Defectiveness of avian erythroblastosis virus: synthesis of a 75K gag-related protein

Cellular sequences are present in the presumptive avian myeloblastosis virus genome

EcoRI restriction endonuclease fragments from a lambda proviral DNA hybrid containing the entire presumptive avian myeloblastosis virus (AMV) provirus, and from a lambda proviral hybrid containing a partial myeloblastosis-associated virus type 1 (MAV-1)-like provirus were compared by heteroduplex analysis. The cloned presumptive AMV provirus was also analyzed by electron microscopy, using R-loop formation with purified 35S RNA isolated from virions of the standard AMV complex. The results indicate that the putative AMV genome contains a segment absent in its MAV-1-like helper virus. This segment represents a substitution in the region of the genome that in MAV-1 virus is occupied by the envelope gene and is approximately 900 +/- 160 nucleotide pairs in length. Hybridization of specific probes from the presumptive AMV genome to Southern blots of EcoRI-digested cellular DNA has revealed that these substituted sequences are homologous to chicken and duck DNA that is not related to chicken endogenous proviral sequences.

Transformation-defective mutants of feline sarcoma virus which express a product of the viral src gene

Mink cell cultures infected with the Snyder-Theilen strain of feline sarcoma-leukemia virus were cloned from single cells under conditions favoring single virus-single cell interactions. The primary colonies included (i) typical feline sarcoma virus (FeSV)-transformed nonproducer clones, one of which segregated revertants, and (ii) FeSV-infected, phenotypically normal clones, three of which spontaneously converted to the transformed phenotype. The revertants and spontaneous transformants were compared with parental and sister clones expressing the opposite phenotype. Transformed subclones formed colonies in agar, were tumorigenic in nude mice, and failed to bind epidermal growth factor, whereas flat sister subclones were indistinguishable from uninfected mink cells in each of these assays. Sister subclones derived from the same infectious event contained FeSV proviruses integrated at the same molecular site, regardless of which phenotype was expressed. One revertant clone, however, lacked most FeSV proviral DNA sequences but retained terminal portions of the FeSV genome which persisted at the original site of proviral DNA insertion. Two flat subclones expressed viral RNA and the phosphorylated "gag-x" polyprotein (pp78gag-x) encoded by the gag and src sequences of the FeSV genome. Both of these clones were susceptible to retransformation by FeSV. Although unable to induce foci, the viruses rescued from these cells contained as much FeSV RNA as the focus-forming viruses rescued from transformed sister subclones and could be retransmitted to mink cells, again inducing FeSV gene products without signs of morphological transformation. We conclude that these FeSV genomes represent transformation-defective mutants.

Characterization of the transforming gene of Fujinami sarcoma virus

The src gene present in all avian sarcoma viruses is not present in the genome of Fujinami sarcoma virus, a potent sarcoma-inducing virus in chickens. Fujinami virus is defective and requires helper virus for replication. RNA from a mixture of helper and transforming viruses consists of two components, 35S and 28S. Oligonucleotide fingerprinting of each RNA component revealed that the 35S component was identical to the RNA of the helper virus. Thus, the genome of Fujinami virus must be the 28S RNA, which corresponds approximately to a molecular weight of 1.7 x 10(6) or 5300 nucleotides. Fujinami viral RNA shares several oligonucleotides with helper viral RNA at both 3' and 5' ends but contains a unique sequence of at least 3000 nucleotides in the middle of the genome. Fujinami viral RNA contains no src-specific oligonucleotides of the Rous sarcoma virus genome and did not hybridize with DNA complementary to the src sequences. The 60,000-dalton src protein of Rous sarcoma virus was undetectable in Fujinami virus-transformed cells. Instead, these transformed cells contain a protein of 140,000 daltons precipitable by antisera against virion proteins, which is likely to be the transforming protein of this virus.

Fujinami sarcoma virus: an avian RNA tumor virus with a unique transforming gene

The oncogenic properties and RNA of the Fujinami avian sarcoma virus (FSV) and the protein it encodes were investigated and compared to those of other avian tumor viruses with sarcomagenic properties such as Rous sarcoma virus and the acute leukemia viruses MC29 and erythroblastosis virus. Cloned stocks of FSV caused sarcomas in all chickens inoculated and were found to contain a 4.5-kilobase (kb) and an 8.5-kb RNA species. The 4.5-kb RNA was identified as the genome of defective FSV because it was absent from nondefective FSV-associated helper virus and because the titer of focus-forming units increased with the ratio of 4.5-kb to 8.5-kb RNA in virus preparations. This is, then, the smallest known tumor virus RNA with a transforming function. Comparisons with other viral RNAs, based on oligonucleotide mapping and molecular hybridization, indicated that 4.5-kb FSV RNA contains a 5' gag gene-related sequence of 1 kb, an internal specific sequence of about 3 kb that is unrelated to Rous sarcoma virus, MC29, and erythroblastosis virus, and a 3'-terminal sequence of about 0.5 kb related to the conserved C region of avian tumor viruses. The lack of some or all nucleotide sequences of the essential virion genes, gag, pol, and env, and the isolation of FSV-transformed nonproducer cell clones indicated that FSV is replication defective. A 140,000-dalton, gag-related non-structural protein was found in FSV-transformed producer and nonproducer cells and was translated in vitro from full-length FSV RNA. This protein is expected to have a transforming function both because its intracellular concentration showed a positive correlation with the percentage of transformed cells in a culture and because FSV is unlikely to code for major additional proteins since the genetic complexities of FSV RNA and the FSV protein are almost the same. It is concluded that the transforming onc gene of FSV is distinct from that of Rous sarcoma virus and other avian tumor viruses with sarcomagenic properties. Hence, multiple mechanisms exist for sarcomagenic transformation of avian cells.

Cell-free translation of avian erythroblastosis virus RNA

Avian erythroblastosis virus (AEV) RNA rescued from nonproducer cells by superinfection with a helper virus is translated into three polypeptides in the messenger-dependent rabbit reticulocyte lysate. A 75,000 molecular weight polypeptide (P75AEV) is synthesized from 28S RNA and is encoded by the 5' section of the AEV RNA, including gag-related and AEV-specific sequences. The P75AEV synthesized in infected cells and the P75AEV synthesized in the cell-free system are electrophoretically identical. A 44,000 molecular weight polypeptide (P44AEV) is synthesized from 20-24S RNA, apparently from the 3' section of the AEV-specific RNA sequence. A minor 37,000 molecular weight polypeptide (P37AEV) is synthesized from 20S AEV RNA. A comparison is drawn between the cell-free products of MC29 and AEV RNAs.

Transfection by DNAs of avian erythroblastosis virus and avian myelocytomatosis virus strain MC29

Chicken embryo fibroblasts and NIH 3T3 mouse cells were transformable by DNAs of chicken cells infected with avian myelocytomatosis virus strain MC29 or with avian erythroblastosis virus. Transfection of chicken cells appeared to require replication of MC29 or avian erythroblastosis virus in the presence of a nontransforming helper virus. In contrast, NIH 3T3 cells transformed by MC29 or avian erythroblastosis virus DNA contained only replication-defective transforming virus genomes.

Comparative tryptic peptide mapping studies suggest a role in cell transformation for the gag-related protein of avian erythroblastosis virus and avian myelocytomatosis virus strains CMII and MC29

The gag-related proteins found in cells transformed by avian erythroblastosis virus (AEV) and the avian myelocytomatosis viruses MC29 and CMII have been compared by tryptic peptide fingerprinting. A comparison of the methionine-containing tryptic peptides of the AEV 75-kilodalton protein, the CMII 90-kilodalton protein, and the MC29 110-kilodalton protein with the gag gene product Pr76 of their naturally occurring helper leukemia viruses enabled us to distinguish those peptides related to the gag gene from the non-gag-related peptides. The 12 non-gag peptides found in the AEV 75-kilodalton protein were unique to this protein and not found in the MC29 110-kilodalton or CMII 90-kilodalton proteins. In contrast, the MC29 110-kilodalton protein shared two methionine-containing non-gag tryptic peptides with the CMII 90-kilodalton protein. When these experiments were repeated with [14C]lysine and [14C]arginine as the labeled amino acids, the MC29 110-kilodalton protein and the CMII 90-kilodalton protein were found to share 30 out of approximately 40 non-gag-related peptides. These results demonstrate that viruses with a similar transformation spectrum synthesize related proteins and suggest that the gag-related proteins represent the transforming proteins of the replication-defective avian leukemia viruses.

Biochemical and immunological characterization of polyproteins coded for by the McDonough, Gardner-Arnstein, and Snyder-Theilen strains of feline sarcoma virus

The McDonough (SM), Gardner-Arnstein (GA), and Snyder-Theilen (ST) strains of feline sarcoma virus (FeSV) code for high-molecular-weight polyproteins that contain varying amounts of the amino-terminal region of the FeLV gag gene-coded precursor protein and a polypeptide(s) of an as yet undetermined nature. The SM-FeSV primary translational product is a 180,000-dalton polyprotein which is immediately processed into a highly unstable 60,000-dalton molecule containing the p15-p12-p30 fragment of the FeLV gag gene-coded precursor protein and a 120,000-dalton FeSV-specific polypeptide. The GA- and ST-FeSV genomes code for polyproteins of 95,000 and 85,000 daltons, respectively, which in addition to the amino-terminal moiety (p15-12 and a portion of p30) of the FeLV gag gene-coded precursor protein also contain FeSV-specific polypeptides. However, the GA- and ST-FeSV polyproteins appear to be relatively stable molecules (half-lives of around 16 h) and are not significantly processed into smaller polypeptides. Immunological and biochemical analysis of each of the above FeSV translational products revealed that the sarcoma-specific regions of the GA- and ST-FeSV polyproteins are antigenically cross-reactive and exhibit common methionine-containing peptides. These findings favor the concept that these sarcoma-specific polypeptides are coded for by the similar subsets of cellular sequences incorporated into the GA- and ST-FeSV genomes during the generation of these transforming agents.

Three laboratory strains of spleen focus-forming virus: comparison of their genomes and translational products

The molecular properties of three laboratory strains of the spleen focus-forming virus were compared. All strains contain genetic sequences related to the env gene of mink cell focus-inducing murine type C leukemia viruses, and each strain codes for a glycoprotein of 50,000 to 52,000 daltons which shares specific immunological properties with the gp70's of mink cell focus-inducing viruses. In contrast to this constancy, gag gene products coded for by these strains vary significantly. The gag and env gene products are synthesized from separate mRNA's, and the mRNA for the env gene product is approximately 18S. Unlike other acute leukemia viruses, which can transform various undifferentiated cells, have large unique sequence cellular gene inserts fused to helper virus gag genes, and have one known genome-length intracellular mRNA, the spleen focus-forming virus transforms only specific hematopoietic stem cells, is an env gene rather than a gag gene recombinant virus, and has a second distinct and smaller class of intracellular mRNA. Our data therefore indicate that the Friend strain of the spleen focus-forming virus is a unique replication-defective acute leukemia virus.

Target cell specificity of defective avian leukemia viruses: hematopoietic target cells for a given virus type can be infected but not transformed by strains of a different type

Defective avian leukemia viruses of the avian erythroblastosis (AEV), avian myelocytomatosis (MC29), and avian myeloblastosis (AMV) type induce the proliferation of leukemic cells with properties of erythroblasts, macrophages, and myeloblasts, respectively. Their target cells can be separated and have properties of cells of the erythroid (AEV) and myeloid lineage (MC29 and AMV), respectively. In the present study we have shown that this target cell specificity is not due to the ability of the different strains to infect only certain types of hematopoietic cells. Instead, AEV was found to replicate in macrophages and to induce the expression of p75 AEV, its presumptive transforming protein. Likewise, MC29 was found to replicate in AEV-infected erythroblasts as well as in AMV-infected myeloblasts and to express the p110 MC29 protein in these cells. Superinfection with MC29 or AMV of ts34 AEV-infected erythroblasts did not impair their capacity to accumulate hemoglobin after shift to nonpermissive temperature. Our results support a model in which the transforming proteins of AEV, MC29, and MAV block the differentiation of their target cells by competitively inhibiting the action of a hypothetical homologous cellular differentiation protein synthesized in the corresponding target cells only.

Three new types of viral oncogene of cellular origin specific for haematopoietic cell transformation

The RNAs of seven replication-defective leukaemia virus (DLV) strains contain three types of unique sequences, which correlate with the capacity of a given virus strain to transform erythroblasts, macrophage-like cells and myeloblasts, respectively. These sequences, termed erb, mac and myb, have their counterparts in the normal DNA of avian and mammalian species. Our results indicate that DLVs represent recombinants between a common 'vector' related to a chicken endogenous virus and one of three types of cellular gene possibly involved in haematopoietic differentiation.

Chicken hematopoietic cells transformed by seven strains of defective avian leukemia viruses display three distinct phenotypes of differentiation

Chicken hematopoietic cells transformed in vitro and in vivo by seven strains of replication-defective avian leukemia viruses were assayed for the expression of six erythroid and five myeloid differentiation parameters, including differentiation-specific surface antigens as detected by newly developed antisera. The transformed cells were found to display three distinct phenotypes of differentiation. First, cells transformed by AEV resemble erythroblasts. They express heme, globin, carbonic anhydrase and erythrocyte cell surface antigen at low levels, and histone H5 and erythroblast cell surface antigen at high levels. Second, cells transformed by MC29, CMII, OK10 and MH2 viruses have macrophage-like properties. They strongly express Fc receptors, phagocytic capacity and macrophage cell surface antigen, but only weakly express myeloblast cell surface antigen and are negative for ATPase activity. Third, cells transformed by AMV and E26 viruses resemble myeloblasts in that they weakly express Fc receptors, phagocytic capacity and macrophage cell surface antigen but strongly express myeloblast cell surface antigen and ATPase activity. No difference was found between in vitro- and in vivo-transformed cells in the parameters tested. In light of recent genetic and biochemical evidence, we believe that these phenotypes reflect the action of three new types of viral-transforming genes, designated erb (erythroblast), mac (macrophage) and myb (myeloblast).

Cell-surface antigens induced by RNA tumour viruses

Host animals show an immune response to the surface of cells infected with RNA tumour viruses. An element of this response is due to expression of viral structural antigens, but the major part is due to virus-induced cell-surface antigens (CSAs). This article compares the properties of CSAs of the avian, murine and feline retrovirus systems.