Abelson murine leukemia virus mutants deficient in kinase activity and lymphoid cell transformation.

Abelson murine leukemia virus transforms both lymphoid cells and fibroblasts in vitro and induces a unique type of thymus-dependent lymphoma in vivo. Four fibroblast-transforming strains of Abelson murine leukemia virus were identified, based on the sizes of the Abelson murine leukemia virus-specific phosphoproteins produced by these isolates. Two of these strains, the standard P120- and the P160-producing viruses, transformed lymphoid cells efficiently in vitro and induced Abelson disease in vivo. Two other strains, which synthesized small Abelson murine leukemia virus-specific proteins with molecular weights of 90,000 (P90) and 100,000 (P100), transformed lymphoid cells very poorly both in vitro and in vivo. The reduced oncogenic potentials of these isolates were correlated with a high level of synthesis of fairly unstable P90 and P100. In addition, neither P90 nor P100 functional efficiently in protein kinase assays. The correlation of abnormal metabolism and deficient protein kinase activity with the reduced oncogenic potentials of these virus strains supported a direct role for these proteins and the kinase activity in transformation. Furthermore, these results suggested that the requirements for lymphoid cell transformation and fibroblast transformation are different.     

The same normal cell protein is phosphorylated after transformation by avian sarcoma viruses with unrelated transforming genes.

The phosphorylation of a normal cellular protein of molecular weight 34,000 (34K) is enhanced in Rous sarcoma virus-transformed chicken embryo fibroblasts apparently as a direct consequence of the phosphotransferase activity of the Rous sarcoma virus-transforming protein pp60src. We have prepared anti-34K serum by using 34K purified from normal fibroblasts to confirm that the transformation-specific phosphorylation described previously occurs on a normal cellular protein and to further characterize the nature of the protein. In this communication, we also show that the phosphorylation of 34K is also increased in cells transformed by either Fujinami or PRCII sarcoma virus, two recently characterized avian sarcoma viruses whose transforming proteins, although distinct from pp60src, are also associated with phosphotransferase activity. Moreover, comparative fingerprinting of tryptic phosphopeptides shows that the major site of phosphorylation of 34K is the same in all three cases.     

Cellular responsiveness to growth factors correlates with a cell's ability to express the transformed phenotype

Five random subclones of the rat fibroblast line F2408 vary in their frequency of transformation by the unrelated Kirsten murine sarcoma virus and Abelson murine leukemia virus. The same pattern of sensitivity is displayed when the cells are induced to anchorage-independent growth (transformed) by epidermal, platelet-derived, and sarcoma growth factors, or by whole serum. Our results demonstrate that a growth factor's ability to render cells anchorage independent is not unique to transforming growth factors, but common to many growth factors; anchorage-independent growth is a function of the total growth factor concentration in the medium; cells vary in their inherent responsiveness to growth-factor-induced anchorage-independent growth; and cells resistant to growth-factor-induced anchorage-independent growth are also resistant to transformation by a variety of tumor viruses. We conclude that the way a cell responds to growth factors plays a central role in the expression of the transformed phenotype.     

Changes in protein phosphorylation in Rous sarcoma virus-transformed chicken embryo cells.

Rous sarcoma virus encodes a tyrosine-specific protein kinase (p60src) which is necessary for cell transformation. To identify substrates for this kinase, we set out to detect phosphotyrosine-containing proteins in Rous sarcoma virus-transformed chicken embryo cells, making use of the known alkali stability of phosphotyrosine. 32P-labeled phosphoproteins were separated by isoelectric focusing and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The gels were then incubated in alkali. Using this procedure with normal cells, we detected a total of about 190 alkali-resistant phosphoproteins. In Rous sarcoma virus-transformed cells, five phosphoproteins were found which were not detectable in normal cells. Two of these are probably structural proteins of the virus. The other three transformation-dependent phosphoproteins, and four other phosphoproteins which were elevated by transformation, all contained phosphotyrosine. Increased phosphorylation of these proteins did not occur with cells infected with a mutant Rous sarcoma virus, temperature sensitive for transformation, grown at the restrictive temperature. We conclude that these seven proteins are probably substrates of p60src, although they may be substrates for other tyrosine-specific protein kinases activated by p60src.     

Changes in the synthesis and phosphorylation of cellular proteins in chick fibroblasts transformed by two avian sarcoma viruses

35S- and 32P-labeled proteins from control chick embryo fibroblasts and from fibroblasts transformed by UR2 sarcoma virus, or by a temperature-sensitive mutant (tsLA29) of Rous sarcoma virus, were separated by two-dimensional electrophoresis on giant gels to detect transformation-specific changes in protein synthesis and total phosphorylation. A nontransforming avian retrovirus, UR2-associated virus (UR2AV), was also studied. Virus-coded proteins appear in whole cell lysates of all infected cells. The structural proteins can be identified by comparison with proteins immunoprecipitated with antivirus serum. The transforming proteins pp60src and p68ros, present in cells transformed with Rous sarcoma virus and UR2, respectively, are phosphorylated in vivo. Eighteen increases and eight decreases in cellular phosphoproteins are associated with transformation, and revert toward normal levels when cells infected with tsLA29 are incubated at 42 degrees C. These changes are more extensive than previously reported, but none represent new phosphorylations, since all phosphoproteins seen in transformed cells also appear to be phosphorylated to a certain extent in control cells. Fifteen cellular proteins show increased relative rates of synthesis apparently related either to transformation or to growth at 42 degrees C. Four other proteins are increased exclusively in cells incubated at 42 degrees C, but not at 37 degrees C, whether transformed or not. Eleven additional increases in the synthesis of cellular proteins, many quite large, and one seemingly a de novo induction, appear to be specific for transformation. These changes occur in cells transformed by either UR2 or Rous sarcoma virus at 37 degrees C, do not occur with UR2AV infection, and tend to revert in cells infected with tsLA29 incubated at 42 degrees C. These 11 changes may represent increases in cellular gene expression that are related specifically to the maintenance of the transformed state.     

Comparison of the expression of the src gene of Rous sarcoma virus in vitro and in vivo.

We have compared the polypeptide products of the src gene of several strains of Rous sarcoma virus produced by in vitro translation of heat-denatured 70S virion RNA in the nuclease-treated reticulocyte lysate with those present in chick cells transformed by these viruses. We have done this by immunoprecipitation, using sera from rabbits injected at birth with Schmidt-Ruppin Rous sarcoma virus. In vitro translation results in the synthesis of at least nine polypeptides which appear to be encoded by the src gene. These range in size from 17,000 to 60,000 daltons. The sera from tumor-bearing rabbits precipitated these polypeptides arising from the in vitro translation of RNA from Schmidt-Ruppin Rous sarcoma virus of both subgroup A and subgroup D and from one stock of Prague Rous sarcoma virus of subgroup C. In each case, all of this family of related polypeptides could be precipitated except the smallest, the 17,000-dalton polypeptide. No precipitation of analogous polypeptides resulting from the translation of RNA from other strains of Rous sarcoma virus was observed. Cells transformed by these three strains of Rous sarcoma virus contain easily detectable amounts of a polypeptide, p60src, essentially identical to the 60,000-dalton in vitro product. With one exception, they do not contain significant amounts of polypeptides analogous to the smaller in vitro products which can be precipitated by these sera. Cells transformed by one stock of Schmidt-Ruppin Rous sarcoma virus of subgroup A did contain a 39,000-dalton polypeptide, which was related, by peptide mapping, to the 60,000-dalton polypeptide and was similar in size to a precipitable in vitro product. The 60,000-dalton polypeptide present in transformed cells appeared to be phosphorylated 10 to 25 min after its synthesis, metabolically very stable, and not derived from a precursor polypeptide. All immunoprecipitates from transformed cells which contained p60src also contained an 80,000-dalton phosphoprotein. This polypeptide is unrelated to p60src, as determined by peptide mapping, and may well be a host cell polypeptide which is specifically associated with p60src.     

Some lymphoid cell lines transformed by Abelson murine leukemia virus lack a major 36,000-dalton tyrosine protein kinase substrate.

Fibroblasts transformed by Abelson murine leukemia virus differ from normal fibroblasts in that they contain several cellular proteins, including one of 29 and one of 36 kilodaltons, which are phosphorylated at tyrosine residues. Since it has been shown before that these proteins also become phosphorylated at tyrosine after transformation of fibroblasts by a number of other retroviruses, their phosphorylation may play an important role in the transformation of these cells. In contrast, the 36-kilodalton phosphoprotein was not detectable in three of the four lines of Abelson virus-transformed B lymphoma cell lines studied here. These three cell lines, RAW307.1.1, 18-48, and 18-81, and a B lymphoma induced by mineral oil, WEHI 279, were all found to lack both the phosphorylated and unphosphorylated forms of the 36-kilodalton protein. It thus appears that expression of this major cell protein is not essential for the survival of B lymphoma cells in culture and that the phosphorylation of the 36-kilodalton protein at tyrosine is not essential for transformation of pre-B lymphocytes by Abelson virus.     

Detection of tyrosine-specific protein kinases with gastrin as exogenous substrate

Gastrin was recently shown to be phosphorylated on its single tyrosine by the epidermal growth factor (EGF)-stimulated tyrosine protein kinase (TPK). The TPK previously detected in the murine lymphoma (LSTRA) induced by the Moloney murine leukemia virus phosphorylates gastrin, the apparent K_m is 65 μM and the maximum rate 1900 pmol/min per mg; the kinase is more efficeint with MnCl₂ than with MgCl₂, is stimulated by NaVO₃ and inhibited by ZnCl₂. Gastrin phosphorylation is observed only when a TPK is expressed by the cell: extracts of fibroblasts infected with a temperature-sensitive mutant of the Rous sarcoma virus had no gastrin kinase activity when grown at the non-permissive temperature whereas cells grown at the permissive temperature were transformed and disclosed a clear gastrin kinase activity. Gastrin kinases were detected in various transformed cells; human lymphomas, K562 cells, cells from a patient with acute proliferative leukemia, and normal cels; human T and B lymphocytes.     

Abelson virus drives the differentiation of Harvey virus-infected erythroid cells

Abelson murine leukemia virus (A-MuLV) and Harvey murine sarcoma virus (Ha-MSV) are retroviruses carrying unrelated onc genes. However, both of these viruses are capable of stimulating the growth and differentiation of erythroid precursor cells; the target cells for both appear at the same time during fetal development and follow a similar pattern throughout ontogeny. In addition, the colonies induced by each virus are morphologically similar and synthesize the adult form of hemoglobin. However, A-MuLV-infected cells are Epo-independent, whereas Ha-MSV-infected cells are Epo-dependent. Superinfection of Ha-MSV-infected cells with A-MuLV overrides their Epo-dependency. Thus, the consequences of the infection are determined by the interaction of the different onc gene products with identical or similar erythroid cells.     

Construction and isolation of a transforming murine retrovirus containing the src gene of Rous sarcoma virus.

Recombinant murine retroviruses containing the src gene of the avian retrovirus Rous sarcoma virus were isolated. Such viruses were isolated from cells after transfection with DNAs in which the src gene was inserted into the genome of the amphotropic murine retrovirus 4070A. The isolated viruses had functional gag and pol genes, but they were all env defective since the src gene was inserted in the middle of the env gene coding region. Infectious transforming virus could be isolated only from cells transfected with DNA constructions in which the src gene was in the same polarity as that of a long terminal repeat of the amphotropic viral genome. These recombinant viruses encoded a pp60src protein with a molecular weight similar to that of the Schmidt-Ruppin strain of Rous sarcoma virus. In addition, the src protein(s) of these recombinant viruses was as active as protein kinases in the immune complex protein kinase assay. Intravenous injection of helper-independent Moloney and Friend murine leukemia virus pseudotypes of the src recombinant viruses into 6-week-old NIH Swiss mice resulted in the appearance of splenic foci within 2 weeks, splenomegaly and, later after infection (8 to 10 weeks), anemia. Infectious transforming virus could be recovered from the spleens of diseased animals. Such viruses encoded pp60src but not p21ras or mink cell focus-forming virus-related glycoproteins.     

Biochemical characterization of cells transformed via transfection by feline sarcoma virus proviral DNA.

Murine fibroblasts transformed by transfection with DNA from mink cells infected with the Snyder-Theilen strain of feline sarcoma virus and subgroup B feline leukemia virus were analyzed for the presence of integrated proviral DNA and the expression of feline leukemia virus- and feline sarcoma virus-specific proteins. The transformed murine cells harbored at least one intact feline sarcoma virus provirus, but did not contain feline leukemia virus provirus. The transformed murine cells expressed an 85,000-dalton protein that was precipitated by antisera directed against feline leukemia virus p12, p15, and p30 proteins. No feline oncornavirus-associated cell membrane antigen reactivity was detected on the surfaces of the transformed murine cells by indirect membrane immunofluorescence techniques. The 85,000-dalton feline sarcoma virus-specific protein was also found in feline cells transformed by transfection. However, these cells also contained env gene products. The results of this study demonstrate that the feline sarcoma virus genome is sufficient to transform murine cells and that expression of the 85,000-dalton gag-x protein is associated with transformation of both murine and feline cells transformed by transfection.     

The transforming proteins of PRCII virus and Rous sarcoma virus form a complex with the same two cellular phosphoproteins

P105 and P110, the presumptive transforming proteins of PRCII avian sarcoma virus, have been found to be present in transformed chicken cells in two forms: as monomers and as part of a complex which contains both a 50,000-dalton and a 90,000-dalton cellular phosphoprotein. The 90,000-dalton cellular protein was found to be identical to one of the proteins in chicken cells whose synthesis is induced by stress. The 50,000-dalton protein was found to contain phosphotyrosine when isolated from the complex and therefore may be a substrate for the tyrosine protein kinase activity which is associated with P105 and P110. These same two cellular phosphoproteins have previously been shown to be present in a complex with pp60src, the tyrosine protein kinase which is the transforming protein of Rous sarcoma virus. However, not all avian sarcoma virus transforming proteins with associated tyrosine protein kinase activities form a complex efficiently with these cellular proteins. Little if any of P90, the putative transforming protein of Yamaguchi 73 virus, was found in a complex with the 50,000-dalton and 90,000-dalton cellular phosphoproteins.     

Rous sarcoma virus-transformed fibroblasts adhere primarily at discrete protrusions of the ventral membrane called podosomes

Rous sarcoma virus-transformed BHK cells (RSV/B4-BHK) adhere to a fibronectin-coated substratum primarily at specific dot-shaped sites. Such sites contain actin and vinculin and represent close contacts with the substratum as revealed by interference reflection microscopy. Only a few adhesion plaques and actin filament bundles can be detected in these cells as compared to untransformed parental fibroblasts. In thin sections examined with transmission electron microscopy (TEM) these adhesion sites correspond to short protrusions of the ventral cell surface that contact the substratum at their apical portion. These structures, which may represent cellular feet, are therefore called podosomes. By screening a number of different transformed fibroblasts plated on a fibronectin-coated substratum we find that podosomes are common to mammalian and avian cell lines transformed either by Rous sarcoma virus (RSV) or by Fujinami avian sarcoma virus (FSV), whose oncogenes encode specific tyrosine kinases. Using antibodies reacting with phosphotyrosine in immunofluorescence experiments, we show that phosphotyrosine-containing molecules are concentrated in podosomes. Podosomes are not detected in fibroblasts transformed by other retroviruses (Snyder-Theilen sarcoma virus, Abelson leukemia virus and Kirsten sarcoma virus) or by DNA tumor viruses (polyoma, SV40), indicating that podosome-mediated adhesion in transformed fibroblasts is related to the peculiar properties of some oncoproteins and possibly to their tropism for adhesion systems. Podosomes and adhesion plaques, although similar in cytoskeletal protein composition, have different mechanisms and kinetics of formation. Assembly of podosomes, in fact (i) does not require fetal calf serum (FCS) in the adhesion medium, that is necessary for the organization of adhesion plaques; (ii) does not require protein synthesis; and (iii) is insensitive to the ionophore monensin, that prevents adhesion plaque formation. Moreover, during attachment to fibronectin-coated dishes, podosomes appear in the initial phase (60 min) of attachment, while adhesion plaques require a minimum of 180 min. In conclusion podosomes of RSV- and FSV-transformed fibroblasts represent a phenotypic variant of adhesion structures.     

Transformed mammalian cells secrete specific proteins and phosphoproteins.

We have examined the proteins secreted into the growth medium by normal and transformed cells. Transformed cell lines from several mammalian species all secrete proteins in the 58,000 dalton molecular weight range. These proteins are all immunologically related and are secreted at low levels or not at all by the parental normal cell lines. Secretion of the 58K proteins occurs with either DNA or RNA virus transformation and with spontaneous transformation. The transformed cells also secrete phosphoproteins in the same size range, but these are immunologically distinct from the 58K proteins mentioned above. The sizes of the phosphoproteins are species-specific and unrelated to the transforming virus. Incubation of conditioned media from transformed cell cultures with gamma-32P-ATP labels phosphoproteins of the same sizes, indicating the presence in the media of both protein kinase and substrate. All three properties (58K protein, phosphoprotein, in vitro phosphorylation) are closely correlated with transformation in cells transformed by temperature-sensitive viruses. The biological implications of these results remain unknown, but the results may be relevant to recent data on the (phospho)proteins and protein kinase encoded by RNA tumor viruses and the molecular basis of the transformed phenotype.     

Immunological characterization of proteins detected by phosphotyrosine antibodies in cells transformed by Rous sarcoma virus.

Phosphotyrosine antibodies were used to identify tyrosine-phosphorylated proteins in Rous sarcoma virus (RSV)-transformed chicken embryo fibroblasts. A large number of tyrosine phosphoproteins were detected. A similar set of proteins was observed in RSV-transformed murine cells. An 85,000-dalton protein, however, was present in transformed avian cells but missing in transformed murine cells. Neither the 85,000-dalton protein nor any of the other tyrosine phosphoproteins appeared to be viral structural proteins. Use of RSV mutants encoding partially deleted src gene products enabled us to identify a 60,000-dalton cellular tyrosine phosphoprotein that comigrated with wild-type pp60v-src. With the exception of calpactin I, the major tyrosine phosphoproteins detected in immunoblots appeared to be different from several previously characterized substrates of pp60v-src with similar molecular masses (ezrin, vinculin, and the fibronectin receptor).     

Production of Virus by Mammalian Cells Transformed by Rous Sarcoma and Murine Sarcoma Viruses

Cultured cells of mammalian tumors induced by ribonucleic acid (RNA)-containing oncogenic viruses were examined for production of virus. The cell lines were established from tumors induced in rats and hamsters with either Rous sarcoma virus (Schmidt-Ruppin or Bryan strains) or murine sarcoma virus (Moloney strain). When culture fluids from each of the cell lines were examined for transforming activity or production of progeny virus, none of the cell lines was found to be infectious. However, electron microscopic examination of the various cell lines revealed the presence of particles in the rat cells transformed by either Rous sarcoma virus or murine sarcoma virus. These particles, morphologically similar to those associated with murine leukemias, were found both in the extracellular fluid concentrates and in whole-cell preparations. In the latter, they were seen budding from the cell membranes or lying in the intercellular spaces. No viruslike particles were seen in preparations from hamster tumors. Exposure of the rat cells to (3)H-uridine resulted in the appearance of labeled particles with densities in sucrose gradients typical of virus (1.16 g/ml.). RNA of high molecular weight was extracted from these particles, and double-labeling experiments showed that this RNA sedimented at the same rate as RNA extracted from Rous sarcoma virus. None of the hamster cell lines gave radioactive peaks in the virus density range, and no extractable high molecular weight RNA was found. These studies suggest that the murine sarcoma virus produces an infection analogous to certain "defective" strains of Rous sarcoma virus, in that particles produced by infected cells have a low efficiency of infection. The control of the host cell over the production and properties of the RNA-containing tumorigenic viruses is discussed.     

Activation of the Murine Sarcoma Virus Genome After Infection with the Murine Leukemia Virus as Determined by Cell Agglutination

Non-virus-producing NIH/3T3 cells transformed by the murine sarcoma virus are agglutinated by conconavalin A to the same low level as normal NIH/3T3 cells. Infection with the murine leukemia virus greatly increases the agglutination of transformed cells but not that of normal cells. These data suggest that the morphological expression of cell transformation and the surface alterations associated with increased cell agglutination are controlled by the expressions of different sarcoma virus genes.     

Selection of Revertants of Kirsten Sarcoma Virus Transformed Nonproducer BALB/3T3 Cells

Revertants of Kirsten sarcoma virus transformed nonproducer BALB/3T3 cells (KA31 cells) were isolated after exposing the transformed cells to 5-fluorodeoxyuridine at high cell density, or when suspended in methylcellulose. Revertants were also isolated by treating KA31 cells with the lectin, concanavalin A, which is manyfold more toxic to transformed cells than for normal cells. The revertants resemble BALB/3T3 cells in their morphology and growth characteristics in that they have a low saturation density, fail to grow in 1% calf serum or when suspended in methylcellulose, and cease to synthesize DNA after reaching their saturation density. Infection by murine leukemia virus rescues Kirsten sarcoma virus from only the concanavalin-A-selected variants, though all the revertants are susceptible to infection by leukemia virus. The concanavalin A revertants also become transformed after infection with murine leukemia virus. All the revertants can be transformed by Kirsten sarcoma virus but not by simian virus 40.     

Conservation of function of Drosophila melanogaster abl and murine v-abl proteins in transformation of mammalian cells.

The Drosophila melanogaster abl and the murine v-abl genes encode tyrosine protein kinases (TPKs) whose amino acid sequences are highly conserved. To assess functional conservation between the two gene products, we constructed Drosophila abl/v-abl-chimeric Abelson murine leukemia viruses. In these chimeric Abelson murine leukemia viruses, the TPK and carboxy-terminal regions of v-abl were replaced with the corresponding regions of D. melanogaster abl. The chimeric Abelson murine leukemia viruses were able to mediate morphological and oncogenic transformation of NIH 3T3 cells and were able to abrogate the interleukin-3 dependence of a lymphoid cell line. We also found that a virus that contained both TPK and carboxy-terminal Drosophila abl regions had no in vitro transforming activity for primary bone marrow cells and lacked the ability to induce tumors in susceptible mice. A virus that replaced only a portion of the v-abl TPK region with that of Drosophila abl had low activity in in vitro bone marrow transformation and tumorigenesis assays. These results indicate that the transforming functions of abl TPKs are only partially conserved through evolution. These results also imply that the TPK region of v-abl is a major determinant of its efficient lymphoid cell-transforming activity.