Genetic and biochemical analysis of transformation-competent, replication-defective simian virus 40 large T antigen mutants.

To study the role of the biochemical and physiological activities of simian virus 40 (SV40) large T antigen in the lytic and transformation processes, we have analyzed DNA replication-defective, transformation-competent T-antigen mutants. Here we describe two such mutants, C8/SV40 and T22/SV40, and also summarize the properties of all of the mutants in this collection. C8/SV40 and T22/SV40 were isolated from C8 and T22 cells (simian cell lines transformed with UV-irradiated SV40). Early regions encoding the defective T antigens were cloned into a plasmid vector to generate pC8 and pT22. The mutations responsible for the defects in viral DNA replication were localized by marker rescue, and subsequent DNA sequencing revealed missense and one nonsense mutation. The T22 mutation predicts a change of histidine to glutamine at residue 203. C8 has two mutations, one predicts lysine224 to glutamamic acid and the other changes the codon for glutamic acid660 to a stop codon; therefore, C8 T antigen lacks the 49 carboxy-terminal amino acids. pC8A and pC8B were constructed to contain the C8 mutations separately. Plasmids pT22, pC8, pC8A, and pC8B were able to transform primary rodent cell cultures. T22 T antigen is defective in binding to the SV40 origin. C8B (49-amino-acid truncation) is a host-range mutant defective in a late function in CV-1 but not BSC cells. Analysis of T antigens in mutant SV40-transformed mouse cells suggests that the replicative function of T antigen is important in generating SV40 DNA rearrangements that allow the expression of "100K" variant T antigens in the transformants.     

DNA-binding properties of simian virus 40 T-antigen mutants defective in viral DNA replication.

Three simian virus 40 (SV40)-transformed monkey cell lines, C2, C6, and C11, producing T-antigen variants that are unable to initiate viral DNA replication, were analyzed with respect to their affinity for regulatory sequences at the viral origin of replication. C2 and C11 T antigens both bound specifically to sequences at sites 1 and 2 at the viral origin region, whereas C6 T antigen showed no specific affinity for any viral DNA sequences under all conditions tested. Viral DNA sequences encoding the C6 T antigen have recently been cloned out of C6 cells and used to transform an established rat cell line. T antigen from several cloned C6-SV40-transformed rat lines failed to bind specifically to the origin. C6 DNA contains three mutations: two located close to the amino terminus of T antigen at amino acid positions 30 and 51 and a third located internally at amino acid position 153. Two recombinant SV40 DNA mutants were prepared containing either the amino-terminal mutations at positions 30 and 51 (C6-1) or the internally located mutation at position 153 (C6-2) and used to transform Rat 2 cells. Whereas T antigen from C6-2-transformed cells lacked any specific affinity for these sequences. Therefore, the single mutation at amino acid position 153 (Asn leads to Thr) is sufficient to abolish the origin-binding property of T antigen. A T antigen-specific monoclonal antibody, PAb 100, which had been previously shown to immunoprecipitate an immunologically distinct origin-binding subclass of T antigen, recognized wild-type or C6-1 antigens, but failed to react with C6 or C6-2 T antigens. These results indicate that viral replication function comprises properties of T antigen that exist in addition to its ability to bind specifically to the SV40 regulatory sequences. Furthermore, it is concluded from these data that specific viral origin binding is not a necessary feature of the transforming function of T antigen.     

Properties of the simian virus 40 (SV40) large T antigens encoded by SV40 mutants with deletions in gene A

The biochemical properties of the large T antigens encoded by simian virus 40 (SV40) mutants with deletions at DdeI sites in the SV40 A gene were determined. Mutant large T antigens containing only the first 138 to 140 amino acids were unable to bind to the SV40 origin of DNA replication as were large T antigens containing at their COOH termini 96 or 97 amino acids encoded by the long open reading frame located between 0.22 and 0.165 map units (m.u.). All other mutant large T antigens were able to bind to the SV40 origin of replication. Mutants with in-phase deletions at 0.288 and 0.243 m.u. lacked ATPase activity, but ATPase activity was normal in mutants lacking origin-binding activity. The 627-amino acid large T antigen encoded by dlA2465, with a deletion at 0.219 m.u., was the smallest large T antigen displaying ATPase activity. Mutant large T antigens with the alternate 96- or 97-amino acid COOH terminus also lacked ATPase activity. All mutant large T antigens were found in the nuclei of infected cells; a small amount of large T with the alternate COOH terminus was also located in the cytoplasm. Mutant dlA2465 belonged to the same class of mutants as dlA2459. It was unable to form plaques on CV-1p cells at 37 or 32 degrees C but could form plaques on BSC-1 monolayers at 37 degrees C but not at 32 degrees C. It was positive for viral DNA replication and showed intracistronic complementation with any group A mutant whose large T antigen contained a normal carboxyl terminus. These findings and those of others suggest that both DNA binding and ATPase activity are required for the viral DNA replication function of large T antigen, that these two activities must be located on the same T antigen monomer, and that these two activities are performed by distinct domains of the polypeptide. These domains are distinct and separable from the domain affected by the mutation of dlA2465 and indicate that SV40 large T antigen is made up of at least three separate functional domains.     

Biochemical activities of T-antigen proteins encoded by simian virus 40 A gene deletion mutants.

We have analyzed T antigens produced by a set of simian virus 40 (SV40) A gene deletion mutants for ATPase activity and for binding to the SV40 origin of DNA replication. Virus stocks of nonviable SV40 A gene deletion mutants were established in SV40-transformed monkey COS cells. Mutant T antigens were produced in mutant virus-infected CV1 cells. The structures of the mutant T antigens were characterized by immunoprecipitation with monoclonal antibodies directed against distinct regions of the T-antigen molecule. T antigens in crude extracts prepared from cells infected with 10 different mutants were immobilized on polyacrylamide beads with monoclonal antibodies, quantified by Coomassie blue staining, and then assayed directly for T antigen-specific ATPase activity and for binding to the SV40 origin of DNA replication. Our results indicate that the T antigen coding sequences required for origin binding map between 0.54 and 0.35 map units on the SV40 genome. In contrast, sequences closer to the C terminus of T antigen (between 0.24 and 0.20 map units) are required for ATPase activity. The presence of the ATPase activity correlated closely with the ability of the mutant viruses to replicate and to transform nonpermissive cells. The origin binding activity was retained, however, by three mutants that lacked these two functions, indicating that this activity is not sufficient to support either cellular transformation or viral replication. Neither the ATPase activity nor the origin binding activity correlated with the ability of the mutant DNA to activate silent rRNA genes or host cell DNA synthesis.     

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.     

Transformation of a continuous rat embryo fibroblast cell line requires three separate domains of simian virus 40 large T antigen.

Mouse C3H 10T1/2 cells and the established rat embryo fibroblast cell line REF-52 are two cell lines widely used in studies of viral transformation. Studies have shown that transformation of 10T1/2 cells requires only the amino-terminal 121 amino acids of simian virus 40 (SV40) large T antigen, while transformation of REF-52 cells requires considerably more of large T antigen, extending from near the N terminus to beyond residue 600. The ability of a large set of linker insertion, small deletion, and point mutants of SV40 T antigen to transform these two cell lines and to bind p105Rb was determined. Transformation of 10T1/2 cells was greatly reduced by mutations within the first exon of the gene for large T antigen but was only modestly affected by mutations affecting the p105Rb binding site or the p53 binding region. All mutants defective for transformation of 10T1/2 cells were also defective for transformation of REF-52 cells. In addition, mutants whose T antigens had alterations in the Rb binding site showed a substantial reduction in transformation of REF-52 cells, and the degree of this reduction could be correlated with the ability of the mutant T antigens to bind p105Rb. There was a tight correlation between the ability of mutants to transform REF-52 cells and the ability of their T antigens to bind p53. These results demonstrate that multiple regions of large T antigen are required for full transformation by SV40.     

Linker insertion mutants of simian virus 40 large T antigen that show trans-dominant interference with wild-type large T antigen map to multiple sites within the T-antigen gene.

Linker insertion mutants affecting the simian virus 40 (SV40) large tumor (T) antigen were constructed by inserting a 12-base-pair oligonucleotide linker into restriction endonuclease cleavage sites located within the early region of SV40. One mutant, with the insertion at amino acid 5, was viable in CV-1p and BSC-1 cells, indicating that sequences very close to the amino terminus of large T could be altered without affecting the lytic infection cycle of SV40. All other mutants affecting large T were not viable. In complementation assays between the linker insertion mutants and either a late-gene mutant, dlBC865, or a host range/helper function (hr/hf) mutant, dlA2475, delayed complementation was seen with the 6 of the 10 nonviable mutants. Of these 10 mutants, 5 formed plaques 3 to 4 days later than in control complementations, while complementation by one of the mutants, inA2827, with an insertion at amino acid 520, was delayed more than 1 week. Most mutants which showed delayed complementation replicated less well in Cos-1 cells than did a control mutant, dlA1209, which produced no T antigen. The replication of inA2827(aa520) was reduced by more than 90%. Similar interference with viral DNA replication was seen when CV-1, HeLa, or 293 cells were cotransfected with an origin-defective plasmid encoding wild-type large T antigen and with inA2827(aa520). Only one of the mutant T antigens, inA2807(aa303), was unstable. These results indicate that some of the mutant T antigens interfered with functions of wild-type T required for viral DNA replication. However, not all of the mutants which showed delayed complementation also showed interference with viral DNA replication. This indicates that mutant large T antigens may interfere trans dominantly with multiple activities of wild-type large T antigen.     

Mapping the transcriptional transactivation function of simian virus 40 large T antigen

T antigen is able to transactivate gene expression from the simian virus 40 (SV40) late promoter and from several other viral and cellular promoters. Neither the mechanisms of transactivation by T antigen nor the regions of T antigen required for this activity have been determined. To address the latter point, we have measured the ability of a set of SV40 large T antigen mutants to stimulate gene expression in CV-1 monkey kidney cells from the SV40 late promoter and Rous sarcoma virus (RSV) long terminal repeat (LTR) promoter. Transactivation, although reduced, was retained by an N-terminal 138-amino-acid fragment of T antigen. Mutants with alterations at various locations within the N-terminal 85 amino acids transactivated the RSV LTR promoter less well than did wild-type T antigen. Most of these were also partially defective in their ability to transactivate the SV40 late promoter. Two mutants with lesions in the DNA-binding domain that were unable to bind to SV40 DNA were completely defective for transactivation of both promoter, while a third mutant with a lesion in the DNA-binding domain which retained origin-binding activity transactivated both promoters as well as did wild-type T antigen. Only a low level of transactivation was seen with mutant T antigens which had lesions in or near the zinc finger region (amino acids 300 to 350). Mutations which caused defects in ATPase activity, host range/helper function, binding to p53, binding to the retinoblastoma susceptibility protein, or nuclear localization had little or no effect on transactivation. These results suggest that N-terminal portion of T antigen possesses an activation activity. The data are consistent with the idea that the overall conformation of T antigen is important for transactivation and that mutations in other regions that reduce or eliminate transactivation do so by altering the conformation or orientation of the N-terminal region so that its ability to interact with various targets is diminished or abolished.     

Role of single-stranded DNA binding activity of T antigen in simian virus 40 DNA replication

We have previously mapped the single-stranded DNA binding domain of large T antigen to amino acid residues 259 to 627. By using internal deletion mutants, we show that this domain most likely begins after residue 301 and that the region between residues 501 and 550 is not required. To study the function of this binding activity, a series of single-point substitutions were introduced in this domain, and the mutants were tested for their ability to support simian virus 40 (SV40) replication and to bind to single-stranded DNA. Two replication-defective mutants (429DA and 460EA) were grossly impaired in single-stranded DNA binding. These two mutants were further tested for other biochemical activities needed for viral DNA replication. They bound to origin DNA and formed double hexamers in the presence of ATP. Their ability to unwind origin DNA and a helicase substrate was severely reduced, although they still had ATPase activity. These results suggest that the single-stranded DNA binding activity is involved in DNA unwinding. The two mutants were also very defective in structural distortion of origin DNA, making it likely that single-stranded DNA binding is also required for this process. These data show that single-stranded DNA binding is needed for at least two steps during SV40 DNA replication.     

Replication and transformation functions of in vitro-generated simian virus 40 large T antigen mutants

We used sodium bisulfite mutagenesis to introduce point mutations within the early region of the simian virus 40 genome. Seventeen mutants which contained amino acid changes in the amino-terminal half of the large T antigen coding sequence were assayed for their ability to replicate viral DNA and to induce transformation in the established rodent cell line Rat-3. The mutants fell into four basic classes with respect to these two biological functions. Five mutants had wild-type replication and transformation activities, six were totally defective, three were replication deficient and transformation competent, and two were replication competent and transformation deficient. Within these classes were mutants which displayed intermediate phenotypes, such as four mutants which were not totally deficient in viral replication or cellular transformation but instead showed reduced large T antigen function relative to wild type. Three large T mutants displayed transforming activity that was greater than that of wild type and are called supertransforming mutants. Of the most interest are mutants differentially defective in replication and transformation activities. These results both support and extend previous findings that two important biological functions of large T antigen can be genetically separated.     

Simian virus 40 host range/helper function mutations cause multiple defects in viral late gene expression.

Simian virus 40 (SV40) deletion mutants dlA2459 and dlA2475 express T antigens that lack the normal carboxy terminus. These mutants are called host range/helper function (hr/hf) mutants because they form plaques at 37 degrees C on BSC-1 and Vero monkey kidney cell lines but not on CV-1p monkey kidney cells. Wild-type SV40 can provide a helper function to permit growth of human adenoviruses in monkey kidney cells; the hr/hf mutants cannot. Progeny yields of hr/hf mutants are also cold sensitive in all cell lines tested. Patterns of viral macromolecular synthesis in three cell lines (Vero, BSC-1, and CV-1) at three temperatures (40, 37, and 32 degrees C) were examined to determine the nature of the growth defect of hr/hf mutants. Mutant viral DNA replication was similar to that of the wild type in all three cell lines, indicating that the mutations affect late events in the viral lytic cycle. In mutant-infected Vero cells, in which viral yields were highest, late mRNA levels were similar to those observed during wild-type infection. Levels of viral late mRNA from mutant-infected CV-1 and BSC-1 cells at 32 and 37 degrees C were reduced relative to those of wild-type-infected cells. The steady-state level of the major viral capsid protein, VP1, in mutant-infected CV-1 cells was reduced to the same extent as was late mRNA. The synthesis of agnoprotein could not be detected in mutant-infected CV-1 cells but was readily detected in CV-1 cells infected by wild-type SV40. Primer extension analyses indicated that most late mRNAs from mutant-infected CV-1 cells utilize start sites downstream from the major wild-type cap site (nucleotide 325) and the agnoprotein initiation codon (nucleotide 335). These results indicate that deletion of the carboxyl-terminal domain of T antigen affects viral late mRNA production, both quantitatively and qualitatively. The agnoprotein is detected late in the wild-type SV40 lytic cycle and is thought to play a role in the assembly or maturation of virions. Reduced hr/hf progeny yields could result from decreased capsid protein synthesis and, in the absence of detectable levels of agnoprotein, from inefficient use of available capsid proteins.     

trans-dominant defective mutants of simian virus 40 T antigen.

We constructed a collection of linker insertion mutants in the simian virus 40 (SV40) genome and studied several of these with changes limited to a part of the large T antigen gene corresponding to an amino acid sequence shared with other ATPases. Two of these mutants were found to have a novel phenotype in that they could not be complemented for plaque formation by a late-region deletion mutant. These two mutants, in contrast to other mutants in this region, were able to transform rat cells in culture at a frequency close to that of the wild-type gene. The noncomplementing mutants were found to be potent inhibitors of SV40 DNA replication despite the presence of wild-type T antigen in the transfected cells. This inhibition was shown to be the result of the introduced mutations in the large T antigen gene. We conclude that the large T antigens of the noncomplementing mutants can act as inhibitors of SV40 DNA replication.     

Nonviable mutants of simian virus 40 with deletions near the 3'' end of gene A define a function for large T antigen required after onset of viral DNA replication

Deletion mutants of simian virus 40 (SV40) with lesions at the three DdeI sites near the 3' end of the early region were constructed. Mutants with deletions at 0.203 and 0.219 map units (mu) which did not change the large T antigen reading frame were viable. This extends slightly the upstream boundary for the location of viable mutants with deletions in the 3' end of the A gene. Mutants with frameshift deletions at 0.193 and 0.219 mu were nonviable. These are the first nonviable mutants with deletions in this portion of the A gene. None of the three nonviable mutants with deletions at 0.219 mu produced progeny viral DNA. These three mutants all used the alternate reading frame located in this portion of the SV40 early region. The mutant with a deletion at 0.193 mu, dlA2459, was positive for viral DNA replication and was defective for adenovirus helper function. All of these mutations were located in the portion of the SV40 large T antigen which has no homology to the polyoma T antigens. These results indicate that this portion of large T antigen is required for some late step in the viral growth cycle and suggest that adenovirus helper function is required for productive infection by SV40.     

SV40-transformed simian cells support the replication of early SV40 mutants

CV-1, an established line of simian cells permissive for lytic growth of SV40, were transformed by an origin-defective mutant of SV40 which codes for wild-type T antigen. Three transformed lines (COS-1, -3, -7) were established and found to contain T antigen; retain complete permissiveness for lytic growth of SV40; support the replication of tsA209 virus at 40 degrees C; and support the replication of pure populations of SV40 mutants with deletions in the early region. One of the lines (COS-1) contains a single integrated copy of the complete early region of SV40 DNA. These cells are possible hosts for the propagation of pure populations of recombinant SV40 viruses.     

Functional role of BK virus tumor antigens in transformation.

We have examined the role of the human papovavirus BK virus (BKV) tumor (T) antigen(s) in the maintenance of transformation and have identified the domain of T antigen essential for transformation. BKV-transformed BHK 21 and NIH 3T3 cells expressing antisense T-antigen RNA lose their ability to grow in soft agar, indicating the need for the continued expression of T antigen for the maintenance of the transformed phenotype. Experiments using translation termination linker insertion and deletion mutagenesis of BKV T antigen demonstrate that amino acids 356 to 384 are essential for transformation. Although BKV T antigen shares 100, 95, and 82% amino acid homology with that of simian virus 40 (SV40) for the nuclear localization signal, p53-binding domain, and DNA-binding domain, respectively, the transformation domains of BKV and SV40 T antigens share only 54% homology. Also, BKV T antigen lacks a substantial portion of the ATPase domain of SV40, and our results indicate the dispensability of the remaining portion for transformation by this protein. We suggest that the differences in the amino acids in the identified transformation domains together with the differences in the ATPase domains may account for the differences in the transformation potentials of the two proteins.     

T antigen and template requirements for SV40 DNA replication in vitro.

A cell-free system for replication of SV40 DNA was used to assess the effect of mutations altering either the SV40 origin of DNA replication or the virus-encoded large tumor (T) antigen. Plasmid DNAs containing various portions of the SV40 genome that surround the origin of DNA replication support efficient DNA synthesis in vitro and in vivo. Deletion of DNA sequences adjacent to the binding sites for T antigen either reduce or prevent DNA synthesis. This analysis shows that sequences that had been previously defined by studies in vivo to constitute the minimal core origin sequences are also necessary for DNA synthesis in vitro. Five mutant T antigens containing amino acid substitutions that affect SV40 replication have been purified and their in vitro properties compared with the purified wild-type protein. One protein is completely defective in the ATPase activity of T antigen, but still binds to the origin sequences. Three altered proteins are defective in their ability to bind to origin DNA, but retain ATPase activity. Finally, one of the altered T antigens binds to origin sequences and contains ATPase activity and thus appears like wild-type for these functions. All five proteins fail to support SV40 DNA replication in vitro. Interestingly, in mixing experiments, all five proteins efficiently compete with the wild-type protein and reduce the amount of DNA replication. These data suggest that an additional function of T antigen other than origin binding or ATPase activity, is required for initiation of DNA replication.     

Mutational analysis of simian virus 40 T antigen: isolation and characterization of mutants with deletions in the T-antigen gene.

A series of mutants of simian virus 40 has been constructed with deletions in the coding sequence for large T antigen. Nucleotide sequence analysis indicates that 4 mutants have in-phase and 11 have out-of-phase deletions. Mutant DNAs were assayed for the following activities: the ability to form plaques, the ability to produce T antigen as scored by indirect immunofluorescence, viral DNA replication, and morphological transformation of rat cells. Two viable mutants were found, and these had deletions confined to the carboxyl terminus of T antigen. Only those mutants coding for polypeptides greater than 40% of the length of wildtype T antigen produced detectable nuclear fluorescence. The two viable mutants with deletions in the carboxyl terminus of the protein retained the ability both to replicate their DNA, although at a reduced level, and to transform nonpermissive cells. Mutants with sequence changes that result in the loss of more than 117 amino acids from the carboxyl terminus were not viable and were also defective in the DNA replication and transformation functions of T antigen, although several produced detectable nuclear fluorescence. These functions were also sensitive to the removal of amino acids near the amino terminus and in the middle of the protein.     

Site-directed mutagenesis of the simian virus 40 large T-antigen gene: replication-defective amino acid substitution mutants that retain the ability to induce morphological transformation.

We used a heteroduplex deletion loop mutagenesis procedure for directing sodium bisulfite-induced mutations to specific sites on viral or plasmid DNA to generate a series of SV40 large T-antigen point mutants. The mutations were directed to a region of the T-antigen gene, 0.5 map units, that is thought to be important for interaction of the protein with the viral origin of DNA replication. Of the 16 mutants reported here, 10 had lost the ability to replicate their DNA, and 3 others showed a reduced level of replication compared to wild type. All of the mutants tested were capable of transforming rat cells in culture by the dense focus assay. We conclude that the sequences of the early region around 0.5 map units are critical for the replication of viral DNA but not for the transformation function of T antigen.     

Mechanisms of interference with simian virus 40 (SV40) DNA replication by trans-dominant mutants of SV40 large T antigen.

Mutations at multiple sites within the simian virus 40 (SV40) early region yield large T antigens which interfere trans dominantly with the replicative activities of wild-type T antigen. A series of experiments were conducted to study possible mechanisms of interference with SV40 DNA replication caused by these mutant T antigens. First, the levels of wild-type T antigen expression in cells cotransfected with wild-type and mutant SV40 DNAs were examined; approximately equal levels of wild-type T antigen were seen, regardless of whether the cotransfected mutant was trans dominant or not. Second, double mutants that contained the mutation of inA2827, a strong trans-dominant mutation with a 12-bp linker inserted at the position encoding amino acid 520, and various mutations in other parts of the large-T-antigen coding region were constructed. The trans-dominant interference of inA2827 was not affected by second mutations within the p105Rb binding site or the amino or carboxy terminus of large T antigen. Mutation of the nuclear localization signal partially reduced the trans dominance of inA2827. The large T antigen of mutant inA2815 contains an insertion of 4 amino acids at position 168 of large T; this T antigen fails to bind SV40 DNA but is not trans dominant for DNA replication. The double mutant containing the mutations of both inA2815 and in A2827 was not trans dominant. The large T antigen of dlA2433 lacks amino acids 587 to 589, was unstable, and failed to bind p53. Combining the dlA2433 mutation with the inA2827 mutation also reversed the trans dominance completely, but the effect of the dlA2433 mutation on trans dominance can be explained by the instability of this double mutant protein. In addition, we examined several mutants with conservative point mutations in the DNA binding domain and found that most of them were not trans dominant. The implications of the results of these experiments on possible mechanisms of trans dominance are discussed.