Relationship of replication and transcription of Simian Virus 40 DNA

Global effects of DNA replication and DNA replication origin activity on eukaryotic gene expression

This report provides a global view of how gene expression is affected by DNA replication. We analyzed synchronized cultures of Saccharomyces cerevisiae under conditions that prevent DNA replication initiation without delaying cell cycle progression. We use a higher-order singular value decomposition to integrate the global mRNA expression measured in the multiple time courses, detect and remove experimental artifacts and identify significant combinations of patterns of expression variation across the genes, time points and conditions. We find that, first, approximately 88% of the global mRNA expression is independent of DNA replication. Second, the requirement of DNA replication for efficient histone gene expression is independent of conditions that elicit DNA damage checkpoint responses. Third, origin licensing decreases the expression of genes with origins near their 3' ends, revealing that downstream origins can regulate the expression of upstream genes. This confirms previous predictions from mathematical modeling of a global causal coordination between DNA replication origin activity and mRNA expression, and shows that mathematical modeling of DNA microarray data can be used to correctly predict previously unknown biological modes of regulation.

The minimum replication origin of merkel cell polyomavirus has a unique large T-antigen loading architecture and requires small T-antigen expression for optimal replication

Merkel cell polyomavirus (MCV) is a recently discovered human polyomavirus causing the majority of human Merkel cell carcinomas. We mapped a 71-bp minimal MCV replication core origin sufficient for initiating eukaryotic DNA replication in the presence of wild-type MCV large T protein (LT). The origin includes a poly(T)-rich tract and eight variably oriented, GAGGC-like pentanucleotide sequences (PS) that serve as LT recognition sites. Mutation analysis shows that only four of the eight PS are required for origin replication. A single point mutation in one origin PS from a naturally occurring, tumor-derived virus reduces LT assembly on the origin and eliminates viral DNA replication. Tumor-derived LT having mutations truncating either the origin-binding domain or the helicase domain also prevent LT-origin assembly. Optimal MCV replication requires coexpression of MCV small T protein (sT), together with LT. An intact DnaJ domain on the LT is required for replication but is dispensable on the sT. In contrast, PP2A targeting by sT is required for enhanced replication. The MCV origin provides a novel model for eukaryotic replication from a defined DNA element and illustrates the selective pressure within tumors to abrogate independent MCV replication.

DNA sequences outside the simian virus 40 early region cause downregulation of T-antigen production in permissive simian cells

Using a series of modified wtSV40 and early region SV40 DNAs we assayed the effect of viral late region sequences on T-antigen production by the SV40 early region. We found that SV40 late region (L-SV40) DNA sequences reduced T-antigen (T-Ag) production by the SV40 early region (E-SV40) when both viral regions were linked as they are in wtSV40 DNA. This was demonstrated by Western analysis which showed that E-SV40 DNA produced 10 times more T-Ag than wtSV40 DNA L-SV40, with its own promoter but unlinked to E-SV40 DNA, also greatly inhibited T-Ag production when it was contrasfected with E-SV40. Therefore, L-SV40 DNA inhibited T-Ag production by E-SV40 DNA when present in cis or in trans. We have shown that expression of the SV40 late transcription unit dominated that of the early (T-Ag gene) transcription unit because late region RNA accumulated to much higher levels than early viral RNA. However, in contrasfected cells L-SV40 DNA did not replicate to higher levels than E-SV40 DNA. We offer a model for control of T-Ag expression in which a relatively small amount of T-Ag activates late transcription at the expense of T-Ag gene transcription and that this represents a switch from early to late viral gene expression. We suggest that when activation of the late transcription unit occurs at the late promoter, expression of the T-Ag gene is greatly reduced. The L-SV40 promoter may inhibit T-Ag gene transcription by sequestering cellular factors required for early transcription, factors which may be present in limited amounts. We suggest further that activation of late transcription allows for the necessary production of large amounts of capsomeres and virions and downregulation of early transcription prevents the early region from interfering with capsid synthesis. We tested the model using a construct with a wild-type T-Ag gene but with mutations in the SV40 major late promoter which prevent the promoter from being bound by cellular repressors of late transcription. We found that this construct, which overproduces late SV40 RNA, was defective for T-Ag production. This indicates that activation of the late promoter results in repression of T-Ag gene expression.

Simian virus 40 T antigen activates the late promoter by modulating the activity of negative regulatory elements

Late promoter activity measured before viral DNA replication results from a complex involvement of negative and positive cis-acting elements located both in the enhancer and in the 21-bp repeats. GC motifs located within the 21-bp repeats act in cooperation with sequences overlapping the early TATA box to down-regulate the late promoter activity. Analysis of insertion mutants indicates that the late promoter might be negatively regulated at least partially by the early promoter machinery. The GTI motif located within the enhancer as well as the GC motifs lose the ability to down-regulate the late promoter in the presence of T antigen. Results obtained with tsA58 protein indicate that two different domains of T antigen are involved in the negative autoregulation of the early promoter activity and in the release of the down-regulation of the late promoter by the GC motifs.

Replication dependent and cell specific activation of the polyomavirus early promoter

The relationship of viral DNA replication to the activation of viral gene expression is usually considered with respect to late genes. In this report we examine the replication activation of the polyomavirus early promoter. Using origin active and inactive mutants to drive luciferase gene expression from the polyomavirus early promoter, we show that the early promoter is also subjected to a replication dependent activation. The degree of activation can be up to a hundred fold greater than that seen without replication and is about 13 fold on a per template basis. This replication based activation is, however, cell type dependent and was seen in FOP cells but not in 3T6 cells. Analysis of the requirements of cis acting DNA show that these enhancer elements affect early transcription predominantly through the activation of replication, although some replication independent stimulation can also be seen. The implications of this result for the regulation of polyomavirus early gene regulation are considered.

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.

Control elements situated downstream of the major transcriptional start site are sufficient for highly efficient polyomavirus late transcription

In a transient expression assay in mouse fibroblasts in which neither replication nor T-antigen synthesis occurred, the polyomavirus late promoter functioned faithfully and even more efficiently than the simian virus 40 early promoter. Surprisingly, the DNA sequences upstream of the main transcriptional start sites were not required to obtain the high mRNA level observed. It appeared to result from the combined action of a basal promoter element within the A enhancer domain and of a more downstream element, located in the VP3 intron and abutting the late splice donor. We also show that although an enhancer region was required, enhancer function per se was not. Instead, it appeared that only a defined subset of the DNA-protein interactions necessary for enhancer function was involved in late promoter activity.

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.

A transcription factor from simian virus 40 chromosomes which activates the viral late promoter in vitro

We have characterized a transcription factor, obtained from simian virus 40 (SV40) chromosomes, which activates transcription from the SV40 late promoter in vitro. The late promoter-activating factor was distinct from SV40 T antigen as judged by its behavior on chromatography on hydroxylapatite; it was not recognized by anti-T antibodies, while T antigen itself was recognized. T antigen from SV40 chromosomes, on the other hand, abolished transcription in vitro from the early promoter. In DNase I footprinting experiments, a partially purified late promoter-activating factor preparation protected a region of DNA centered on SV40 nucleotide 270, which is between the repeated 72-base-pair enhancer and the major late RNA start site. Proteins from HeLa cells did not give the same footprint at this position. Gel mobility shift assays showed that proteins from SV40-infected CV-1 cells form a complex with DNA containing this binding site. The complex has a different rate of gel migration and a higher stability than complexes formed with proteins from uninfected cells.

Simian virus 40 T antigen alters the binding characteristics of specific simian DNA-binding factors

The late promoter of simian virus 40 is transcriptionally activated, in trans, by large T antigen, the primary viral early gene product. Although large T antigen is a well-characterized DNA-binding protein, a variety of data suggest that its trans-activation function does not require direct interaction with DNA. We demonstrate that defined late promoter elements, omega (omega), tau (tau), and delta (delta), necessary for T-antigen-mediated trans-activation, are binding sites for simian cellular factors, not T antigen. Two of the late promoter elements (omega and tau) are shown to bind the same factor or family of factors. These factors bind to a site very similar to that for the HeLa cell factor AP1. We refer to these factors as the simian AP1-sequence recognition proteins (sAP1-SRPs). Compared with normal simian CV-1P cells, the sAP1-SRPs from T-antigen-producing COS cells, or from 14-h simian virus 40-infected CV-1P cells, showed altered binding patterns to both the omega and tau binding sites. In addition, the sAP1-SRPs from T-antigen-containing cells bound to the tau site more stably than did the analogous factors from normal CV-1P cells. The altered pattern of binding and the increased stability of binding correlated with the presence of T antigen in the cell. Additionally, the alteration of the binding pattern within 14 h of infection in CV-1P cells is temporally correct for late promoter activation. Overall, the data show (i) that the late promoter elements necessary for T-antigen-mediated trans-activation contain binding sites for simian cellular DNA-binding proteins; (ii) that the presence of T antigen causes alterations in the binding characteristics of specific simian cellular DNA-binding factors or families of factors; and (iii) that factors which bind to the late promoter elements required for activation have altered and more stable binding characteristics in the presence of T antigen. These points strongly suggest that T antigen mediates trans-activation indirectly through the alteration of binding of at least one specific simian cellular factor, sAP1-SRP, or through the induction of a family of sAP1-SRP factors.

Simian virus 40 T antigen alters the binding characteristics of specific simian DNA-binding factors

The late promoter of simian virus 40 is transcriptionally activated, in trans, by large T antigen, the primary viral early gene product. Although large T antigen is a well-characterized DNA-binding protein, a variety of data suggest that its trans-activation function does not require direct interaction with DNA. We demonstrate that defined late promoter elements, omega (omega), tau (tau), and delta (delta), necessary for T-antigen-mediated trans-activation, are binding sites for simian cellular factors, not T antigen. Two of the late promoter elements (omega and tau) are shown to bind the same factor or family of factors. These factors bind to a site very similar to that for the HeLa cell factor AP1. We refer to these factors as the simian AP1-sequence recognition proteins (sAP1-SRPs). Compared with normal simian CV-1P cells, the sAP1-SRPs from T-antigen-producing COS cells, or from 14-h simian virus 40-infected CV-1P cells, showed altered binding patterns to both the omega and tau binding sites. In addition, the sAP1-SRPs from T-antigen-containing cells bound to the tau site more stably than did the analogous factors from normal CV-1P cells. The altered pattern of binding and the increased stability of binding correlated with the presence of T antigen in the cell. Additionally, the alteration of the binding pattern within 14 h of infection in CV-1P cells is temporally correct for late promoter activation. Overall, the data show (i) that the late promoter elements necessary for T-antigen-mediated trans-activation contain binding sites for simian cellular DNA-binding proteins; (ii) that the presence of T antigen causes alterations in the binding characteristics of specific simian cellular DNA-binding factors or families of factors; and (iii) that factors which bind to the late promoter elements required for activation have altered and more stable binding characteristics in the presence of T antigen. These points strongly suggest that T antigen mediates trans-activation indirectly through the alteration of binding of at least one specific simian cellular factor, sAP1-SRP, or through the induction of a family of sAP1-SRP factors.

Analysis of simian virus 40 infection of CV-1 cells by quantitative two-color fluorescence with flow cytometry

Quantitative two-color fluorescent analysis of Simian virus (SV40) infection of permissive CV-1 cells was investigated. Analysis included by quantitation of cellular DNA, the early viral tumor (T) antigen with a monoclonal antibody, and late viral (V) antigens with a polyclonal antibody. T antigen was detected in all phases of the cell cycle at 6 and 12 h, after SV40 infection of growth arrested cells. At later time intervals, the percentage of T-antigen-positive cells increased with the induction of the cells into successive rounds of DNA synthesis and an increase in tetraploid-polyploid cells. The amount of T antigen per cell increased as the cells entered the successive stages of the cell cycle (G0/G1----G2 + M----tetraploid S and G2 + M). The V antigen from adsorbed virus was detected immediately after infection. Synthesis of V antigen began in late S and G2 + M phases of the cell cycle. This quantitative analysis allows a definitive determination of antigen per cell in a population correlated with the cell cycle and may be useful in correlating viral and cellular events with transformation.

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.

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.

Sequence-specific binding of simian virus 40 A protein to nonorigin and cellular DNA

The simian virus 40 A protein (T antigen) recognized and bound to the consensus sequence 5'-GAGGC-3' in DNA from many sources. Sequence-specific binding to single pentanucleotides in randomly chosen DNA predominated over binding to nonspecific sequences. The asymmetric orientation of protein bound to nonorigin recognition sequences also resembled that of protein bound to the origin region of simian virus 40 DNA. Sequence variations in the DNA adjacent to single pentanucleotides influenced binding affinities even though methylation interference and protection studies did not reveal specific interactions outside of pentanucleotides. Thus, potential locations of A protein bound to any DNA can be predicted although the determinants of binding affinity are not yet understood. Sequence-specific binding of A protein to cellular DNA would provide a mechanism for specific alterations of host gene expression that facilitate viral function.

Sequence-specific binding of simian virus 40 A protein to nonorigin and cellular DNA

The simian virus 40 A protein (T antigen) recognized and bound to the consensus sequence 5'-GAGGC-3' in DNA from many sources. Sequence-specific binding to single pentanucleotides in randomly chosen DNA predominated over binding to nonspecific sequences. The asymmetric orientation of protein bound to nonorigin recognition sequences also resembled that of protein bound to the origin region of simian virus 40 DNA. Sequence variations in the DNA adjacent to single pentanucleotides influenced binding affinities even though methylation interference and protection studies did not reveal specific interactions outside of pentanucleotides. Thus, potential locations of A protein bound to any DNA can be predicted although the determinants of binding affinity are not yet understood. Sequence-specific binding of A protein to cellular DNA would provide a mechanism for specific alterations of host gene expression that facilitate viral function.

The simian virus 40 minimal origin and the 72-base-pair repeat are required simultaneously for efficient induction of late gene expression with large tumor antigen

We have studied the temporal regulation of simian virus 40 (SV40) late gene expression by construction and transient expression analysis of plasmids containing the transposon Tn9 chloramphenicol acetyltransferase gene placed downstream from the late control region. The SV40 origin region in the early (but not the late) orientation promotes chloramphenicol acetyltransferase gene expression efficiently in monkey cells lacking large tumor (T) antigen. In monkey cells producing T antigen, the promoter activity of the late control region is induced by approximately 1,000-fold above the basal level. By deletion and point mutagenesis, we define two domains of the late control region required for efficient induction with T antigen. Domain I is the minimal replication origin containing T-antigen binding site II. Domain II consists of the 72-base-pair (bp) repeat and a 19-bp downstream sequence up to nucleotide 270. Domains I and II should act synergistically because the absence of either one or the other decreases induction efficiency by 2 orders of magnitude. Though a complete copy of domain II is optimal, the origin-proximal 22-bp portion of this domain is sufficient. The 21-bp repeat, located between domains I and II, is dispensable for this induction, as are sequences located downstream from nucleotide 270 in the late orientation.

Stimulation of simian virus 40 late gene expression by simian virus 40 tumor antigen

The early simian virus 40 (SV40) gene product, large tumor (T) antigen, is responsible for the initiation of viral DNA replication and the autoregulation of early gene expression through direct protein-DNA interactions. We investigated the role of T antigen in late viral gene expression, independent of its function in amplifying templates through DNA replication. SV40 DNA was transfected into BSC-1 and COS-1 cells and cultured in the presence of inhibitors of DNA replication. Electrophoretic immunoblot analysis indicated that both the onset and the extent of SV40 late gene expression is increased in COS-1 cells, which constitutively express SV40 T antigen. Blot hybridization analysis of poly(A)-selected RNA demonstrated that the level of synthesis of the major late structural protein VP-1 in COS-1 cells was due to increased transcription. Similar results were obtained when plasmids that contain the SV40 late gene but lack both the origin for viral DNA replication and the early gene coding region were transfected onto COS-1 cells. Using lines of SV40-transformed monkey kidney cells that express altered T antigens, we found that enhanced expression of the late gene product is correlated with the ability of T antigen to bind SV40 DNA. These results indicate that large T antigen plays a role in the stimulation of late viral gene expression.

Polyomavirus and simian virus 40 large T antigens bind to common DNA sequences

The large T antigens of polyomavirus and simian virus 40 (SV40) recognize and bind to specific, noncoding DNA sequences which are located between the beginning of the early and late transcription units in their respective genomes. Each large T antigen binds to multiple sites within this intergenic DNA stretch. Polyomavirus large T antigen binds to at least two sites within its DNA, and SV40 large T antigen binds to three sites within SV40 DNA. Comparison of the DNA sequences which comprise the binding sites in polyomavirus DNA or those which make up the binding sites in SV40 DNA has led to recognition of a common sequence, -GAGGC-, which is repeated within each large-T-antigen-binding site. We tested the hypothesis that repeats of this pentanucleotide form the recognition-binding site for polyomavirus and SV40 large T antigen. This was accomplished by measuring the binding of each large T antigen to both polyomavirus and SV40 DNA and to synthetic DNA substrates which did or did not contain repeats of the -GAGGC- sequence. Polyomavirus large T antigen bound to specific fragments of SV40 DNA, and SV40 large T antigen bound with specificity to polyomavirus DNA. In each case, the DNA fragments bound by the heterologous large T antigen were the same as those bound by the homologous large T antigen. Moreover, polyomavirus and SV40 large T antigen only bound to synthetic DNA substrates which contained repeats of the pentameric sequence. This synthetic DNA also competed effectively with native polyomavirus or SV40 DNA as a substrate in binding reactions with one or the other large T antigen. These results led us to conclude that repeats of the -GAGGC- sequence form the recognition-binding site for both polyomavirus and SV40 large T antigen.

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.

Salt-resistant association of simian virus 40 T antigen with simian virus 40 DNA in nucleoprotein complexes

Treatment of nucleoprotein complexes (NPCs) from simian virus 40 (SV40)-infected TC7 cells with NaCl (1 or 2 M) or guanidine-hydrochloride (1 or 2 M) resulted in a significant fraction of T antigen still associated with SV40 (I) DNA. Immunoprecipitation of the salt-treated NPCs with SV40 anti-T serum indicated that T antigen is preferentially associated with SV40 (I) DNA rather than with SV40 (II) DNA. Treatment of the NPCs with 4 M guanidine-hydrochloride, however, resulted in a substantial decrease in the amount of SV40 (I) and (II) DNA associated with T antigen. As the temperature was increased to 37 degrees C during incubation of NPCs with NaCl or guanidine-hydrochloride, there was a decrease in the amount of SV40 (I) and (II) DNA immunoprecipitated with SV40 anti-T serum. In the absence of salt, temperature had no effect on the association of T antigen with the SV40 DNA in the NPCs. Treatment of NPCs from SV40 wildtype or tsA58-infected cells grown at the permissive temperature with 1 or 2 M NaCl indicated that tsA T antigen has the same sensitivities as wild-type T antigen to high salt treatment when bound to DNA in NPCs. Characterization of the proteins associated with SV40 (I) DNA after high salt treatment revealed that, in addition to T antigen, a certain amount of viral capsid proteins VP1 and VP3 remained associated with the DNA. Complexes containing SV40 (I) DNA had a sedimentation value of 53S after 1 M NaCl treatment and 43S after 2 M NaCl treatment.

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.

Mutational analysis of simian virus 40 T antigen: stimulation of cellular DNA synthesis and activation of rRNA genes by mutants with deletions in the T-antigen gene

The biological activity of several deletion mutants of simian virus 40, cloned in pBR322, was determined. Three functions of the simian virus 40 A gene were studied: (i) the ability to express T antigen; (ii) the ability to induce cell DNA replication; and (iii) the ability to reactivate silent rRNA genes in hybrid cells. Recombinant plasmid DNA was introduced into cells by manual microinjection or by transfection. The results (together with previous reports) indicate that the critical sequences for these three functions are located separately on the simian virus 40 A gene, as follows: (i) the sequences necessary for the detection of the common antigenic determinant of T antigen extend from nucleotide 4147 to nucleotide 4001 (map units 0.45 to 0.42); (ii) the sequences critical for the stimulation of cell DNA synthesis extend from nucleotide 4327 to nucleotide 4001 (map units 0.49 to 0.42); and (iii) those critical for the reactivation of rRNA genes extend approximately from nucleotide 3827 to nucleotide 3526 (map units 0.39 to 0.33).

Mutational analysis of simian virus 40 T antigen: stimulation of cellular DNA synthesis and activation of rRNA genes by mutants with deletions in the T-antigen gene

The biological activity of several deletion mutants of simian virus 40, cloned in pBR322, was determined. Three functions of the simian virus 40 A gene were studied: (i) the ability to express T antigen; (ii) the ability to induce cell DNA replication; and (iii) the ability to reactivate silent rRNA genes in hybrid cells. Recombinant plasmid DNA was introduced into cells by manual microinjection or by transfection. The results (together with previous reports) indicate that the critical sequences for these three functions are located separately on the simian virus 40 A gene, as follows: (i) the sequences necessary for the detection of the common antigenic determinant of T antigen extend from nucleotide 4147 to nucleotide 4001 (map units 0.45 to 0.42); (ii) the sequences critical for the stimulation of cell DNA synthesis extend from nucleotide 4327 to nucleotide 4001 (map units 0.49 to 0.42); and (iii) those critical for the reactivation of rRNA genes extend approximately from nucleotide 3827 to nucleotide 3526 (map units 0.39 to 0.33).

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.

Construction and characterization of viable deletion mutants of simian virus 40 lacking sequences near the 3' end of the early region

Five viable deletion mutants of simian virus 40 (SV40) were prepared and characterized. These mutants lack 15 to 60 base pairs between map positions 0.198 and 0.218, near the 3' end of the early region of SV40 and extend further into the body of the A gene, encoding the large T antigen, than previously described deletion mutants. These mutants were isolated after transfection of monkey kidney CV-1p cells with full-sized linear DNA prepared by partial digestion of form I SV40 DNA with restriction endonucleases HinfI or MboII, followed by removal of approximately 25 base pairs of DNA from the 5' termini using lambda-5'-exonuclease and purification of the DNA in agarose gels. Based on camparisons of the DNA sequence of SV40 and polyoma virus, these mutations map in the 19% of the SV40 A gene that shares no homology with the A gene of polyoma virus. The mutations exist in two different genetic backgrounds: the original set of mutants (dl2401 through dl2405) was prepared, using as a parent SV40 mutant dl862, which has a deletion at the single HpaII site (0.725 map unit). A second set (dl2491 through dl2495) contains the same deletions in a wild-type SV40 (strain SV-S) background. Relative to wild-type SV40, the original mutants showed reduced rates of growth, lower yields of progeny virus and viral DNA, and smaller plaque size; in these properties the mutants resembled parental dl862, although mutant progeny yields were usually lower than yields of dl862, suggesting a possible interaction between the two deletions. The second set of mutants had growth properties and progeny yields similar to those of wild-type SV40; however, Southern blotting experiments indicated that viral DNA replication proceeds at a slightly reduced rate. All of the mutants transformed mouse NIH/3T3 cells and mouse embryo fibroblasts at the same frequency as wild-type SV40. Mutants dl2402, dl2492, and dl2405 consistently produced denser and larger foci in both types of cells. All mutants directed the synthesis of shortened large T antigens. Adenovirus helper function was retained by all mutants.

Stimulation of host centriolar antigen in TC7 cells by simian virus 40: requirement for RNA and protein syntheses and an intact simian virus 40 small-t gene function

Simian virus 40 (SV 40) stimulated a host cell antigen in the centriolar region after infection of African green monkey kidney (AGMK) cells. The addition of puromycin and actinomycin D to cells infected with SV40 within 5 h after infection inhibited the stimulation of the host cell antigen, indicating that de novo protein and RNA syntheses that occurred within the first 5 h after infection were essential for the stimulation. Early viable deletion mutants of SV40 with deletions mapping between 0.54 and 0.59 map units on the SV40 genome, dl2000, dl2001, dl2003, dl2004, dl2005, dl2006, and dl2007, did not stimulate the centriolar antigen above the level of uninfected cells. This indicated that an intact, functional small-t protein was essential for the SV40-mediated stimulation of the host cell antigen. Our studies, using cells infected with nondefective adenovirus-SV40 hybrid viruses that lack the small-t gene region of SV40 (Ad2+ND1, Ad2+ND2, Ad2+ND3, Ad2+ND4, and Ad2+ND5), revealed that the lack of small-t gene function of SV40 could be complemented by a gene function of the adenovirus-SV40 hybrid viruses for the centriolar antigen stimulation. Thus, adenovirus 2 has a gene(s) that is analogous to the small-t gene of SV40 for the stimulation of the host cell antigen in AGMK cells.

Evidence for simian virus 40 late transcriptional control: mixed infections of wild-type simian virus 40 and a late leader deletion mutant exhibit trans effects on late viral RNA synthesis

Mixed infections involving equal multiplicities of wild-type simian virus 40 and viable deletion mutant dl861 resulted in decreased cytoplasmic levels of wild-type-derived male mRNA, as well as very low to undetectable levels of mutant-derived late mRNA, as compared with individual infections. The dl861 deletion removes 16 to 25 base pairs from the late leader region. This deletion was shown to be the direct cause of the mixed-infection effect; replacement of the deletion with wild-type sequences restored normal levels of late mRNAs in mixed infections. Other viral functions, e.g., early gene expression and replication, were found to be unaffected by the dl861 deletion. Further examination of the mixed-infection effect showed that the levels of unspliced nuclear precursors of late mRNA, derived from both the mutant and wild-type genomes, were decreased or undetectable, in accord with the cytoplasmic results. Thus, the effect appears to be occurring at the transcriptional level. These data demonstrate a trans-acting effect on late transcription, which is detectable due to the presence of the dl861 mutant in the mixed infection. This finding is indicative of a diffusible factor which exerts a control on simian virus 40 late gene expression at the transcriptional level. A model for positive control of simian virus 40 late gene expression is presented.

Different forms of simian virus 40 large tumor antigen varying in their affinities for DNA

In various permissive monkey cell lines infected with simian virus 40 there are two major forms of large T antigen which differ in their rate of sedimentation through sucrose gradients. The lighter (5 to 7S) form sedimented slightly more rapidly than the 4S tRNA marker, whereas the heavier (16S) form sedimented slightly more slowly than the 18S rRNA marker. The small t antigen did not form complexes which sedimented as rapidly as those formed by the large T antigen. The 16S T antigen form was converted to the slowly sedimenting 5 to 7S form in the presence of 1.0 M NaCl. The majority of large T antigen synthesized in cell-free protein-synthesizing systems primed by mRNA isolated from infected cells sedimented as the 5 to 7S form even when premixed with excess quantities of cellular T antigen. The formation of the 16S form in infected cells did not require ongoing viral or cellular DNA replication because considerable quantities of this T antigen class were produced in the presence of DNA synthesis inhibitors, such as cytosine arabinoside. Both 5 to 7S and 16S forms could be isolated separately and, therefore, each could be analyzed as to its individual properties. The 5 to 7S T antigen form bound more efficiently and tightly to DNA and had specific affinity for sequences at the viral origin of replication, whereas the 16S form bound less efficiently to DNA and exhibited very little specificity for origin-containing DNA sequences. It is therefore likely that the active DNA-binding species of T antigen isolated from infected cells is the 5 to 7S form.

Simian virus 40 mutant with transposed T-antigen and VP1 genes

A simian virus 40 mutant with the T-antigen gene transposed to the late region of the viral genome has been constructed. This transposed molecule directed the synthesis of a full-sized, 92,000-dalton large T antigen in both permissive and nonpermissive cells. This large T antigen functioned in the initiation of viral DNA replication and in the transformation of nonpermissive cells. T-antigen synthesis by this transposed genome had the characteristics of late transcription, thus indicating that functional large T antigen of simian virus 40 is not required for the initiation of late transcription.

Transforming genes and gene products of polyoma and SV40

The small DNA-containing viruses, SV40 and polyoma, transform cells in vitro and induce tumors in vivo. For both viruses two genes required for transformation have been found. The genes required for transformation are also involved in productive infection. Although the two viruses are similar in their effects on cells, the organization of the transforming genes and gene products is different. The purpose of this review is to compare what is known about the biology and the biochemistry of the early regions of the two viruses. The genetic and biochemical studies defining the sequences important for transformation will be reviewed. Then, the products of the transforming genes, called T antigens, will be discussed in detail. There is a substantial body of descriptive information on those products, and studies on the function of the T antigens have also begun.

Mapping the in vivo arrangement of nucleosomes on simian virus 40 chromatin by the photoaddition of radioactive hydroxymethyltrimethylpsoralen

Intracellular simian virus 40 (SV40) chromatin was photoreacted with a 3H-labeled psoralen derivative, hydroxymethyltrimethylpsoralen (HMT), at 48 h postinfection. Psoralen compounds have been shown to readily penetrate intact cells and, in the presence of long-wavelength UV light, form covalent adducts to DNA, preferentially at regions unprotected by nucleosomes. The average distribution pattern of [3H]HMT on the SV40 genome was determined by specific activity measurements of the DNA fragments generated by HindIII plus HpaII or by AtuI restriction enzyme digestion. At levels of 1 to 10 [3H]HMT photoadducts per SV40 molecule, the radiolabel was found to be distributed nonrandomly. Comparison of the labeling pattern in vivo with that of purified SV40 DNA labeled in vitro revealed one major difference. A region of approximately 400 base pairs, located between 0.65 and 0.73 on the physical map, was preferentially labeled under in vivo conditions. This finding strongly suggests that the highly accessible region near the origin of replication, previously observed on isolated SV40 "minichromosomes," exists on SV40 chromatin in vivo during a lytic infection.

The appearance of DNase I hypersensitive sites at the 5' end of the late SV40 genes is correlated with the transcriptional switch

DNase I digestion of the SV40 nuclear chromosome late in infection reveals three hypersensitive sites on the late side of the Bg1 I site. Two of these sites at bp 370, 270 correspond to the 5' side of the late transcripts while the third at bp 190, to a region that is required for early transcription. Early in infection, as well as in an SV40 transformed cell line and a T-Ag negative revertant (deleted in the coding region for T-Ag) only one of these sites is present - the one associated with early transcription. Thus, the positions of these major hypersensitive sites are related to the differential expression of the early and late genes. The presence of the characteristic hypersensitive site corresponding to "early" region expression in the revertant, where large T antigen is not synthesized, but where the early "promotor" is intact, indicates that large T antigen is not responsible for this particular hypersensitive site. Additional minor specific DNase I cuts were found on the early genes, at early times only, at 300, 550, 850 bp from Bg1 I site. In the transformed cell line, one of these minor cuts is found about 350-400 bp from the Bg1 I site and in the revertant, where this region is deleted, a new site is created at 100 bp.

Ability of nonpermissive mouse cells to express a simian virus 40 late function(s)

Mouse cells are fully nonpermissive for simian virus 40 (SV40). Infection does not lead to detectable virus replication. In this report, it was shown, first, that spliced 16S and 19S SV40 late mRNA were present in cytoplasmic and polysomal polyadenylated acid+ RNA preparations from SV40-infected baby mouse kidney cells. The 16S and 19S SV40 late mRNA's produced in infected baby mouse kidney cells were identical to or similar to the 16S and 19S SV40 late mRNA's produced in permissive monkey cells as judged by their S1 mapping patterns performed with the late strand of HpaII-BamHI fragment B and by their sedimentation patterns in a sucrose gradient. It was also shown that the 16S late mRNA from infected baby mouse kidney cells could be translated into a polypeptide which was identical to or similar to virion protein VP1 in every aspect examined, including the patter of peptide mapping by limited proteolysis. Second, we reported that mouse kidney cells produced detectable, although low, levels of SV40 virion protein VP1, as shown by the sodium dodecyl sulfate-polyacrylamide gel autoradiogram of [35S]methionine-labeled proteins immunoprecipitated by a rabbit antiserum directed against SV40 virion proteins. Third, it was reported that infected baby mouse kidney cells produced late mRNA's either (i) when the infection was done at a restrictive temperature with the nonleaky tsA58 mutant or (ii) in cells treated with 100 microgram of cycloheximide per ml, in which large T antigen synthesis was inhibited by more than 99.9%. This suggested that large T antigen was not required for the synthesis of late mRNA in mouse cells.

Properties of simian virus 40 small t antigen overproduced in bacteria

We constructed a series of bacterial plasmids which contained the Escherichia coli lac promoter fused to a simian virus 40 restriction fragment coding for small t antigen. These plasmids expressed different levels of intact viral protein depending on the length of the constructed ribosome binding site. Small t antigen synthesized by the most efficient producer, HP1, constituted 0.5 to 1% of the total cellular protein. On the basis of extensive characterization by immunoprecipitation, gel electrophoresis, isoelectric focusing, tryptic fingerprint analysis, and chromatographic properties, this plasmid-encoded protein was virtually identical to authentic simian virus 40 small t antigen. Partial purification of the HP1-encoded and authentic small t antigens revealed the presence of both monomeric and multimeric forms.

Simian virus 40-associated small RNA: mapping on the simian virus 40 genome and characterization of its synthesis

The simian virus 40 (SV40)-associated small RNA (SAS-RNA) has previously been shown to arise late in SV40 lytic infection and to bear homology with the SV40 early mRNA's, or the SV40 genome, at map position 0.21. By using hybridization analysis, we determined that the SAS-RNA is between 62 and 65 nucleotides in length and its homology region lies between nucleotides 2760 and 2825 of the SV40 late(+) DNA strand. Viable deletion mutants which lacked part or all of this region made no SAS-RNA, strongly indicating that this is the coding region of the SAS-RNA. The expected sequence for the SAS-RNA, determined from the DNA sequence between nucleotides 2760 and 2825, appeared to be very pyrimidine rich (76% uridine and cytidine). Deletion or alteration of sequences immediately preceding the SAS-RNA coding region (approximately nucleotides 2716 to 2748) resulted in the loss of SAS-RNA production. These sequences may be part of a promotor for SAS-RNA synthesis or a processing site for its excision from long nuclear late transcripts. Under growth conditions where late transcription was not fully initiated (tsA58 at 41 degrees C; wild-type SV40 in the presence of 1-beta-D-arabinofuranosylcytosine), no SAS-RNA was produced, indicating that the expression of the SAS-RNA is regulated by a mechanism related to the control of late transcription.

Transcription and RNA processing by the DNA tumour viruses

Messenger RNA synthesis by the DNA tumour viruses proceeds by a complex but versatile series of transcription and RNA processing steps. The major mechanistic features of this pathway are probably very similar to those used by the animal cell host itself. The viruses have, however, evolved intricate arrangements of protein coding sequences and sites for RNA initiation, polyadenylation and splicing which allow them to use their genetic information to maximum advantage.

Regulation of simian virus 40 early transcription in vitro by a purified tumor antigen

Cloned DNA templates were used to direct the transcription of early and late simian virus 40 (SV40) genes by a cell-free RNA-synthesizing system. Transcription by RNA polymerase II was sensitive to low levels of alpha-amanitin and completely dependent on exogenously added DNA template. RNA products of discrete lengths were efficiently synthesized when transcription was directed by DNA restriction fragments containing promoter sequences for either early or late genes of SV40. Addition of the D2 tumor antigen to the template DNA inhibited transcription originating from the SV40 early promoter. In contrast, the D2 protein had little or no effect on the transcription from SV40 or adenovirus 2 (Ad2) late promoter sequences. When a mixture of cloned DNA containing SV40 early promoter and Ad2 late promoter was used to direct RNA synthesis, the D2 protein specifically inhibited the synthesis of SV40 early genes but not that of Ad2 late sequences. The D2 DNA binding protein also had no effect on the transcription directed by SV40 mutant templates that contain an intact early promoter sequence but lack specific tumor-antigen binding sites. We have confirmed that, under the conditions of the transcription assay, the D2 protein binds and interacts specifically with its recognition sites on wild-type template DNAs but fails to bind to mutant or Ad2 DNA templates that lack sequences containing SV40 tumor-antigen binding sites. These findings provide evidence that a direct interaction between tumor antigen and its specific binding sites on DNA is the mechanism by which the SV40 A gene autoregulates its transcription.

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.

Control of simian virus 40 gene expression at the levels of RNA synthesis and processing: thermally induced changes in the ratio of the simian virus 40 early mRNA's and proteins

Examination of the simian virus 40 early mRNA's from infected AGMK or CV-1 cells showed that the ratio of large T- to small t-antigen mRNA's increased with an increased incubation temperature. In tsA58 mutant-infected cells, an increased incubation temperature resulted in the overproduction of early RNAs'; however, the ratio of the early mRNA's was the same, at any temperature, in both wild-type- and tsA58-infected cells. Thus, the thermally induced alteration in the early mRNA ratios was apparently not affected by the tsA mutation or by the overproduction of early RNA in tsA mutant-infected cells. Time course studies at various temperatures showed that, although the ratio of large T- to small t-antigen mRNA's increased with temperature, at any one temperature it was consistent from early to late times of infection. Furthermore, the ratio of the early mRNA's adjusted in temperature shift experiments. Thus, the ratio of the early mRNA's appeared to be intrinsic to the thermodynamic environment of the cell. The thermally induced alterations in the early mRNA's were reflected at the protein level by parallel changes in the ratio of large T- to small t-antigens. These data suggest a level of gene expression control which may function at the stage of splicing.

Ubiquitous, interspersed repeated sequences in mammalian genomes

DNA base sequence comparisons demonstrate that the principal family of 300-nucleotide interspersed human DNA sequences, the repetitive double-strand regions of HeLa cell heterogeneous nuclear RNA, and specific RNA polymerase III in vitro transcripts of cloned human DNA sequences are all representatives of a closely related family of sequences. A segment of approximately 30 residues of these sequences is highly conserved in mammalian evolution because it is also present in the interspersed repeated DNA sequences of Chinese hamsters. Further DNA sequence comparisons demonstrate that a portion of this highly conserved segment of repetitive mamalian DNA sequence is similar to a sequence found within a low molecular weight RNA that hydrogen-bonds to poly(A)-terminated RNA molecules of Chinese hamsters and a sequence that forms half of a perfect inverted repeat near the origin of DNA replication in papovaviruses.

Effect of a tsA mutation of simian virus 40 late gene expression: variations between host cell lines

Infection of AGMK or CV-1 cells by the early simian virus 40 mutant tsA58 at the permissive temperature (32 degrees C) followed by a shift to the nonpermissive temperature (41 degrees C) caused a substantial decrease in the levels of late viral RNA in the cytoplasm of AGMK cells but not CV-1 cells. At the translational level, this depression of late viral RNA levels was reflected by a decrease in late viral protein synthesis. Thus, in AGMK cells, an early region gene product (presumably large T-antigen) appeared to be continuously required for efficient expression of the late viral genes. In contrast, late simian virus 40 gene expression, once it is initiated in CV-1 cells, continued efficiently regardless of the tsA mutation. The difference in expression of the late simian virus 40 genes in these tsA mutant-infected monkey kidney cell lines may reflect a difference in host cell proteins which regulate viral gene expression in conjunction with early viral proteins.