Cellular information in the genome of recovered avian sarcoma virus directs the synthesis of transforming protein

Dichloroacetate stimulates changes in the mitochondrial network morphology via partial mitophagy in human SH-SY5Y neuroblastoma cells

Dichloroacetate (DCA) is beneficial in cancer therapy because it induces apoptosis and decreases cancer growth in vitro and in vivo without affecting non-cancer cells. DCA stimulates the activity of the enzyme pyruvate dehydrogenase by inhibiting pyruvate dehydrogenase kinase. Consequently, DCA promotes oxidative phosphorylation after glycolysis. Therefore, DCA produces changes in energy metabolism that could affect the mitochondrial network and mitophagy. This investigation determined the effects of DCA treatment on mitophagy in human neuroblastoma SH-SY5Y cells. SH-SY5Y cells were cultured and distributed into 3 groups: control, NH4Cl and chloroquine. Each group was treated with DCA at 0, 5, 30 and 60 mM for 16 h. Samples were analyzed for cell viability, mtDNA copy number, mitochondrial network morphology and expression of key proteins involved in mitochondrial dynamics, such as LC3b, FIS1, OPA1, PARKIN and PINK1. In all groups, DCA caused a decrease in cell viability, an induction of autophagy in a dose-dependent manner and a decrease in Tim23, FIS1 and PARKIN protein expression, leading to profound morphological changes in the mitochondrial network resulting in shorter and more fragmented filaments. However, TFAM protein levels remained unchanged. Similarly, the mitochondrial copy number was not significantly different among the treatment groups. In conclusion, DCA induces mitophagy and remodeling of the mitochondrial network. In this remodeling, DCA induces a decrease in the expression of key proteins involved in protein degradation and mitochondrial dynamics but does not significantly affect the mtDNA density. Blocking late phase autophagy increases the effects of DCA, suggesting that autophagy protects the cell, at least partially, against DCA.

Using small molecules and chemical genetics to interrogate signaling networks

The limited clinical success of therapeutics targeting cellular signaling processes is due to multiple factors, including off-target effects and complex feedback regulation encoded within the signaling network. To understand these effects, chemical proteomics and chemical genetics tools have been developed to map the direct targets of kinase inhibitors, determine the network-level response to inhibitor treatment, and to infer network topology. Here we provide an overview of chemical phosphoproteomic and chemical genetic methods, including specific examples where these methods have been applied to yield biological insight regarding network structure and the system-wide effects of targeted therapeutics. The challenges and caveats associated with each method are described, along with approaches being used to resolve some of these issues. With the broad array of available techniques the next decade should see a rapid improvement in our understanding of signaling networks regulation and response to targeted perturbations, leading to more efficacious therapeutic strategies.

Epidermal growth factor induces internalization but not degradation of the epidermal growth factor receptor in a human breast cancer cell line

Metabolism of the epidermal growth factor (EGF) receptor was studied in the MDA-MB-231 human breast cancer cell line. As in normal fibroblasts the EGF receptor from MDA-MB-231 cells was synthesized from a Mr = 160,000 precursor and tunicamycin treatment of cells resulted in accumulation of a Mr = 130,000 polypeptide. Unlike normal fibroblasts in which a Mr = 170,000 mature form of the EGF receptor was found, MDA-MB-231 cells contained a Mr = 172,000 mature form. Addition of EGF to MDA-MB-231 cells led to rapid internalization of EGF receptors, however, internalization did not affect receptor half-life and receptors did not recycle to the cell surface. EGF receptors could be visualized by immunofluorescence and remained sequestered in intracellular membranous structures following internalization. EGF was degraded slowly by MDA-MB-231 cells relative to degradation of EGF by normal cells. A high endogenous level of in vivo phosphorylation of threonine 654 of the EGF receptor was found in MDA-MB-231 cells and treatment of cells with 12-O-tetradecanoyl-phorbol-13-acetate (TPA) further stimulated phosphorylation of this residue. EGF induced receptor internalization resulted in dephosphorylation of threonine 654. The significance of these unusual properties of EGF receptor metabolism in MDA-MB-231 cells is discussed.

Identification of a human gene (HCK) that encodes a protein-tyrosine kinase and is expressed in hemopoietic cells

We have isolated cDNAs representing a previously unrecognized human gene that apparently encodes a protein-tyrosine kinase. We have designated the gene as HCK (hemopoietic cell kinase) because its expression is prominent in the lymphoid and myeloid lineages of hemopoiesis. Expression in granulocytic and monocytic leukemia cells increases after the cells have been induced to differentiate. The 57-kilodalton protein encoded by HCK resembles the product of the proto-oncogene c-src and is therefore likely to be a peripheral membrane protein. HCK is located on human chromosome 20 at bands q11-12, a region that is affected by interstitial deletions in some acute myeloid leukemias and myeloproliferative disorders. Our findings add to the diversity of protein-tyrosine kinases that may serve specialized functions in hemopoietic cells, and they raise the possibility that damage to HCK may contribute to the pathogenesis of some human leukemias.

Rous sarcoma virus mutant dlPA105 induces different transformed phenotypes in quail embryonic fibroblasts and neuroretina cells

dlPA105 is a spontaneous variant of Rous sarcoma virus, subgroup E, which carries a deletion in the N-terminal portion of the v-src gene coding sequence. This virus was isolated on the basis of its ability to induce proliferation of quiescent quail neuroretina cells. The altered v-src gene encodes a phosphoprotein of 45,000 daltons which possesses tyrosine kinase activity. DNA sequencing of the mutant v-src gene has shown that deletion extends from amino acid 33 to 126 of wild-type p60v-src. We investigated the tumorigenic and transforming properties of this mutant virus. dlPA105 induced fibrosarcomas in quails with an incidence identical to that induced by wild-type virus. Quail neuroretina cells infected with the mutant virus were morphologically transformed and formed colonies in soft agar. In contrast, dlPA105 induced only limited morphological alterations in quail fibroblasts and was defective in promoting anchorage-independent growth of these cells. Synthesis and tyrosine kinase activity of the mutant p45v-src were similar in both cell types. These data indicate that the portion of the v-src protein deleted in p45v-src is dispensable for the mitogenic and tumorigenic properties of wild-type p60v-src, whereas it is required for in vitro transformation of fibroblasts. The ability of dlPA105 to induce different transformation phenotypes in quail fibroblasts and quail neuroretina cells is a property unique to this Rous sarcoma virus mutant and provides evidence for the existence of cell-type-specific response to v-src proteins.

Identification of a human gene (HCK) that encodes a protein-tyrosine kinase and is expressed in hemopoietic cells

We have isolated cDNAs representing a previously unrecognized human gene that apparently encodes a protein-tyrosine kinase. We have designated the gene as HCK (hemopoietic cell kinase) because its expression is prominent in the lymphoid and myeloid lineages of hemopoiesis. Expression in granulocytic and monocytic leukemia cells increases after the cells have been induced to differentiate. The 57-kilodalton protein encoded by HCK resembles the product of the proto-oncogene c-src and is therefore likely to be a peripheral membrane protein. HCK is located on human chromosome 20 at bands q11-12, a region that is affected by interstitial deletions in some acute myeloid leukemias and myeloproliferative disorders. Our findings add to the diversity of protein-tyrosine kinases that may serve specialized functions in hemopoietic cells, and they raise the possibility that damage to HCK may contribute to the pathogenesis of some human leukemias.

Antipeptide antiserum identifies a widely distributed cellular tyrosine kinase related to but distinct from the c-fps/fes-encoded protein

We raised antibodies directed against a synthetic peptide representing an amino acid sequence of the conserved kinase domain of the transforming protein of Fujinami sarcoma virus (FSV) (P140). The antiserum obtained specifically recognized FSV-P140 and its cellular homolog and in addition, it recognized a new cellular protein of 94,000 daltons (NCP94) in avian and mammalian cells. NCP94 was found to be associated with a cyclic nucleotide-independent protein kinase activity that was specific for tyrosine residues. Although NCP94 and FSV-P140 share antigenic determinants, NCP94 is not a cellular homolog of FSV-P140: NCP94 and the previously identified c-fps/fes product were different in their tryptic fingerprints and in their tissue specificities. Thus, the function of NCP94 in normal cells is probably different than that of the c-fps/fes product. NCP94 was expressed in every tissue and cell line that was examined. In chickens, NCP94 levels were highest during embryonic development and NCP94 expression was high in gizzard, brain, and spleen throughout embryonic and adult life. The universal expression of NCP94 suggests that this protein may be involved in an essential function of normal cells. NCP94 may be a new cellular tyrosine kinase of the src gene family.

Retrovirus shuttle vector for study of kinase activities of pp60c-src synthesized in vitro and overproduced in vivo

We have constructed a recombinant murine retrovirus which efficiently transduces avian pp60c-src into murine cells and which is easily rescued from infected cells in plasmid form. To characterize the virus, several randomly selected NIH 3T3 lines were isolated after infection with recombinant retroviral stocks. All lines overproduced avian pp60c-src and appeared morphologically normal. Immunoprecipitates made from these lines with antisera specific for pp60c-src were tested for their kinase activities in vitro. We find that both autokinase and enolase kinase activities increase proportionately with the level of pp60c-src in the immunoprecipitates. To further test the authenticity of the pp60c-src encoded by the retroviral vector, these analyses were repeated in the presence of polyomavirus middle T antigen. Avian pp60c-src was activated as a protein kinase, indicating that the virally encoded pp60c-src interacts normally with middle T antigen. Interestingly, by increasing the intracellular levels of pp60c-src 15-fold over normal endogenous levels, we were unable to obtain a proportionate increase in the amount of middle-T-antigen-pp60c-src complex. Finally, using the shuttle features designed into the vector, we have isolated the first fully processed cDNA encoding functional avian pp60c-src X pp60c-src synthesized in vitro with this cDNA had intrinsic protein kinase activity and no detectable phosphatidylinositol kinase activity.

Five enzymes of the glycolytic pathway serve as substrates for purified epidermal-growth-factor-receptor kinase

Several enzymes of the glycolytic pathway are phosphorylated in vitro and in vivo by retroviral transforming protein kinases. These substrates include the enzymes phosphoglycerate mutase (PGM), enolase and lactate dehydrogenase (LDH). Here we show that purified EGF (epidermal growth factor)-receptor kinase phosphorylates the enzymes PGM and enolase and also the key regulatory enzymes of the glycolytic pathway, phosphofructokinase and glyceraldehyde-3-phosphate dehydrogenase (GAPDH), in an EGF-dependent manner. Stoichiometry of phosphate incorporation into GAPDH (calculated from native Mr) is the highest, reaching approximately 1. LDH and other enzymes of the glycolytic pathway are not phosphorylated by the purified EGF-receptor kinase. These enzymes are phosphorylated under native conditions, and the Km values of EGF-receptor kinase for their phosphorylation are close to the physiological concentrations of these enzymes in the cell. EGF stimulates the reaction by 2-5-fold by increasing the Vmax. without affecting the Km of this process. Phosphorylation is rapid at 22 degrees C and at higher temperatures. However, unlike the self-phosphorylation of EGF-receptor, which occurs at 4 degrees C, the glycolytic enzymes are poorly phosphorylated at this temperature. Some enzymes, in particular enolase, increase the receptor Km for ATP in the autophosphorylation process and thus may act as competitive inhibitors of EGF-receptor self-phosphorylation. On the basis of the Km values of EGF receptor for the substrate enzymes and for ATP in the phosphorylation reaction, these enzymes may also be substrates in vivo for the EGF-receptor kinase.

N-terminal deletions in Rous sarcoma virus p60src: effects on tyrosine kinase and biological activities and on recombination in tissue culture with the cellular src gene

We have constructed deletions within the region of cloned Rous sarcoma virus DNA coding for the N-terminal 30 kilodaltons of p60src. Infectious virus was recovered after transfection. Deletions of amino acids 15 to 149, 15 to 169, or 149 to 169 attenuated but did not abolish transforming activity, as assayed by focus formation and anchorage-independent growth. These deletions also had only slight effects on the tyrosine kinase activity of the mutant src protein. Deletion of amino acids 169 to 264 or 15 to 264 completely abolished transforming activity, and src kinase activity was reduced at least 10-fold. However, these mutant viruses generated low levels of transforming virus by recombination with the cellular src gene. The results suggest that as well as previously identified functional domains for p60src myristylation and membrane binding (amino acids 1 to 14) and tyrosine kinase activity (amino acids 250 to 526), additional N-terminal sequences (particularly amino acids 82 to 169) can influence the transforming activity of the src protein.

Activation of the transforming potential of p60c-src by a single amino acid change

Previous work showed that overexpression of the cellular src (c-src) gene does not cause transformation of chicken cells in culture. However, viral stocks isolated from cells transfected with Rous sarcoma virus DNA containing the c-src gene in place of the viral src gene did occasionally produce foci. Virus obtained from these foci were highly transforming and appeared to arise via spontaneous mutation in the c-src-containing viral populations. The p60 proteins of the transforming mutant src viruses were found to have higher levels of in vitro tyrosine kinase activity than the levels observed with the parental viruses. In this study, we have molecularly cloned the src DNA sequences of two transforming mutant src viruses. When compared to the DNA sequence of the parental c-src viruses, the mutant viruses contain single point mutations that result in single amino acid changes in the src gene products (p60 proteins). Both amino acid changes reside in the tyrosine kinase domain of the protein. The mutation detected in one virus involves replacement of the normal Glu-378 in p60c-src by Gly, whereas the p60 of the other transforming virus has Phe instead of the normal Ile-441. Our data indicate that when p60c-src is expressed at elevated levels in a retroviral context, a single amino acid change in its primary sequence can activate the kinase activity of this protein and cause cellular transformation.

Retrovirus shuttle vector for study of kinase activities of pp60c-src synthesized in vitro and overproduced in vivo

We have constructed a recombinant murine retrovirus which efficiently transduces avian pp60c-src into murine cells and which is easily rescued from infected cells in plasmid form. To characterize the virus, several randomly selected NIH 3T3 lines were isolated after infection with recombinant retroviral stocks. All lines overproduced avian pp60c-src and appeared morphologically normal. Immunoprecipitates made from these lines with antisera specific for pp60c-src were tested for their kinase activities in vitro. We find that both autokinase and enolase kinase activities increase proportionately with the level of pp60c-src in the immunoprecipitates. To further test the authenticity of the pp60c-src encoded by the retroviral vector, these analyses were repeated in the presence of polyomavirus middle T antigen. Avian pp60c-src was activated as a protein kinase, indicating that the virally encoded pp60c-src interacts normally with middle T antigen. Interestingly, by increasing the intracellular levels of pp60c-src 15-fold over normal endogenous levels, we were unable to obtain a proportionate increase in the amount of middle-T-antigen-pp60c-src complex. Finally, using the shuttle features designed into the vector, we have isolated the first fully processed cDNA encoding functional avian pp60c-src X pp60c-src synthesized in vitro with this cDNA had intrinsic protein kinase activity and no detectable phosphatidylinositol kinase activity.

Antipeptide antiserum identifies a widely distributed cellular tyrosine kinase related to but distinct from the c-fps/fes-encoded protein

We raised antibodies directed against a synthetic peptide representing an amino acid sequence of the conserved kinase domain of the transforming protein of Fujinami sarcoma virus (FSV) (P140). The antiserum obtained specifically recognized FSV-P140 and its cellular homolog and in addition, it recognized a new cellular protein of 94,000 daltons (NCP94) in avian and mammalian cells. NCP94 was found to be associated with a cyclic nucleotide-independent protein kinase activity that was specific for tyrosine residues. Although NCP94 and FSV-P140 share antigenic determinants, NCP94 is not a cellular homolog of FSV-P140: NCP94 and the previously identified c-fps/fes product were different in their tryptic fingerprints and in their tissue specificities. Thus, the function of NCP94 in normal cells is probably different than that of the c-fps/fes product. NCP94 was expressed in every tissue and cell line that was examined. In chickens, NCP94 levels were highest during embryonic development and NCP94 expression was high in gizzard, brain, and spleen throughout embryonic and adult life. The universal expression of NCP94 suggests that this protein may be involved in an essential function of normal cells. NCP94 may be a new cellular tyrosine kinase of the src gene family.

N-terminal deletions in Rous sarcoma virus p60src: effects on tyrosine kinase and biological activities and on recombination in tissue culture with the cellular src gene

We have constructed deletions within the region of cloned Rous sarcoma virus DNA coding for the N-terminal 30 kilodaltons of p60src. Infectious virus was recovered after transfection. Deletions of amino acids 15 to 149, 15 to 169, or 149 to 169 attenuated but did not abolish transforming activity, as assayed by focus formation and anchorage-independent growth. These deletions also had only slight effects on the tyrosine kinase activity of the mutant src protein. Deletion of amino acids 169 to 264 or 15 to 264 completely abolished transforming activity, and src kinase activity was reduced at least 10-fold. However, these mutant viruses generated low levels of transforming virus by recombination with the cellular src gene. The results suggest that as well as previously identified functional domains for p60src myristylation and membrane binding (amino acids 1 to 14) and tyrosine kinase activity (amino acids 250 to 526), additional N-terminal sequences (particularly amino acids 82 to 169) can influence the transforming activity of the src protein.

Neoplastic transformation of normal and carcinogen-induced preneoplastic Syrian hamster embryo cells by the v-src oncogene

The ability of cloned Rous sarcoma virus (RSV) DNA encoding the v-src oncogene to neoplastically transform normal, diploid Syrian hamster embryo (SHE) cells was examined. Transfection of RSV DNA into early passage SHE cells resulted in a low but significant number of tumors when treated cells were injected into nude mice. Tumors formed with a low frequency (two tumors out of ten sites injected) and only after a long latency period (14 weeks). In contrast to the normal SHE cells, several different carcinogen-induced preneoplastic immortal SHE cell lines were highly susceptible to transformation by the v-src oncogene to the neoplastic phenotype. Tumors formed with high efficiency and a short latency period (less than 3 weeks). Further studies were performed to determine the basis for the inefficient transformation of the normal SHE cells. NeoR clones isolated after cotransfection of SHE cells with pSV2-neo and RSV DNAs were neither morphologically altered nor immortal and did not contain detectable levels of the v-src gene product. These results suggest that neoplastic transformation by v-src DNA in the normal cells is initially suppressed. However, cells from a v-src-induced tumor expressed v-src RNA, and antibody to v-src protein precipitated from the tumor cells a 60,000-molecular-weight protein which displayed protein kinase activity. Karyotypic analyses confirmed that the tumor was derived from Syrian hamster cells and suggested that it was clonal in nature. These results indicate that the v-src oncogene was primarily responsible for neoplastic transformation of SHE cells. In contrast to the results with the v-src oncogene, our previous studies showed that v-Ha-ras oncogene alone is unable to induce neoplastic transformation of SHE cells. Furthermore, the v-myc oncogene was able to compliment v-Ha-ras to neoplastically transform SHE cells, while cotransfection with v-src plus v-myc did not increase the incidence of tumors.

Low level of cellular protein phosphorylation by nontransforming overproduced p60c-src

We have previously found that Rous sarcoma virus variants in which the viral src (v-src) gene is replaced by the cellular src (c-src) gene have no transforming activity. In this study, we analyzed the basis for the inability of the p60c-src overproduced by these variants to transform cells. Phosphorylations of tyrosine residues in total cell protein or in cellular 34K protein are known to be markedly enhanced upon infection with wild-type Rous sarcoma virus. We found that these tyrosine phosphorylations were only slightly increased in the c-src-containing virus-infected cells, whereas both levels were significantly increased by infection with wild-type Rous sarcoma virus, or transforming mutant viruses which are derived from c-src-containing viruses by spontaneous mutation. Phosphorylation at tyrosine 416 of p60 itself was also extremely low in overproduced p60c-src and high in p60s of transforming mutant viruses. In immunoprecipitates with monoclonal antibody, the overproduced p60c-src had much lower casein tyrosine kinase activity than did p60v-src. We previously showed that p60 myristylation and plasma membrane localization may be required for cell transformation. p60c-src was similar to transforming p60s in these properties. These results strongly suggest that the low level of tyrosine phosphorylation by overproduced p60c-src accounts for its inability to transform cells.

Neoplastic transformation of normal and carcinogen-induced preneoplastic Syrian hamster embryo cells by the v-src oncogene

The ability of cloned Rous sarcoma virus (RSV) DNA encoding the v-src oncogene to neoplastically transform normal, diploid Syrian hamster embryo (SHE) cells was examined. Transfection of RSV DNA into early passage SHE cells resulted in a low but significant number of tumors when treated cells were injected into nude mice. Tumors formed with a low frequency (two tumors out of ten sites injected) and only after a long latency period (14 weeks). In contrast to the normal SHE cells, several different carcinogen-induced preneoplastic immortal SHE cell lines were highly susceptible to transformation by the v-src oncogene to the neoplastic phenotype. Tumors formed with high efficiency and a short latency period (less than 3 weeks). Further studies were performed to determine the basis for the inefficient transformation of the normal SHE cells. NeoR clones isolated after cotransfection of SHE cells with pSV2-neo and RSV DNAs were neither morphologically altered nor immortal and did not contain detectable levels of the v-src gene product. These results suggest that neoplastic transformation by v-src DNA in the normal cells is initially suppressed. However, cells from a v-src-induced tumor expressed v-src RNA, and antibody to v-src protein precipitated from the tumor cells a 60,000-molecular-weight protein which displayed protein kinase activity. Karyotypic analyses confirmed that the tumor was derived from Syrian hamster cells and suggested that it was clonal in nature. These results indicate that the v-src oncogene was primarily responsible for neoplastic transformation of SHE cells. In contrast to the results with the v-src oncogene, our previous studies showed that v-Ha-ras oncogene alone is unable to induce neoplastic transformation of SHE cells. Furthermore, the v-myc oncogene was able to compliment v-Ha-ras to neoplastically transform SHE cells, while cotransfection with v-src plus v-myc did not increase the incidence of tumors.

Low level of cellular protein phosphorylation by nontransforming overproduced p60c-src

We have previously found that Rous sarcoma virus variants in which the viral src (v-src) gene is replaced by the cellular src (c-src) gene have no transforming activity. In this study, we analyzed the basis for the inability of the p60c-src overproduced by these variants to transform cells. Phosphorylations of tyrosine residues in total cell protein or in cellular 34K protein are known to be markedly enhanced upon infection with wild-type Rous sarcoma virus. We found that these tyrosine phosphorylations were only slightly increased in the c-src-containing virus-infected cells, whereas both levels were significantly increased by infection with wild-type Rous sarcoma virus, or transforming mutant viruses which are derived from c-src-containing viruses by spontaneous mutation. Phosphorylation at tyrosine 416 of p60 itself was also extremely low in overproduced p60c-src and high in p60s of transforming mutant viruses. In immunoprecipitates with monoclonal antibody, the overproduced p60c-src had much lower casein tyrosine kinase activity than did p60v-src. We previously showed that p60 myristylation and plasma membrane localization may be required for cell transformation. p60c-src was similar to transforming p60s in these properties. These results strongly suggest that the low level of tyrosine phosphorylation by overproduced p60c-src accounts for its inability to transform cells.

Acquisition of host cell genetic information by avian sarcoma virus rescued from rat cells transformed by B77 virus

The properties of avian sarcoma virus B77 grown in chick cells were compared with those of virus obtained by fusion of rat cells transformed by B77 virus ( RB77 cells) with chick cells ( FB77 virus). Differences in the B77 and FB77 viral genomes were demonstrated by the fingerprint technique. The rescued FB77 virus contained sequences homologous to the normal cell genome. These results suggest that the rescued FB77 virus is a recombinant between B77 virus and rat genomic elements. The RNAs from B77 and FB77 viruses were found to have similar molecular weights. The migration rates of the structural proteins and the large glycoprotein (gp 85) in polyacrylamide gels were the same for the B77 and FB77 viruses, but the small glycoprotein (gp) of the FB77 virus was found to be slightly larger than the gp37 of the B77 virus.

Cellular src gene product detected in the freshwater sponge Spongilla lacustris

Serum from Rous sarcoma virus tumor-bearing rabbits immunoprecipitated from extracts of the freshwater sponge Spongilla lacustris a tyrosine-specific protein kinase with characteristics similar to the chicken pp60c-src kinase activity. An immune competition assay confirmed the relationship between the protein from sponges and viral pp60v-src.

Analysis of BHK cell growth kinetics after microinjection of catalytic subunit of cyclic AMP-dependent protein kinase

The effect of catalytic subunit (C) of cyclic AMP-dependent protein kinase on cell growth kinetics of BHK cells was assessed by microinjection with chicken erythrocyte ghosts as vehicles for introduction of the protein into the cytosol of large populations of cells. The advantage in using chicken erythrocytes for microinjection is that the inactive erythrocyte nuclei serve as a probe for identifying and analyzing microinjection events. By utilizing this procedure, BHK cells were microinjected with an amount of C that was 5- to 10-fold greater than their endogenous levels. Growth kinetics were analyzed by [3H]thymidine incorporation and autoradiography. Cells were stained after autoradiography to more clearly reveal the chicken nuclei, and at each time point, cells were categorized into four groups: (i) not microinjected, not in S phase, (ii) not microinjected, in S phase, (iii) microinjected, not in S phase, (iv) microinjected, in S phase. Those cells not microinjected served as internal controls. Two experimental protocols were used to test the notion that C is involved in blocking cell progression through G1 phase of the cell cycle. First, cells were arrested in G0 phase by serum deprivation, microinjected with C or control proteins, and stimulated to proceed to S phase by the addition of serum or purified growth factors. Second, cells were collected in mitosis, microinjected with C or control proteins, and stimulated to proceed to S phase by the addition of serum. The results of these studies indicate that a 5- to 10-fold increase in the intracellular concentration of C is not a sufficient signal to arrest cell growth in G1 phase. Thus, growth-inhibitory effects of cyclic AMP on BHK cells are unlikely to be the result of activation of cyclic AMP-dependent protein kinase.

Aspects of the metabolism of the epidermal growth factor receptor in A431 human epidermoid carcinoma cells

The biosynthesis and posttranslational metabolism of the epidermal growth factor (EGF) receptor were examined in the A431 human epidermoid carcinoma cell line. Polyclonal antibody against the receptor specifically immunoprecipitated two [35S]methionine-labeled proteins of Mr = 160,000 and 170,000. Pulse chase experiments showed the Mr = 160,000 protein to be a precursor of the Mr = 170,000 protein. Preincubation with tunicamycin resulted in immunoprecipitation of a single band of Mr = 130,000, whereas monensin inhibited maturation to the Mr = 170,000 form. Digestion of the Mr = 160,000 and 170,000 proteins with endoglycosidase H resulted in the appearance of Mr = 130,000 and 165,000 proteins, respectively. Prolonged pulse-chase experiments indicated that the half-life of the receptor is ca. 20 h in the absence of EGF and 5 h in the presence of EGF. Approximately three- to five-fold more phosphate is incorporated into the mature receptor upon addition of EGF, due primarily to increases in levels of phosphotyrosine and phosphoserine. Phosphate was also present on the Mr = 160,000 protein and the Mr = 130,000 protein found in the presence of tunicamycin.

Analysis of BHK cell growth kinetics after microinjection of catalytic subunit of cyclic AMP-dependent protein kinase

The effect of catalytic subunit (C) of cyclic AMP-dependent protein kinase on cell growth kinetics of BHK cells was assessed by microinjection with chicken erythrocyte ghosts as vehicles for introduction of the protein into the cytosol of large populations of cells. The advantage in using chicken erythrocytes for microinjection is that the inactive erythrocyte nuclei serve as a probe for identifying and analyzing microinjection events. By utilizing this procedure, BHK cells were microinjected with an amount of C that was 5- to 10-fold greater than their endogenous levels. Growth kinetics were analyzed by [3H]thymidine incorporation and autoradiography. Cells were stained after autoradiography to more clearly reveal the chicken nuclei, and at each time point, cells were categorized into four groups: (i) not microinjected, not in S phase, (ii) not microinjected, in S phase, (iii) microinjected, not in S phase, (iv) microinjected, in S phase. Those cells not microinjected served as internal controls. Two experimental protocols were used to test the notion that C is involved in blocking cell progression through G1 phase of the cell cycle. First, cells were arrested in G0 phase by serum deprivation, microinjected with C or control proteins, and stimulated to proceed to S phase by the addition of serum or purified growth factors. Second, cells were collected in mitosis, microinjected with C or control proteins, and stimulated to proceed to S phase by the addition of serum. The results of these studies indicate that a 5- to 10-fold increase in the intracellular concentration of C is not a sufficient signal to arrest cell growth in G1 phase. Thus, growth-inhibitory effects of cyclic AMP on BHK cells are unlikely to be the result of activation of cyclic AMP-dependent protein kinase.

Cellular src gene product detected in the freshwater sponge Spongilla lacustris

Serum from Rous sarcoma virus tumor-bearing rabbits immunoprecipitated from extracts of the freshwater sponge Spongilla lacustris a tyrosine-specific protein kinase with characteristics similar to the chicken pp60c-src kinase activity. An immune competition assay confirmed the relationship between the protein from sponges and viral pp60v-src.

Expression of the chicken c-src gene in COS cells

The cellular homolog of the Rous sarcoma virus transforming gene (v-src) was cloned into a plasmid containing the simian virus 40 origin of replication and transcriptional signals. This recombinant plasmid, designated pSVOHCS11 , directs the synthesis of relatively high levels of c-src mRNA and c-src protein ( pp60c -src), when the plasmid is studied 48 to 72 h after calcium phosphate-mediated DNA transfection of COS (monkey) cells. The level of c-src mRNA synthesis is 50-fold higher than the amount of c-src RNA produced in uninfected chicken embryo fibroblasts. Furthermore, the level of pp60c -src expressed in pSVOHCS11 -transfected COS cells is approximately the same as that of pp60v -src in Rous sarcoma virus-transformed cells. Using this recombinant plasmid, we demonstrated that c-src mRNA contains sequences which map 3' to the previously identified c-src-v-src regions of homology. In view of the small amount of c-src mRNA and protein that can be isolated from uninfected cells, this transient expression system offers a convenient source of material for further analyses of the c-src gene product.

Aspects of the metabolism of the epidermal growth factor receptor in A431 human epidermoid carcinoma cells

The biosynthesis and posttranslational metabolism of the epidermal growth factor (EGF) receptor were examined in the A431 human epidermoid carcinoma cell line. Polyclonal antibody against the receptor specifically immunoprecipitated two [35S]methionine-labeled proteins of Mr = 160,000 and 170,000. Pulse chase experiments showed the Mr = 160,000 protein to be a precursor of the Mr = 170,000 protein. Preincubation with tunicamycin resulted in immunoprecipitation of a single band of Mr = 130,000, whereas monensin inhibited maturation to the Mr = 170,000 form. Digestion of the Mr = 160,000 and 170,000 proteins with endoglycosidase H resulted in the appearance of Mr = 130,000 and 165,000 proteins, respectively. Prolonged pulse-chase experiments indicated that the half-life of the receptor is ca. 20 h in the absence of EGF and 5 h in the presence of EGF. Approximately three- to five-fold more phosphate is incorporated into the mature receptor upon addition of EGF, due primarily to increases in levels of phosphotyrosine and phosphoserine. Phosphate was also present on the Mr = 160,000 protein and the Mr = 130,000 protein found in the presence of tunicamycin.

Role of the mitogenic property and kinase activity of p60src in tumor formation by Rous sarcoma virus

Expression of the src gene of Rous sarcoma virus in chicken embryo neuroretinal cells results in morphological transformation and sustained proliferation of this normally resting cell population. PA101 and PA104 are two mutants of Rous sarcoma virus which induce neuroretinal cell proliferation in the absence of morphological transformation. Their mitogenic property is temperature sensitive, and they both encode p60src proteins with low kinase activity. To study the role of the mitogenic function and protein kinase activity of p60src in tumorigenesis, we investigated the oncogenicity of PA101 and PA104. Both mutants were less tumorigenic than wild-type virus when injected into chicks. Tumorigenicity was further assayed by inoculating infected chicken embryo fibroblasts and neuroretinal cells onto the chorioallantoid membrane of embryonated duck eggs. This system provides a nonpermissive and immunodeficient environment for xenogenic cell grafting and allows the study of cell tumorigenicity within a temperature range of 37 to 39.5 degrees C. Chicken embryo fibroblasts and neuroretinal cells infected with PA101 were as tumorigenic as wild type-infected cells at 37 degrees C, but tumor development was significantly reduced at 39.5 degrees C. In contrast, both cell types infected with PA104 displayed sharply reduced tumorigenicity. Cell cultures derived from PA101 tumors induced on the chorioallantoid membrane were similar to the corresponding cells maintained in vitro in terms of morphology, production of plasminogen activator, relative amounts of phosphotyrosine in total cellular proteins, and phosphorylation of 34,000-molecular-weight protein. These results indicate that the expression of the mitogenic function of src does not account per se for cell tumorigenicity and that tumor formation is compatible with low levels of p60src protein kinase activity.

Differential inhibition of cellular and viral pp60src kinase by P1,P4-di(adenosine-5')tetraphosphate

We contrasted the protein kinase activities of pp60v-src, the transforming protein of Rous sarcoma virus, and its normal cellular homolog pp60c-src with respect to inhibition by P1,P4-di(adenosine-5')tetraphosphate by using the immune complex protein kinase assay. The concentration of P1,P4-di(adenosine-5')tetraphosphate required for 50% inhibition of pp60v-src kinase (1 microM) was found to be significantly lower than that required for inhibition of pp60c-src kinase (46 microM). Viral and cellular pp60src kinases differed to a lesser extent with respect to inhibition by adenosine-5'-tetraphosphate, di(guanosine-5')tetraphosphate, and ADP. No significant differences were found in the ATP Km values of pp60v-src (0.108 +/- 0.048 microM) and pp60c-src kinases (0.056 +/- 0.012 microM). These results demonstrate that the protein kinase activities of viral and cellular pp60src are functionally distinguishable, particularly on the basis of enhanced sensitivity of the viral enzyme to inhibition by P1,P4-di(adenosine-5')tetraphosphate. These functional differences are likely to be due to differences in the conformation of the active site and may be important for determining transformation potential.

Differential inhibition of cellular and viral pp60src kinase by P1,P4-di(adenosine-5')tetraphosphate

We contrasted the protein kinase activities of pp60v-src, the transforming protein of Rous sarcoma virus, and its normal cellular homolog pp60c-src with respect to inhibition by P1,P4-di(adenosine-5')tetraphosphate by using the immune complex protein kinase assay. The concentration of P1,P4-di(adenosine-5')tetraphosphate required for 50% inhibition of pp60v-src kinase (1 microM) was found to be significantly lower than that required for inhibition of pp60c-src kinase (46 microM). Viral and cellular pp60src kinases differed to a lesser extent with respect to inhibition by adenosine-5'-tetraphosphate, di(guanosine-5')tetraphosphate, and ADP. No significant differences were found in the ATP Km values of pp60v-src (0.108 +/- 0.048 microM) and pp60c-src kinases (0.056 +/- 0.012 microM). These results demonstrate that the protein kinase activities of viral and cellular pp60src are functionally distinguishable, particularly on the basis of enhanced sensitivity of the viral enzyme to inhibition by P1,P4-di(adenosine-5')tetraphosphate. These functional differences are likely to be due to differences in the conformation of the active site and may be important for determining transformation potential.

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.

Isolation of a T-lymphotropic retrovirus from a patient at risk for acquired immune deficiency syndrome (AIDS)

A retrovirus belonging to the family of recently discovered human T-cell leukemia viruses (HTLV), but clearly distinct from each previous isolate, has been isolated from a Caucasian patient with signs and symptoms that often precede the acquired immune deficiency syndrome (AIDS). This virus is a typical type-C RNA tumor virus, buds from the cell membrane, prefers magnesium for reverse transcriptase activity, and has an internal antigen (p25) similar to HTLV p24. Antibodies from serum of this patient react with proteins from viruses of the HTLV-I subgroup, but type-specific antisera to HTLV-I do not precipitate proteins of the new isolate. The virus from this patient has been transmitted into cord blood lymphocytes, and the virus produced by these cells is similar to the original isolate. From these studies it is concluded that this virus as well as the previous HTLV isolates belong to a general family of T-lymphotropic retroviruses that are horizontally transmitted in humans and may be involved in several pathological syndromes, including AIDS.

Association of pp36, a phosphorylated form of the presumed target protein for the src protein of Rous sarcoma virus, with the membrane of chicken cells transformed by Rous sarcoma virus

A cellular protein with a molecular mass of approximately 36 kilodaltons is the presumed target protein of the src protein [the transforming protein encoded by Rous sarcoma virus (RSV)]. The cellular location of the phosphorylated 36-kilo-dalton protein (pp36) in chicken embryo fibroblasts transformed by the Schmidt-Ruppin strain of RSV has been investigated. In these studies, two-dimensional electrophoresis was used for detection of the phosphoproteins in total cell extracts and also in fractionated subcellular components. We conclude that pp36 is localized in the plasma membrane, on the basis of the following observations. (i) Fractionation of 32P-labeled cell extracts showed that pp36 is almost exclusively localized in the crude membrane fraction and no appreciable amount was found in nuclear or cytoplasmic fractions. (ii) On further fractionation of the crude membrane fraction, pp36 was localized mostly in the plasma membrane rather than in other membranous fractions. (iii) Isolated plasma membrane by itself phosphorylated the 36-kilodalton protein on incubation with [gamma-32P]ATP.

Effect of several nucleotides on the phosphorylating activities of the Rous-sarcoma-virus transforming protein pp60v-src and its cellular homologue, pp60c-src

In the presence of ADP and GDP the tyrosine-phosphorylating activities of the viral as well as the cellular pp60src show a similar concentration-dependent inhibition in vitro. Addition of diadenosine 5',5"'-p1p4 tetraphosphate (Ap4A) to the kinase assay leads to an inhibition of the viral kinase activity, whereas the cellular kinase is not influenced.

The expression in eukaryotes of a tyrosine kinase which is reactive with pp60v-src antibodies

All specimens of Eumetazoa and Parazoa, ranging from mammals, birds, teleosts, sharks, lampreys, amphioxus, insects, down to sponges showed the pp60c-src associated kinase activity, indicating that c-src, which is the cellular homologue of the oncogene v-src of Rous sarcoma virus (RSV) is probably present in all multicellular animals. Protozoa and plants did not show pp60c-src kinase activity. The degree of c-src expression depends on the taxonomic rank of the Eumetazoa tested, and is organ-specific with nervous tissues displaying the highest kinase activities. In the central nervous system of mammals and birds we found a high c-src expression, and in that of the lampreys, amphioxus, and insects the lowest. Unexpectedly, total extracts of sponges showed an amount of pp60c-src kinase activity similar to that of brain cell extracts of mammals and birds. These findings suggest that pp60c-src is a phylogenetic old protein that might have evolved together with the multicellular organisation of Metazoa, and that might be of importance in proliferation and differentiation of nontransformed cells.

Chromosomal localization of the human homolog (c-sis) of the simian sarcoma virus onc gene

Nonrandom chromosome rearrangements of chromosome 22 have been identified in different human malignancies. As a result of Southern blot hybridization of a c-sis probe to DNA's from mouse-human somatic cell hybrids, the human homolog (c-sis) of the transforming gene of simian sarcoma virus was assigned to chromosome 22. Hybrids between thymidine kinase-deficient mouse cells and human fibroblasts carrying a translocation of the region q11-qter of chromosome 22 to chromosome 17 were also analyzed. These studies demonstrate that the human c-sis gene is on region 22q11 greater than qter.

Comparison between the viral transforming gene (src) of recovered avian sarcoma virus and its cellular homolog

Recovered avian sarcoma viruses are recombinants between transformation-defective mutants of Rous sarcoma virus and the chicken cellular gene homologous to the src gene of Rous sarcoma virus. We have constructed and analyzed molecular clones of viral deoxyribonucleic acid from recovered avian sarcoma virus and its transformation-competent progenitor, the Schmidt-Ruppin A strain of Rous sarcoma virus. A 2.0-megadalton EcoRI fragment containing the entire src gene from each of these clones was subcloned and characterized. These fragments were also used as probes to isolate recombinant phage clones containing the cellular counterpart of the viral src gene, termed cellular src, from a lambda library of chicken deoxyribonucleic acid. The structure of cellular src was analyzed by restriction endonuclease mapping and electron microscopy. Restriction endonuclease mapping revealed extensive similarity between the src regions of Rous sarcoma virus and recovered avian sarcoma virus, but striking differences between the viral src's and cellular src. Electron microscopic analysis of heteroduplexes between recovered virus src and cellular src revealed a 1.8-kilobase region of homology. In the cellular gene, the homologous region was interrupted by seven nonhomologous regions which we interpret to be intervening sequences. We estimate the minimum length of cellular src to be about 7.2 kilobases. These findings have implications concerning the mechanism of formation of recovered virus src and possibly other cell-derived retrovirus transforming genes.

DNA sequence of the viral and cellular src gene of chickens. 1. Complete nucleotide sequence of an EcoRI fragment of recovered avian sarcoma virus which codes for gp37 and pp60src

Recovered avian sarcoma virus is a class of virus obtained from chicken tumors induced by mutants of Rous sarcoma virus which have a deletion in the src gene. We have determined the entire nucleotide sequence of a 3.1-kilobase EcoRI DNA fragment of molecularly cloned recovered avian sarcoma virus DNA. This DNA fragment contains part of the env gene and the entire src gene. Amino acid sequences of both gene products were deduced from the DNA sequences; the predicted amino acid sequences were verified by protein studies. An env protein (gp37) was found to be composed of 205 amino acids with three glycosylation sites. gp37 had a long stretch of hydrophobic residues near the carboxyl terminus. The src gene product, pp60src, was composed of 526 amino acids and contained the possible sites for tyrosine and serine phosphorylation. The amino acid sequences predicted in this study differ significantly from the amino acid sequence predicted previously for the Schmidt-Ruppin strain of Rous sarcoma virus.

DNA sequence of the viral and cellular src gene of chickens. II. Comparison of the src genes of two strains of avian sarcoma virus and of the cellular homolog

The nucleotide sequence of the src gene and flanking regions of the Schmidt-Ruppin strain of Rous sarcoma virus (SR-A) was determined. The src region of SR-A was very homologous to that of recovered avian sarcoma virus (rASV1441), with only 17 differences among 1,578 nucleotides. The size of the predicted protein was 526 amino acids in both viruses, of which 6 amino acids were different. The differences in nucleotides and amino acids between the two viruses localized within the 5' two-thirds of the src coding region. There were also viruses localized within the 5' two-thirds of the src coding region. There were also some differences in the region flanking the 5' end of src. Since rASVs are considered to be recombinatns between deletion mutants of SR-A and cellular-src (c-src) sequences, several segments of c-src DNA were also sequenced to understand the molecular basis for the recombination. At 14 of 17 bases where SR-A and rASV1441 differed, rASV1441 had the same sequence as c-src. Three of these sequences corresponded to sequences of oligonucleotides which were previously identified in RNAs of nearly all isolates of rASV but which were absent in SR-A RNA. In the 5'-flanking sequences of the src gene, c-src was more similar to rASV1441 than to SR-A. These results confirm the cellular origin of the src sequences of rASVs and provide information about the possible sites of the recombination.

Cellular transforming genes

Cellular genes potentially capable of inducing oncogenic transformation have been identified by homology to the transforming genes of retroviruses and by the biological activity of cellular DNA's in transfection assays. DNA's of various tumors induce transformation with high efficiencies, indicating that oncogenesis can involve dominant genetic alterations resulting in activation of cellular transforming genes. The identification and characterization of cellular transforming genes and their possible involvement in naturally occurring cancers, is discussed.

Role of 3'-end of viral genome in tumor heteroinduction by the avian sarcoma virus

Transformation defective virus was derived by restriction endonuclease cleavage from a clone of the avian sarcoma virus Schmidt-Ruppin strain, strongly oncogenic for rats. The transfection experiments of chicken cells by digested proviral DNA gave rise to transformation defective virus. The td virus was possible to recover in vivo in chickens. The tumors obtained after a long latent period contained the sarcoma virus which was able to transform chicken cells in vitro and to induce tumors in chickens. All viruses, parental, td- and recovered were of D subgroup specificity. The tumor induction experiments in rats have shown that the recovery of viral genome deletion in td mutant by cellular sequences was not enough to regain the oncogenicity for rats. The results stressed the importance of 3-end sequences of the virus genome, probably the sequences in C region for heteroinduction ability of the avian sarcoma virus.

Isolation of 16L virus: a rapidly transforming sarcoma virus from an avian leukosis virus-induced sarcoma

We have isolated a replication-defective rapidly transforming sarcoma virus (designated 16L virus) from a fibro-sarcoma in a chicken infected with td107A, a transformation-defective deletion mutant of subgroup A Schmidt-Ruppin Rous sarcoma virus. 16L virus transforms fibroblasts and causes sarcomas in infected chickens within 2 wk. Its genomic RNA is 6.0 kilobases and contains sequences homologous to the transforming gene (fps) of Fujinami sarcoma virus (FSV). RNase T1 oligonucleotide analysis shows that the 5' and 3' terminal sequences of 16L virus are indistinguishable from (and presumably derived from) td107A RNA. The central part of 16L viral RNA consists of fps-related sequences. These oligonucleotides fall into four classes: (i) oligonucleotides common to the putative transforming regions of FSV and another fps-containing avian sarcoma virus, UR1; (ii) an oligonucleotide also present in FSV but not in UR1; (iii) an oligonucleotide also present in UR1 but not in FSV; and (iv) an oligonucleotide not present in either FSV, UR1, or td107A. Cells infected with 16L virus synthesize a protein of Mr 142,000 that is immunoprecipitated with anti-gag antiserum. This protein has protein kinase activity. These results suggest that 16L virus arose by recombination between td107A and the cellular fps gene.

Carcinogen- and radiation-transformed C3H 10T1/2 cells contain RNAs homologous to the long terminal repeat sequence of a murine leukemia virus

Carcinogen- or radiation-transformed C3H 10T1/2 murine fibroblasts transcribe a set of poly(A)+RNAs that contain sequences homologous to the long terminal repeat (LTR) sequence of Moloney murine sarcoma virus. These LTR-containing RNAs consist of a series of discrete bands ranging in size from about 38 to 18 S. The higher molecular weight molecules (30-38 S) in this set of RNAs also contain sequences homologous to the gag, pol, and env genes of a murine leukemia virus. A 24S RNA contains sequences homologous to the env gene of murine leukemia virus. A 20S and an 18S RNA also share homology with the LTR probe but fail to hybridize to the gag, pol, or env probes or to a probe for the U3 region of the LTR sequence. Thus, the latter transcripts do not appear to arise from a known endogenous murine leukemia virus genome. Although this entire set of RNAs is absent from normal C3H 10T1/2 cells (or is present at an extremely low level), these RNAs are induced by BrdUrd or 5-azacytidine. The presence of these RNAs may provide highly sensitive molecular markers of transformation of murine cells.

Avian sarcoma virus UR2 encodes a transforming protein which is associated with a unique protein kinase activity

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.