Altered phosphorylation of free and bound forms of monkey p53 and simian virus 40 large T antigen during lytic infection.

We have identified the phosphorylation sites in monkey p53 as well as specific changes in the phosphorylation state of free and complexed forms of simian virus 40 (SV40) large T antigen (T) and monkey p53 isolate from SV40 lytically infected CV1 cells. Phosphopeptide analyses of free T and p53 (To and p53o) and complexed T and p53 (T+ and p53+) fractions indicated several quantitative increases in the specific phosphorylation of complexed forms of both proteins. The N terminus of monkey p53+ is phosphorylated at Ser-9, Ser-15, Ser-20, either Ser-33 or Ser-37, and at least one of Ser-90 to Ser-99. The C-terminal sites are Ser-315 and Ser-392. On comparing p53+ with p53o, we found that labeling of the two N-terminal phosphotryptic peptides encompassing residues 1 to 20 and 33 to 101 was increased fivefold and that Ser-315 was sevenfold more labeled than was Ser-392. When T+ was compared with To, the N-terminal peptide containing phosphorylation sites Ser-106 through Thr-124 was twofold more labeled, the peptide containing Ser-657 through Ser-679 was sixfold more labeled and contained up to four phosphorylated serine residues, and Ser-639 and Thr-701 appeared unchanged. Overall, T+ molecules appeared to contain 3.5 mol more of labeled phosphate than did To, with the N-terminal peptide appearing fully phosphorylated. The phosphopeptide patterns obtained for lytic T+ and To fractions were nearly identical to those found for wild-type SV40 T (stably complexed with mouse p53) and mutant 5080 T (defective for p53 binding) expressed in transformed C3H10T1/2 cells (L. Tack, C. Cartwright, J. Wright, A. Srinivasan, W. Eckhart, K. Peden, and J. Pipas, J. Virol. 63:3362-3367, 1989). These results indicate that increases in specific phosphorylation sites in both T+ and p53+ correlate with the association of T with p53. The enhanced phosphorylation state may be a consequence of complex formation between T and p53 or reflect an increased affinity of p53 for highly phosphorylated forms of T.

Infection of CV1 cells expressing the polyoma virus middle T antigen or the SV40 agnogene product with simian virus 40 host-range mutants.

SV40 viruses bearing mutations at the carboxy-terminus of large T antigen exhibit a host-range phenotype: such viruses are able to grow in BSC monkey kidney cells at 37 degrees C, but give at least 10,000-fold lower yields than wild type virus in BSC cells at 32 degrees C or in CV1 monkey kidney cells at either temperature. The block to infection in the nonpermissive cell type occurs after the onset of viral DNA replication. Infectious progeny virions are produced at very low efficiency. Although capsid proteins are synthesized at decreased levels, this does not account for the magnitude of the defect. Presumably some step of virion assembly or maturation is affected in these mutants. We have previously reported that the viral agnogene product, a protein thought to be involved in viral assembly or release, fails to accumulate in CV1 cells infected with host-range mutants. In polyoma virus the middle T antigen plays a role in virion maturation by influencing the phosphorylation of capsid proteins. In this communication we show that host-range mutants fail to undergo productive infection of CV1 cells expressing middle T antigen. These mutants do form plaques on an agnoprotein-expressing cell line. However, the agnoprotein does not seem to act by correcting the mutational block but rather increases the efficiency of plaque formation.

A DNA replication-positive mutant of simian virus 40 that is defective for transformation and the production of infectious virions.

Simian virus 40 (SV40) mutant 5002 carries base pair substitutions of C-5109----T and C-5082----T. These mutations lie in a region of the genome that encodes amino acids common to the large and small viral tumor antigens (T and t antigens, respectively) and result in amino acid substitutions of Leu-19----Phe and Pro-28----Ser. In contrast to wild-type SV40, which produces large plaques that are clearly visible 8 days postinfection, mutant 5002 is defective for productive infection, producing tiny plaques that arise at around 21 days postinfection. However, 5002 is capable of replicating viral DNA and producing normal amounts of capsid proteins, indicating that the mutations alter an activity of T antigen that is required subsequent to DNA synthesis, such as maturation, viral assembly, or release of virions. The mutant T antigen has normal ATPase activity, is phosphorylated in a manner that is indistinguishable from that of the wild-type T antigen, and retains the ability to oligomerize. 5002 complements mutants defective in T antigen host range-adenovirus helper function for productive infection. Thus, T antigen encodes two activities that affect at least two different steps in viral infection other than DNA replication, one inactivated by mutations in the host range-adenovirus helper domain and one inactivated by the mutations present in 5002. The 5002-encoded T antigen is also defective for transformation of REF52 cells when expressed from the normal SV40 early promoter, although this defect can be partially overcome by expressing the protein from stronger promoters.

Properties of a simian virus 40 mutant T antigen substituted in the hydrophobic region: defective ATPase and oligomerization activities and altered phosphorylation accompany an inability to complex with cellular p53.

We have analyzed the biochemical properties of a nonviable simian virus 40 (SV40) mutant encoding a large T antigen (T) bearing an amino acid substitution (Pro-584-Leu) in its hydrophobic region. Mutant 5080 has an altered cell type specificity for transformation (transforming mouse C3H10T1/2 but not rat REF52 cells), is defective for viral DNA replication, and encodes a T that is unable to form a complex with the cellular p53 protein (K. Peden, A. Srinivasan, J. Farber, and J. Pipas, Virology 168:13-21, 1989). In this article, we show that 5080-transformed C3H10T1/2 cell lines express an altered T that is synthesized at a significantly higher rate but with a shorter half-life than normal T from wild-type SV40-transformed cells. 5080 T did not oligomerize beyond 5 to 10S in size compared with normal T, which oligomerized predominantly to 14 to 20S species. In addition, the 5080 T complex had significantly decreased ATPase activity and had a 10-fold-lower level of in vivo phosphorylation compared with that of normal T. Two-dimensional phosphopeptide analysis indicated several changes in the specific 32P labeling pattern, with altered phosphorylation occurring at both termini of the mutant protein compared with the wild-type T. Loss of p53 binding is therefore concomitant with changes in ATPase activity, oligomerization, stability, and in vivo phosphorylation of T and can be correlated with defective replication and restricted transformation functions. That so many biochemical changes are associated with a single substitution in the hydrophobic region of T is consistent with its importance in regulating higher-order structural and functional relationships in SV40 T.

Alterations in the structure of new and old forms of simian virus 40 large T antigen (T) defined by age-dependent epitope changes: new T is the same as ATPase-active T.

The reactivity of simian virus 40 large T antigen labeled under pulse-chase conditions towards 22 antibodies was measured. Changes in epitope reactivity occurred in several domains of T as it matured, defining major structural alterations that distinguished mature from new molecules. New T reacted best with the same antibodies that bind and inhibit ATPase-active T. These antibodies thus can distinguish new T as a distinct structural and functional form.

The p53 complex from monkey cells modulates the biochemical activities of simian virus 40 large T antigen.

We have compared the ATPase, DNA-binding, and helicase activities of free simian virus 40 (SV40) large T antigen (To) and T antigen complexed with cellular p53 (T+p53). Each activity is essential for productive viral infection. The T+p53 and To fractions were prepared by sequential immunosorption of infected monkey cells with monoclonal antibodies specific for p53 and T antigen. The immune-complexed T fractions were then assayed in parallel. For ATP hydrolysis, the Vmax for T+p53 was 143 nmol of ADP per min per mg of protein, or 18-fold greater than for To. ATP had no effect on the stability of the T+p53 complex. The T+p53 complex was significantly more active than To in hydrolyzing dATP, dGTP, GTP, and UTP. Of the nucleotide substrates tested, the greatest relative increase (T+p53/To) was in hydrolyzing dGTP and GTP. In DNase footprinting assays performed under replication conditions, the T+p53 complex protected regions I, II, and III of origin DNA while equivalent amounts of To protected only regions I and II. Region III is known to contribute to the efficiency of DNA replication and contains the SP1-binding sites of the early viral promoter. The T+p53 fraction was also a more efficient helicase than To, especially with a GC-rich primer and template. Thus, the T+p53 complex has enhanced ATPase, GTPase, DNA-binding, and helicase activities. These findings imply that complex formation between cellular monkey p53 and SV40 T antigen modulates a number of essential activities of T in SV40 productive infection.

Characterization of simian virus 40 large T antigen by using different monoclonal antibodies: T-p53 complexes are preferentially ATPase active and adenylylated.

We used 21 monoclonal antibodies (PAbs 100 to 117, 405, 419, and KT3) specific for different determinants in simian virus 40 (SV40) large T antigen (T) and one antibody specific for p53 that coprecipitates T complexed with p53 (T-p53) to analyze T in SV40-infected CV1 cells. We measured the ATPase specific activity, extent of adenylylation, and p53 content of T precipitated by antibodies directed against the N-terminal region I (0.65 to 0.62 map units), the midregion III (0.43 to 0.28 map units) containing both the ATPase- and nucleotide-binding sites, and the C-terminal region IV (0.28 to 0.17 map units) of T. Lytic T appeared to exist in three different forms with respect to p53 binding and ATPase activity. The most ATPase-active form of T was that precipitated by PAb 122. This T-p53 complex contained only 6% of the total T but contributed 35% of the ATPase activity, on average. Free p53 isolated from 3T6, Ann-1, or L929 cells had no apparent ATPase activity. A second form of T precipitated by several antibodies had little associated p53 but appreciable ATPase activity, accounting for 15 to 20% of total T and 60 to 70% of the ATPase activity. The rest of T constituted the third form and was also depleted in p53 but had a decreased ATPase specific activity. Thus, the remaining 75 to 80% of T had 15 to 20% of the ATPase specific activity. Antibodies specific for region III precipitated T with both altered ATPase activity and altered amounts of bound p53. PAbs 104 and 114 reacted with ATPase-active T but inhibited ADP hydrolysis, suggesting that they were inactivating antibodies. T that was preferentially adenylylated in vitro corresponded to T that was also preferentially ATPase active. T bound to p53 was adenylylated to a higher specific activity than total T. In addition, p53 itself was significantly adenylylated under these conditions. The results suggest that ATPase activity and p53 binding are structurally and functionally related and that p53 alters biochemical activities of T and plays a role in productive infection.

Two major replicating simian virus 40 chromosome classes. Synchronous replication fork movement is associated with bound large T antigen during elongation.

We have analyzed the asynchronous progression of replication forks through the early (E) and late (L) gene sides in bidirectionally replicating SV40 chromosomes during lytic infection. By cutting purified replicating DNA with an appropriate single-site restriction endonuclease and measuring the contour lengths of replicated and unreplicated segments by electron microscopy, the positions of the two replication forks in each elongating intermediate were determined. Our results indicate that there are at least two major classes of replicating SV40 chromosomes which differ in their relative rate of E and L fork movement, the presence or absence of bound SV40 large T antigen during elongation, and the termination region utilized. These two classes also have altered apparent start sites for initiating bidirectional replication, flanking either side of core ori. The largest group (67%) replicated synchronously was associated with T antigen during elongation, appeared to initiate bidirectional elongation at nucleotide 5203 or 41 base pairs (bp) toward the E side of 0/5243, at the junction of T binding site I and ori, and terminated at the typical region centered at 0.5 map units. A second group (24%) replicated asynchronously with the L fork moving 3 times faster than the E fork, was not associated with T antigen during elongation, and terminated at a broad region centered at 0.73 map units. This group appeared to initiate at nucleotide 29 at the junction of the AT-rich region of ori, T binding site I, and the start of the 21-bp repeated transcriptional control sequences. A third group (9%) appeared to initiate at nucleotide 5148 or 95 bp to the E side of 0/5243 and replicated asynchronously preferentially on the E side at early times. However, this group is related to the synchronous class in that it contains bound T antigen and both forks move synchronously past 30% elongation, terminating at the same region. The association of T antigen with synchronous but not asynchronous DNA molecules indicates that T functions in regulating fork movement during elongation. A synchronization role implies that both forks are closely associated with one another in replicating molecules with bound T. Replicating molecules lacking T not only elongated highly asynchronously but preferential fork progression occurred almost exclusively on the L side. The ori region in asynchronous compared to synchronous intermediates was differentially sensitive to BglI digestion, indicating that nuclease digestion can distinguish between different populations of replicating molecules.(ABSTRACT TRUNCATED AT 400 WORDS)

Free and viral chromosome-bound simian virus 40 T antigen: changes in reactivity of specific antigenic determinants during lytic infection.

Simian virus 40 (SV40) large T antigen (TAg), both free and bound to mature 70S and replicating 90S SV40 chromosomes, was prepared from lytically infected cells. The relative reactivity of the different TAg-containing fractions toward 10 monoclonal antibodies directed against three different regions in SV40 TAg and toward an antibody against the p53 protein was measured. The results for free TAg indicated that all of the determinants in both the amino-terminal (0.65 to 0.62 map units) and carboxy-terminal (0.28 to 0.17 map units) regions were highly reactive, whereas all five determinants located between 0.43 and 0.28 map units in the midregion of TAg were poorly reactive. For TAg bound to replicating chromosomes, all but one of the antibodies specific for TAg were highly reactive. Thus, antigenic sites in the middle of TAg, the region important for nucleotide binding and ATP hydrolysis (an activity required for viral DNA replication), were more accessible in TAg-replicating DNA complexes. As replicating molecules matured into 70S chromosomes, three or more determinants at different locations in TAg bound to chromatin became two- to fivefold less reactive, indicating other changes in TAg structure. Overall, at least nine different antigenic determinants in the TAg molecule were identified. Anti-p53 was reactive with about 10% of the free TAg and the same amount of SV40 chromosomes of all ages, suggesting that p53-TAg complexes are not preferentially associated with either replicating or mature viral chromosomes. When the reactivity of both mature and replicating labeled SV40 chromosomes with polyclonal tumor anti-T was measured as a function of time after purification, TAg bound to mature chromosomes appeared to dissociate about fourfold faster than that bound to replicating chromosomes. The relative amount of TAg in various subcellular fractions was measured by an enzyme-linked immunosorbent assay. Approximately 1.3% of the total TAg was estimated to be associated with SV40 chromosomes in infected cells. Based on the relative amounts of TAg and viral DNA in the 70S and 90S fractions, replicating chromosome-TAg complexes were estimated to bind 4.8 times more TAg per DNA molecule, on the average, than mature chromosome-TAg complexes. Together, these results are consistent with major differences in TAg structure when free and associated with replicating and nonreplicating SV40 chromosomes.

Both trans-acting factors and chromatin structure are involved in the regulation of transcription from the early and late promoters in simian virus 40 chromosomes.

We isolated simian virus 40 (SV40) chromosomes from lytically infected CV-1 cells at various times during the late phase and transcribed them in vitro with either whole-cell or nuclear extracts of HeLa cells. The late promoter was 3- to 10-fold more active than the early promoter. With bare SV40 DNA templates, the early promoter was up to 10-fold stronger than the late promoter. The relative strengths of the early and late promoters on SV40 chromosomes were essentially independent of template concentration or length of the replicative phase of the infection. When monoclonal antibodies or antisera against T antigen (T Ag) were added to SV40 chromosomes or when T Ag, both free and chromatin bound, was removed by immunoprecipitation with anti-T, the activity of the late promoter remained essentially unchanged. Washing with 0.4 M NaCl removed T Ag from more than 90% of the mature chromosomes associated with T Ag. Transcription from the late promoter still predominated in the salt-washed T Ag-depleted chromosomes, even though there was a marked increase in early promoter activity. The depression of the early promoter could be reversed by adding the T Ag-containing extract back to the depleted chromosomes. Extraction of SV40 chromosomes with 1.5 M NaCl resulted in a decrease in the activity of the late promoter and a further increase in the activity of the early promoter so that the relative amounts of early and late RNA synthesized were similar to those for bare SV40 DNA templates. Late RNA synthesis from bare SV40 DNA templates was stimulated by high-speed supernatants prepared from nuclear extracts of SV40-infected cells but not from those of uninfected cells. Pretreatment of the supernatants with anti-T did not alter the result. Our findings indicate that the activity of the early and late SV40 promoters is regulated by at least two different mechanisms at the chromosomal level. One is mediated by a subclass of T Ag bound to SV40 chromosomes which represses early SV40 transcription but has no effect on late transcription. A second level of regulation, involving a tightly bound trans-acting chromosomal factor and a stable nucleoprotein structure, favors the late promoter over the early promoter by up to 10-fold.

Analysis of simian virus 40 chromosome-T-antigen complexes: T-antigen is preferentially associated with early replicating DNA intermediates.

The fraction and DNA composition of simian virus 40 chromosomes that were complexed with large T-antigens (T-Ag) were determined at the peak of viral DNA replication. Simian virus 40 chromatin containing radiolabeled DNA was extracted by the hypotonic method of Su and DePamphilis (Proc. Natl. Acad. Sci. U.S.A. 73:3466-3470, 1976) and then fractionated by sucrose gradient sedimentation into replicating (90S) and mature (70S) chromosomes. Viral chromosomes containing T-Ag were isolated by immunoprecipitation with saturating amounts of either an anti-T-Ag monoclonal antibody or an anti-T-Ag hamster serum under conditions that specifically precipitated T-Ag protein from cytosol extracts. An average of 10% of the uniformly labeled DNA in the 90S pool and 7.5% in the 70S pool was specifically precipitated, demonstrating that under these conditions immunologically reactive T-Ag was tightly bound to only 8% of the total viral chromosomes. In contrast, simian virus 40 replicating intermediates (RI) represented only 1.2% of the viral DNA, but most of these molecules were associated with T-Ag. At the shortest pulse-labeling periods, an average of 72 +/- 18% of the radiolabeled DNA in 90S chromosomes could be immunoprecipitated, and this value rapidly decreased as the labeling period was increased. Electron microscopic analysis of the DNA before and after precipitation revealed that about 55% of the 90S chromosomal RI and 72% of the total RI from both pools were specifically bound to T-Ag. Comparison of the extent of replication with the fraction of RI precipitated revealed a strong selection for early replicating DNA intermediates. Essentially all of the RI in the 70S chromosomes were less than 30% replicated and were precipitated with anti-T-Ag monoclonal antibody or hamster antiserum. An average of 88% of the 90S chromosomal RI which were from 5 to 75% replicated were immunoprecipitated, but the proportion of RI associated with T-Ag rapidly decreased as replication proceeded beyond 70% completion. By the time sibling chromosomes had separated, only 3% of the newly replicated catenated dimers in the 90S pool (<1% of the dimers in both pools) were associated with T-Ag. Measurements of the fraction of radiolabeled DNA in each quarter of the genome confirmed that T-Ag was preferentially associated with newly initiated molecules in which the nascent DNA was nearest the origin of replication. These results are consistent with a specific requirement for the binding of T-Ag to viral chromosomes to initiate DNA replication, and they also demonstrate that T-Ag does not immediately dissociate from chromosomes once replication begins. The biphasic relationship between the fraction of T-Ag-containing RI and the extent of DNA replication suggests either that 1 or 2 molecules of T-Ag remain stably bound until replication is about 70% completed or that 4 to 6 molecules of T-Ag are randomly released from each RI at a uniform rate throughout replication.

Chromatin assembly. Relationship of chromatin structure to DNA sequence during simian virus 40 replication.

The accessibility of five specific DNA sequences to six different single site restriction endonucleases was evaluated in replicating and mature simian virus 40 chromosomes isolated by three different methods. Electron microscopic and gel electrophoretic analysis of the DNA digestion products demonstrated that DNA accessibility in chromatin was established within 400 base pairs of replication forks and remained essentially unchanged during production of mature chromosomes and their subsequent re-entry into the replication pool. Saturating amounts of each enzyme reproducibly cut a fraction of the chromosomes, ranging from 13 to 49%. This is consistent with a nearly random phasing of chromatin structure. Examples in which all chromosomes were either cleaved or intact were never observed. Although variation in the accessibility of DNA sites near the origin of replication could be interpreted as preferred phasing in about 25% of the chromosomes, the finding that two isoschizomers, Hpa II and Msp I, did not cut chromosomes to the same extent precludes an unambiguous interpretation of the extents of cleavage of individual restriction enzymes. Since the extent of DNA cleavage observed at each restriction site was essentially indistinguishable in replicating as compared to mature chromosomes, the accessibility of DNA sequences near the origin is not obviously related to replication. Furthermore, the accessibility of DNA sites on one arm of a single replication fork was the same as the homologous sites on the other arm, consistent with a nearly random phasing of chromatin structure on both arms. This suggests that chromatin assembly occurs independently on the 2 sibling molecules of a single replicating chromosome.