A novel translational regulation function for the simian virus 40 large-T antigen gene.

Cells use the interferon-induced, double-stranded-RNA-dependent protein kinase PKR as a defense against virus infections. Upon activation, PKR phosphorylates and thereby inactivates the protein synthesis initiation factor eIF-2, resulting in the cessation of protein synthesis. Viruses have evolved various strategies to counteract this cellular defense. In this paper, we show that simian virus 40 (SV40) large-T antigen can antagonize the translational inhibitory effect resulting from the activation of PKR in virus-infected cells. Unlike the situation with other virus-host cell interactions, SV40 large-T antigen does not block the activation of PKR, suggesting that SV40 counteracts the cellular antiviral response mediated by PKR at a step downstream of PKR activation. Mutational analysis of large-T antigen indicates that a domain located between amino acids 400 and 600 of large-T antigen is responsible for this function. These results define a novel translational regulatory function for the SV40 large-T antigen.     

Nuclear subcompartmentalization of simian virus 40 large T antigen: evidence for in vivo regulation of biochemical activities

Simian virus 40 large T antigen (large T) in the early and the late phases of infection differs significantly in its sequence-specific DNA-binding and ATPase activities, indicating that different large-T populations participate in virus-specific events at various stages of the infectious cycle. To further characterize these large-T populations, we have analyzed nuclear subclasses of large T, isolated from their in vivo location, for their biochemical activities. We show that chromatin- and nuclear matrix-associated large-T molecules exhibit different simian virus 40 control region (ORI) DNA-binding and ATPase activities. The association of large T with a certain nuclear substructure, therefore, subcompartmentalizes large-T molecules exerting different biochemical activities. Nuclear subcompartmentalization thus may provide a higher-order level for the regulation of biochemical activities of large T in vivo.     

Immunoprecipitation of some forms of simian virus 40 large-T antigen by antibodies to synthetic peptides.

Antibodies were raised against six synthetic peptides corresponding to overlapping amino acid sequences (106 through 145) from a putative DNA binding domain in simian virus 40 (SV40) large-T antigens. All six antipeptide sera immunoprecipitated large-T from crude extracts of SV40-transformed cells, but the efficiency varied widely; in general, antibodies to the longer peptides produced the strongest anti-large-T activity. Antisera were purified by immunoaffinity chromatography on immobilized peptide. The purified antisera recognized only some forms of large-T; full-sized large-T from transformed cells, super-T from SV3T3 C120 cells, and 70,000-dalton T-antigen from Taq-BamHI cells were immunoprecipitated, whereas large-T from productively infected cells reacted irreproducibly, and the full-sized protein, synthesized in vitro or eluted from sodium dodecyl sulfate-containing gels, and the 33,000- and 22,000-dalton truncated large-Ts from Swiss SV3T3 and MES2006 cells, respectively, were not immunoprecipitated. This pattern of reactivity was explained when extracts were fractionated by sucrose density centrifugation, and it was found that only rapidly sedimenting forms of large-T were immunoprecipitated by the antipeptide sera; that is, large-T complexed with nonviral T antigen was detected, whereas lighter forms were not detected. Cascade immunoprecipitations did not support the view that this result was caused by the low affinity of the peptide antisera for large-T, and Western blotting experiments confirmed that the peptide antisera react directly with immobilized, monomeric large-T but not with nonviral T antigen. Immunoprecipitation assays to detect large-T:nonviral T antigen complexes bound specifically to fragments of SV40 DNA showed that under conditions of apparent antibody excess, DNA still bound to the complex.     

Association of a murine 53,000-dalton phosphoprotein with simian virus 40 large-T antigen in transformed cells.

Serum raised against a mouse 53,000-dalton (53K) phosphoprotein precipitates both the 53K immunogen and simian virus 40 large-T from lysates of simian virus 40-transformed 3T3 cells. This serum, designated F5, does not recognize antigenic determinants on native or denatured large-T and precipitates large-T because the 53K phosphoprotein forms a stable complex with large-T. This complex sediments at 23S on sucrose density gradients, corresponding to a molecular weight of 600K to 1,000K, and appears to contain only 53K and large-T as major components. It is held together by noncovalent bonds and is located in the cell nucleus. All the 53K immunoprecipitated from cell lysates by F5 is present in the high-molecular-weight complex, but large-T can be separated into a complexed and a free form on sucrose density gradients. The complexed form of large-T is more readily phosphorylated than the free form. We have been unable to detect an association of large-T with comparable host cell proteins during productive infections with simian virus 40.     

Mapping of the viral mRNA encoding a super-T antigen of 115,000 daltons expressed in simian virus 40-transformed rat cell lines

Simian virus 40-transformed V11 F1 clone 1 subclone 7 rat cells produced a considerable amount of an elongated form of large-T antigen with an Mr of 115,000 (115K super-T antigen), but these cells did not produce detectable traces of normal-sized large-T antigen (86,000 daltons) (P. May, M. Kress, M. Lange, and E. May, Cold Spring Harbor Symp. Quant. Biol. 44:189-200, 1980). First, a comparison of the tryptic peptide fingerprints of 115K super-T and large-T antigens suggested that 115K super-T antigen is simian virus 40 coded and contains a duplication of amino acid sequences of large-T antigen. Second, from S1 mapping analysis of 115K super-T mRNA, performed with various restriction fragments of simian virus 40 DNA, it was concluded that super-T mRNA is a form of large-T mRNA containing a tandem duplication of the sequence extending from approximately 0.46 to 0.35 map unit. The duplicated sequence corresponded to that region of the simian virus 40 genome in which 12 of 13 tsA mutation sites are clustered (C. J. Lai and D. Nathans, Virology 66:70-81, 1975).     

Characterization of the amino-terminal tryptic peptide of simian virus 40 small-t and large-T antigens.

Simian virus 40 small-t and large-T antigen were synthesized in vitro and labeled with methionine donated by initiator tRNA. Tryptic peptide fingerprinting was used to identify the amino-terminal peptide of the two proteins. Similar fingerprint analysis of small-t and large-T made in vitro in the absence of acetyl coenzyme A showed that the mobility of the amino-terminal peptide was changed under these conditions and suggested that it is acetylated. These data establish that the amino-terminal methionine residue of simian virus 40 small-t and large-T results from an initiation event, not post-translational cleavage, and provides additional evidence that the amino terminus of both proteins is acetylated. The identification of the amino-terminal peptide provides a useful marker for further studies on different forms of T-antigen from cells infected with and transformed by simian virus 40 and related viruses.     

Mutations near the carboxyl terminus of the simian virus 40 large tumor antigen alter viral host range.

We report the characterization of three mutants of simian virus 40 with mutations that delete sequences near the 3' end of the gene encoding large tumor antigen (T antigen). Two of these mutants, dl1066 and dl1140, exhibit an altered viral host range. Wild-type simian virus 40 is capable of undergoing a complete productive infection on several types of established African green monkey kidney lines, including BSC40 and CV1P. dl1066 and dl1140 grow on BSC40 cells at 37 degrees C. However, both mutants fail to form plaques on BSC40 cells at 32 degrees C or on CV1P cells at any temperature. These mutants are capable of replicating viral DNA in the nonpermissive cell type, indicating a defect in an activity of T antigen not related to its replication function. Furthermore this defect can be complemented in trans by the wild type or by a variety of DNA replication-negative T antigen mutants, so long as they produce a normal carboxyl-terminal region of the molecule. Our data are consistent with the hypothesis that the C-terminal region of T antigen constitutes a functional domain. We propose that this domain encodes an activity that is required for simian virus 40 productive infection on the CV1P cell line, but not on BSC40.     

Modulation of p53 protein expression during cellular transformation with simian virus 40.

We analyzed the relation of metabolic stabilization of the p53 protein during cellular transformation by simian virus 40 (SV40) to (i) expression of the transformed phenotype and (ii) expression of the large tumor antigen (large T). Analysis of SV40-tsA28-mutant-transformed rat cells (tsA28.3 cells) showed that both p53 complexed to large T and free p53 (W. Deppert and M. Haug, Mol. Cell. Biol. 6:2233-2240, 1986) were metabolically stable when the cells were cultured at 32 degrees C and expressed large T and the transformed phenotype. At the nonpermissive temperature (39 degrees C), large-T expression is shut off in these cells and they revert to the normal phenotype. In such cells, p53 was metabolically unstable, like p53 in untransformed cells. To determine whether metabolic stabilization of p53 is directly controlled by large T, we next analyzed the metabolic stability of complexed and free p53 in SV40 abortively infected normal BALB/c mouse 3T3 cells. We found that neither p53 in complex with large T nor free p53 was metabolically stable. However, both forms of p53 were stabilized in SV40-transformed cells which had been developed in parallel from SV40 abortively infected cultures. Our results indicate that neither formation of a complex of p53 with large T nor large-T expression as such is sufficient for a significant metabolic stabilization of p53. Therefore, we suggest that metabolic stabilization of p53 during cellular transformation with SV40 is mediated by a cellular process and probably is the consequence of the large-T-induced transformed phenotype.     

DNA binding properties of a mutant T antigen from the simian virus 40-transformed human cell line simian virus 80

We investigated whether the T antigen of the simian virus 40-transformed human cell line simian virus 80 ( SV80 ) specifically recognizes DNA sequences of its own template, i.e, the viral sequences integrated in the SV80 cellular genome. In vitro DNA binding experiments clearly indicated that, in contrast to wild-type T antigen, SV80 T antigen does not specifically bind to sites on the integrated viral DNA in SV80 cells.     

Extensive mutagenesis of the nuclear location signal of simian virus 40 large-T antigen.

Site-directed mutagenesis was used to change Lys-128 of the simian virus 40 large-T nuclear location signal to Met, Ile, Arg, Gln, Asn, Leu, or His. Except for the large-T antigen of the Arg mutation, which was present in cytoplasmic and nuclear compartments, the resultant proteins were unable to enter the nucleus. By contrast, mutations at other sites within the signal were generally less severe in their effect. In some cases (Lys-128 to Gln, Asn, and His), the apparently cytoplasmic variants were able to support limited plasmid DNA replication, suggesting that low levels of large-T antigen undetectable by immunofluorescence were present in the nucleus. Such mutants did not support viral DNA replication. We conclude that there is a strong requirement for a basic residue at position 128 in the large-T nuclear location signal, with Lys the preferred residue.     

Biochemical properties of the 145,000-dalton super-T antigen from simian virus 40-transformed BALB/c 3T3 clone 20 cells

SV3T3 C120 cells contain a 145,000-dalton form of simian virus 40 (SV40) super-T antigen but little if any normal-sized large-T. The subcellular location of super-T, its DNA binding properties, and its interaction with nonviral tumor antigen (NVT) were examined. Immunofluorescence microscopy and subcellular fractionation indicated that super-T is almost exclusively nuclear. Chromatography on double-stranded DNA-cellulose showed that super-T binds to double-stranded DNA and has an elution profile indistinguishable from normal-sized large-T. Super-T also binds specifically to a fragment of SV40 DNA which contains the origin of DNA replication. However, immunoprecipitation of super-T or large-T either with anti-tumor cell serum or with anti-NVT serum from fractions obtained by sucrose density centrifugation of 32P-labeled or [35S]methionine-labeled extracts revealed clear differences in the sedimentation characteristics of these proteins. The bulk of labeled 145,000-dalton super-T sedimented between 4S and 10S, whereas the bulk of 32P-labeled large-T from normal SV40-transformed cells sedimented as two peaks at 23S to 25S and 16S to 18S. By contrast, the sedimentation properties of NVT from the SV3T3 C120 cells were similar to those normally observed with other SV3T3 cell lines. The reason for this apparent difference in complex formation between super-T and NVT and that normally observed with large-T is unclear, but it probably has no deleterious effect on the ability of super-T to maintain transformation.     

Analysis of an activatable promoter: sequences in the simian virus 40 late promoter required for T-antigen-mediated trans activation.

The late promoter of simian virus 40 (SV40) is activated in trans by the viral early gene product, T antigen. We inserted the wild-type late-promoter region, and deletion mutants of it, into chloramphenicol acetyltransferase transient expression vectors to identify promoter sequences which are active in the presence of T antigen. We defined two promoter activities. One activity was mediated by a promoter element within simian virus 40 nucleotides 200 to 270. The activity of this element was detectable only in the presence of an intact, functioning origin of replication and accounted for 25 to 35% of the wild-type late-promoter activity in the presence of T antigen. The other activity was mediated by an element located within a 33-base-pair sequence (simian virus nucleotides 168 to 200) which spans the junction of the 72-base-pair repeats. This element functioned in the absence of both the origin of replication and the T-antigen-binding sites and appeared to be responsible for trans-activated gene expression. When inserted into an essentially promoterless plasmid, the 33-base-pair element functioned in an orientation-dependent manner. Under wild-type conditions in the presence of T antigen, the activity of this element accounted for 65 to 75% of the late-promoter activity. The roles of the 33-base-pair element and T antigen in trans-activation are discussed.     

Simian virus 40 (SV40) small t antigen inhibits SV40 DNA replication in vitro.

We describe a biochemical function of simian virus 40 small t antigen, the inhibition of simian virus 40 large T antigen-mediated viral DNA replication in an in vitro replication system. Our results suggest that in this system, small t antigen prevents protein phosphatase 2A-mediated activation of large T antigen.