New properties of simian virus 40 large T antigen

An 8,000-molecular-weight (8K) T antigen was found in all cells transformed by simian virus 40. The 8K T antigen was weakly labeled in vivo with [35S]methionine or 32Pi. A deletion in the human papovavirus BK genome, in the region coding for the carboxy-terminal end of the large T antigen, reduced the size of the 8K T antigen. The last 80 amino acids of the large T antigen include the sequence Asp-Asp-Asp-Asp unique to the activation peptide of trypsinogen. Large T antigen bound diisopropyl fluorophosphate and was retained by D-phenylalanine coupled to Sepharose beads, an affinity adsorbent that can retain chymotrypsin. The large T antigen and the recA protein of Escherichia coli, a known protease, have several properties in common as well as several similar sequences. Antibodies against large T antigen interacted with native recA protein.     

Use of simian virus 40 large T-beta-galactosidase fusion proteins in an immunochemical analysis of simian virus 40 large T antigen.

Simian virus 40 large T antigen is a multifunctional protein that is encoded by the early region of the viral genome. We constructed fusion proteins between simian virus 40 large T antigen and beta-galactosidase by cloning HindIII fragments A and D of the virus into the HindIII sites of expression vectors pUR290, pUR291, and pUR292. Large amounts of the fusion protein were synthesized when the DNA fragment encoding part of simian virus 40 large T antigen was in frame with the lacZ gene of the expression vector. Using Western blotting and a competition radioimmunoassay, we assessed the binding of existing anti-T monoclonal and polyclonal antibodies to the two fusion proteins. Several monoclonal antibodies reacted with the protein encoded by the fragment A construction, but none reacted with the protein encoded by the fragment D construction. However, mice immunized with pure beta-galactosidase-HindIII fragment D fusion protein produced good levels of anti-T antibodies, which immunoprecipitated simian virus 40 large T antigen from lytically infected cells, enabling derivation of monoclonal antibodies to this region of large T antigen. Therefore, the fusion proteins allowed novel epitopes to be discovered on large T antigen and permitted the precise localization of epitopes recognized by existing antibodies. The same approach can also be used to produce antibodies against defined regions of any gene.     

Purification of simian virus 40 large T antigen by immunoaffinity chromatography.

Simian virus 40 large T antigen from lytically infected cells has been purified to near homogeneity by immunochromatography of the cell extract on a protein A-Sepharose-monoclonal antibody column. The resulting T antigen retains biochemical activity; i.e., it hydrolyzes ATP and binds to simian virus 40 DNA at the origin of replication.     

Two separable functional domains of simian virus 40 large T antigen: carboxyl-terminal region of simian virus 40 large T antigen is required for efficient capsid protein synthesis.

The carboxyl-terminal portion of simian virus 40 large T antigen is essential for productive infection of CV-1 and CV-1p green monkey kidney cells. Mutant dlA2459, lacking 14 base pairs at 0.193 map units, was positive for viral DNA replication, but unable to form plaques in CV-1p cells (J. Tornow and C.N. Cole, J. Virol. 47:487-494, 1983). In this report, the defect of dlA2459 is further defined. Simian virus 40 late mRNAs were transcribed, polyadenylated, spliced, and transported in dlA2459-infected cells, but the level of capsid proteins produced in infected CV-1 green monkey kidney cells was extremely low. dlA2459 large T antigen lacks those residues known to be required for adenovirus helper function, and the block to productive infection by dlA2459 occurs at the same stage of infection as the block to productive adenovirus infection of CV-1 cells. These results suggest that the adenovirus helper function is required for productive infection by simian virus 40. Mutant dlA2459 was able to grow on the Vero and BSC-1 lines of African green monkey kidney cells. Additional mutants affecting the carboxyl-terminal portion of large T were prepared. Mutant inv2408 contains an inversion of the DNA between the BamHI and BclI sites (0.144 to 0.189 map units). This inversion causes transposition of the carboxyl-terminal 26 amino acids of large T antigen and the carboxyl-terminal 18 amino acids of VP1. This mutant was viable, even though the essential information absent from dlA2459 large T antigen has been transferred to the carboxyl terminus of VP1 of inv2408. The VP1 polypeptide carrying this carboxyl-terminal portion of large T could overcome the defect of dlA2459. This indicates that the carboxyl terminus of large T antigen is a separate and separable functional domain.     

Functional characterization of temperature-sensitive mutants of simian virus 40 large T antigen.

We investigated the molecular properties of eight temperature-sensitive mutants of simian virus 40 large T antigen (tsA mutants). The mutants have single amino acid substitutions that block DNA replication at 39 to 41 degrees C in vivo. In vitro, five of the mutant proteins were highly sensitive to a brief heat shock at 39 degrees C, while the three remaining proteins were only partially sensitive at 41 degrees C. We characterized the five most defective mutant proteins, using a variety of biochemical assays for replication functions of T antigen. Heat shock of purified T antigen with a mutation at amino acid 422 significantly impaired the oligomerization, origin-binding, origin-unwinding, ATPase, and helicase functions of T antigen. In contrast, substitution of amino acid 186, 357, 427, or 438 had more selective, temperature-sensitive effects on T-antigen functions. Our findings are consistent with the conclusion that T antigen functions via a hierarchy of interrelated domains. Only the ATPase activity remained intact in the absence of all other functions. Hexamer formation appears to be necessary for core origin-unwinding and helicase activities; the helicase function also requires ATPase activity. All five tsA mutants were impaired in functions important for the initiation of DNA replication, but three mutants retained significant elongation functions.     

Self-assembly of simian virus 40 large T antigen oligomers by divalent cations.

In simian virus 40-transformed cells, simian virus 40 large T antigen can be detected in different forms separable by sucrose density gradient centrifugation. In our experiments, light forms sedimented around 5 to 7S, oligomers such as tetramers were detected around 16S, and higher aggregates sedimented in a broad distribution reaching above 23S. The oligomers sedimenting at and above 16S could be disassembled into the slowly sedimenting 5 to 7S forms by chelating agents [EDTA or ethylene bis(oxonitrilo)tetraacetate]. After the addition of divalent cations (CaCl2 or MgCl2) in excess of chelating agents, oligomeric forms reassembled and appeared in a sedimentation pattern resembling that observed before treatment with chelating agents. Time course studies permitted the identification of the 5 to 7S forms as precursors upon pulse-labeling (15 min); the 16S and higher oligomers were identified as the successors after a 14-h chase. Treatment of extracts of pulse-chase-labeled cells with chelating agents again disassembled the oligomers, whereas pulse-labeled precursors did not change their 5 to 7S sedimentation pattern. Adding an excess of divalent cations reassembled the pulse-chase-labeled T antigen to oligomers but did not influence the sedimentation behavior of pulse-labeled 5 to 7S precursors. It is therefore reasonable to assume that a posttranslational modulation induces divalent cation binding, leading finally to the oligomerization of T antigen. Thus, some of the multifunctional activities of T antigen can be dictated by divalent cation binding properties.     

The zinc finger region of simian virus 40 large T antigen

Simian virus 40 large T antigen contains a single sequence element with an arrangement of cysteines and histidines that is characteristic of a zinc finger motif. The finger region maps from amino acids 302 through 320 and has the sequence Cys-302LeuLysCys-305IleLysLysGluGlnProSerHisTyrLysTyrHis- 317GluLysHis-320. In a conventional representation, the binding of zinc to the cysteines and histidines at positions 302, 305, 317, and 320 would form two minor loops and one major loop from the intervening amino acids. We made single amino acid substitutions at every position in the finger to identify possible functional elements within the putative metal-binding domain. Amino acids in the zinc finger could be divided into three classes characterized by distinct roles in DNA replication and transformation. Class 1 consisted of amino acids in the two minor loops of the finger and in the amino-terminal part of the major loop. Mutations here did not affect either replication or transformation. Class 2 consisted of the SerHisTyrLysTyr amino acids located in the carboxy terminus of the major loop of the finger. Mutations in this contiguous region reduced replication of the mutant viruses to different degrees. This clustering suggested that the region is an active site important for a specific function in DNA replication. With the exception of a mutation in the histidine at position 313, these mutations had no effect on transformation. Class 3 consisted of the proposed zinc-binding amino acids at positions 302, 305, 317, and 320 and the histidine at position 313 in the major loop of the finger. Mutations in these amino acids abolished the viability of the virus completely and had a distinctive effect on the transforming functions of the protein. Thus, the five cysteines and histidines of class 3 may play an important role in determining the overall structure of the protein. The histidine at position 313 may function both in the active site where it is located and in cooperation with the proposed zinc-binding ligands.     

Mutational analysis of simian virus 40 large T antigen DNA binding sites.

We have tested the effects of various mutations within SV40 T antigen DNA recognition sites I and II on specific T antigen binding using the DNase footprint technique. In addition, the replication of plasmid DNA templates carrying these T antigen binding site mutations was monitored by Southern analysis of transfected DNA in COS cells. Deletion mapping of site I sequences defined a central core of approximately 18 bp that is both necessary and sufficient for T antigen recognition; this region contains the site I contact nucleotides that were previously mapped using methylation-interference and methylation-protection experiments. A similar deletion analysis delineated sequences that impart specificity of binding to site II. We find that T antigen is capable of specific recognition of site II in the absence of site I sequences, indicating that binding to site II in vitro is not dependent on binding of T antigen at site I. Site II binding was not diminished by small deletion or substitution mutations that perturb the 27-bp palindrome central to binding site II, whereas extensive substitution of site II sequences completely eliminated specific site II binding. Analysis of the replication in COS7 cells of plasmids that contain these mutant origins revealed that sequences both at the late side of binding site I and within the site II palindrome are crucial for viral DNA replication, but are not involved in binding T antigen.     

Improved localization of phosphorylation sites in simian virus 40 large T antigen.

The location of phosphorylation sites in the large T antigen of simian virus 40 has been studied both by partial chemical cleavage and by partial proteolysis of various forms of large T. These included the full-size wild-type molecule with an apparent molecular weight of 88,000, deleted molecules coded for by the mutants dl1265 and dl1263, and several shortened derivatives generated by the action of a cellular protease. These molecules differed from each other by variations in the carboxy-terminal end. In contrast, a ubiquitous but minor large T form with a molecular weight of 91,000 was found to be modified in the amino-terminal half of the molecule. In addition to the phosphorylation of threonine at position 701 (K.-H. Scheidtmann et al., J. Virol. 38:59-69, 1981), two other discrete domains of phosphorylation were recognized, one at either side of the molecule. The amino-terminal region was located between positions 81 and 124 and contained both phosphothreonine and phosphoserine residues. The carboxy-terminal region was located between approximate positions 500 and 640 and contained at least one phosphoserine residue but no phosphothreonine. The presence in the phosphorylated domains of large T of known recognition sequences for different types of protein kinases is discussed, together with possible functions of large T associated with these domains.     

Metabolic turnover of phosphorylation sites in simian virus 40 large T antigen.

Four (groups of) phosphorylation sites exist in the large T antigen of simian virus 40, and they involve at least two serine and two threonine residues (Van Roy et al. J. Virol. 45:315-331, 1983). All the phosphorylation sites were found to be modified and again dephosphorylated at discrete rates, with phosphoserine residues having the highest turnover rate. The measured half-lives ranged between 3 h (for the carboxy-terminal phosphoserine site) and 5.5 h (for the amino-terminal phosphothreonine site). The influence of four temperature-sensitive A mutations on phosphorylation of large T antigen was also examined. At restrictive temperature, phosphorylation of the carboxy-terminal phosphoserine in mutated large T antigen was found to be particularly impaired. These data emphasize the physiological importance of the latter phosphorylation site.     

The simian virus 40 large tumor antigen

In this review, I hope to achieve the following: (a) to document the presence of a lysosome-like proton pump ATPase in many different membrane systems of animal, plant and microbial origin; (b) to glean from the diverse data common characteristics of these ATPases, especially as regards their similarities and differences with mitochondrial-type F1F0 proton pump ATPases; and (c) to consider questions of synthesis and regulation of a cellular proton pump system with such a widespread distribution.     

Antigenic binding sites of monoclonal antibodies specific for simian virus 40 large T antigen.

We isolated 16 new monoclonal antibodies that recognize large T antigen of simian virus 40 and mapped the epitopes to three distinct regions of the large T antigen. Also, 3 of the 16 recognized the large T antigen of the human papovavirus BKV.     

Recombinant retroviruses encoding simian virus 40 large T antigen and polyomavirus large and middle T antigens.

We used a murine retrovirus shuttle vector system to construct recombinants capable of constitutively expressing the simian virus 40 (SV40) large T antigen and the polyomavirus large and middle T antigens as well as resistance to G418. Subsequently, these recombinants were used to generate cell lines that produced defective helper-free retroviruses carrying each of the viral oncogenes. These recombinant retroviruses were used to analyze the role of the viral genes in transformation of rat F111 cells. Expression of the polyomavirus middle T antigen alone resulted in cell lines that were highly tumorigenic, whereas expression of the polyomavirus large T resulted in cell lines that were highly tumorigenic, whereas expression of the polyomavirus large T resulted in cell lines that were unaltered by the criteria of morphology, anchorage-independent growth, and tumorigenicity. More surprisingly, SV40 large T-expressing cell lines were not tumorigenic despite the fact that they contained elevated levels of cellular p53 and had a high plating efficiency in soft agar. These results suggest that the SV40 large T antigen is not an acute transforming gene like the polyomavirus middle T antigen but is similar to the establishment genes such as myc and adenovirus EIa.     

Association of simian virus 40 T antigen with replicating nucleoprotein complexes of simian virus 40.

An immunoprecipitation assay was established for simian virus 40 T-antigen-bound nucleoprotein complexes by means of precipitation with sera from hamsters bearing simian virus 40-induced tumors. About 80% of simian virus 40 replicating nucleoprotein complexes in various stages of replication were immunoprecipitated. In contrast, less than 21% of mature nucleoprotein complexes were immunoprecipitated. Pulse-chase experiments showed that T antigen was lost from most of the nucleoprotein complexes concurrently with completion of DNA replication. T antigen induced by dl-940, a mutant with a deletion in the region coding for small T antigen, was also associated with most of the replicating nucleoprotein complexes. Once bound with replicating nucleoprotein complexes at the permissive temperature, thermolabile T antigen induced by tsA900 remained associated with the complexes during elongation of the replicating DNA chain at the restrictive temperature. These results suggest that simian virus 40 T antigen (probably large T antigen) associates with nucleoprotein complexes at or before initiation of DNA replication and that the majority of the T antigen dissociates from the nucleoprotein complexes simultaneously with completion of DNA replication.     

Rapid and sensitive quantitative immunoassay for the large simian virus 40 T antigen

A quantitative, enzyme-linked immunoadsorbent assay has been developed for the simian virus 40 large T antigen. When hamster anti-simian virus 40 tumor serum was used, this method permitted specific identification of large T antigen and its analog, the D2 hybrid protein, a molecule with the same C-terminal approximately 600 amino acids as large T antigen. The sensitivity limit of this test was 0.63 ng of protein. The slopes of the regression lines of the enzyme-linked immunosorbent assay titrations performed with highly purified D2 or simian virus 40 large T antigen and with crude extracts of simian virus 40-infected monkey and transformed human cells were identical. Thus, the curve generated with a purified protein, such as D2, can serve as a quantitative standard for the measurement of large T antigen in a wide variety of extracts. Furthermore, solutions containing high salt concentrations and buffers containing up to 0.1% Nonidet P-40 did not interfere with the assay, making it applicable to the measurement of large T antigen in a variety of chromatographic fractions. The enzyme-linked immunosorbent assay was three times more sensitive, was significantly faster to perform, and was quantitatively valid over a much broader large-T-antigen concentration range than the complement fixation test. As such, it should be useful in future studies of the structure and function of this protein.     

Expression of simian virus 40 large T antigen in embryonal carcinoma cell hybrids.

Previous work has shown that murine embryonal carcinoma cells are refractory to infection with various viruses, including simian virus 40. Thus, large T and small t antigens, the products of the simian virus 40 early region, are not produced when the virus infects embryonal carcinoma cells, in contrast to other cell types. We show, by qualitative and quantitative analyses, that embryonal carcinoma cell hybrids, containing a simian virus 40 early region integrated into human DNA, are capable of producing viral large T antigen.     

The distribution of large T antigen in simian virus 40 nucleoprotein complexes

Simian virus 40 large T antigen binds to two types of nucleoprotein complexes from lytically infected cells: those containing replicating virus DNA (100S complexes) and those containing nonreplicating virus DNA (70S complexes). Analysis by agarose gel electrophoresis showed that replicating DNA was found exclusively in 100S complexes, although these complexes also contained large amounts of form I and form II DNA. In contrast, no replicating DNA was found in 70S complexes, and pulse-labeled DNA in these complexes migrated as form I and form II DNA that presumably had recently completed replication. Immunoprecipitation and gel electrophoresis showed that large T antigen was associated with both types of complexes. From 21 to 62% of replicating DNA in 100S complexes was bound to T antigen. Our estimates indicated, however, that more than three-fourths of the DNA molecules in 100S complexes were nonreplicating and unassociated with T antigen. In 70S complexes, 12 to 31% of pulse-labeled DNA was bound to T antigen, but because there were more DNA molecules in the 70S complexes, they contained a greater absolute amount of T antigen.     

Measurements of the molecular size of the simian virus 40 large T antigen.

A measure of the molecular weight of the large simian virus 40 T antigen was sought by SDS-polyacrylamide gel electrophoresis, random-coil chromatography, and sedimentation-velocity analysis in a density gradient. Large T antigen obtained from a simian virus 40-transformed human cell line either by immunoprecipitation or by standard preparatory methods migrated like a 94,000-molecular-weight (approximately 94K) polypeptide in SDS-gels but was found to have an approximate was observed with T antigen obtained from lytically infected monkey cells. In view of the strong theoretical basis for the guanidine method and the agreement with the sedimentation data, these findings suggest that the molecular weight of this protein is approximately 75 to 80K as opposed to 94 to 100K and, therefore, that considerably less than the entire early region of simian virus 40 is required to encode it. This size estimate is in keeping with earlier results which revealed a normal-size T antigen in cells infected with viable deletion mutants lacking as much as 10% of the early region.     

Properties of the DNA-binding domain of the simian virus 40 large T antigen.

T antigen (Tag) from simian virus 40 binds specifically to two distinct sites in the viral origin of replication and to single-stranded DNA. Analysis of the protein domain responsible for these activities revealed the following. (i) The C-terminal boundary of the origin-specific and single-strand-specific DNA-binding domain is at or near amino acid 246; furthermore, the maximum of these DNA-binding activities coincides with a narrow C-terminal boundary, spanning 4 amino acids (246 to 249) and declines sharply in proteins with C termini which differ by a few (4 to 10) amino acids; (ii) a polypeptide spanning residues 132 to 246 of Tag is an independent domain responsible for origin-specific DNA binding and presumably for single-stranded DNA binding; and (iii) a comparison of identical N-terminal fragments of Tag purified from mammalian and bacterial cells revealed differential specificity and levels of activity between the two sources of protein. A role for posttranslational modification (phosphorylation) in controlling the DNA-binding activity of Tag is discussed.