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.     

The DnaAcos allele of Escherichia coli: hyperactive initiation is caused by substitution of A184V and Y271H,resulting in defective ATP binding and aberrant DNA replication control

Chromosomal DNA replication is regulated at the level of commitment to this biochemical pathway. In Escherichia coli, DnaA protein appears to regulate this process. A mutant form, DnaAcos, carrying four amino acid substitutions, is apparently defective in responding to regulatory signals, because it induces hyperactive initiation from the bacterial replication origin (oriC). In this report, the phenotype of hyperactive initiation is shown to be the result of two specific amino acid substitutions. One (A184V) immediately adjacent to a Walker A box (P loop motif) causes a defect in ATP binding (Carr and Kaguni, 1996, Mol Microbiol 20: 1307-1318). The second amino acid substitution (Y271H) appears to stabilize the activity of the mutant protein carrying the A184V substitution. The mutant protein carrying both amino acid substitutions (A184V + Y271H) is defective in modulating the frequency of initiation from oriC, as demonstrated by marker frequency analysis of oriC and a locus near the replication terminus. These results indicate that a defect in ATP binding results in aberrant control of DNA replication.     

Simian virus 40 large T-antigen point mutants that are defective in viral DNA replication but competent in oncogenic transformation.

The large T antigen of simian virus 40 (SV40) is a multifunctional protein that is essential in both the virus lytic cycle and the oncogenic transformation of cells by SV40. To investigate the role of the numerous biochemical and physiological activities of T antigen in the lytic and transformation processes, we have studied DNA replication-deficient, transformation-competent large T-antigen mutants. Here we describe the genetic and biochemical analyses of two such mutants, C2/SV40 and C11/SV40. The mutants were isolated by rescuing the integrated SV40 DNA from C2 and C11 cells (CV-1 cell lines transformed with UV-irradiated SV40). The mutant viral early regions were cloned into the plasmid vector pK1 to generate pC2 and pC11. The mutations that are responsible for the deficiency in viral DNA replication were localized by marker rescue. Subsequent DNA sequencing revealed point mutations that predict amino acid substitutions in the carboxyl third of the protein in both mutants. The pC2 mutation predicts the change of Lys----Arg at amino acid 516. pC11 has two mutations, one predicting a change of Pro----Ser at residue 522, and another predicting a Pro----Arg change at amino acid 549. The two C11 mutations were separated from each other to form two distinct viral genomes in pC11A and pC11B. pC2, pC11, pC11A, and pC11B are able to transform both primary and established rodent cell cultures. The C11 and C11A T antigens are defective in ATPase activity, suggesting that wild-type levels of ATPase activity are not necessary for the oncogenic transformation of cells by T antigen.     

Association of simian virus 40 T antigen with the nuclear matrix of infected and transformed monkey cells.

The subnuclear distribution of simian virus 40 large T antigen within nuclei of transformed Cos and C6 monkey cells was examined. Cos cells express wild-type T antigen but lack viral sequences required for DNA replication, whereas C6 cells contain a functional viral origin but express a replication-defective mutant T antigen which is unable to bind specifically to viral DNA. Discrete subpopulations of T antigen were isolated from the soluble nucleoplasm, chromatin, and nuclear matrix of both cell lines. Although only a small quantity (2 to 12%) of the total nuclear T antigen from Cos cells was associated with the nuclear matrix, a high proportion (25 to 50%) of C6 T antigen was bound to this structure. Results obtained from lytically infected monkey cells showed that early in infection, before viral replication was initiated, a higher proportion (22%) of T antigen was found associated with the nuclear matrix compared with amounts found associated with this structure later in infection (5 to 8%). These results suggest that an increased association of T antigen with this structure is not correlated with viral replication. T antigen isolated from the C6 nuclear matrix was more highly phosphorylated than was soluble C6 T antigen and was capable of binding to the host p53 protein. C6 DNA contains three mutations: two corresponding to N-terminal changes at amino acid positions 30 and 51 and a third located internally at amino acid position 153. By analysis of the subnuclear distribution of T antigen from rat cells transformed by C6 submutant T antigens, it was determined that one or both of the mutations at the NH2 terminus are responsible for the increased quantity of C6 T antigen associated with the nuclear matrix. These results suggest that neither a functional viral DNA replication origin nor the origin binding property of T antigen is required for association of this protein with the nuclear matrix.     

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.     

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.     

Simian virus 40 T antigens and J domains: analysis of Hsp40 cochaperone functions in Escherichia coli

The N-terminal exon of DNA tumor virus T antigens represents a J domain that can direct interaction with the host-encoded Hsp70 chaperones. We have taken advantage of rapid Hsp40 cochaperone assays with Escherichia coli to assess simian virus 40 (SV40)-encoded J-domain loss of function. We found a strong correlation between loss of cochaperone function in E. coli and defective SV40 growth, suggesting that the major role of the J domain in DNA tumor viruses is to provide cochaperone function. We also report the expression of native SV40 virus T antigens in E. coli. Our results show that small t antigen, but not large T antigen (LT) or LT truncation TN125 or TN136, can functionally replace under limited growth conditions DnaJ (Hsp40) function in vivo. In addition, purified small t antigen can efficiently stimulate E. coli DnaK's (Hsp70) ATPase in vitro, thus behaving like a bona fide cochaperone. Furthermore, small t amino acids 83 to 174, which are adjacent to the viral J domain, can replace the E. coli DnaJ J-domain glycine-phenylalanine-rich domain, immediately adjacent to the J-domain sequences, even in the absence of significant amino acid similarity to their DnaJ counterpart. Taken together, our studies demonstrate that functionally related Hsp40 proteins from mammalian viral systems can be rapidly studied in bacteria and exploited to probe the universally conserved Hsp70 chaperone machine mechanism.     

Polyomavirus small T antigen enhances replication of viral genomes in 3T6 mouse fibroblasts.

Transfection of 3T6 cells with a cloned polyomavirus genome encoding only large T antigen resulted in DNA replication with only about 1/10 the efficiency of wild-type viral DNA coding for all three T antigens. This replication defect was at least in part overcome by the simultaneous transfections of polyomavirus genomes which allowed the expression of small T antigen. We conclude that polyomavirus small T antigen has a (probably indirect) role in replication.     

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.     

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.     

Simian virus 40 mutant T antigens with relaxed specificity for the nucleotide sequence at the viral DNA origin of replication.

Base substitution of the ori region of simian virus 40 leads to plaque morphology mutants with markedly decreased DNA replication. Second-site mutations within the simian virus 40 T antigen gene suppress the plaque phenotype and replication defect of base-substituted ori mutants. Two second-site mutations have been mapped to a small segment of the T antigen gene, just beyond the distal splice junction. DNA sequence analysis revealed a single missense change in this segment of the T antigen gene of each of these second-site revertants, leading to a change in codon 157 in one case and codon 166 in the other. The mutant T antigens displayed relaxed specificity for the ori signal, i.e., they can function with several variously modified ori sequences, including those with small nucleotide deletions or insertions that are inactive for replication when coupled with wild-type T antigen. Thus a region of T antigen has been identified that appears to be intimately involved in vivo in binding to the ori sequence to initiate viral DNA replication.     

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.     

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

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

Temperature-sensitive mutants identify crucial structural regions of simian virus 40 large T antigen.

We have completed the cloning and sequencing of all known temperature-sensitive, amino acid substitution mutants of simian virus 40 large T antigen (tsA mutants). Surprisingly, many of the mutants isolated from distinct viral strains by different laboratories are identical. Thus, 17 independently isolated mutants represent only eight distinct genotypes. This remarkable clustering of tsA mutations in a few "hot spots" in the amino acid sequence of T antigen and the temperature-sensitive phenotypes of the mutations strongly suggest that these amino acids play crucial roles in organizing the structure of one or more functional domains. Most of the mutations are located in highly conserved regions of T antigen that correlate with DNA binding, protein-protein interactions, or ATP binding. With the exception of one mutant with a lesion in the putative ATP-binding region, all the mutants are temperature sensitive for DNA replication.     

Hsc70 contacts helix III of the J domain from polyomavirus T antigens: addressing a dilemma in the chaperone hypothesis of how they release E2F from pRb

Hsc70's expected binding site on helix II of the J domain of T antigens appears to be blocked in its structure bound to tumor suppressor pRb. We used NMR to map where mammalian Hsc70 binds the J domain of murine polyomavirus T antigens (PyJ). The ATPase domain of Hsc70 unexpectedly has its biggest effects on the NMR peak positions of the C-terminal end of helix III of PyJ. The Hsc70 ATPase domain protects the C-terminal end of helix III of PyJ from an uncharged paramagnetic probe of chelated Gd(III), clearly suggesting the interface. Effects on the conserved HPD loop and helix II of PyJ are smaller. The NMR results are supported by a novel assay of Hsc70's ATP hydrolysis showing that mutations of surface residues in PyJ helix III impair PyJ-dependent stimulation of Hsc70 activity. Evolutionary trace analysis of J domains suggests that helix III usually may join helix II in contributing specificities for cognate hsp70s. Our novel evidence implicating helix III differs from evidence that Escherichia coli DnaK primarily affects helix II and the HPD loop of DnaJ. We find the pRb-binding fragment of E2F1 to be intrinsically unfolded and a good substrate for Hsc70 in vitro. This suggests that E2F1 could be a substrate for Hsc70 recruited by T antigen to an Rb family member. Importantly, our results strengthen the chaperone hypothesis for E2F release from an Rb family member by Hsc70 recruited by large T antigen. That is, it now appears that Hsc70 can freely access helix III and the HPD motif of large T antigen bound to an Rb family member.     

Identification of a New Motif in Family B DNA Polymerases by Mutational Analyses of the Bacteriophage T4 DNA Polymerase

Structure-based protein sequence alignments of family B DNA polymerases revealed a conserved motif that is formed from interacting residues between loops from the N-terminal and palm domains and between the N-terminal loop and a conserved proline residue. The importance of the motif for function of the bacteriophage T4 DNA polymerase was revealed by suppressor analysis. T4 DNA polymerases that form weak replicating complexes cannot replicate DNA when the dGTP pool is reduced. The conditional lethality provides the means to identify amino acid substitutions that restore replication activity under low-dGTP conditions either by correcting the defect produced by the first amino acid substitution or by generally increasing the stability of polymerase complexes; the second type are global suppressors that can effectively counter the reduced stability caused by a variety of amino acid substitutions. Some amino acid substitutions that increase the stability of polymerase complexes produce a new phenotype—sensitivity to the antiviral drug phosphonoacetic acid. Amino acid substitutions that confer decreased ability to replicate DNA under low-dGTP conditions or drug sensitivity were identified in the new motif, which suggests that the motif functions in regulating the stability of polymerase complexes. Additional suppressor analyses revealed an apparent network of interactions that link the new motif to the fingers domain and to two patches of conserved residues that bind DNA. The collection of mutant T4 DNA polymerases provides a foundation for future biochemical studies to determine how DNA polymerases remain stably associated with DNA while waiting for the next available dNTP, how DNA polymerases translocate, and the biochemical basis for sensitivity to antiviral drugs.