Comparison of phosphorylation of two polyoma virus middle T antigens in vivo and in vitro.

Two species of polyoma virus middle T antigen were detected in both lytically infected and transformed cells by in vitro kinase assay of immunoprecipitates. A minor species with an apparent molecular weight of 58,000 (58K) represented less than 10% of the total middle T protein. This species was roughly 10 times more active as a phosphate acceptor than was the predominant 56K form. Partial proteolytic mapping experiments showed that the same site was phosphorylated in both species. Mapping of the middle T antigens from a series of deletion mutants suggested that the major site of phosphorylation is tyrosine residue 315. Phosphorylation occurred on both middle T species in vivo, involving sites predominantly other than the tyrosine labeled in vitro. The 56K and 58K middle T forms differed from each other in their in vivo phosphorylation patterns. Some phosphate was incorporated into the 58K species in a region of the molecule to which at least part of the apparent molecular weight different could be mapped. hr-t mutant NG-59, which codes for a slightly altered middle T, produced only a single species (56K) which was inactive in the in vitro kinase reaction. Moreover, no 58K species appeared in vivo with this mutant. hr-t mutants are therefore defective in both aspects of phosphorylation. Phenotypically normal revertant cells of a polyoma transformed line failed to express any middle T antigens or associated kinase activity.     

An activity phosphorylating tyrosine in polyoma T antigen immunoprecipitates.

Polyoma T antigen immunoprecipitates contain a protein kinase-like activity which preferentially phosphorylates material of 50-60,000 daltons molecular weight. Phosphorylation is not diminished in extracts of polyoma tsA mutant-infected cells shifted to the nonpermissive temperature late in infection, conditions which inactivate the large T antigen. Phosphorylation is reduced or absent in cells infected with polyoma host range nontransforming (hr-t) mutants, which have defective small and medium T antigens. The major acceptor of phosphate is not the heavy chain of immunoglobulin, but appears to be the polyoma medium T antigen. The large T antigen is also phosphorylated, but usually to a lower specific activity. In terms of acid and alkali sensitivity and electrophoretic and chromatographic mobility in one and two dimensions, the phosphorylated residue behaves identically to phosphotyrosine and differently than phosphorylated serine, threonine, lysine and histidine.     

Antibody to the nonapeptide Glu-Glu-Glu-Glu-Tyr-Met-Pro-Met-Glu is specific for polyoma middle T antigen and inhibits in vitro kinase activity

Middle T antigen of polyoma virus has an associated tyrosine kinase activity which phosphorylates tyrosine residue 315 on middle T in immunoprecipitates. A peptide representing the sequence of middle T from residue 311 to 319 has been synthesized. This peptide acts as a weak inhibitor of the kinase reaction. An antiserum has been raised against this peptide after conjugation to bovine serum albumin. The antibody is middle T-specific. Middle T antigen precipitated by this serum is largely inactive in the kinase reaction. Dissociation of the immune complex with peptide releases middle T in a kinase-active form.     

Inhibition of polyoma virus middle T antigen-associated tyrosyl kinase activity by N-ethylmaleimide

The middle T antigen (MT Ag) encoded by polyoma virus has an associated protein kinase activity which transfers a phosphoryl group from ATP or GTP to a tyrosine residue on MT Ag in immunoprecipitates formed between polyoma virus-infected or transformed cell extracts and serum from animals bearing polyoma-induced tumors. Incubation of such immunoprecipitates or polyoma-transformed cell extracts prior to immunoprecipitation with the sulfhydryl reagent, N-ethylmaleimide (NEM), resulted in a significant inhibition of MT Ag-associated kinase activity. Inactivation of this enzyme activity by NEM was found to be dependent upon the incubation pH, time of incubation, and NEM concentration. ATP, GTP, and ADP in the presence of Mg2+ were found to decrease the rate of NEM-mediated inactivation of MT Ag-associated kinase activity, while CTP and UTP did not detectably alter the rate of enzyme inhibition by NEM. These results suggest that the MT Ag-associated kinase possesses at least one NEM-sensitive sulfhydryl group essential for phosphotransferase activity which may be present at or near the enzyme catalytic site.     

An antibody to a synthetic peptide recognizes polyomavirus middle-T antigen and reveals multiple in vitro tyrosine phosphorylation sites.

Antibodies were raised against three synthetic peptides corresponding to sequences surrounding tyrosine 315, a putative in vitro phosphorylation site in polyomavirus middle-T antigen. Only one of the peptides (called C and corresponding to residues 311 to 330) elicited antibodies that recognized middle-T efficiently. Middle-T present in immunoprecipitates formed with purified anti-C serum still accepted phosphate on tyrosine in an in vitro kinase reaction. This implies that tyrosines other than 315 and 322 that lie within the antibody binding region are phosphorylated under these conditions. This conclusion was supported by the altered partial V8 proteolysis fingerprint of the labeled middle-T. Two-dimensional tryptic fingerprint analysis of 32P-labeled middle-T showed that several tryptic peptides identified as including tyrosine 315 and 322 were missing from middle-T labeled in anti-C immunoprecipitates compared with middle-T labeled in immunoprecipitates made by using anti-tumor cell serum. However, one major labeled peptide remained. This peptide was also present in fingerprints of 32P-labeled middle-T coded by M45, dl23, pAS131, and dl1013, but a peptide with altered mobility was present in dl8 middle-T. This identified the peptide as including tyrosine 250. We deduce from these data that (i) the presence of the antibody against peptide C inhibits phosphorylation of tyrosines 315 and 322; (ii) middle-T labeled in the kinase reaction after immunoprecipitation with anti-C serum is phosphorylated on tyrosine 250; and (iii) when anti-tumor cell serum is used in the in vitro kinase reaction, middle-T is phosphorylated at multiple sites, including residues 250, 315, and 322.     

Phosphorylation of polyoma T antigens.

The T antigens of polyoma virus have been examined for phosphorylation in vivo and associated protein kinase activities in vitro. The 100K "large" T antigen is the major phosphoprotein among the T antigen species in vivo as determined by labeling virus-infected cells with 32P-orthophosphate. Hr-t mutants show normal phosphorylation of their 100K T antigens. The wild-type 56K plasma membrane-associated "middle" T antigen is also phosphorylated in the cell, but to a lesser extent than the 100K; this low level phosphorylation is also observed in the presumably altered 56K protein induced by hr-t mutant NG59 and in the 50K truncated "middle" T of hr-t mutant SD15. Addition of dibutyryl cyclic AMP to the medium does not affect labeling of either large or middle T antigens in wild-type- or mutant-infected cells. Thus no differences are observed in T antigen phosphorylation in vivo between wild-type virus and hr-t mutants. Hr-t mutants are defective in a protein kinase activity assayed in vitro by adding gamma-32P-ATP to T antigen immunoprecipitates. In the case of wild-type virus, the 56K protein is the major phosphate acceptor in the in vitro kinase reaction, with a somewhat lower level of phosphorylation observed in the 100K band. Hr-t mutants NG59 and SD15 show no labeling of the altered 56K or 50K, respectively, but do show detectable levels of 32P in the 100K bands. A wild-type virus carrying a small deletion affecting the 100K and 56k bands shows a normal level of kinase activity associated with the truncated T antigens. Ts-a mutants appear to be normal with respect to the middle T antigen-associated kinase. Photoaffinity labeling of infected cell extracts with 8-azido cyclic AMP shows that the two major classes of regulatory subunits of cyclic AMP-dependent protein kinases are present in the immunoprecipitates. Phosphorylation of histone H1 occurs when this substrate is added to immunoprecipitates of either mock-infected or virus-infected cells, again demonstrating the presence of cellular kinases. Further experiments will be required to determine whether the middle T antigen of polyoma virus is itself a protein kinase or simply a substrate for one or more cellular kinases.     

An 81 kd protein complexed with middle T antigen and pp60c-src: a possible phosphatidylinositol kinase

It has previously been shown that a proportion of middle T antigen molecules exist in a stable complex with pp60c-src. Here we show that there appears to be a third component to the complex, a protein of molecular mass 81 kd (p81). p81 was phosphorylated exclusively on tyrosine residues in kinase assays performed using immunoprecipitates from polyoma virus-transformed cells and antibodies to both middle T and pp60c-src, and was also detected when immunoprecipitates were made from lysates of 32P-labeled cells. p81 was bound to middle T and pp60c-src in cell lines containing transforming mutants of middle T, but not (in phosphorylated form) to all nontransforming mutants. A parallel investigation of phosphatidylinositol kinase activity in immune complexes containing these middle T mutants revealed a complete coincidence between the presence of p81 and phosphatidylinositol kinase activity. We therefore suggest that p81 is a phosphatidylinositol kinase.     

Significance of the gastrin homology and surrounding sequences in polyomavirus middle T antigen for cell transformation.

Deletion of residues 305 to 327 of polyomavirus middle T antigen, including the (Glu)6-Tyr-315 sequence that is a preferred site of phosphorylation in vitro by pp60c-src, markedly altered viral transformation of rat cells. The efficiency of transformation by the deletion mutant depended on how it was introduced into cells, and the resulting transformants displayed limited growth rates in monolayer and in suspension. Substitution of the polyomavirus residues 305 to 327 with a homologous region (containing [Glu]5-Ala-Tyr) from porcine gastrin did not restore wild-type transforming activity. These mutant middle T antigens interacted with pp60c-src and were phosphorylated in vitro. Thus, although a sequence of consecutive glutamic acid residues followed by a tyrosine is a dominant structural element which strongly influences the physical properties of middle T antigen, its presence did not ensure the biological activity of the protein. Other elements in this region of middle T antigen also contributed substantially to the transforming capacity of polyomavirus.     

Cross-reactivity of antibodies against synthetic peptides

Antiserum against the synthetic peptide Lys-Arg-Ser-Arg-His-Phe, corresponding to the carboxy terminus of polyoma virus medium tumor antigen (medium T antigen), immunoprecipitates a protein of 36,000 daltons from polyoma virus-infected and uninfected cell extracts treated with the sulfhydryl group reagent N-ethyl-maleimide. This protein appears to share an antigenic determinant with medium T antigen that is normally buried inside the protein or covered up by another protein or cellular structure. The two-dimensional tryptic fingerprints of the 36K protein and of medium T antigen are apparently unrelated to each other. Antiserum against the octapeptide Ac-Met-Asp-Lys-Val-Leu-Asn-Arg-Tyr, including the amino-terminal heptapeptide sequence of the simian virus 40 (SV40) large tumor (T) and small T antigens, cross-reacts with polyoma virus large T antigen, which has an identical amino-terminal heptapeptide sequence except that Lys is replaced by Arg and Asn by Ser. The problem of cross-reactivities of antipeptide sera is discussed.     

N-terminal amino acid sequences of the polyoma middle-size T antigen are important for protein kinase activity and cell transformation.

We constructed deletion mutations which removed N-terminal coding sequences of various lengths from a cloned polyoma middle-size T antigen (MT antigen) gene. We introduced the MT antigen genes into a simian virus 40 expression vector so that they were expressed at high levels under the control of the simian virus 40 late promoter in COS-1 cells. The deletion mutant genes synthesized truncated MT antigens whose size was consistent with the deletion of either 70 or 106 amino acids from N termini, owing to initiation of translation at internal methionine codons in the MT antigen-coding region. The truncated MT antigens were found in cell membrane fractions but failed to show MT antigen-associated protein kinase activity. The cloned deletion mutant DNAs failed to transform rat F2408 or mouse NIH 3T3 cells. Therefore, N-terminal amino acid sequences of the polyoma MT antigen, as well as C-terminal sequences, are important for protein kinase activity and cell transformation.     

Phosphoinositide kinase activity and transformation

We have used the DNA tumor virus polyoma as a model system to examine whether the phosphatidylinositol (PI) turnover pathway is a critical target for transforming gene products. Polyoma-infected cells show elevated levels of polyphosphoinositides and polyphosphoinositols, and a PI kinase activity is associated with middle T antigen, a transforming gene product of polyoma virus. In anti-T immunoprecipitates from polyoma-infected or -transformed cells, comparisons of wild-type and polyoma mutants defective for transformation show a strong correlation between middle T-associated PI kinase activity and transforming ability. Middle T has previously been found to associate at the plasma membrane with pp60 c-src and to activate it as a tyrosine kinase. c-src itself does not appear to phosphorylate PI; however, the middle T/pp60 c-src tyrosine kinase activity may be important for activation of PI kinase. Ammonium orthovanadate, a tyrosine phosphatase inhibitor, elevates the middle T/pp60 c-src-associated PI kinase activity. We propose that middle T/pp60 c-src activates a PI kinase and modulates PI turnover in vivo by tyrosine phosphorylation.     

Expression of biologically active middle T antigen of polyoma virus from recombinant baculoviruses.

Two different recombinant baculoviruses have been generated for expressing the middle T antigen (MT) of polyoma virus in insect (Sf9) cells. One (pAcI-PyMT) produces moderate levels of MT and the other (pVL-PyMT) high levels. Indirect immunofluorescence and cellular fractionation studies with pAcI-PyMT infected Sf9 cells give results similar to those observed with wild type polyoma virus infected mouse cells, and show MT to be mainly associated with cytoplasmic membranes in the insect cell. In the latter, a sub-population of MT is phosphorylated in in vitro protein kinase assays. The yields of MT from pVL-PyMT infected cells are high enough to suggest that this protein can now be produced by this method in sufficient amounts for definitive biochemical and crystallographic analyses.     

Protein kinase C promotes the phosphorylation of immunoprecipitated middle T antigen from polyoma-transformed cells

Stimulation of protein kinase C in polyoma virus-transformed cells increased the phosphorylation of tyrosine residues of the viral middle T (mT) antigen in mT:pp60c-src complexes precipitated by anti-mT antibodies. This increase might have been due to a stimulation of the complex's pp60c-src tyrosine kinase activity or to an increased ability of the mT protein to be phosphorylated by pp60c-src. These observations suggest that cellular protein kinase C might control the ability of polyoma virus to transform its host cell.     

Characterization of viable mutants of polyomavirus cold sensitive for maintenance of cell transformation

We mutagenized a cloned fragment of polyoma DNA encoding portions of the middle size (MT) and large T antigens. We regenerated infectious viral genomes containing the mutagenized DNA and tested their transforming ability at 32 and 39 degrees C. We isolated three nontransforming mutants and two mutants which were cold sensitive for the maintenance of cell transformation. The nontransforming mutants contained amber termination codons in the reading frame for the MT antigen. They synthesized truncated MT antigens which lacked MT-associated protein kinase activity. The cold-sensitive mutants synthesized MT antigens indistinguishable from wild type with regard to size, stability at 32 and 39 degrees C, intracellular location, and associated protein kinase activity. One of the mutants was shown by nucleotide sequence analysis to contain a single amino acid change in the MT antigen, located two residues upstream from the C-terminal hydrophobic region, and no changes in the large T antigen. The other mutant contained two amino acid changes in the MT antigen and two amino acid changes in the large T antigen.     

Common elements in growth factor stimulation and oncogenic transformation: 85 kd phosphoprotein and phosphatidylinositol kinase activity

The phosphorylation of proteins on tyrosine in vivo and in vitro was examined in 3T3 cells stimulated by platelet-derived growth factor (PDGF) and transformed by polyoma middle T antigen (MTAg) by using an antibody directed against phosphotyrosine (P-tyr). Two common events were observed upon PDGF stimulation or MTAg transformation of cells: the appearance in the immunoprecipitates of an 85 kd phosphoprotein, and increased phosphatidylinositol (PI) kinase activity. In PDGF-stimulated cells, the 85 kd phosphoprotein and PI kinase activity appeared rapidly, within 1 min of growth factor addition. The PI kinase activity and 85 kd phosphorylation were also increased in anti-P-tyr immunoprecipitates from cells transformed by v-fms and v-sis, but not by SV40 T antigen. The presence of the tyrosine-phosphorylated 85 kd protein correlated with PI kinase activity during several purification steps. These results suggest that the 85 kd phosphoprotein, a putative PI kinase, is a substrate for both the PDGF receptor and MTAg/pp60c-src tyrosine kinase activities.     

Expression of polyoma early gene products in E. coli.

The three products of the early region of polyoma virus have been cloned for expression in E. coli using the Tac promoter. Although the identical promoter and ribosome binding site are used in each final construction, the observed level of protein expression is different for each protein. While plasmids expressing wild type T antigens as well as a plasmid expressing the truncated Py-1387T middle T antigen lacking the membrane-anchoring sequence give rise to synthesis of proteins readily detectible by 35S-methionine labeling and immunoprecipitation, only small T and the middle T of Py-1387T are made in amounts sufficient for ready detection in total cell protein. Unlike middle T expressed in animal cells, middle T produced in E. coli is not detectibly phosphorylated. Further, the E. coli protein lacks tyrosine kinase activity.     

Mapping of phosphorylation sites in polyomavirus large T antigen.

The phosphorylation sites of polyomavirus large T antigen from infected or transformed cells were investigated. Tryptic digestion of large T antigen from infected, 32Pi-labeled cells revealed seven major phosphopeptides. Five of these were phosphorylated only at serine residues, and two were phosphorylated at serine and threonine residues. The overall ratio of phosphoserine to phosphothreonine was 6:1. The transformed cell line B4 expressed two polyomavirus-specific phosphoproteins: large T antigen, which was only weakly phosphorylated, and a truncated form of large T antigen of 34,000 molecular weight which was heavily phosphorylated. Both showed phosphorylation patterns similar to that of large T antigen from infected cells. Peptide analyses of large T antigens encoded by the deletion mutants dl8 and dl23 or of specific fragments of wild-type large T antigen indicated that the phosphorylation sites are located in an amino-terminal region upstream of residue 194. The amino acid composition of the phosphopeptides as revealed by differential labeling with various amino acids indicated that several phosphopeptides contain overlapping sequences and that all phosphorylation sites are located in four tryptic peptides derived from a region between Met71 and Arg191. Two of the potential phosphorylation sites were identified as Ser81 and Thr187. The possible role of this modification of large T antigen is discussed.     

Phosphorylation of middle T by pp60c-src: a switch for binding of phosphatidylinositol 3-kinase and optimal tumorigenesis

Substitution of phenylalanine for tyrosine 315 of the polyoma virus middle T (mT) protein lowers the incidence and limits the spectrum of tumors induced following inoculation of the virus into newborn mice. This substitution removes the major site of phosphorylation by pp60c-src without altering the ability of mT to associate with or to activate pp60c-src. The mutant mT fails to show binding of a phosphatidylinositol 3-kinase (Ptdlns 3-kinase) activity that is normally present in wild-type mT complexes. Furthermore, an anti-peptide antiserum that specifically recognizes mT lacking phosphate at tyrosine 315 precipitates binary (mT-pp60c-src) but not ternary (mT-pp60c-src-Ptdlns 3-kinase) complexes from wild-type infected cell extracts. Reprecipitation with either anti-pp60c-src or anti-mT serum brings down ternary complexes containing mT phosphorylated on tyrosine 315. Phosphorylation of mT by pp60c-src in vivo is therefore a critical event for binding of Ptdlns 3-kinase and for expression of the full tumorigenic potential of the virus.     

Location of sites in human lipocortin I that are phosphorylated by protein tyrosine kinases and protein kinases A and C

Lipocortin I is a 39-kilodalton membrane-associated protein that in A431 cells is phosphorylated on tyrosine in response to epidermal growth factor (EGF). We have used recombinant human lipocortin I as a substrate for several protein kinases and identified phosphorylated residues by a combination of peptide mapping and sequence analysis. Lipocortin I was phosphorylated near the amino terminus at Tyr-21 by recombinant pp60c-src. The same tyrosine residue was phosphorylated by polyoma middle T/pp60c-src complex, by recombinant pp50v-abl, and with A431 cell membranes by the EGF receptor/kinase. The primary site of phosphorylation by protein kinase C was also near the amino terminus at Ser-27. The major site of phosphorylation by adenosine cyclic 3',5'-phosphate dependent protein kinase was on the carboxy-terminal half of the molecule at Thr-216. These sites are compared to the phosphorylation sites previously located in the structurally related protein lipocortin II.     

Characterization of middle T antigen expressed by using an adenovirus expression system.

The adenovirus Ad5(pymT) has been used to express middle T antigen at very high levels in 293 cells. The middle T antigen produced was localized to membranes and was modified in the same way as that expressed in polyoma virus-infected mouse cells. It was phosphorylated in vivo on serine residues and in vitro on tyrosine residues. The in vivo phosphorylations occurred between residues 223 and 275. The middle T antigen encoded by A d5(pymT) was phosphorylated in vitro in a complex with human pp60c-src. Interestingly, the extreme overexpression of middle T antigen did not cause a parallel increase in the amount of complex; most of the pp60c-src remained unassociated. Immunoaffinity purification resulted in approximately 100 micrograms of middle T antigen from a 100-mm tissue culture dish. Several cell proteins copurified with the Ad5(pymT)-derived middle T antigen. Two of these, the 74- and 63-kilodalton species, are of particular interest because they were also purified from mouse tumors expressing middle T antigen.