simian sarcoma virus have homologous oncogenes, but in different contexts of the viral genomes

We have identified the oncogene and the putative transforming protein of the Parodi-Irgens feline sarcoma virus (PI-FeSV). The PI-FeSV is defective and needs a helper virus for its replication. The v-onc sequences in the PI-FeSV were found to be related to the v-sis sequences of the simian sarcoma virus (SSV). PI-FeSV nonproducer cells express two viral RNAs, a 6.8-and a 3.3-kilobase RNA. The 6.8-kilobase RNA contains gag, sis, and env sequences but lacks the pol gene. The 3.3-kilobase RNA, on the other hand, contains only env sequences. We have detected one feline leukemia virus-related protein product in these cells, namely, a 76-kilodalton protein which contains determinants of the feline leukemia virus gag proteins p15 and p30. The v-sis sequences in the PI-FeSV have been located near the 5' end of the viral genome. Taken together, these results imply that the p76 protein contains both feline leukemia virus gag and sis sequences and probably is the transforming protein of this virus. In contrast, in SSV the sis sequences are located towards the 3' end of the viral genome, and the sis protein is thought to be expressed via a subgenomic RNA. PI-FeSV and SSV therefore use different schemes to express their onc-related sequences. The v-sis sequences in the PI-FeSV contain restriction sites which reflect the different origin of the v-sis sequences in the PI-FeSV and SSV. The homologous oncogenes of the PI-FeSV and SSV thus were transduced by two different retroviruses, feline leukemia virus and the simian sarcoma-associated virus, apparently from the genomes of different species.     

Role of the gag polyprotein precursor in packaging and maturation of Rous sarcoma virus genomic RNA.

Rous sarcoma virus nucleocapsid protein (NC) has been shown by site-directed mutagenesis to be involved in viral RNA packaging and in the subsequent maturation of genomic RNA in the progeny viral particles. To investigate whether NC exerts these activities as a free protein or as a domain of the polyprotein precursor Pr76gag, we have constructed several mutants unable to process Pr76gag and analyzed their properties in a transient-transfection assay of chicken embryo fibroblasts, the natural host of Rous sarcoma virus. A point mutation in the protease (PR) active site completely prevents Pr76gag processing. The full-length Pr76gag polyprotein is still able to package viral RNA, but cannot mature it. A shorter gag precursor polyprotein lacking the C-terminal PR domain, but retaining that of the NC protein, is however, unable even to package viral RNA. This indicates that the NC protein can participate in packaging viral RNA only as part of a full-length Pr76gag and that the PR domain is, indirectly or directly, also involved in RNA packaging. These results also demonstrate that processing of Pr76gag is necessary for viral RNA dimerization.     

Autogenous regulation of RNA translation and packaging by Rous sarcoma virus Pr76gag.

Unspliced cytoplasmic retroviral RNA in chronically infected cells either is encapsidated by Gag proteins in the manufacture of virus or is used to direct synthesis of Gag proteins. Several models have been suggested to explain the sorting of viral RNA for these two purposes. Here we present evidence supporting a simple biochemical mechanism that accounts for the routing of retroviral RNA. Our results indicate that ribosomes compete with the Gag proteins to determine the fate of nascent retroviral RNA. Although the integrity of the entire Rous sarcoma virus leader sequence is important for retroviral packaging and translation, the RNA structure around the third small open reading frame, which neighbors the psi site required for packaging of the RNA, is particularly critical for maintenance of the balance between translation and packaging. These results support the hypothesis that Gag proteins autogenously regulate their synthesis and encapsidation of retroviral RNA and that an equilibrium exists between RNA destined for translation and packaging that is based on the intracellular levels of Gag proteins and ribosomes. To test the model, mRNAs with natural or mutated 5' leader sequences from Rous sarcoma virus were expressed in avian cells in the presence and absence of Pr76gag. We demonstrate that Pr76gag acts as a translational repressor of these mRNAs in a dose-dependent manner, supporting the hypothesis that Pr76gag can sort retroviral RNA for translation and encapsidation.     

Characterization of ribosome binding on Rous sarcoma virus RNA in vitro.

We determined the sites at which ribosomes form initiation complexes on Rous sarcoma virus RNA in order to determine how initiation of Pr76gag synthesis at the fourth AUG codon from the 5' end of Rous sarcoma virus strain SR-A RNA occurs. Ribosomes bind almost exclusively at the 5'-proximal AUG codon when chloride is present as the major anion added to the translational system. However, when chloride is replaced with acetate, ribosomes bind at the two 5'-proximal AUG codons, as well as at the initiation site for Pr76gag. We confirmed that the 5'-proximal AUG codon is part of a functional initiation site by identifying the seven-amino acid peptide encoded there. Our results suggest that (i) translation in vitro of Rous sarcoma virus virion RNA results in the synthesis of at least two polypeptides; (ii) the pattern of ribosome binding observed for Rous sarcoma virus RNA can be accounted for by the modified scanning hypothesis; and (iii) the interaction between 40S ribosomal subunits or 80S ribosomal complexes is stronger at the 5'-proximal AUG codon than at sites farther downstream, including the initiation site for the major viral proteins.     

Generation of avian myeloblastosis virus structural proteins by proteolytic cleavage of a precursor polypeptide.

The four major internal structural proteins (the group-specific antigens) of avian myeloblastosis virus are formed by sequential cleavage of a precursor polypeptide with M_r = 76,000 (Pr76). The evidence for this conclusion is based on analysis of immune precipitates from lysates of AMV⁴-infected cells treated with a multivalent antiserum directed against these proteins. Sodium dodecyl sulfate gel electrophoresis of such immune precipitates from cells pulse-labeled with [³⁵S]-methionine reveals five metabolically unstable radioactive polypeptides. These polypeptides behave kinetically as precursors to virion proteins. Double-label ion-exchange chromatography of tryptic digests of the unstable polypeptides demonstrates that the largest precursor, Pr76, contains the amino acid sequences of all four virion proteins. It appears not to contain the sequence of the fifth and smallest internal virion protein. The four smaller precursors are intermediate cleavage products of Pr76.The arrangement of the virion proteins in Pr76 was determined by labeling cells shortly after inhibiting polypeptide chain initiation. The relative amounts of radioactivity both in completed virion proteins and in the tryptic peptides of Pr76 implies the same order for three of the four proteins. The exact position of one protein remains uncertain.On the basis of these experiments, we propose a cleavage pathway for the generation of the structural proteins of AMV. We also demonstrate that cleavage of precursors can proceed in crude extracts of AMV-infected cells. This proteolysis, while resistant to several protease inhibitors, is completely blocked by addition of agents that disrupt membranes.     

Avian oncovirus MH2: molecular cloning of proviral DNA and structural analysis of viral RNA and protein

Viral RNA, molecularly cloned proviral DNA, and virus-specific protein of avian retrovirus MH2 were analyzed. The complexity and sequence conservation of the transformation-specific v-myc sequences of MH2 RNA were compared with those of the other members of the MC29 subgroup of acute leukemia viruses, MC29, CMII, and OK10, and with chicken cellular c-myc sequences. All T1 oligonucleotides mapping within the 1.3-kilobase coding region of MC29 v-myc have homologous counterparts in the RNAs of all MC29 subgroup viruses and in c-myc. These counterparts are either identical in composition or altered by single point mutations. Hence, the 47,000-dalton carboxy-terminal sequences of the transforming proteins of these viruses and of the cellular gene product are probably highly conserved but may contain single amino acid substitutions. T1 oligonucleotide mapping of MH2 RNA indicated that the MH2 v-myc sequences map close to the 3' end of viral RNA. A genomic library of an MH2-transformed quail cell line was prepared by using the Charon 4A vector system. By screening with an myc-specific probe, a clone containing the entire MH2 provirus (lambda MH2-1) was isolated. Digestion of cloned DNA with KpnI yielded a 5.1-kilobase fragment hybridizing to both gag- and myc-specific probes. Further restriction mapping of lambda MH2-1 DNA showed that about 1.6 kilobases of the gag gene are present near the 5' end of proviral DNA, and the conserved part of v-myc, i.e., 1.3 kilobases, is present near the 3' end of proviral DNA. These two domains are separated by a segment of at least 1 kilobase of different genetic origin, including additional unique sequences unrelated to virion genes. Tryptic peptide analysis of the gag-related protein of MH2, p100, revealed gag-specific peptides and several unique methionine-containing peptides. One of the latter is possibly shared with the polymerase precursor protein Pr180gag-pol, but no myc-specific peptides, defined for the MC29 protein p110gag-myc, appear to be present in MH2 p100. The data on viral RNA, proviral DNA, and protein of MH2 reveal a unique genetic structure for this virus of the MC29 subgroup and suggest that its v-myc gene is not expressed as a gag-related protein.     

Generation of altered transcripts by retroviral insertion within the c-myb gene in two murine monocytic leukemias

Two murine monocytic leukemia cell lines, WEHI-265 and WEHI-274, were found to carry a rearranged c-myb gene. The rearrangements are due to insertion of a deleted Moloney murine leukemia virus (Mo-MLV) provirus in the 5' region of the c-myb gene and thus are similar to rearrangements in the ABPL tumors (G. L. C. Shen-Ong, M. Potter, J. F. Mushinski, S. Lavu, and E. P. Reddy, Science 226:1077-1080, 1984). In each cell line, the retroviral insertion has induced high levels of two aberrant RNA species, which, as in the ABPL tumors (G. L. C. Shen-Ong, H. C. Morse, M. Potter, and J. F. Mushinski, Mol. Cell. Biol. 6:380-392, 1986), contain both viral (Mo-MLV) and cellular (myb) sequences. Both species lack the sequences encoding the amino terminus of the c-myb protein and thus could encode a protein which, like the v-myb gene products (and the predicted ABPL myb proteins), is truncated at the amino terminus. We have found that the larger (5.3 kilobase [kb]) and more abundant of the tumor-specific myb RNAs was predominantly nuclear, while the smaller species (3.9 kb) was cytoplasmic. Furthermore, our data imply that the 3.9-kb RNA was derived from the 5.3-kb RNA by an additional splice which utilized a cryptic splice acceptor site within the viral gag sequences. On the basis of subcellular distribution and predicted translational potential, we conclude that the 3.9-kb RNA is probably the mRNA which encodes a truncated myb protein. We also show that, due to different insertion points in W265 and W274, the W274 myb RNAs contained sequences from a c-myb exon upstream of the exons represented in the W265 (and ABPL) RNAs. The significance of our findings with regard to transformation by myb in these tumors is discussed.     

RNA and protein encoded by MH2 virus: evidence for subgenomic expression of v-myc.

MH2 and MC29 are highly related myc-containing avian retroviruses. We found that MH2, unlike MC29, synthesizes a 2.6-kilobase subgenomic mRNA containing myc sequences as well as sequences from the 5' end of the genome. A 57-kilodalton protein containing myc, but not gag, sequences (p57myc) was detected by hybrid selection and in vitro translation of RNA from MH2-transformed cells. Gradient separation of MH2 intracellular RNAs indicated that p57myc is encoded by the subgenomic RNA. A highly oncogenic MH2 virus variant (MH2YS3) (M. Linial, Virology 119:382-391, 1982) was shown to encode only p57myc and not P100, the previously described MH2-encoded polyprotein (Hu et al., Virology, 89:162-178, 1978). Cells transformed by subclones of this virus synthesized predominantly the 2.6-kilobase RNA rather than genomic 5.4-kilobase RNA. These results suggest that only p57myc is required for maintenance of the transformed state after MH2 infection.     

Generation of transforming viruses in cultures of chicken fibroblasts infected with an avian leukosis virus.

During serial passages of an avian leukosis virus (the transformation-defective, src deletion mutant of Bratislava 77 avian sarcoma virus, designated tdB77) in chicken embryo fibroblasts, viruses which transformed chicken embryo fibroblasts in vitro emerged. Chicken embryo fibroblasts infected with these viruses (SK770 and Sk780) had a distinctive morphology, formed foci in monolayer cultures, and grew independent of anchorage in semisolid agar. Bone marrow cells were not transformed by these viruses. Another virus (SK790) with similar properties emerged during serial subcultures of chicken embryo fibroblasts after a single infection with tdB77. The 50S to RNAs isolated from these viruses contained a tdB77-sized genome (7.6 kilobases), 8.7- and 5.7-kilobase RNAs, and either a 4.1-kilobase RNA or a 4.6-kilobase RNA. These RNAs did not hybridize with cDNA's representing the src, erb, mac, and myb genes of avian acute transforming viruses. Cells transformed by any one of the Sk viruses (SK770, SK780, or SK790) synthesized two novel gag-related polyproteins having molecular weights of 110,000 (p110) and 125,000 (p125). We investigated the compositions of these proteins with monospecific antiviral protein sera. We found that p110 was a gag-pol fusion protein which contained antigenic determinants, leaving 49,000 daltons which was antigenically unrelated to the structural and replicative proteins of avian leukosis viruses. An analysis of the SK viral RNAs with specific DNA probes indicated that the 5.7-kilobase RNA contained gag sequences but lacked pol sequences and, therefore, probably encoded p125. The transforming ability, the deleted genome, and the induced polyproteins of the SK viruses were reminiscent of the properties of several replication-defective acute transforming viruses.     

Nucleotide sequence and expression in Escherichia coli of the Lactococcus lactis citrate permease gene.

The plasmid-encoded citrate determinant of the Lactococcus lactis subsp. lactis var. diacetylactis NCDO176 was cloned and functionally expressed in a Cit- Escherichia coli K-12 strain. From deletion derivative analysis, a 3.4-kilobase region was identified which encodes the ability to transport citrate. Analysis of proteins encoded by the cloned fragment in a T7 expression system revealed a 32,000-dalton protein band, which correlated with the ability of cells to transport citrate. Energy-dependent [1,5-14C]citrate transport was found with membrane vesicles prepared from E. coli cells harboring the citrate permease-expressing plasmid. The gene encoding citrate transport activity, citP, was located on the cloned fragment by introducing a site-specific mutation that abolished citrate transport and resulted in a truncated form of the 32,000-dalton expression product. The nucleotide sequence for a 2.2-kilobase fragment that includes the citP gene contained an open reading frame of 1,325 base pairs coding for a very hydrophobic protein of 442 amino acids, which shows no sequence homology with known citrate carriers.     

Polyprotein Precursors to Mouse Mammary Tumor Virus Proteins

Mouse mammary tumor virus (MMTV) derived from the culture medium of GR cells contained seven proteins, identified as gp55, gp33, p25, pp20, p16, p12, and p10. The major viral phosphoprotein was the 20,000-molecular-weight protein, pp20. Immunoprecipitation of cytoplasmic extracts from pulse-labeled GR cells identified three MMTV gag-specific proteins, termed Pr78(gag), Pr110(gag), and Pr180(gag+). These intracellular polyproteins were precipitable from cytoplasmic extracts by antisera to virions p25 and p12 but not by antisera to gp55. The major intracellular gag-specific precursor polyprotein, Pr78(gag), contained antigenic determinants and tryptic peptides characteristic of p25, p12, p10, and presumably pp20. This precursor is presumably derived from nascent chain cleavage or rapid posttranslational cleavage of the larger intracellular precursor-like protein, designated Pr110(gag). Pr110(gag) contained all but one of the leucine-containing tryptic peptides of Pr78(gag), plus several additional peptides. In addition to Pr78(gag) and Pr110(gag), monospecific antisera to virion p12 and p25 were also capable of precipitating from pulse-labeled cells a small amount of a 180,000-molecular-weight precursor-like protein, designated Pr180(gag+). This large polyprotein contained nearly all of the leucine-containing tryptic peptides of Pr78(gag) and Pr110(gag) plus several additional peptides. By analogy to type C viral systems, Pr180(gag+) is presumed to represent a gag-pol common precursor which is the major pathway for synthesis of MMTV polymerase. Immunoprecipitation of cytoplasmic extracts from pulse-labeled cells with antisera to gp55 identified two env-specific proteins, designated gPr76(env) and gP79(env). The major env precursor, gPr76(env), could be labeled with radioactive glucosamine and was shown to contain antigenic determinants and tryptic peptides characteristic of gp55 and gp33. A minor glycoprotein, gP79(env), contained both fucose and glucosamine and was precipitable from cytoplasmic extracts with monospecific serum to gp55. It is suggested that gP79(env) represents fucosylated gPr76(env) which is transiently synthesized and cleaved rapidly into gp55 and gp33.     

Mitotic apparatus and nucleoli compartmentalization of 50,000-dalton type II regulatory subunit of cAMP-dependent protein kinase in estrogen receptor negative MDA-MB-231 human breast cancer cells

Affinity purified RI and RII antibodies of regulatory subunits (R) of type I (RI) and type II (RII) cAMP-dependent protein kinase were utilized to determine the immunological characterization and specific compartmentalization of R in estrogen receptor negative MDA-MB-231 human breast cancer cells. The 8-azido-(32P)-cAMP binding analysis of MDA-MB-231 cell extracts exhibited 47,000- and 50,000-dalton cAMP receptor proteins. RI and RII antibodies, by immunoprecipitation, detected the 47,000- and 50,000-dalton proteins, respectively. The 47,000-dalton protein was identified as RI as it showed a similar molecular weight as of bovine RI on SDS-polyacrylamide gel electrophoresis. Although 50,000-dalton protein did not co-migrate with bovine heart 54,000-dalton RII, it was identified as RII of MDA-MB-231 cells since it was specifically precipitated with RII antibody but not with RI antibody. An indirect immunofluorescence revealed that during different phases of growth of MDA-MB-231 cells, 50,000-dalton RII was specifically compartmentalized in the mitotic spindle and nucleoli of the cells whereas RI did not exhibit a specific compartmentalization in the cells, but was distributed throughout the cell components. These results suggest specific role(s) of 50,000-dalton RII at the nuclei of MDA-MB-231 cells.