Structure and processing of the p2 region of avian sarcoma and leukemia virus gag precursor polyproteins

We have purified two low-molecular-weight polypeptides from the Prague C strain of Rous sarcoma virus and have identified these as products of the gag precursor Pr76 by protein sequencing and by amino acid analysis. Both polypeptides are derived from a stretch of 22 amino acids within Pr76 that separates p19 and p10. We refer to this region as p2. Together the two cleavage products form the entire p2 region. The junctions of p19 with the amino-terminal fragment of p2 and of p10 with the carboxy-terminal fragment of p2 define two new processing sites within the gag precursor, Tyr-155-His-156 and Gly-177-Ser-178. Both polypeptides are major cleavage products of Pr76 that occur in Prague C Rous sarcoma virus at an estimated 1,000 copies per virion. They also are prominent components of avian myeloblastosis virus. The combination of gel filtration and reverse-phase high-pressure liquid chromatography, which was used for the isolation of the two fragments of p2, resolved over a dozen other low-molecular-weight polypeptides from avian sarcoma and leukemia viruses that previously were undetected. This technique thus should serve as a useful procedure for further characterization of viral components.

Effect of transformation by Rous sarcoma virus on the character and distribution of actin in Rat-1 fibroblasts: a biochemical and microscopical study

Actin has been measured in subcellular fractions from Rat-1 fibroblasts and in Rous sarcoma virus-transformed Rat-1 cells (VIT), using the DNase 1 inhibition assay. The transformed cells showed a significant shift in the actin monomer (G)in equilibrium with polymer (F) equilibrium within the cell cytosol, and a significant increase in actin in the Triton-insoluble cytoskeletal core in comparison with untransformed cells. This incorporation of actin into the cytoskeletal core fraction is associated with a change in filamentous actin assemblies from 'stress fibre' patterns to punctate filament aggregates. These differences have been correlated with changes in morphology, in actin, vinculin and alpha-actinin distribution, in adhesion plaque formation and with the production of pp60v-src-associated protein kinase activity in the transformed cells. Changes in actin distribution and its polymerization in response to src-gene expression may play an important role in the determination of the transformed cell characteristics.

Purified tyrosine kinases, the EGF receptor kinase and the src kinase, can catalyze the phosphorylation of the band 3 protein from human erythrocytes

The band 3 glycoprotein from human erythrocytes was found to be phosphorylated on tyrosine residues by the purified EGF receptor kinase and the purified src kinase in vitro. Kinetic analysis revealed that Km of the band 3 protein phosphorylation by the EGF receptor kinase was 0.17 microM and 0.65 microM in the absence and presence of EGF (3 X 10(-7)M), respectively, and that in the case of the src kinase it was 0.4 microM. From these data the band 3 protein can be regarded as one of the best substrates common for the EGF receptor kinase and the src kinase in vitro.

HTLV-III gag protein is processed in yeast cells by the virus pol-protease

The gag-pol gene of HTLV-III (human T-lymphotropic virus), the virus linked to AIDS (acquired immune deficiency syndrome), was expressed in yeast, and processing of the gag precursor into proteins of the same size as those in the virion was observed. Processing of the gag gene in yeast cells mimics the process that naturally occurs in mammalian cells during maturation of virions. Therefore it was possible to perform mutational analysis of the virus genome to localize the gene that codes for the protease function to the amino terminal coding region of the pol gene. Since this region overlaps the gag gene, it is likely that ribosomal frameshifting occurs from gag to pol. Antibodies in all of the AIDS patients' sera tested recognized the yeast synthesized gag proteins, although the sera showed differences in relative reactivity to the individual gag proteins and the precursor. This yeast system should be valuable not only for production of viral proteins for diagnostic or vaccine purposes but also for analysis of the genetics and biochemistry of viral gene functions--parameters that are difficult to study otherwise with this virus.

Tyr527 is phosphorylated in pp60c-src: implications for regulation

The Rous sarcoma virus oncogene product, pp60v-src, transforms cultured fibroblasts but its corresponding proto-oncogene product, pp60c-src, does not. Both proteins are known to be protein-tyrosine kinases. Published results suggest that the kinase activity of pp60c-src is inhibited relative to that of pp60v-src, due perhaps to phosphorylation of a tyrosine in pp60c-src that is not phosphorylated in pp60v-src. In this study, it was observed that the tyrosine phosphorylated in pp60c-src is Tyr527, six residues from the COOH-terminus of the protein. The region of pp60c-src from residue 515 to the COOH-terminus, including Tyr527, has been replaced with a different sequence in pp60v-src. Thus, the increase in transforming ability and kinase activity that occurred in the genesis of pp60v-src may have resulted from the loss of a tyrosine involved in negative regulation.

Neither arginine nor histidine can carry out the function of lysine-295 in the ATP-binding site of p60src

All 15 protein kinases whose amino acid sequence is known contain a lysine residue at a position homologous to that of lysine-295 in p60src, the transforming protein of Rous sarcoma virus. The ATP analog p-fluorosulfonyl 5'-benzoyl adenosine inactivates both p60src and the catalytic subunit of the cyclic AMP-dependent protein kinase by modification of this lysine. We used oligonucleotide-directed mutagenesis to examine the possible functions of this residue. Lysine-295 in p60src was replaced with a glutamic acid, an arginine, or a histidine residue, and mutant p60src proteins were characterized in chicken cells infected by mutant viruses. None of these three mutant p60src proteins had tyrosine protein kinase activity in vitro, and none induced morphological transformation of infected cells. Since neither a histidine nor an arginine residue can replace the function of lysine-295, we suggest that it carries out the specialized function of proton transfer in the phosphotransferase reaction. All three mutant viruses underwent reversion to wild type during passage in tissue culture. Because the rate with which this occurred differed significantly among the mutants, reversion appears to have resulted from errors in transcription, rather than from recombination with the cellular src gene.

Stimulation of ribosomal protein S6 kinase activity by pp60v-src or by serum: dissociation from phorbol ester-stimulated activity

Ribosomal protein S6 kinase activity was measured in lysates prepared from serum-deprived chicken embryo fibroblasts (CEF) treated for various times with phorbol 12-myristate 13-acetate (PMA). Maximal activity was observed within 15 min, and it declined to the initial level by 4 hr. Incubation of these cells with PMA 4-60 hr after the initial treatment did not result in an additional increase in S6 protein kinase activity. These results are consistent with down-regulation of the PMA receptor, protein kinase C, and the dependence of PMA-stimulated S6 kinase activity on this enzyme. Long-term pretreatment of CEF with PMA only partially attenuated the stimulation of the S6 protein kinase activity by serum or by expression of the Rous sarcoma virus transforming gene product, pp60v-src. A similar protein kinase activity also was stimulated in cells treated with cycloheximide or sodium vanadate. Pretreatment with PMA had little effect on this response. These data indicate that it is likely that there are at least two mechanisms through which S6 kinase activity can be regulated, one of which apparently utilizes protein kinase C whereas the other(s) does not. Additional experiments show PMA-stimulated glucose transport was not attenuated by long-term incubation with phorbol ester, suggesting that another mechanism, which is not dependent on the presence of protein kinase C, maintains this response after the proposed down-regulation of the PMA receptor.

Purification and characterization of the feline sarcoma virus tyrosine-specific kinase pp85gag-fes

The transforming phosphoprotein pp85gag-fes of the Snyder-Theilen strain of feline sarcoma virus (ST-FeSV) was purified in a form which exhibits tyrosine-specific kinase activity. Cell lysates of ST-FeSV-transformed mink nonproducer cells were applied to a column of DEAE-Sephacel and eluted with a linear gradient of NaCl in phosphate buffer. Kinase activity was found uncomplexed (pp85gag-fes) in the flow-through and was eluted with 200 mM NaCl in a complex with pp50 and pp90. The flow-through material was further fractionated by chromatography on hydroxylapatite, followed by phosphocellulose and a final gel filtration step using Sephacryl S200. The final preparation was specifically enriched 1400-fold, and tyrosine-specific kinase activity was increased by about 300-fold as determined by autophosphorylation or phosphorylation of casein. Pp85gag-fes kinase activity was inhibited by nicotinamide adenosine dinucleotide (NAD) and slightly inhibited by NADH, while quercetin, a strong inhibitor for pp60src-associated tyrosine kinase activity, had no inhibiting effect.

Phosphorylation and inactivation of protein phosphatase 1 by pp60v-src

Protein phosphatase 1, one of four major protein phosphatases involved in cellular regulation, was phosphorylated in vitro by pp60v-src, the transforming gene product of Rous sarcoma virus. Phosphorylation was accompanied by a loss of protein phosphatase activity. The inactivation of protein phosphatase 1 was time-dependent and the extent of inactivation correlated closely with the stoichiometry of phosphorylation. Under optimal conditions, 0.34 +/- 0.01 mol of phosphate were incorporated per mol of protein phosphatase and the activity of the enzyme was decreased by 39 +/- 2%. The inactivation required the presence of both MgATP and pp60v-src. There was no loss of activity when adenosine 5'-[beta gamma-imido]triphosphate was used in place of ATP. Phosphorylation of protein phosphatase 1 occurred exclusively on tyrosine residues and was blocked by specific antibodies to pp60v-src. During preincubation of pp60v-src at 41 degrees C, its protein kinase activity towards casein was lost rapidly. The ability of pp60v-src to phosphorylate and inactivate protein phosphatase 1 declined in parallel with the loss of casein kinase activity. Limited chymotryptic digestion of 32P-labeled protein phosphatase 1 (Mr 37,000) resulted in its quantitative conversion to a Mr 33,000 species. Conversion to this species was accompanied by the loss of 32P-labeling and by reactivation of the protein phosphatase. When various concentrations of chymotrypsin were used in the digestion, there was a close correlation between conversion to the Mr 33,000 species and the restoration of protein phosphatase activity. pp60v-src was unable to phosphorylate or inactivate a partially proteolyzed species of protein phosphatase 1 (Mr 33,000/34,000).

Avian retrovirus nucleocapsid protein, pp12, produced in Escherichia coli has biochemical properties identical to unphosphorylated viral protein

The avian sarcoma and leukosis viruses contain an RNA binding nucleocapsid protein, pp12, in the phosphorylated form. An Escherichia coli expression vector carrying the Rous sarcoma virus Prague C strain gene coding for this protein has been constructed using a site-directed deletion mutagenesis method to place start and stop codons into translational reading frame with the N- and C-terminal coding sequences of the protein, respectively. The protein is produced efficiently in bacteria (rp12), is soluble and readily purified. It is also indistinguishable from the unphosphorylated viral pp12 protein in its migration on SDS-polyacrylamide gels, reactivity with rabbit antisera directed against purified viral pp12, low RNA-binding affinity, and ability to serve as a substrate for in vitro phosphorylation at serine-40 by protease-activated kinase I. The ability to analyze the biochemical activities of the normal, modified, and mutant forms of this protein is an essential step in elucidating its role in the retroviral life cycle. This expression clone will be especially useful in testing for the effects of mutations before they are reconstructed into retroviral genomes for analyses.

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.

Myristylation of gag protein in human T-cell leukemia virus type-I and type-II

We found that p19gag of HTLV-I and p23gag of HTLV-II are myristylated. The p28, which is immunologically cross-reactive with monoclonal antibody against p19gag of HTLV-I was also shown to be myristylated in the HTLV-I-infected cell lines MT-2 and HUT102. However, no myristylated p28 was found in HTLV-II-infected cell lines, Mo and Ton1.

A murine recombinant retrovirus containing the src oncogene transforms erythroid precursor cells in vitro

A murine retrovirus (MRSV) containing the src gene of Rous sarcoma virus has been shown to cause an erythroproliferative disease in mice (S. M. Anderson and E. M. Scolnick, J. Virol. 46:594-605, 1983). We now demonstrate that this same virus can transform erythroid progenitor cells in vitro. Infection of fetal liver cells or spleen and bone marrow cells from phenylhydrazine-treated adult mice gave rise to colonies of erythroid cells which grew in methylcellulose under conditions not favorable for the growth of normal erythroid cells. The presence of pp60src in the transformed erythroid cells was demonstrated by an immune complex protein kinase assay. The time course of appearance and subsequent differentiation of erythroid colonies indicated that the target cell for MRSV was a 6- to 8-day burst-forming unit. Differentiation of the erythroid progenitors was not blocked by the presence of pp60src, and the cells retained sensitivity to the hormone erythropoietin. In fact, the transformed cells exhibited increased hormone sensitivity since the number, the size, and the extent of hemoglobinization of the colonies were all increased by the addition of small amounts of erythropoietin. MRSV was not susceptible to restriction by the Fv-2 locus, as MRSV could transform hematopoietic cells from C57BL/6 mice. These results indicate that (i) the erythroid proliferation observed in vivo is caused by a direct effect of MRSV on erythroid progenitors and (ii) the transformed erythroid precursors acquire a growth advantage over uninfected cells without losing the ability to differentiate and respond to physiologic regulators.

Polyomavirus middle T protein encoded by a retrovirus transforms nonestablished chicken embryo cells

A murine retrovirus encoding the middle T protein of polyomavirus infected and transformed nonestablished chicken embryo cells. The infected cultures formed colonies in soft agar-containing medium and released infectious transforming virus. Middle T protein expressed in the transformed chicken cells associated with p60c-src and, in immunoprecipitates, enhanced the tyrosine protein kinase activity of p60c-src.

The 36-kilodalton substrate of pp60v-src is myristylated in a transformation-sensitive manner

A primary intracellular substrate for pp60v-src kinase in a variety of avian and mammalian cells is a protein of 34 to 39 kilodaltons (kD). After incubation of chicken embryo fibroblasts (CEF) with [3H]myristic acid for 4 hours, the 36-kD protein contained covalently bound myristic acid by several criteria: (i) the radioactively labeled material comigrated with the 36-kD protein on sodium dodecyl sulfate-polyacrylamide gels in one and two dimensions, (ii) the labeled material was insoluble in chloroform-methanol, and (iii) radioactively labeled myristate could be recovered from the purified 36-kD protein. The resistance of the acyl fatty acid moiety to hydrolysis by hydroxylamine suggested that the covalent linkage to the 36-kD protein may be through an amide linkage. The [3H]myristic-acid labeling of the 36-kD protein in Rous sarcoma virus-transformed CEF showed a reduction of up to 45 percent when compared to an identical amount of 36-kD protein derived from normal cells; this reduction was not due to general changes in myristic acid metabolism in transformed cells.

Phosphatidylinositol kinase activities in normal and Rous sarcoma virus-transformed cells

The phosphatidylinositol (PI), phosphatidylinositol 4-phosphate (PIP), and diacylglycerol kinase activities in the plasma membrane-rich fraction of chicken embryo fibroblasts infected with a temperature-sensitive mutant of Rous sarcoma virus increased when the cells were shifted from the nonpermissive temperature, 41 degrees C, to the permissive temperature, 35 degrees C. Temperature shift from 35 to 41 degrees C decreased the lipid kinase activities in the membrane vesicles. These changes accompanied the changes observed in pp60v-src protein kinase activity. Thermal inactivation at 41 degrees C did not appreciably reduce PI and PIP kinase activities in membrane vesicles prepared from uninfected or Rous sarcoma virus-transformed cells, whereas pp60v-src protein kinase activity in the membrane vesicles was rapidly inactivated under the same conditions. These data suggest that pp60v-src may indirectly enhance PI and PIP phosphorylation but not directly contribute to this pathway.

Processing of p60v-src to its myristylated membrane-bound form

p60src of wild-type Rous sarcoma virus is myristylated at its N-terminal glycine residue. We have shown previously that this myristylation is necessary for p60src membrane association and for cell transformation by using src mutants with alterations within the N-terminal 30 kilodaltons of p60src. In this study we analyzed the process of p60src myristylation in wild type- and mutant-infected cells. All myristylated src proteins examined lack the initiator methionine, but two mutant src proteins lacking the initiator methionine are not myristylated, indicating that removal of the initiator methionine and myristylation are not obligatorily coupled. Analysis of the kinetics of myristylation and the association of p60src with cellular proteins p50 and p90 indicated that myristylation occurs before p60src becomes membrane associated and that transient association with p50 and p90 occurs regardless of myristylation. Myristylation is required for stable association of p60src with the plasma membrane but is not sufficient for membrane association. A mutant with an src deletion of amino acids 169 through 264 has an src protein that is myristylated but not membrane bound, remaining stably associated with p50 and p90. This mutant is transformation defective. Several N-terminal deletion mutants possessing tyrosine kinase activity have myristylated and membrane-bound src proteins but are not fully active in cell transformation, suggesting that additional N-terminal functional domains exist.

Restriction of the in vitro and in vivo tyrosine protein kinase activities of pp60c-src relative to pp60v-src

The tyrosine protein kinase activities of pp60c-src and pp60v-src were compared. The activities were qualitatively similar in vitro when the src proteins were bound in an immune complex with monoclonal antibody; both proteins utilized either ATP or GTP as phosphate donors, preferred Mn2+ to Mg2+, and had similar exogenous substrate specificities. The specific activity of pp60c-src was about 10-fold lower than that of pp60v-src for exogenous substrate phosphorylation but was only 1.1- to 2-fold lower than that of pp60v-src for autophosphorylation. Six glycolytic enzymes, including three not previously identified as substrates for pp60src phosphorylation, were phosphorylated by both pp60c-src and pp60v-src. Levels of pp60c-src fourfold higher than the amount of pp60v-src in src-plasmid-transformed cells did not detectably alter the level of phosphotyrosine in cellular proteins, but increasing the expression of pp60c-src another twofold (which induces cells to form foci in monolayer culture (P.J. Johnson, P.M. Coussens, A.V. Danko, and D. Shalloway, Mol. Cell. Biol. 5:1073-1083, 1985) resulted in a threefold increase in the level of cellular protein phosphotyrosine. Immunoprecipitation and analysis of the alkali-stable phosphoproteins by two-dimensional electrophoresis showed that, in contrast to pp60v-src-transformed cells, pp36 and enolase are only weakly phosphorylated in these high-level pp60c-src overexpresser cells. Even allowing for the in vitro differences in specific activities of phosphorylation, these results suggest that the pp60c-src tyrosine protein phosphorylating activity may be restricted relative to that of pp60v-src by additional in vivo mechanisms.

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.

A cAMP-independent serine/threonine kinase activity is associated with the mos sequences of ts110 Moloney murine sarcoma virus-encoded P85gag-mos

Two proteins, termed P85gag-mos and P58gag, are encoded by the temperature-sensitive transformation mutant, ts110 Moloney murine sarcoma virus (MuSV). Based on temperature-shift studies, P85gag-mos is believed to be important for the transforming potential of ts110 MuSV and has been found to be associated with a thermolabile kinase activity that phosphorylates both P85gag-mos and P58gag in immune complexes. Modifications of the original kinase assay conditions are reported here that have allowed a 30-fold increase in the specific activity of P85gag-mos phosphorylated in vitro. The in vitro P85gag-mos-phosphorylating activity was found to be unresponsive to 10 microM-cAMP or 10 microM-cGMP. Addition of 1 mM-pyrophosphate, a known phosphatase inhibitor, to the reaction mixture resulted in an increased yield of phosphorylated P85gag-mos and P58gag; the molar phosphate incorporation per mole of P85gag-mos increased from 0.032 to 0.9, whereas the specific activity of in vitro-phosphorylated P58gag increased 18-fold, from 0.013 to 0.234. pH curves of the in vitro kinase reaction further confirmed the presence of phosphatase activity; in the absence of pyrophosphate, a sharp optimum at pH 4 to 5 was observed, whereas it shifted broadly to pH 7.0 in the presence of pyrophosphate. Under the latter conditions, several experiments were performed in order to determine if the kinase was associated with either gag or mos sequences of P85gag-mos. Antisera directed against p15, p12 and p30 sequences of the gag protein region of P85gag-mos yielded immune complexes that allowed phosphorylation in vitro of P85gag-mos. No phosphorylating activity was detected in immune complexes containing MuSV-124-encoded P62gag. An anti-mos serum generated against a synthetic peptide representing the predicted v-mos amino acid residues 37 to 55 recognizes P85gag-mos and allowed phosphorylation of P85gag-mos in vitro in the absence of P58gag. Peptide mapping of both phosphorylated P85gag-mos and P58gag, by using a combination of Cleveland and Western/immunoperoxidase techniques, demonstrated that P85gag-mos became phosphorylated not only on gag sequences, but also at the N-terminal portion of v-mos. Phosphoamino acid analyses of P85gag-mos and P58gag phosphorylated in vitro under these modified conditions yielded predominantly phosphoserine and lesser amounts of phosphothreonine. Metabolically 32P-labelled P85gag-mos and P58gag were also found to contain phosphoserine and phosphothreonine. Based on these results, we conclude that a cAMP-independent, serine/threonine protein kinase activity is associated with the mos sequences of P85gag-mos.

Protein kinase C phosphorylates pp60src at a novel site

The transforming protein of Rous sarcoma virus (pp60v-src) and its normal cellular homolog (pp60c-src) are demonstrated to be phosphorylated at serine 12 in vivo under certain conditions. We propose that protein kinase C is responsible for this modification based on the following evidence. First, the tumor promoters, 12-O-tetradecanoylphorbol-13-acetate and teleocidin, and synthetic diacylglycerol, known activators of protein kinase C in vivo, cause nearly complete phosphorylation of pp60src at serine 12. Second, among five purified serine/threonine-specific protein kinases tested, only protein kinase C phosphorylates pp60c-src and pp60v-src in vitro at serine 12. Third, purified protein kinase C phosphorylates a synthetic peptide corresponding to the N-terminal 20 amino acids of pp60c-src at serine 12. The physiological significance of this novel phosphorylation is discussed.

pp60src-dependent protein phosphorylation in membranes from Rous sarcoma virus-transformed chicken embryo fibroblasts

The Rous sarcoma virus (RSV)-transforming protein, pp60src, is a plasma membrane-associated tyrosine-specific protein kinase. A 36,000-Da cellular polypeptide (p36) which is phosphorylated at tyrosine in RSV-transformed chicken embryo fibroblasts (RSV-CEF) is also plasma membrane associated. To determine if p36 is directly phosphorylation and kinase activity in situ in the plasma membrane, src-dependent protein phosphorylation in membranes isolated from RSV-CEF has been characterized. These membrane preparations contained high ATPase and phosphoprotein phosphatase activities; but when sufficient concentrations of [gamma-32P]ATP were used, the phosphorylation of pp60src and the phosphorylation of p36 were linear for 1 min or more, and the initial rates of phosphorylation could therefore be determined. In membranes from RSV-CEF pp60src and p36 became phosphorylated predominantly at tyrosine, while in membranes from uninfected cells p36 was phosphorylated at low levels at serine. When membranes from RSV-CEF were preincubated with tumor-bearing rabbit (TBR) serum, the IgG became phosphorylated while the phosphorylation of p36 was inhibited, suggesting that p36 is directly phosphorylated by pp60src. Phosphorylation of pp60src, p36, and TBR-IgG was dependent on growth temperature in membranes from cells infected by a temperature-sensitive mutant, tsNY68, although some dependence on growth temperature was observed even with membranes from wild-type RSV-infected cells. However, at the nonpermissive temperature, tsNY68 pp60src retained 20-40% of its kinase activity, providing supporting for the proposal (B. M. Sefton, T. Hunter, and K. Beemon (1980, J. Virol, 33, 220-229) that transformation may result from a small quantitative change in pp60src activity. The phosphorylation of pp60src and its kinase activity were not coordinately affected by growth temperature or mutations within src, indicating that different factors affect the phosphoacceptor capacity and kinase activity of the protein.

The fate of the surface protein gp70 during entry of retrovirus into mouse fibroblasts

The kinetics of the viral surface protein gp70 and the viral core proteins p30 and p15C were followed during retrovirus entry into mouse fibroblasts. All three proteins were internalized, but whereas essentially all the gp70 was degraded, approximately one-third of the core proteins remained stable in the cells. These diverging routes of the different proteins are in agreement with the proposed route, that retrovirus enters the cells by endocytosis followed by a membrane fusion between the virus membrane and the vesicle membrane.

Cytoskeleton-associated Pr65gag and assembly of retrovirus temperature-sensitive mutants in chronically infected cells

Certain temperature-sensitive (ts) mutants of murine leukemia virus (MuLV) were observed to be defective in virus assembly. These mutants also accumulated intracellular core protein precursor, Pr65gag, at 39 degrees, the nonpermissive temperature. At 39 degrees, virions released from cells infected with the various ts mutants also contained elevated levels of Pr65gag relative to virions released at 33 degrees, the permissive temperature. Detergent extraction of pulse-labeled cells with Nonidet P-40 (NP-40) generated an NP-40-insoluble cytoskeleton-enriched fraction. Reextraction of this fraction with deoxycholate followed by gel electrophoresis of solubilized, immunoprecipitated viral proteins showed that in Moloney MuLV (Mo-MuLV) ts3-infected cells, and in Rauscher MuLV (R-MuLV) ts17- and ts24-infected cells, increased amounts of intracellular viral Pr65gag rapidly become associated with the cytoskeleton-enriched fraction during pulse labeling at nonpermissive temperature. Furthermore, examination of cell extracts from chase-incubated cells infected with these ts mutants revealed that Pr65gag accumulated in the cytoskeleton-enriched fraction at 39 degrees but not at 33 degrees. During steady-state labeling, as much as half of the intracellular Pr65gag becomes associated with the cytoskeleton-enriched fraction (i.e., is not solubilized by NP-40) at 39 degrees. At permissive temperature only 10-15% of the intracellular Pr65gag is cytoskeleton associated. In contrast, cells infected with R-MuLV ts25 or ts26 showed little or no preferential localization of Pr65gag in the cytoskeleton-enriched cell fraction during a short pulse at 39 degrees, but Pr65gag accumulated in both the NP-40-soluble and -insoluble fractions during a chase incubation relative to the condition at 33 degrees. Based upon these and previous results (Edbauer and Naso, 1983), models for retrovirus assembly are described in which the association of Pr65gag with the cell membrane and cytoskeleton plays a critical role in virus assembly, budding, and postbudding maturation.

Morphological evidence for cyclic AMP-induced reverse transformation in vole cells infected with avian sarcoma virus

Normal fibroblasts of the vole displayed moderately spread or flattened, spindle-shaped, or polygonal morphologies and attached firmly to a substrate. Topographic features of these cells included sparse microvilli, ruffles, and filopodia. Microfilament bundles, intermediate filaments, and long microtubules generally parallel to each other, and the long axis of the cell or its extensions were present in the cytoplasm. Fibronectin was abundant, and fibronectin fibrils often formed junctions at the cell membrane with microfilament bundles. Transformation with avian sarcoma virus converted 90% of the cells to spheres 5 to 10 microns in diameter. In contrast to the normal vole cells, microfilament bundles were absent, microtubules were short and randomly arranged, and fibronectin was no longer visible. Exposure to dibutyryl cyclic AMP and testololactone caused a majority of the spherical cells to stretch and flatten, a process referred to as reverse transformation. Microtubules radiated out to the cell periphery and became parallel in cell extensions, while long microfilament bundles appeared in the cytoplasm. Parallel intermediate filaments were arranged throughout the cell. This ultrastructural analysis of reverse transformation in avian sarcoma virus-transformed vole cells detailed the status of the cytoskeletal system and showed agreement with earlier findings (Puck et al., J. Cell. Physiol. 107:399-412, 1981) using indirect immunofluorescence.

55,000-dalton, retrovirus-associated, cell membrane glycoprotein: purification and quantitative measurements of expression in viruses, cells, and tissues

We have purified to homogeneity and characterized a 55,000-dalton rat cell membrane glycoprotein, gp55. This protein was originally identified in preparations of a defective pseudotype of the Kirsten sarcoma virus and shown to be present in several rodent retrovirus particles. The gp55 was purified from this defective virus by concanavalin A and heparin affinity chromatography, as well as by preparative sodium dodecyl sulfate-gel electrophoresis. Both preparations displayed similar purity and antigenic characteristics. The 125I-labeled gp55 was precipitated by antisera against rodent retroviruses, but not by monospecific antisera against purified type C virus structural proteins, thus indicating that gp55 was retrovirus associated, but unrelated to known retrovirus structural proteins. Competition radioimmunoassay with an anti-rat virus serum which recognized rodent group-specific antigens on gp55 indicated: the presence of gp55 antigens in 15 rodent cell lines, but not 10 nonrodent cell lines; no effect of viral infection or cell transformation on the amount of gp55 expressed; up to 100-fold increases in the concentration of the gp55 antigens in nine rodent retroviruses, but not in five nonrodent viruses, as compared to cells; the presence of gp55 in rodent sera, especially of the NZB mouse, where anti-gp55 antibody was also detected; a lymphoid and epithelial tissue distribution of gp55 in rats and mice. Additional competition radioimmunoassays with a broad-reacting antivirus serum also detected the presence of gp55 in nonrodent, mink, and human cells and thus distinguished rat type, rodent group, and interspecies antigenic determinants on gp55. In conclusion, gp55 is a cell membrane glycoprotein associated in high concentration with retroviruses.

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

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

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

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