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.     

Activation of the SV40 late promoter: direct effects of T antigen in the absence of viral DNA replication

We have examined the activation of the SV40 late promoter by inserting the late promoter and the viral origin of replication into chloramphenicol acetyltransferase (CAT) transient expression vectors. Very little late promoter activity was detected in CV-1 cells, compared with high activity in COS cells, in which replication occurs due to endogenous T antigen. Nonreplicative counterparts of these plasmids, containing a mutated origin of replication, produced significantly more late promoter activity in COS cells than any of the plasmids in CV-1 cells. When plasmids were cotransfected into CV-1 cells with a plasmid that supplies T antigen, the nonreplicative plasmid displayed 30% of the activity of the replicative plasmid. Using mutant T antigens unable to replicate viral DNA, late promoter activation occurred only with mutant T antigens that retain DNA binding activity. These results demonstrate that T antigen can substantially stimulate late promoter activity directly and independent of viral 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.     

Activation of the human epsilon- and beta-globin promoters by SV40 T antigen.

We have studied the effect of the SV40 T antigen on expression from human globin promoters fused to the bacterial chloramphenicol acetyltransferase (CAT) gene and compared its effect with the SV40 enhancer and the adenovirus E1A protein. We have observed that expression of p epsilon GLCAT and p beta GLCAT (the epsilon-globin or beta-globin promoter linked to the CAT gene) was significantly stimulated when cotransfected with a cloned T antigen plasmid into CV-1 cells, indicating that trans-activation of the globin promoters was mediated by SV40 T antigen. Transfection of the p beta GLCAT-SV (p beta GLCAT containing the SV40 enhancer element) into CV-1 cells resulted in a 50-60-fold increase in CAT activity as compared to p beta GLCAT (no enhancer). However, cotransfection of the p beta GLCAT-SV with the cloned T antigen resulted in an additional increase of CAT expression, which suggests that T antigen and the SV40 enhancer activate globin gene expression independently. We found that T antigen but not E1A could further stimulate the expression of an enhancer-containing plasmid in CV-1 cells; whereas E1A but not T antigen could further stimulate p epsilon GLCAT expression in COS-1 cells which constitutively express the SV40 T antigen. These results suggest that T antigen and E1A also act independently. Deletion analysis showed that the minimum sequence required for a detectable level of stimulation of the epsilon-globin promoter by T antigen is 177 bp 5' to the cap site, suggesting that the target sequences for response to T antigen do not reside in the canonical 100 bp promoter region, but rather reside in sequences further upstream, and therefore the cellular factors interacting with T antigen are not the TATA or CAT box binding proteins, but the proteins interacting with upstream regulatory sequences.     

Modified SV40 for analysis of mismatch repair in simian and human cells

We have developed a way of introducing specific mispairs into the genome of simian virus 40 and of determining the fate of the mispaired bases in simian and human cells. Mispairs are introduced into viral DNA within the intron of the gene coding for the large T antigen. Each DNA molecule harbors a single mispair in a defined orientation. Transfection of mismatch-containing SV40 DNA into host cells yields plaques, each corresponding to a productive infection initiated by a single viral DNA molecule. Isolation of DNA derived from individual plaques and determination of the DNA sequence at the site of the mispair reveals whether correction occurred and what the repair products are. Here we describe repair patterns for G/T and A/C mispairs in CV-1 African green monkey kidney cells, and for G/T mispairs in human fibroblasts derived from 3 normal individuals, 1 patient with xeroderma pigmentosum (complementation group A), and 3 patients with Bloom's syndrome. G/T mispairs, which arise in resting DNA through the deamination of 5-methylcytosine (mC) to form thymine, are corrected in all cases with extremely high efficiency and nearly always in favor of guanine. In contrast, A/C mispairs are corrected randomly and relatively inefficiently in simian cells.     

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.     

Purification of the simian virus 40 (SV40) T antigen DNA-binding domain and characterization of its interactions with the SV40 origin.

To better define protein-DNA interactions at a eukaryotic origin, the domain of simian virus 40 (SV40) large T antigen that specifically interacts with the SV40 origin has been purified and its binding to DNA has been characterized. Evidence is presented that the affinity of the purified T antigen DNA-binding domain for the SV40 origin is comparable to that of the full-length T antigen. Furthermore, stable binding of the T antigen DNA-binding domain to the SV40 origin requires pairs of pentanucleotide recognition sites separated by approximately one turn of a DNA double helix and positioned in a head-to-head orientation. Although two pairs of pentanucleotides are present in the SV40 origin, footprinting and band shift experiments indicate that binding is limited to dimer formation on a single pair of pentanucleotides. Finally, it is demonstrated that the T antigen DNA-binding domain interacts poorly with single-stranded DNA.     

Persistence of freely replicating SV40 recombinant molecules carrying a selectable marker in permissive simian cells

We have demonstrated that a SV40-pBR322 recombinant vector (pSV2-gpt) carrying a bacterial gene of selectable phenotype (Eco-gpt) may persist extrachromosomally in COS1 cells, a simian cell line that endogenously produces SV40 large T antigen. The amount of circular (supercoiled) recombinant DNA was estimated to be between 5 and 2000 copies per cell among several pSV2-transformed COS1 clonal lines examined. Complete pSV2 molecules were found in the majority of the transformants, although some of the pSV2 DNAs recovered were shown to have deletions in the pBR322 region. Our results indicate that removal of the pBR322 "inhibitory sequence" in pSV2 is not necessary for stable maintenance of these recombinant molecules in COS1 cells. In addition, large amounts of pSV2-related high molecular weight DNAs, probably concatemers of pSV2, were detected in the transformed lines.     

An N-terminal deletion mutant of simian virus 40 (SV40) large T antigen oligomerizes incorrectly on SV40 DNA but retains the ability to bind to DNA polymerase alpha and replicate SV40 DNA in vitro.

A peptide encompassing the N-terminal 82 amino acids of simian virus 40 (SV40) large T antigen was previously shown to bind to the large subunit of DNA polymerase alpha-primase (I. Dornreiter, A. Höss, A. K. Arthur, and E. Fanning, EMBO J. 9:3329-3336, 1990). We report here that a mutant T antigen, T83-708, lacking residues 2 to 82 retained the ability to bind to DNA polymerase alpha-primase, implying that it carries a second binding site for DNA polymerase alpha-primase. The mutant protein also retained ATPase, helicase, and SV40 origin DNA-binding activity. However, its SV40 DNA replication activity in vitro was reduced compared with that of wild-type protein. The reduction in replication activity was accompanied by a lower DNA-binding affinity to SV40 origin sequences and aberrant oligomerization on viral origin DNA. Thus, the first 82 residues of SV40 T antigen are not strictly required for its interaction with DNA polymerase alpha-primase or for DNA replication function but may play a role in correct hexamer assembly and efficient DNA binding at the origin.     

Analysis of nonpermissivity in mouse cells overexpressing simian virus 40 T antigen.

To analyze the nature of the nonpermissivity of mouse cells for simian virus 40 (SV40) DNA replication, we isolated mouse cells producing SV40 T antigen (Tag) at levels equal to or greater than that found in COS1 cells. These mouse cells were nonpermissive for the replication of exogenously added SV40 DNA, although purified Tag isolated from these cells was able to support SV40 DNA replication in vitro. Furthermore, when mouse cells expressing Tag were fused to monkey cells, SV40 DNA replication was observed. These results indicate that the mere production of large quantities of wild-type SV40 Tag does not overcome the block of nonpermissivity in mouse cells and that cellular factors must play a critical role.     

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.     

Protein-induced bending of the simian virus 40 origin of replication

A 3.5 S protein, isolated from mammalian nuclei, specifically binds to DNA fragments containing the simian virus 40 (SV40) origin of replication. Two distinct nucleoprotein complexes are formed, a complex with high electrophoretic mobility carrying probably only one protein molecule, and a complex with reduced electrophoretic mobility carrying probably two protein molecules per DNA fragment. Band shift competition as well as methylation interference assays locate the binding site of the protein in the A + T-rich "late" region of the origin between SV40 nucleotides 13 and 35. The late origin binding (LOB) protein and T antigen bind simultaneously to adjacent sites in the origin. Using circularly permuted DNA fragments of identical lengths we show that the LOB protein induces pronounced bending of the origin fragment. The bending center maps at the 5' end of the adenine tract with one bound protein molecule and at the 3' end when two LOB proteins are bound to one origin fragment.     

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.