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.     

Membrane association of the transforming protein of avian sarcoma virus UR2 and mutants temperature sensitive for cellular transformation and protein kinase activity.

The localization of the transforming protein P68gag-ros of avian sarcoma virus UR2, which has a hydrophobic region at the N terminus of its ros-specific tyrosine kinase-encoding sequence, was examined by subcellular fractionation. P68 behaved as an integral membrane protein associated with the plasma membrane of transformed cells. P68 became membrane associated very rapidly in its biogenesis. Three temperature-sensitive mutants of UR2 were isolated and characterized. Cells infected with the mutants were temperature sensitive for morphological alteration and colony formation. The mutant P68 proteins were membrane associated in mutant-infected cells regardless of the temperature but were active as protein kinases only at the permissive temperature. The results suggest that P68 is a membrane-associated protein whose kinase activity plays a crucial role in UR2-mediated cell transformation.     

Transforming properties and substrate specificities of the protein tyrosine kinase oncogenes ros and src and their recombinants.

To determine the sequences of the oncogenes src (encoded by Rous sarcoma virus [RSV]) and ros (encoded by UR2) that are responsible for causing different transformation phenotypes and to correlate those sequences with differences in substrate recognition, we constructed recombinants of the two transforming protein tyrosine kinases (PTKs) and studied their biological and biochemical properties. A recombinant with a 5' end from src and a 3' end from ros, called SRC x ROS, transformed chicken embryo fibroblasts (CEF) to a spindle shape morphology, mimicking that of UR2. Neither of the two reverse constructs, ROS x SRC I and ROS x SRC II, could transform CEF. However, a transforming variant of ROS x SRC II appeared during passages of the transfected cells and was called ROS x SRC (R). ROS x SRC (R) contains a 16-amino-acid deletion that includes the 3' half of the transmembrane domain of ros. Unlike RSV, ROS x SRC (R) also transformed CEF to an elongated shape similar to that of UR2. We conclude that distinct phenotypic changes of RSV- and UR2-infected cells do not depend solely on the kinase domains of their oncogenes. We next examined cellular proteins phosphorylated by the tyrosine kinases of UR2, RSV, and their recombinants as well as a number of other avian sarcoma viruses including Fujinami sarcoma virus Y73, and some ros-derived variants. Our results indicate that the UR2-encoded receptorlike PTK P68gag-ros and its derivatives have a very restricted substrate specificity in comparison with the nonreceptor PTKs encoded by the rest of the avian sarcoma viruses. Data from ros and src recombinants indicate that sequences both inside and outside the catalytic domains of ros and src exert a significant effect on the substrate specificity of the two recombinant proteins. Phosphorylation of most of the proteins in the 100- to 200-kDa range correlated with the presence of the 5' src domain, including the SH2 region, but not with the kinase domain in the recombinants. This corroborates the conclusion given above that the kinase domain of src or ros per se is not sufficient to dictate the transforming morphology of these two oncogenes. High-level tyrosyl phosphorylation of most of the prominent substrates of src is not sufficient to cause a round-shape transformation morphology.     

Role of gag sequence in the biochemical properties and transforming activity of the avian sarcoma virus UR2-encoded gag-ros fusion protein.

The transforming protein P68gag-ros of avian sarcoma virus UR2 is a transmembrane tyrosine protein kinase molecule with the gag portion protruding extracellularly. To investigate the role of the gag moiety in the biochemical properties and biological functions of the P68gag-ros fusion protein, retroviruses containing the ros coding sequence of UR2 were constructed and analyzed. The gag-free ros protein was expressed from one of the mutant retroviruses at a level 10 to 50% of that of the wild-type UR2. However, the gag-free ros-containing viruses were not able to either transform chicken embryo fibroblasts or induce tumors in chickens. The specific tyrosine protein kinase activity of gag-free ros protein is about 10- to 20-fold reduced as judged by in vitro autophosphorylation. The gag-free ros protein is still capable of associating with membrane fractions including the plasma membrane, indicating that sequences essential for recognition and binding membranes must be located within ros. Upon passages of the gag-free mutants, transforming and tumorigenic variants occasionally emerged. The variants were found to have regained the gag sequence fused to the 5' end of the ros, apparently via recombination with the helper virus or through intramolecular recombination between ros and upstream gag sequences in the same virus construct. All three variants analyzed code for gag-ros fusion protein larger than 68 kDa. The gag-ros recombination junction of one of the transforming variants was sequenced and found to consist of a p19-p10-p27-ros fusion sequence. We conclude that the gag sequence is essential for the transforming activity of P68gag-ros but is not important for its membrane association.     

Cloning and characterization of an envelope-specific probe from xenotropic murine leukemia proviral DNA.

UR2 is a newly characterized avian sarcoma virus whose genome contains a unique sequence that is not related to the sequences of other avian sarcoma virus transforming genes thus far identified. This unique sequence, termed ros, is fused to part of the viral gag gene. The product of the fused gag-ros gene of UR2 is a protein of 68,000 daltons (P68) immunoprecipitable by antiserum against viral gag proteins. In vitro translation of viral RNA and in vivo pulse-chase experiments showed that P68 is not synthesized as a large precursor and that it is the only protein product encoded in the UR2 genome, suggesting that it is involved in cell transformation by UR2. In vivo, P68 was phosphorylated at both serine and tyrosine residues. Immunoprecipitates of P68 with anti-gag antisera had a cyclic nucleotide-independent protein kinase activity that phosphorylated P68, rabbit immunoglobulin G in the immune complex, and alpha-casein. The phosphorylation by P68 was specific to tyrosine of the substrate proteins. P68 was phosphorylated in vitro at only one tyrosine site, and the tryptic phosphopeptide of in vitro-labeled P68 was different from those of Fujinami sarcoma virus P140 and avian sarcoma virus Y73-P90. A comparison of the protein kinases encoded by UR2, Rous sarcoma virus, Fujinami sarcoma virus, and avian sarcoma virus Y73 revealed that UR2-P68 protein kinase is distinct from the protein kinases encoded by those viruses by several criteria. Our results suggest that several different protein kinases encoded by viral transforming genes have the same functional specificity and cause essentially the same cellular alterations.     

Phosphatidylinositol kinase activity in virus-transformed and nontransformed cells.

We assayed phosphatidylinositol (PI) kinase (EC 2.7.1.67) activity in detergent extracts of nontransformed or virus-transformed cells. Nontransformed chicken embryo fibroblasts (CEF) contain PI kinase activity with an apparent specific activity of 20 pmol/min per mg of protein. This activity sedimented as a single peak with a molecular weight of approximately 60,000 in a glycerol gradient, although immunoprecipitation with anti-p60src sera showed that the PI kinase activity is distinct from p60c-src. Extracts from CEF transformed by Rous sarcoma virus, Fujinami sarcoma virus, or avian sarcoma virus UR2 showed no elevation of PI kinase activity over nontransformed CEF. Removal of the oncogene products from extracts by immunoprecipitation did not change the level of PI kinase activity in extracts, suggesting that putative virus-coded PI kinases do not make a significant contribution to overall levels of PI kinase activity in transformed cells. Additionally, P140gag-fps was separated from cellular PI kinase by phosphocellulose chromatography. This partially purified fraction contained low PI kinase activity distinct from P140gag-fps, indicating that P140gag-fps has no detectable PI kinase activity.     

Protein kinase activity of FSV (Fujinami sarcoma virus) P130gag-fps shows a strict specificity for tyrosine residues

A number of oncogenic viruses encode transforming proteins with protein kinase activities apparently specific for tyrosine residues. Recent evidence has raised questions as to the substrate specificity of these kinases in general and the physiological relevance of tyrosine phosphorylation in particular. The P130gag-fps transforming protein of Fujinami sarcoma virus (FSV) is strongly phosphorylated at 2 tyrosine residues in FSV-transformed cells of which 1 (Tyr-1073) is also the major site of P130gag-fps intermolecular autophosphorylation in vitro. We have investigated the specificity of the protein kinase activity intrinsic to FSV P130gag-fps by using site-directed mutagenesis to change the codon for Tyr-1073 to those for the other commonly phosphorylated hydroxyamino acids, serine and threonine. This approach has some advantages over the use of synthetic peptides to define protein kinase recognition sites in that the protein containing the altered target site can be expressed in intact cells. In addition it allows higher order as well as primary structure of the enzyme recognition site to be considered. Neither serine nor threonine were phosphorylated when substituted for tyrosine at position 1073 of P130gag-fps indicating a stringent specificity for tyrosine as a substrate of the P130gag-fps protein kinase autophosphorylating activity. Consistent with the suggestion that tyrosine phosphorylation is of functional significance we find that these and other FSV Tyr-1073 mutants have depressed enzymatic and oncogenic capacities.     

A lysine in the ATP-binding site of P130gag-fps is essential for protein-tyrosine kinase activity.

The P130gag-fps transforming protein of Fujinami sarcoma virus (FSV) possesses tyrosine-specific protein kinase activity and autophosphorylates at Tyr-1073. Within the kinase domain of P130gag-fps is a putative ATP-binding site containing a lysine (Lys-950) homologous to lysine residues in cAMP-dependent protein kinase and p60v-src which bind the ATP analogue p-fluorosulfonylbenzoyl-5' adenosine. FSV mutants in which the codon for Lys-950 has been changed to codons for arginine or glycine encode metabolically stable but enzymatically defective proteins which are unable to effect neoplastic transformation. Kinase-defective P130gag-fps containing arginine at residue 950 was normally phosphorylated at serine residues in vivo suggesting that this amino acid substitution has a minimal effect on protein folding and processing. The inability of arginine to substitute for lysine at residue 950 suggests that the side chain of Lys-950 is essential for P130gag-fps catalytic activity, probably by virtue of a specific interaction with ATP at the phosphotransfer active site. Tyr-1073 of the Arg-950 P130gag-fps mutant protein was not significantly autophosphorylated either in vitro or in vivo, but could be phosphorylated in trans by enzymatically active P140gag-fps. These data indicate that Tyr-1073 can be modified by intermolecular autophosphorylation.     

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.     

A noncatalytic domain conserved among cytoplasmic protein-tyrosine kinases modifies the kinase function and transforming activity of Fujinami sarcoma virus P130gag-fps.

Proteins encoded by oncogenes such as v-fps/fes, v-src, v-yes, v-abl, and v-fgr are cytoplasmic protein tyrosine kinases which, unlike transmembrane receptors, are localized to the inside of the cell. These proteins possess two contiguous regions of sequence identity: a C-terminal catalytic domain of 260 residues with homology to other tyrosine-specific and serine-threonine-specific protein kinases, and a unique domain of approximately 100 residues which is located N terminal to the kinase region and is absent from kinases that span the plasma membrane. In-frame linker insertion mutations in Fujinami avian sarcoma virus which introduced dipeptide insertions into the most stringently conserved segment of this N-terminal domain in P130gag-fps impaired the ability of Fujinami avian sarcoma virus to transform rat-2 cells. The P130gag-fps proteins encoded by these transformation-defective mutants were deficient in protein-tyrosine kinase activity in rat cells. However v-fps polypeptides derived from the mutant Fujinami avian sarcoma virus genomes and expressed in Escherichia coli as trpE-v-fps fusion proteins displayed essentially wild-type enzymatic activity, even though they contained the mutated sites. Deletion of the N-terminal domain from wild-type and mutant v-fps bacterial proteins had little effect on autophosphorylating activity. The conserved N-terminal domain of P130gag-fps is therefore not required for catalytic activity, but can profoundly influence the adjacent kinase region. The presence of this noncatalytic domain in all known cytoplasmic tyrosine kinases of higher and lower eucaryotes argues for an important biological function. The relative inactivity of the mutant proteins in rat-2 cells compared with bacteria suggests that the noncatalytic domain may direct specific interactions of the enzymatic region with cellular components that regulate or mediate tyrosine kinase function.     

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.     

Genetic structure, transforming sequence, and gene product of avian sarcoma virus UR1

We analyzed the genetic structure and gene products of the newly isolated avian sarcoma virus UR1, which recently has been shown to be replication defective and to contain no sequences homologous to the src gene of Rous sarcoma virus. The sizes of the genomic RNAs of UR1 and its associated helper virus, UR1AV, were determined to be 29S and 35S (5.9 and 8.5 kilobases), respectively, by gel electrophoresis and sucrose gradient sedimentation. RNase T1 oligonucleotide mapping of purified viral RNAs indicated that UR1 RNA contains eight unique oligonucleotides in the middle of the genome and shares four 5'-terminal and three 3'-terminal oligonucleotides with UR1AV RNA. The unique sequences of UR1 and Fujinami sarcoma virus were found to be closely related to each other by molecular hybridization of UR1 RNA with DNA complementary to the unique sequence of Fujinami sarcoma virus RNA, but minor differences were found by oligonucleotides fingerprinting. In the regions flanking the unique sequences, UR1 and Fujinami sarcoma viral RNAs contain distinct oligonucleotides, which are shared with oligonucleotides of the respective helper viral RNAs. Cell transformed with UR1 produce a single 29S RNA species which contains a UR1 unique sequence; this species is most likely the mRNA coding for the transforming protein. In UR1-transformed cells, a phosphoprotein fo 150,000 daltons (p150) was detected by immunoprecipitation with antiserum against gag proteins. p150 was associated with a protein kinase activity that was capable of phosphorylating p150 itself, immunoglobulin G of antiserum, and a soluble substrate, alpha-casein. This enzyme transferred phosphate exclusively to tyrosine residues of substrates in vitro, but p 150 labeled in vivo with 32P contained both phosphoserine and phosphotyrosine. The in vitro kinase reaction was not affected by the presence of cyclic AMP or cyclic GMP and strongly preferred Mn2+ over Mg2+. Thus, the properties of UR1 protein are almost identical to those of Fujinami sarcoma virus protein.     

Biochemical characterization of transformation-specific proteins of acute avian leukemia and sarcoma viruses

The biological and biochemical properties of the transformation-specific proteins of three avian oncornaviruses with different oncogenic potentials were compared, namely the gag-myc protein of the avian myelocytomatosis virus MC29, the gag-erb A protein of the avian erythroblastosis virus AEV, and the gag-fps protein of Fujinami sarcoma virus FSV. These oncogenes were analyzed in transformed fibroblasts that expressed only the transforming proteins but showed no virus replication. Monoclonal antibodies against the viral structural protein p19, which is the N-terminus of the proteins, were used for indirect immunofluorescence, for immunoprecipitation of the proteins from subcellular fractions, and for immunoaffinity column chromatography. With this last method a 3000-fold purification of the proteins was obtained. By indirect immunofluorescence it was shown that the gag-myc protein was located in the nucleus, and bound to DNA after purification. The gag-erb A protein was not nuclear but probably located in the cytoplasm and did not bind to DNA after purification. Neither of the two proteins exhibited protein kinase activity. In contrast, the gag-fps protein did not bind to DNA but showed protein kinase activity after purification. It was not located in the nucleus either.     

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.     

A major site of tyrosine phosphorylation within the SH2 domain of Fujinami sarcoma virus P130gag-fps is not required for protein-tyrosine kinase activity or transforming potential.

Phosphorylation of the major autophosphorylation site (Tyr-1073) within Fujinami sarcoma virus P130gag-fps activates both the intrinsic protein-tyrosine kinase activity and transforming potential of the protein. In this report, a second site of autophosphorylation Tyr-836 was identified. This tyrosine residue is found within a noncatalytic domain (SH2) of P130gag-fps that is required for full protein-kinase activity in both rat and chicken cells. Autophosphorylation of this tyrosine residue implies that the SH2 region lies near the active site in the catalytic domain in the native protein and thus possibly regulates its enzymatic activity. Four mutations have occurred within the SH2 domain between the c-fps and v-fps proteins. Tyr-836 is one of these changes, being a Cys in c-fps. Site-directed mutagenesis was used to investigate the function of this autophosphorylation site. Substitution of Tyr-836 with a Phe had no apparent effect on the transforming ability or protein-tyrosine kinase activity of P130gag-fps in rat-2 cells. Mutagenesis of both autophosphorylation sites (Tyr-1073 and Tyr-836) did not reveal any cooperation between these two phosphorylation sites. The implications of the changes within the SH2 region for v-fps function and activation of the c-fps oncogenic potential are discussed.     

Matrix-independent activation of phosphatidylinositol 3-kinase,Stat3, and cyclin A-associated Cdk2 Is essential for anchorage-independent growth of v-Ros-transformed chicken embryo fibroblasts

The question remains open whether the signaling pathways shown to be important for growth and transformation in adherent cultures proceed similarly and play similar roles for cells grown under anchorage-independent conditions. Chicken embryo fibroblasts (CEF) infected with the avian sarcoma virus UR2, encoding the oncogenic receptor protein-tyrosine kinase (RPTK) v-Ros, or with two of its transformation-impaired mutants were grown in nonadherent conditions in methylcellulose (MC)-containing medium, and the signaling functions essential for Ros-induced anchorage-independent growth were analyzed. We found that the overall tyrosine phosphorylation of cellular proteins in CEF transformed by v-Ros or by two oncogenic nonreceptor protein-tyrosine kinases (PTKs), v-Src and v-Yes, was dramatically reduced in nonadherent conditions compared with that in adherent conditions, indicating that cell adhesion to the extracellular matrix plays an important role in efficient substrate phosphorylation by these constitutively activated PTKs. The UR2 transformation-defective mutants were differentially impaired compared with UR2 in the activation of phosphatidylinositol 3-kinase (PI 3-kinase) and Stat3 in nonadherent conditions. Consistently, the constitutively activated mutants of PI 3-kinase and Stat3 rescued the ability of the UR2 mutants to promote anchorage-independent growth. Conversely, dominant negative mutants of PI 3-kinase and Stat3 inhibited UR2-induced anchorage-independent growth. UR2-infected CEF grown in nonadherent conditions displayed faster cell cycle progression than the control or the UR2 mutant-infected cells, and this appeared to correlate with a PI 3-kinase-dependent increase in cyclin A-associated Cdk2 activity. Treatment of UR2-infected cells with Cdk2 inhibitors led to the loss of the anchorage-independent growth-promoting activity of UR2. In conclusion, we have adopted an experimental system enabling us to study the signaling pathways in cells grown under anchorage-independent conditions and have identified matrix-independent activation of PI 3-kinase and Stat3 signaling functions, as well as the PI 3-kinase-dependent increase of cyclin A-associated Cdk2 kinase activity, to be critical for the Ros-PTK-induced anchorage-independent growth.     

Transformation-defective Rous sarcoma virus mutants with altered p19 of the gag gene and their inhibitory effect on host cell growth.

Mutants (PH2010, PH2011, PH2012) of Rous sarcoma virus which have a growth-inhibitory effect on chicken embryo fibroblasts were isolated from a temperature-sensitive mutant of the Schmidt-Ruppin strain of Rous sarcoma virus (tsNY68). The growth rate of fibroblasts infected with these viruses was about 50 to 60% of that of uninfected fibroblasts. A morphological difference between mutant-infected and uninfected fibroblasts was observed at logarithmic phase but not at stationary phase. Neither the protein p60src nor its associated protein kinase activity was significantly detected by an immunoprecipitation assay in the cells infected with these mutants. Analysis of the unintegrated DNA of the mutant PH2010 showed that a sequence of about 1.4 kilobase pairs at the src gene region is deleted. Further examination of the viral structural proteins in infected cells as well as in virions by immunoprecipitation and peptide mapping revealed that the molecular size of the Pr76 gag protein of the mutant RSV is smaller than that of the mutant tsNY68 because of partial deletion at the p19 gag gene. The peptide maps suggest that the deleted region of the altered p19 of the mutant is near the carboxy terminal of p19. The amount of Prgp92env synthesized in the mutant-infected cells was about fivefold more than that in tsNY68-infected cells.     

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.     

Purified polyoma virus medium T antigen has tyrosine-specific protein kinase activity but no significant phosphatidylinositol kinase activity.

Medium T antigen, the transforming protein of polyoma virus, is associated with pp60c-src and strongly activates its tyrosine-specific protein kinase activity. We investigated whether the medium T-pp60c-src complex is also associated with an activity that phosphorylates the membrane phospholipid phosphatidylinositol, as shown for pp60v-src and p68v-ros, the transforming proteins of Rous sarcoma virus and avian sarcoma virus UR2, respectively. Medium T was purified by affinity chromatography from extracts of polyoma virus-infected mouse fibroblasts. It was bound to antibodies against a peptide corresponding to the carboxy terminus of medium T and released from the immune complex with an excess of the same peptide. In a second step, the partially purified medium T was bound to antibodies against another peptide corresponding to an internal region of medium T and released with excess peptide. Further purification was carried out with a monoclonal antibody against pp60c-src. Samples from each purification step were examined for protein kinase and phosphatidylinositol kinase activity. The highly purified preparations of the medium T-pp60c-src complex showed very low levels of phosphatidylinositol kinase activity, and no difference between medium T from transforming viruses and nontransforming hr-t mutants was detected. In contrast, protein kinase activity was associated with medium T purified from transforming viruses but not from hr-t mutants.     

Enhancement of tyrosyl phosphorylation and protein expression of eps8 by v-Src.

Two eps8 isoforms, p97eps8 and p68eps8, were previously identified as substrates for receptor tyrosine kinases. Analysis of eps8 phosphotyrosine content in v-Src transformed cells (IV5) revealed that both isoforms were highly tyrosyl phosphorylated and their readiness to be phosphorylated by Src in vitro further indicated that they were putative Src substrates as well. Indeed, the enhancement of tyrosyl phosphorylation of p97eps8 detected in cells coexpressing both p97eps8 and active Src relative to that in cells expressing p97eps8 alone supported our hypothesis. The existence of common phosphotryptic peptides between in vitro 32P-labeled p97eps8 and p68eps8 indicated that these two proteins shared the same Src-mediated sites. Further in vitro binding assays demonstrated that p68eps8 was the major eps8 isoforms that could be precipitated by bacterial fusion protein containing Src SH3. Interestingly, both p68eps8 and p97eps8 were preferentially expressed in v-Src transformed cells and the presence of p68eps8 appeared to depend on Src. Since p97eps8 has been implicated in mitogenesis and tumorigenesis, its readiness to be phosphorylated and induced by v-Src might attribute to v-Src-mediated transformation.