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

Cell type-specific replication of simian virus 40 conferred by hormone response elements in the late promoter

The late genes of SV40 are not expressed at significant levels until after the onset of viral DNA replication. We previously identified two hormone response elements (HREs) in the late promoter that contribute to this delay. Mutants defective in these HREs overexpress late RNA at early, but not late, times after transfection of CV-1PD cells. Overexpression of nuclear receptors (NRs) that recognize these HREs leads to repression of the late promoter in a sequence-specific and titratable manner, resulting in a delay in late gene expression. These observations led to a model in which the late promoter is repressed at early times after infection by NRs, with this repression being relieved by titration of these repressors through simian virus 40 (SV40) genome replication to high copy number. Here, we tested this model in the context of the viral life cycle. SV40 genomes containing mutations in either or both HREs that significantly reduce NR binding without altering the coding of any proteins were constructed. Competition for replication between mutant and wild-type viruses in low-multiplicity coinfections indicated that the +1 HRE offered a significant selective advantage to the virus within a few cycles of infection in African green monkey kidney cell lines CV-1, CV-1P, TC-7, MA-134, and Vero but not in CV-1PD' cells. Interestingly, the +55 HRE offered a selective disadvantage in MA-134 cells but had no effect in CV-1, CV-1P, TC-7, Vero, and CV-1PD' cells. Thus, we conclude that these HREs are biologically important to the virus, but in a cell type-specific manner.

T antigens of simian virus 40: molecular chaperones for viral replication and tumorigenesis

Simian virus 40 (SV40) is a small DNA tumor virus that has been extensively characterized due to its relatively simple genetic organization and the ease with which its genome is manipulated. The large and small tumor antigens (T antigens) are the major regulatory proteins encoded by SV40. Large T antigen is responsible for both viral and cellular transcriptional regulation, virion assembly, viral DNA replication, and alteration of the cell cycle. Deciphering how a single protein can perform such numerous and diverse functions has remained elusive. Recently it was established that the SV40 T antigens, including large T antigen, are molecular chaperones, each with a functioning DnaJ domain. The molecular chaperones were originally identified as bacterial genes essential for bacteriophage growth and have since been shown to be conserved in eukaryotes, participating in an array of both viral and cellular processes. This review discusses the mechanisms of DnaJ/Hsc70 interactions and how they are used by T antigen to control viral replication and tumorigenesis. The use of the DnaJ/Hsc70 system by SV40 and other viruses suggests an important role for these molecular chaperones in the regulation of the mammalian cell cycle and sheds light on the enigmatic SV40 T antigen-a most amazing molecule.

A kinase activity associated with simian virus 40 large T antigen phosphorylates upstream binding factor (UBF) and promotes formation of a stable initiation complex between UBF and SL1

Simian virus 40 large T antigen is a multifunctional protein which has been shown to modulate the expression of genes transcribed by RNA polymerase I (Pol I), II, and III. In all three transcription systems, a key step in the activation process is the recruitment of large T antigen to the promoter by direct protein-protein interaction with the TATA binding protein (TBP)-TAF complexes, namely, SL1, TFIID, and TFIIIB. However, our previous studies on large T antigen stimulation of Pol I transcription also revealed that the binding to the TBP-TAFI complex SL1 is not sufficient to activate transcription. To further define the molecular mechanism involved in large T antigen-mediated Pol I activation, we examined whether the high-mobility group box-containing upstream binding factor (UBF) plays any role in this process. Here, using cell labeling experiments, we showed that large T antigen expression induces an increase in UBF phosphorylation. Further biochemical analysis demonstrated that UBF is phosphorylated by a kinase activity that is strongly associated with large T antigen, and that the carboxy-terminal activation domain of UBF is required for the phosphorylation to occur. Using in vitro reconstituted transcription assays, we demonstrated that the inability of alkaline phosphatase treated UBF to efficiently activate transcription can be rescued by large T antigen. Moreover, we showed that large T antigen-induced UBF phosphorylation promotes the formation of a stable UBF-SL1 complex. Together, these results provide strong evidence for an important role for the large T antigen-associated kinase in mediating the stimulation of RNA Pol I transcription.

Simian virus 40 large T antigen stabilizes the TATA-binding protein-TFIIA complex on the TATA element

Large T antigen (T antigen), the early gene product of simian virus 40 (SV40), is a potent transcriptional activator of both cellular and viral genes. Recently we have shown that T antigen is tightly associated with TFIID and, in this position, performs a TATA-binding protein (TBP)-associated factor (TAF)-like function. Based on this observation, we asked whether T antigen affected steps in preinitiation complex assembly. Using purified components in in vitro complex assembly assays, we found that T antigen specifically enhances the formation of the TBP-TFIIA complex on the TATA element. T antigen accomplishes this by increasing the rate of formation of the TBP-TFIIA complex on the TATA element and by stabilizing the complexes after they are formed on the promoter. In addition, DNA immunoprecipitation experiments indicate that T antigen is associated with the stabilized TBP-TFIIA complexes bound to the DNA. In this regard, it has previously been shown that T antigen interacts with TBP; in the present study, we show that T antigen also interacts with TFIIA in vitro. In testing the ability of T antigen to stabilize the TBP-TFIIA complex, we found that stabilization is highly sensitive to the specific sequence context of the TATA element. Previous studies showed that T antigen could activate simple promoters containing the TATA elements from the hsp70 and c-fos gene promoters but failed to significantly activate similar promoters containing the TATA elements from the promoters of the SV40 early and adenovirus E2a genes. We find that the ability to stabilize the TBP-TFIIA complex on the hsp70 and c-fos TATA elements, and not on the SV40 early and E2A TATA elements, correlates with the ability or inability to activate promoters containing these TATA elements.

Simian virus 40 large T antigen interacts with human TFIIB-related factor and small nuclear RNA-activating protein complex for transcriptional activation of TATA-containing polymerase III promoters

The TATA-binding protein (TBP) is common to the basal transcription factors of all three RNA polymerases, being associated with polymerase-specific TBP-associated factors (TAFs). Simian virus 40 large T antigen has previously been shown to interact with the TBP-TAFII complexes, TFIID (B. Damania and J. C. Alwine, Genes Dev. 10:1369-1381, 1996), and the TBP-TAFI complex, SL1 (W. Zhai, J. Tuan, and L. Comai, Genes Dev. 11: 1605-1617, 1997), and in both cases these interactions are critical for transcriptional activation. We show a similar mechanism for activation of the class 3 polymerase III (pol III) promoter for the U6 RNA gene. Large T antigen can activate this promoter, which contains a TATA box and an upstream proximal sequence element but cannot activate the TATA-less, intragenic VAI promoter (a class 2, pol III promoter). Mutants of large T antigen that cannot activate pol II promoters also fail to activate the U6 promoter. We provide evidence that large T antigen can interact with the TBP-containing pol III transcription factor human TFIIB-related factor (hBRF), as well as with at least two of the three TAFs in the pol III-specific small nuclear RNA-activating protein complex (SNAPc). In addition, we demonstrate that large T antigen can cofractionate and coimmunoprecipitate with the hBRF-containing complex TFIIIB derived from HeLa cells infected with a recombinant adenovirus which expresses large T antigen. Hence, similar to its function with pol I and pol II promoters, large T antigen interacts with TBP-containing, basal pol III transcription factors and appears to perform a TAF-like function.

The major transcription initiation site of the SV40 late promoter is a potent thyroid hormone response element

Thyroid hormone receptors (TRs) are members of the nuclear hormone receptor superfamily, which act as transcription factors upon binding to specific DNA sequences called thyroid hormone (T3) response elements (TREs). Such elements are found in the upstream regulatory region of promoters as well as in intragenic sequences of T3-responsive genes. In this report, we demonstrate that SV40 late (SVL) promoter activity is strongly down-regulated by TR in the absence of ligand. Addition of T3 releases this repression, but does not further induce SVL promoter activity. Electrophoretic mobility shift analyses reveal a TR binding element that overlaps with the SV40 major late transcription initiation site. This element closely fits the consensus TRE, formed of two hexanucleotides organized in a tandem repeat separated by 4 nt, and is able to confer T3 responsiveness on a heterologous promoter. We further show that, although the presence of TR leads to quantitatively modified expression of an SVL-driven reporter gene, neither displacement of the site of transcription initiation nor modification of the splicing pattern of the primary transcripts occur.

Chromatin structure and factor site occupancies in an in vivo-assembled transcription elongation complex

The chromatin structure specific to the SV40 late transcription elongation complex as well as the occupancy of several sites that bind transcription factors have been examined. These features have been determined by assessing blockage to restriction enzyme digestion. Cleavage specific to the elongation complex has been quantified using ternary complex analysis. This method involves radioactively labeling the complex by in vitro transcription followed by determining the extent of linearization by electrophoresis in an agarose gel. It was found that not only is the origin region devoid of nucleosomes, but there is also no stable factor occupancy at the BglI, SphI, KpnI and MspI restriction enzyme sites within this region. Thus these sites were cleaved to a high degree, meaning that the binding sites for a number of transcription factors, including OBP/TEF-1, TBP, DAP, as well as a proposed positioned nucleosome, are unoccupied in the native viral transcription elongation complex. The absence of these trans-acting factors from their respective binding sites in the elongation complex indicates that they bind only transiently, possibly cycling on and off during the transcription cycle. This finding implies that various forms of transcription complex are assembled and disassembled during transcription and thus supports a 'hit-and-run' model of factor function.

Novel DNA binding specificities of a putative herpesvirus bZIP oncoprotein

Marek's disease virus is a highly oncogenic herpesvirus that can cause T lymphomas and peripheral nerve demyelination in chickens. meq, a candidate oncogene of Marek's disease virus, encodes a basic leucine zipper (bZIP) transcription factor which contains a large proline-rich domain in its C terminus. On the basis of its bZIP structural homology, meq is perhaps the only member of the jun-fos gene family completely viral in origin. We previously showed that Meq's C-terminal domain has potent transactivation activity and that its bZIP domain can dimerize with itself and with c-Jun also. In an effort to identify viral and cellular targets of Meq, we have determined the optimal binding sites for Meq-Jun heterodimers and Meq-Meq homodimers. By a PCR-based approach using cyclic amplification of selected targets, Meq-Jun heterodimers were found to optimally bind tetradecanoylphorbol acetate response element (TRE) and cyclic AMP response element (CRE) consensus sequences. This result was consistent with the results of our previous functional analysis implicating Meq-Jun heterodimers in the transactivation of the Meq promoter through a TRE- or CRE-like sequence. Interestingly, Meq-Meq homodimers were found to bind two distinct motif elements. The first [GAGTGATG AC(G)TCATC] has a consensus which includes a TRE or CRE core flanked by additional nucleotides critical for tight binding. Methylation interference and mutational analyses confirmed the importance of the flanking residues. The sequences of a subset of TRE and CRE sites selected by Meq-Meq are closely related to the binding motif of Maf, another bZIP oncoprotein. The second putative Meq binding site (RACACACAY) bears a completely different consensus not shared by other bZIP proteins. Binding to this consensus sequence also requires secondary structure characteristics associated with DNA bending. CACA motifs are known to promote DNA curvature and function in a number of special biological processes. Our results lend further weight to the increasing importance of DNA bending in transcriptional regulation and provide a baseline for the identification of Meq-responsive targets.

Induction of transcription by a viral regulatory protein depends on the relative strengths of functional TATA boxes

The mechanisms by which viral regulatory proteins activate the cellular transcription apparatus without binding to specific DNA elements are not fully understood. Several lines of evidence suggest that activation by one such regulatory protein, herpes simplex virus ICP4, could be mediated, at least in part, by TFIID. To test this model, we replaced the TATA box of the ICP4-responsive viral thymidine kinase gene with functional TATA boxes that displayed different apparent affinities for TATA-box-binding protein as measured by DNase I footprinting. We measured the effects of these TATA boxes on ICP4 induction by constructing ICP4-deficient recombinant viruses containing the different TATA alleles and comparing their expression in cells lacking or expressing ICP4. Overall, ICP4 induced weak TATA boxes (those that displayed low apparent affinity for TATA-box-binding protein and low basal expression) the most (18- to 41-fold) and strong TATA boxes the least (7- to 10-fold). Therefore, ICP4 induction correlated inversely with TATA box strength. Using a reconstituted in vitro transcription assay, we determined that the relative levels of induction by ICP4 of the different TATA alleles were similar to those measured in vivo, suggesting that ICP4 was the only viral protein required for induction. These results fit a model in which ICP4 acts in part to enhance binding of TFIID to the TATA box. We compare and contrast these results with those observed with the viral regulatory proteins adenovirus E1a and simian virus 40 large T antigen and the cellular coactivator PC4.

A TEF-1-independent mechanism for activation of the simian virus 40 (SV40) late promoter by mutant SV40 large T antigens

Simian virus 40 (SV40) large tumor antigen (T antigen) stimulates the activity of the SV40 late promoter and a number of cellular and other viral promoters. We have characterized the ability of T antigens with mutations in the DNA-binding domain and within the N-terminal 85 residues to activate the SV40 late promoter. T antigens lacking both nonspecific and sequence-specific DNA-binding activities were able to induce the late promoter. Mutations within the N-terminal 85 residues of T antigen diminished activation by less than twofold. Activation by wild-type and most of the mutant T antigens required intact binding sites for the cellular transcription factor TEF-1 in the late promoter. Curiously, two mutants altered in the N-terminal region and an additional mutant altered in the DNA-binding domain activated a late promoter derivative lacking TEF-1 binding sites, indicating the existence of a TEF-1-independent pathway for activation of the late promoter. A consensus binding site for the TATA binding protein, TBP, was created in variants of late promoters either containing or lacking TEF-1 binding sites. Basal expression was increased by the consensus TBP binding site only when TEF-1 binding sites were present, leading to a reduction in the degree of activation by T antigen. However, activation by a mutant T antigen of the promoter lacking TEF-1 sites was unchanged or slightly enhanced by the consensus TBP binding site. These results suggest that some mutant T antigens can stabilize an interaction between TBP and additional factors bound to the late promoter.

Transrepression of RNA polymerase II promoters by the simian virus 40 small t antigen

Simian virus 40 (SV40) small t antigen (t) can activate transcription from certain RNA polymerase II and III promoters (M. Loeken, I. Bikel, D. M. Livingston, and J. Brady, Cell 55:1171-1177, 1988). Here we report a new function of t, its ability to repress human c-fos promoter and AP-1 transcriptional activity in CV-1P cells. This function is the product of a discrete N-terminal domain of t, because the large T antigen (T)/t-common polypeptide, which contains only the first 82 amino acids common to both T and t of SV40, was, like the intact protein, an active repressor. The data further suggest that the t- and T/t-common-mediated repression of c-fos expression was most likely manifest at the level of transcription. In keeping with the possibility that t affects the expression of the genomic c-fos promoter, it also led to repression of AP-1 formation. Thus, SV40 is both an activator and a repressor of transcription. Its ability to inhibit c-fos expression should be considered in light of the natural history of SV40 in its natural host.

The POU domain protein Tst-1 and papovaviral large tumor antigen function synergistically to stimulate glia-specific gene expression of JC virus

Synergism between transcriptional activators is a powerful way of potentiating their function. Here we show that the glial POU domain protein Tst-1 (also known as Oct-6 and SCIP) and large tumor antigen (T antigen) synergistically increased transcription from both the early and the late promoters of papovavirus JC in glial cells. Synergism between both proteins did not require T-antigen-mediated DNA replication or direct binding of T antigen to the promoter. The ability of T antigen to functionally cooperate with Tst-1 was contained within its N-terminal region, shown by the fact that small tumor antigen (t antigen) could substitute for T antigen in transfection experiments. In addition to this functional synergism, a direct interaction between Tst-1 and T antigen was observed in vitro. Using deletion mutants of Tst-1 and T antigen, the POU domain of Tst-1 and the N-terminal region of T antigen were found to participate in this interaction. Because of the low levels of Tst-1 present in oligodendrocytes, synergism between Tst-1 and T antigen could be an important factor in establishing the lytic infection of oligodendrocytes by JC virus during the course of the fatal demyelinating disease progressive multifocal leukoencephalopathy.

Transcriptional activation by simian virus 40 large T antigen: requirements for simple promoter structures containing either TATA or initiator elements with variable upstream factor binding sites

The simian virus 40 large T antigen is a promiscuous transcriptional activator of many viral and cellular promoters. We show that the promoter structure necessary for T antigen-mediated transcriptional activation is very simple. A TATA or initiator element is required, in addition to an upstream factor-binding site, which can be quite variable. We found that promoters containing an SP1-, ATF-, AP1-, or TEF-I-binding site, in conjunction with a TATA element, can all be activated in the presence of T antigen. In addition, preference for specific TATA elements was indicated. Promoters containing the HSP70 TATA element functioned better than those with the adenovirus E2 TATA element, while promoters containing the simian virus 40 (SV40) early TATA element failed to be activated. In addition, simple promoters containing the initiator element from the terminal deoxynucleotidyltransferase gene could be activated by T antigen. The SV40 late promoter, a primary target for T antigen transcriptional activation, conforms to this simple promoter structure. The region from which most late transcripts initiate contains a cluster of initiator-like elements (SV40 nucleotides [nt] 250 to 335) forming an initiator region (IR). This lies downstream of the previously described octamer-TEF element (SV40 nt 199 to 218) which contains the TEF-I-binding sites shown to be necessary for T antigen-mediated transcriptional activation of the late promoter. We show that a simple late promoter made up of IR sequences and octamer-TEF element-containing sequences is transcriptionally activated by T antigen. These experiments also showed that specific sequences in the IR, SV40 nt 272 to 294, are particularly important for late promoter activation. Previous findings (M. C. Gruda, J. M. Zablotny, J. H. Xiao, I. Davidson, and J. C. Alwine, Mol. Cell. Biol. 13:961-969, 1993) suggested that T antigen could mediate transcriptional activation through interaction with the TATA-binding protein, as well as upstream bound transcription factors. Our present data are predicted by this model and suggest that at least one mechanism by which the T antigen manifests promiscuous transcriptional activation is its ability to interact with numerous transcription factors in a simple promoter context.

Efficient transcriptional activation of many simple modular promoters by simian virus 40 large T antigen

Simian virus 40 (SV40) large T antigen is a multifunctional protein which plays central roles during both lytic and transforming infections by SV40. It is a potent transcriptional activator and increases expression from the SV40 late promoter and from several cellular promoters. To understand better the transcriptional activation activity of large T antigen, we examined its ability to transactivate a set of simple modular promoters containing one of four upstream activation sequences coupled with one of three different TATA box sequences originally constructed and studied by Taylor and Kingston (Mol. Cell. Biol. 10:165-175, 1990). Large T antigen activated transcription from all of these simple promoters. The identity of the TATA box was a more important determinant of the final level of gene expression than was the identity of the upstream activating sequence element. We also determined the ability of a set of mutant SV40 large T antigens to activate a subset of these promoters. Several mutant SV40 large T antigens which had reduced ability to activate the complex SV40 late and Rous sarcoma virus long terminal repeat promoters showed reduced transcriptional activation activity on all of the modular promoters tested. We used a set of promoter derivatives of the human U6 small nuclear RNA promoter containing different TATA boxes and found that wild-type large T antigen could activate transcription from all of them, although to widely different levels of expression.

Polyoma virus early-late switch: regulation of late RNA accumulation by DNA replication

Early in infection of permissive mouse cells, messages from the early region of the polyoma virus genome accumulate preferentially over those from the late region. After initiation of DNA replication, the balance between early and late gene expression is reversed in favor of the late products. In previous work from our laboratory, we showed that viral early proteins do not activate the polyoma late promoter in the absence of DNA replication. Here we show that activation of the late genes in replication-incompetent viral genomes can occur if actively replicating genomes are present in the same cell. A low level of DNA replication, however, is insufficient to induce the early-late switch. Furthermore, replication-competent genomes that fail to accumulate late RNA molecules are defective in the transactivation of replication-incompetent genomes. We suggest that titration of an unknown diffusible factor(s) after DNA replication relieves the block to late RNA accumulation seen in the early phase, with most of this titration being attributable to late-strand RNA molecules themselves.

Transcriptional activation by simian virus 40 large T antigen: interactions with multiple components of the transcription complex

Simian virus 40 (SV40) large T antigen is a potent transcriptional activator of both viral and cellular promoters. Within the SV40 late promoter, a specific upstream element necessary for T-antigen transcriptional activation is the binding site for transcription-enhancing factor 1 (TEF-1). The promoter structure necessary for T-antigen-mediated transcriptional activation appears to be simple. For example, a promoter consisting of upstream TEF-1 binding sites (or other factor-binding sites) and a downstream TATA or initiator element is efficiently activated. It has been demonstrated that transcriptional activation by T antigen does not require direct binding to the DNA; thus, the most direct effect that T antigen could have on these simple promoters would be through protein-protein interactions with either upstream-bound transcription factors, the basal transcription complex, or both. To determine whether such interactions occur, full-length T antigen or segments of it was fused to the glutathione-binding site (GST fusions) or to the Gal4 DNA-binding domain (amino acids 1 to 147) (Gal4 fusions). With the GST fusions, it was found that TEF-1 and the TATA-binding protein (TBP) bound different regions of T antigen. A GST fusion containing amino acids 5 to 172 (region T1) efficiently bound TBP. TEF-1 bound neither region T1 nor a region between amino acids 168 and 373 (region T2); however, it bound efficiently to the combined region (T5) containing amino acids 5 to 383.(ABSTRACT TRUNCATED AT 250 WORDS)

Transcriptional activation by simian virus 40 large T antigen: interactions with multiple components of the transcription complex

Simian virus 40 (SV40) large T antigen is a potent transcriptional activator of both viral and cellular promoters. Within the SV40 late promoter, a specific upstream element necessary for T-antigen transcriptional activation is the binding site for transcription-enhancing factor 1 (TEF-1). The promoter structure necessary for T-antigen-mediated transcriptional activation appears to be simple. For example, a promoter consisting of upstream TEF-1 binding sites (or other factor-binding sites) and a downstream TATA or initiator element is efficiently activated. It has been demonstrated that transcriptional activation by T antigen does not require direct binding to the DNA; thus, the most direct effect that T antigen could have on these simple promoters would be through protein-protein interactions with either upstream-bound transcription factors, the basal transcription complex, or both. To determine whether such interactions occur, full-length T antigen or segments of it was fused to the glutathione-binding site (GST fusions) or to the Gal4 DNA-binding domain (amino acids 1 to 147) (Gal4 fusions). With the GST fusions, it was found that TEF-1 and the TATA-binding protein (TBP) bound different regions of T antigen. A GST fusion containing amino acids 5 to 172 (region T1) efficiently bound TBP. TEF-1 bound neither region T1 nor a region between amino acids 168 and 373 (region T2); however, it bound efficiently to the combined region (T5) containing amino acids 5 to 383.(ABSTRACT TRUNCATED AT 250 WORDS)

Involvement of simian virus 40 (SV40) small t antigen in trans activation of SV40 early and late promoters

We have previously found that simian virus 40 (SV40) small t antigen (small t) can trans activate the E2A and VA-I genes of adenovirus in plasmid DNA-transfected cells (M. R. Loeken, I. Bikel, D. M. Livingston, and J. Brady, Cell 55:1171-1177, 1988). To determine whether trans activation by small t might be involved in the SV40 productive infection cycle, we examined the effects of cotransfecting plasmids encoding small t with plasmids containing the chloramphenicol acetyltransferase (CAT) gene linked to the SV40 early or late promoter. Small t increased three- to fivefold the expression of a CAT plasmid linked to the SV40 early promoter and enhancer. Small t expression had no effect by itself on CAT activity directed by the SV40 late promoter, but small t enhanced the effect of a suboptimal concentration of a plasmid expressing large T up to 10-fold. When the concentration of the plasmid expressing large T was increased to a level at which large T alone stimulated the late promoter ninefold, the enhancement by small t was only twofold. The effects of small t on both the SV40 early and late promoters depended on sequences within the small t-unique domain, since a plasmid expressing only the first 82 amino acids common to both large T and small t was inactive. The effects of small t on early- and late-promoter-directed CAT enzyme activity was reflected in increased CAT mRNA as measured by S1 analysis. These results suggest that SV40 small t may play a role in viral infection by increasing transcription from the early promoter and from the late promoter at times when large T levels are low.

Role of the SV40 enhancer in the early to late shift in viral transcription

Simian virus 40 large tumor antigen is a multifunctional protein, with two of its roles being the promotion of viral DNA replication and replication-independent activation of viral transcription. Replication leads to a shift in transcription from the early-early to the late and late-early cap sites, through mechanisms poorly understood. The viral transcription enhancer contains sequences important for both early and late transcription, and we therefore have carried out experiments to evaluate its role in these events. We find that the ability of replication to lead to a shift diminishes when early-early transcription is made increasingly stronger by multimerizing the enhancer, and suggest that replication might lead to the shift by interfering with the ability of the enhancer to direct initiation to those sites. The natural situation in the virus of having two copies of this element might represent a compromise between maximizing both T antigen expression early in infection and late gene expression after replication begins. We also show that replication-independent transcription activation by T antigen is bidirectional and involves at least in part elements to which the factor TEF-1 binds.

trans activation of the simian virus 40 late promoter by large T antigen requires binding sites for the cellular transcription factor TEF-1

Simian virus 40 (SV40) T antigen stimulates the level of transcription from several RNA polymerase II promoters, including the SV40 late promoter. The mechanism of trans activation appears to be indirect since binding of T antigen to specific DNA sequences is not required. However, specific promoter elements that respond to T antigen have not previously been defined. We identified DNA sequences from the SV40 late promoter whose ability to stimulate transcription is induced by the expression of T antigen. In particular, the Sph I + II motifs of the SV40 enhancer can confer T-antigen inducibility to the normally uninducible herpes simplex virus thymidine kinase gene promoter when multiple copies of the sequence are inserted 5' of the transcription initiation site and TATA sequence. Binding sites for the cellular transcription factor TEF-1 and octamer binding proteins are contained within the Sph I + II motifs, as well as at other positions in the SV40 promoter. To study the role of individual protein-binding sites in trans activation by T antigen, mutations were constructed in various TEF-1 and octamer protein-binding sites of the SV40 late promoter. These mutations did not significantly affect basal promoter activity. However, mutation of all three TEF-1 sites prevented detectable activation by T antigen. DNase I footprinting of the mutated promoters with purified proteins demonstrated that inducibility by T antigen correlated with binding affinity of TEF-1 for the DNA and not with binding affinity of an octamer binding protein.

Simian virus 40 late mRNA leader sequences involved in augmenting mRNA accumulation via multiple mechanisms, including increased polyadenylation efficiency

We have examined the contribution of 5' leader sequences to expression directed by the simian virus 40 (SV40) late promoter. These studies showed that addition of sequences which contain the late leader 3' splice site to the late promoter led to an increase in the accumulation of mRNA expressed by the promoter. No other sequences within the leader region, between SV40 positions 334 and 560, exhibited a substantial influence on mRNA accumulation. The increase was due, at least in part, to the creation of a spliceable mRNA transcript, since mutation of either the 5' or 3' splice site could attenuate the effect. However, sequences at or near the 3' splice site appeared to play a more important role than did the 5' splice site in bringing about this increase. In many instances, mutation of the 3' splice site also led to the accumulation of extended transcripts, whereas mutation of the 5' splice site did not produce this result in any instance. Analysis of these extended transcripts showed that they retained sequences normally lost upon cleavage and polyadenylation. This finding suggested that mutation of the 3' splice site sequence led to decreases in the efficiency of polyadenylation. We propose that the SV40 late leader sequences positively contribute to expression of the viral late genes by increasing mRNA accumulation via multiple mechanisms, including the enhancement of pre-mRNA polyadenylation efficiency.

Simian virus 40 small-t does not transactivate RNA polymerase II promoters in virus infections

Transcriptional stimulatory properties of virus-encoded transactivators appear to be critical for viral gene expression and may be linked to cellular transformation in certain cases. Recently, the simian virus 40 (SV40) 17-kDa small-t antigen was shown to stimulate transcription of polymerase II and III genes in transient transfection assays. In experiments performed in our laboratory, two of the polymerase II promoters of the adenovirus genome, namely, the EII-early and EIII promoters, were transactivation, we examined the transient transfection assays. To further elucidate the mechanism of this transactivation, we examined the ability of small-t to transactivate the adenovirus type 5 EII-early and EIII promoters in CV-1 cells under conditions in which the small-t gene or the reporter genes were introduced into the cells through transfection and other routes. In one approach, we used established CV-1 cell lines which constitutively express the small-t gene, and study of the EII-early promoter was afforded by infection of an EIA-negative adenovirus type 5 variant. For the second approach, a recombinant adenovirus was constructed in which small-t was expressed from a replication origin-negative SV40 early promoter in the EIA region of an adenovirus vector (Ad-SV-t). The effect of small-t on adenovirus EII-early and EIII promoter expression was studied in coinfection or single-infection experiments. In both cases, transcription of the adenovirus early promoters was not stimulated by small-t. These and other results indicate that transactivation of polymerase II promoters by small-t occurs only when the target gene is in a transiently transfected state. Thus, small-t-mediated transactivation of polymerase II promoters is dependent on the type of assay system used and may be mechanistically different from that of the widely studied EIA.

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.

The ability of simian virus 40 large T antigen to immortalize primary mouse embryo fibroblasts cosegregates with its ability to bind to p53

The large T antigen encoded by simian virus 40 (SV40) plays essential roles in the infection of permissive cells, leading to production of progeny virions, and in the infection of nonpermissive cells, leading to malignant transformation. Primary mouse embryo fibroblasts (MEFs) are nonpermissive for SV40, and infection by wild-type SV40 leads to immortalization and transformation of a small percentage of infected cells. We examined the ability of an extensive set of mutants whose lesions affect SV40 large T antigen to immortalize MEFs. We found that immortalization activity was retained by all mutants whose lesions are located upstream of codon 346. This includes a mutant lacking amino acids 168 to 346. We previously showed (M. J. Tevethia, J. M. Pipas, T. Kierstead, and C. Cole, Virology 162:76-89, 1988) that sequences downstream of amino acid 626 are not required for immortalization of primary MEFs. Studies by Thompson et al. (D. L. Thompson, D. Kalderon, A. Smith, and M. Tevethia, Virology 178:15-34, 1990) indicate that all sequences upstream of residue 250, including the domain for binding of tumor suppressor protein Rb, are not required for transformation of MEFs. Together, these studies demonstrate that the immortalization activity of large T antigen for MEFs maps to sequences between 347 and 626. Several mutants with lesions between 347 and 626 retained the ability to immortalize at nearly the wild-type frequency, while others, with small insertions at amino acid 409 or 424 or a deletion of residues 587 to 589, failed to immortalize. The abilities of mutant T antigens to form a complex with tumor suppressor protein p53 were examined. We found that all mutants able to immortalize retained the ability to complex with p53, while all mutants which lost the ability to immortalize were no longer able to bind p53. This suggests that inactivation of the growth-suppressive properties of p53 is essential for immortalization of MEFs.

Simian virus 40 (SV40) T-antigen transcriptional activation mediated through the Oct/SPH region of the SV40 late promoter

Simian virus 40 (SV40) large T antigen is a promiscuous transcriptional activator of many viral and cellular promoters. The SV40 late promoter, a primary target for T-antigen transcriptional activation, contains a previously described T-antigen-activatable binding site (SV40 nucleotides 186 to 225). The T-antigen-activatable binding site element contains overlapping octamer (Oct)- and SPH (TEF-1)-binding sites (Oct/SPH site). Using this Oct/SPH site as an upstream element in a simple promoter, we show that the SPH sites are necessary for transcriptional activation by T antigen. In addition, we show that when Oct 1 is overproduced, it can eliminate T-antigen-mediated transcriptional activation, as well as basal activity, from the simple Oct/SPH promoter as well as the intact SV40 late promoter. This suggests that one function of T antigen in transcriptional activation of the late promoter is to alter factor binding at the Oct/SPH region to favor binding of factors to the SPH sites.

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.

Mutual functional antagonism of the simian virus 40 T antigen and the hepatitis B virus trans activator

The hepatitis B virus X protein (pX) trans activates transcription of a wide variety of viral and cellular genes, apparently by interacting with multiple cellular transcription factors. It has been shown previously that the simian virus 40 early-region gene products (large-T and small-t antigens) prevent trans activation by pX. We show here that this phenomenon can be ascribed solely to the large-T antigen and that T antigen binds to pX in vitro. Mapping studies reveal that the region of large-T antigen around residues 125 and 126 is critical for this binding and also for the ability of T antigen to prevent trans activation by pX. Furthermore, pX in turn interferes with two of the known functions of T antigen, transcriptional trans activation and simian virus 40 DNA replication. We propose that pX and T antigen inactivate each other by forming a nonfunctional complex in vivo.

The human immunodeficiency virus type 1 polyadenylylation signal: a 3' long terminal repeat element upstream of the AAUAAA necessary for efficient polyadenylylation

Several polyadenylylation (PA) signals containing elements upstream of the AAUAAA have recently been characterized. Similar to PA elements found downstream of the AAUAAA, the upstream elements function to increase efficiency of AAUAAA use as a signal for cleavage and PA. Using deletion and linker scanning mutations we show that the PA signal of human immunodeficiency virus type 1 contains upstream elements transcribed from the U3 region of the 3' long terminal repeat. The element that has the greatest effect on PA site use lies 77 to 94 nucleotides upstream of the AAUAAA, between the TATA element and the transcriptional initiation site. Mutations in the adjacent region, between 59 and 76 nucleotides upstream of the AAUAAA, have a smaller effect on PA efficiency. Mutations in a region further upstream, between 141 and 176 nucleotides upstream of the AAUAAA, also affected PA modestly. Functional similarity between upstream elements was indicated by the ability of the human immunodeficiency virus upstream region to replace the upstream region of the simian virus 40 late PA signal. The sequence of the major upstream element of human immunodeficiency virus is uracil-rich, analogous to many defined downstream PA elements. This fact may imply that upstream and downstream elements have similar mechanisms of action.

Replication-dependent transactivation of the polyomavirus late promoter

When a plasmid containing the wild-type polyomavirus intergenic regulatory region fused to the bacterial cat gene was introduced into mouse NIH 3T3 cells along with a plasmid coding for the early viral proteins (T antigens), chloramphenicol transacetylase enzyme activity and mRNA levels were increased about 10-fold over levels observed in the absence of early proteins. To investigate this transactivation phenomenon further, 11 specific deletion mutant derivatives of the wild-type parent plasmid were constructed and studied. One mutant (NAL) with a minimal level of chloramphenicol transacetylase expression in the absence of T antigens was capable of being transactivated more than 40-fold. A number of other mutants, however, had little capacity for transactivation. Each of these mutants had in common a defect in large T-antigen-mediated DNA replication. Interestingly, one of the transactivation-defective mutants showed a basal late promoter activity fivefold higher than that of wild type and replicated in mouse cells in the absence of large T antigen. Subsequently, a small deletion abolishing viral DNA replication was introduced into those mutants capable of transactivation. The effect of the second deletion was to eliminate both replication and transactivation. Finally, wild-type and mutant constructs were transfected into Fisher rat F-111 cells in the presence or absence of early proteins. No transactivation or replication was ever observed in these cells. We concluded from these studies that the observed transactivation of the polyomavirus late promoter by one or more of the viral early proteins was due to either higher template concentration resulting from DNA replication or replication-associated changes in template conformation.

Activity of simian DNA-binding factors is altered in the presence of simian virus 40 (SV40) early proteins: characterization of factors binding to elements involved in activation of the SV40 late promoter

The early proteins of simian virus 40 (SV40) large T and small t antigen (T/t antigen) can each cause the transcriptional activation of a variety of cellular and viral promoters. We showed previously that simian cellular DNA-binding factors (the Band A factors) bind to sequences within the SV40 late promoter which are important for transcriptional activation in the presence of the SV40 early proteins. Band A factors isolated from simian cells which produce T/t antigen (COS cells or SV40-infected CV-1 cells) have altered binding properties in comparison with the factors from normal simian cells (CV-1). This suggests that the transcriptional activation mediated by T/t antigen may be due to either modification of existing factors or induction of new members of a family of factors. We have purified the Band A factors from both COS and CV-1 cells and have determined the binding site by methylation interference and DNase protection footprinting. The COS cell factors have altered chromatographic properties on ion-exchange columns and have higher-molecular-weight forms than the CV-1 cell factors. Major forms of the CV-1 factors migrate between 20 and 24 kilodaltons, while the COS factors migrate between 20 and 28 kilodaltons. The binding sites for the factors from CV-1 and COS cells are similar, covering a rather broad region within the 72-base-pair repeat comprising the AP-1 site and the two-octamer binding protein (OBP100/Oct 1) sites, OBP I and OBP II. Specific binding competition analyses indicate that the two general regions within the binding site (the AP-1-OBP II site and the OBP I site) each retain partial binding ability; however, the factors bind best when the two regions are adjacent in a relatively specific spatial arrangement. The binding site for the Band A factors corresponds very well to sequences necessary for the activation of the late promoter as defined by deletion and base substitution mutagenesis studies (J. M. Keller and J. C. Alwine, Mol. Cell. Biol. 5:1859-1869, 1985; E. May, F. Omilli, M. Emoult-Lange, M. Zenke, and P. Chambon, Nucleic Acids Res. 15:2445-2461, 1987). These data, in combination with the data showing that the Band A factors are modified or induced in the presence of T/t antigen, strongly suggest that T/t antigen mediates its transcriptional activation function, at least in part, through the Band A factors.

Efficiency of utilization of the simian virus 40 late polyadenylation site: effects of upstream sequences

The late polyadenylation signal of simian virus 40 functions with greater efficiency than the early polyadenylation signal, in turn affecting steady-state mRNA levels. Two chloramphenicol acetyltransferase (CAT) transient expression vectors, pL-EPA and pL-LPA, that differ only in their polyadenylation signals were constructed by using the early and late polyadenylation signals, respectively. In transfections of Cos, CV-1P, or HeLa cells and subsequent Northern blot analysis of CAT-specific RNA, approximately five times more steady-state CAT mRNA was produced in transfections with pL-LPA than with pL-EPA. The basis for this difference was not related to the specific promoter used or to RNA stability. Overall, the difference in steady-state mRNA levels derived from the two plasmids appeared to be attributable to intrinsic properties of the two polyadenylation signals, resulting in distinctly different cleavage and polyadenylation efficiencies. Additionally, we found that the utilization of the late polyadenylation site was dramatically reduced by deletion of sequences between 48 and 29 nucleotides 5' of the AAUAAA hexanucleotide. This reduction of mRNA levels was shown not to be caused by altered stability of mutant precursor RNAs or mRNAs, suggesting that these upstream sequences constitute an element of the late polyadenylation signal and may cause, at least to some extent, the greater efficiency of utilization of the late polyadenylation site.

Efficiency of utilization of the simian virus 40 late polyadenylation site: effects of upstream sequences

The late polyadenylation signal of simian virus 40 functions with greater efficiency than the early polyadenylation signal, in turn affecting steady-state mRNA levels. Two chloramphenicol acetyltransferase (CAT) transient expression vectors, pL-EPA and pL-LPA, that differ only in their polyadenylation signals were constructed by using the early and late polyadenylation signals, respectively. In transfections of Cos, CV-1P, or HeLa cells and subsequent Northern blot analysis of CAT-specific RNA, approximately five times more steady-state CAT mRNA was produced in transfections with pL-LPA than with pL-EPA. The basis for this difference was not related to the specific promoter used or to RNA stability. Overall, the difference in steady-state mRNA levels derived from the two plasmids appeared to be attributable to intrinsic properties of the two polyadenylation signals, resulting in distinctly different cleavage and polyadenylation efficiencies. Additionally, we found that the utilization of the late polyadenylation site was dramatically reduced by deletion of sequences between 48 and 29 nucleotides 5' of the AAUAAA hexanucleotide. This reduction of mRNA levels was shown not to be caused by altered stability of mutant precursor RNAs or mRNAs, suggesting that these upstream sequences constitute an element of the late polyadenylation signal and may cause, at least to some extent, the greater efficiency of utilization of the late polyadenylation site.

Production of simian virus 40 large tumor antigen in bacteria: altered DNA-binding specificity and dna-replication activity of underphosphorylated large tumor antigen

A bacterial expression system was used to produce simian virus 40 large tumor antigen (T antigen) in the absence of the extensive posttranslational modifications that occur in mammalian cells. Wild-type T antigen produced in bacteria retained a specific subset of the biochemical activities displayed by its mammalian counterpart. Escherichia coli T antigen functioned as a helicase and bound to DNA fragments containing either site I or the wild-type origin of replication in a manner identical to mammalian T antigen. However, T antigen purified from E. coli did not efficiently bind to site II, an essential cis element within the simian virus 40 origin of replication. It therefore could not unwind origin-containing plasmids or efficiently replicate simian virus 40 DNA in vitro. The ability of protein phosphorylation to modulate the intrinsic preference of full-length T antigen for either site I or site II is discussed.

Deletion analysis of the polyomavirus late promoter: evidence for both positive and negative elements in the absence of early proteins

We have been interested in understanding more about the sequences that constitute the polyomavirus late promoter. Our approach has been to target specific deletions to the viral intergenic region by oligonucleotide-directed mutagenesis. Wild-type and mutant promoter cassettes with defined deletions were then inserted into a promoterless expression vector containing the bacterial chloramphenicol acetyltransferase (CAT) gene (cat). Plasmids were introduced into mouse NIH 3T3 cells by transfection, and promoter activities were assessed by quantitation of both CAT enzyme and cat mRNA levels. In this report, we present the results of experiments designed to map promoter elements which affect late transcription in the absence of early viral proteins and viral DNA replication. Using this approach, we mapped two major cis-acting elements (a positive and a negative one) which affect transcription in our transient expression system. The first, positive, element coincided with the enhancer A element, which is known to be important for early transcription and viral DNA replication. Removal of this element reduced late transcription by 50- to 100-fold. The second element was a negative one; removal of 89 base pairs that included two high-affinity large-T-antigen-binding sites just to the early side of the inverted repeat structure within the replication origin resulted in a 5- to 10-fold increase in late promoter activity. The implications of these findings for late promoter function and regulation are discussed.

Transactivation of both early and late simian virus 40 promoters by large tumor antigen does not require nuclear localization of the protein

The early gene product of simian virus 40, large tumor antigen (T antigen), is required for the onset of viral replication. This protein has also been reported to transactivate viral late gene expression, independently of replication. In this study I have used a vector that permits simultaneously a precise quantitation of simian virus 40 early and late promoter activity with a single nuclease S1 mapping probe. The results show that T antigen can activate the early promoter as well as the late promoter and that only on replicating templates does a shift occur in the ratio of late-to-early transcription. This simultaneous transactivation of early and late promoters occurs in human (HeLa) and monkey (CV-1) cells but does not occur in mouse embryonal carcinoma cells. It is seen with either wild-type T antigen or with a T antigen protein that carries a mutation in the nuclear localization signal. The mutant protein cannot bring about an early-to-late shift, consistent with its inability to support viral replication.

Characterization of a minimal simian virus 40 late promoter: enhancer elements in the 72-base-pair repeat not required

A 272-base-pair (bp) portion of the simian virus 40 regulatory region containing the replication origin, Sp1-binding region, and part of the 72-bp direct repeats makes up a minimal late promoter that is able to direct late-direction RNA synthesis in vivo and in vitro. Fourteen linker-scan mutants within this region were characterized. Mutations in the Sp1-binding region decreased late expression both in vivo and in vitro. By contrast, mutations that eliminate genetically defined elements of the early transcriptional enhancer or that prevent binding of the transcription factors AP-1, AP-2, and AP-3 in the 72-bp repeat region had little or no effect on late-direction expression. These results argue that, at least under certain circumstances, the early transcriptional enhancer sequences are not required for simian virus 40 late gene expression.

trans activation of type 1 interferon promoters by simian virus 40 T antigen

A human transient expression system was used to measure the influence of simian virus 40 T antigen and adenovirus E1a proteins on the activation of alpha interferon subtype 1 (IFN-alpha 1) and IFN-beta promoters linked to the reporter chloramphenicol acetyltransferase gene. Large T-antigen production, amplified by expression plasmid replication in transfected 293 cells, was able to trans activate the IFN-beta promoter 5- to 10-fold, increasing both the constitutive and Sendai virus-induced levels of expression. Surprisingly, the previously quiescent transfected IFN-alpha 1 promoter in T-antigen-expressing cells displayed a level of inducibility similar to IFN-beta. The endogenous IFN-alpha 1 gene was also inducible to a limited extent in cells expressing T antigen. A truncated IFN-beta promoter deleted to position -37 relative to the CAP site was neither inducible nor trans activated by T antigen, suggesting that sequences required for efficient induction were also needed for trans activation. Since 293 cells express adenoviral E1a proteins, experiments were also performed in HeLa cells to assess the relative contribution of T antigen and E1a proteins to IFN trans activation. In HeLa cells, T-antigen coexpression increased the constitutive level of IFN-beta and IFN-alpha 1 promoter activity without augmenting relative inducibility. Coexpression of T antigen and E1a proteins did not have a cooperative effect on type 1 IFN expression.

The herpes simplex virus type 1 alpha protein ICP27 can act as a trans-repressor or a trans-activator in combination with ICP4 and ICP0

The herpes simplex virus type 1 (HSV-1) alpha proteins ICP4, ICP0, and ICP27 are trans-acting proteins which affect HSV-1 gene expression. To investigate potential interactions between these alpha products and to determine the specificity of action of the alpha proteins in combination with each other compared with their activities individually, we performed a series of transient-expression assays. In these assays we used plasmids containing the alpha genes encoding ICP4, ICP0, and ICP27 either singly or in combination as effectors and HSV-1 genes of different kinetic classes and heterologous genes as targets. The HSV-1 targets consisted of promoter-regulatory domains from alpha (ICP0 and ICP27), beta (thymidine kinase and alkaline exonuclease), beta-gamma (glycoprotein D, glycoprotein B, and VP5), and gamma (glycoprotein C) genes, each fused to the chloramphenicol acetyltransferase (CAT) gene. The heterologous target genes consisted of the simian virus 40 early promoter with enhancer and the Rous sarcoma virus long terminal repeat promoter and enhancer each fused to the CAT gene. Target promoter activity was measured by the assay of CAT activity in extracts of transfected cells and by Northern (RNA) blot hybridization of CAT mRNA. The results of these experiments showed that ICP4 activated only HSV-1 target genes, whereas ICP0 activated all of the targets and ICP27 had little effect on any of the targets. ICP4 and ICP0 had a synergistic effect when inducing HSV-1 targets, but they did not have this effect on the heterologous targets pSV2-CAT or pRSV-CAT. In fact, lower levels of CAT activity and CAT mRNA were found in the presence of both effectors than with ICP0 alone. Most interestingly, although the effector plasmid containing the ICP27 gene had little effect on its own, two different and marked effects depending on the target were observed when ICP27 was combined with ICP4 or ICP0 or both. A trans-repression of the induction seen with ICP4 and ICP0 was found when ICP27 was present in the transfections with pSV2-CAT, pRSV-CAT, pICP0-CAT, pICP27-CAT, pTK-CAT, pgD-CAT, pgB-CAT, and pgC-CAT. This resulted in CAT activity levels which were similar to or lower than the basal level of expression of the target genes in the absence of effector plasmids. This trans-repression occurred over a wide range of concentrations of input ICP27 plasmid. In contrast to this repressive effect of ICP27, a trans-activation was seen when ICP4, ICP0, and ICP27 plasmids were combined in transfections with pAE-CAT and pVP5-CAT as targets. This trans-activation also occurred over a 10-fold range of input ICP27 plasmid. These results suggest that ICP27 can facilitate both down

trans activation of type 1 interferon promoters by simian virus 40 T antigen

A human transient expression system was used to measure the influence of simian virus 40 T antigen and adenovirus E1a proteins on the activation of alpha interferon subtype 1 (IFN-alpha 1) and IFN-beta promoters linked to the reporter chloramphenicol acetyltransferase gene. Large T-antigen production, amplified by expression plasmid replication in transfected 293 cells, was able to trans activate the IFN-beta promoter 5- to 10-fold, increasing both the constitutive and Sendai virus-induced levels of expression. Surprisingly, the previously quiescent transfected IFN-alpha 1 promoter in T-antigen-expressing cells displayed a level of inducibility similar to IFN-beta. The endogenous IFN-alpha 1 gene was also inducible to a limited extent in cells expressing T antigen. A truncated IFN-beta promoter deleted to position -37 relative to the CAP site was neither inducible nor trans activated by T antigen, suggesting that sequences required for efficient induction were also needed for trans activation. Since 293 cells express adenoviral E1a proteins, experiments were also performed in HeLa cells to assess the relative contribution of T antigen and E1a proteins to IFN trans activation. In HeLa cells, T-antigen coexpression increased the constitutive level of IFN-beta and IFN-alpha 1 promoter activity without augmenting relative inducibility. Coexpression of T antigen and E1a proteins did not have a cooperative effect on type 1 IFN expression.

Simian virus 40 major late promoter: a novel tripartite structure that includes intragenic sequences

Unlike most genes transcribed by RNA polymerase II, the simian virus 40 late transcription unit does not have a TATA box. To determine what sequences are required for initiation at the major late mRNA cap site of simian virus 40, clustered point mutations were constructed and tested for transcriptional activity in vitro and in vivo. Three promoter elements were defined. The first is centered 31 base pairs upstream of the cap site in a position normally reserved for a TATA box. The second is at the cap site. The third occupies a novel position centered 28 base pairs downstream of the cap site within a protein-coding sequence. The ability of RNA polymerase II to recognize this promoter suggests that there is greater variation in promoter architecture than had been believed previously.

Replication from a proximal simian virus 40 origin is severely inhibited by multiple reiterations of the 72-base-pair repeat enhancer sequence

In a previous study in our laboratory, the effect of the reiteration frequency of the simian virus 40 (SV40) 72-base-pair (bp) repeat enhancer on transcription from the proximal SV40 early promoter was investigated (R. Kumar, T. A. Firak, C. T. Schroll, and K. N. Subramanian, Proc. Natl. Acad. Sci. USA 83:3199-3203, 1986). Increasing the enhancer copy number to four increased transcription proportionately; further increments in enhancer copy number reversed this effect, resulting in a decrease in the transcriptional activation. In the present study, the effect of enhancer reiteration on the replication efficiency of plasmids containing the SV40 origin of replication was investigated in transient replication assays in vivo in COS-1 monkey kidney cells producing the SV40 large tumor antigen required for replication. A plasmid containing the SV40 core origin and three copies of the replication-activating, G+C-rich 21-bp repeat promoter element replicated efficiently. Plasmids containing multiple copies of the 72-bp repeat enhancer cloned in head-to-tail linkage adjacent to the 21-bp repeat and the core origin replicated less efficiently; the decrease in replication efficiency could be correlated with the number of copies of the 72-bp repeat; replication was severely curtailed when 10 or more copies of the 72-bp repeat were present. Replication was not significantly inhibited by an increase in the number of copies of the 21-bp repeat to 15 or by the presence of three copies of a 360-bp pBR322 sequence in the immediate vicinity. Multiple copies of the 72-bp enhancer in cis were unable to inhibit replication from a second SV40 origin of replication situated 2 kilobase pairs away from the enhancer reiteration. Replication of four different test plasmids was not inhibited in trans by cotransfection of an excess of a potential competitor plasmid containing a 24-copy reiteration of the 72-bp enhancer. These results indicate that multiple tandem reiterations of the 72-bp enhancer inhibit replication only when they are present in cis adjacent to the origin of replication. Possible explanations for this inhibitory effect, such as an unfavorable local chromatin structure induced by the multimeric enhancer region or reduced or improper communications between factors bound to the multimeric region and the adjacent replication origin, are discussed.

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.

Role for DNA replication in beta-globin gene activation

Transcriptional activation of the Xenopus laevis beta-globin gene requires the synergistic action of the simian virus 40 enhancer and DNA replication in DEAE-dextran-mediated HeLa cell transfections. Replication does not act through covalent modification of the template, since its requirement was not obviated by the prior replication of the transfected DNA in eucaryotic cells. Transfection of DNA over a 100-fold range demonstrates that replication does not contribute to gene activation simply increasing template copy number. Furthermore, in cotransfections of replicating and nonreplicating constructs, only replicating templates were transcribed. Replication is not simply a requirement of chromatin assembly, since even unreplicated templates generated nucleosomal ladders. Stimulation of beta-globin transcription by DNA replication, though less marked, was also observed in calcium phosphate transfections. We interpret these results as revealing a dynamic role for replication in gene activation.

Expression of simian virus 40 T antigen in Escherichia coli: localization of T-antigen origin DNA-binding domain to within 129 amino acids

The genomic coding sequence of the large T antigen of simian virus 40 (SV40) was cloned into an Escherichia coli expression vector by joining new restriction sites, BglII and BamHI, introduced at the intron boundaries of the gene. Full-length large T antigen, as well as deletion and amino acid substitution mutants, were inducibly expressed from the lac promoter of pUC9, albeit with different efficiencies and protein stabilities. Specific interaction with SV40 origin DNA was detected for full-length T antigen and certain mutants. Deletion mutants lacking T-antigen residues 1 to 130 and 260 to 708 retained specific origin-binding activity, demonstrating that the region between residues 131 and 259 must carry the essential binding domain for DNA-binding sites I and II. A sequence between residues 302 and 320 homologous to a metal-binding "finger" motif is therefore not required for origin-specific binding. However, substitution of serine for either of two cysteine residues in this motif caused a dramatic decrease in origin DNA-binding activity. This region, as well as other regions of the full-length protein, may thus be involved in stabilizing the DNA-binding domain and altering its preference for binding to site I or site II DNA.

Simian virus 40 major late promoter: a novel tripartite structure that includes intragenic sequences

Unlike most genes transcribed by RNA polymerase II, the simian virus 40 late transcription unit does not have a TATA box. To determine what sequences are required for initiation at the major late mRNA cap site of simian virus 40, clustered point mutations were constructed and tested for transcriptional activity in vitro and in vivo. Three promoter elements were defined. The first is centered 31 base pairs upstream of the cap site in a position normally reserved for a TATA box. The second is at the cap site. The third occupies a novel position centered 28 base pairs downstream of the cap site within a protein-coding sequence. The ability of RNA polymerase II to recognize this promoter suggests that there is greater variation in promoter architecture than had been believed previously.

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.

Replication from a proximal simian virus 40 origin is severely inhibited by multiple reiterations of the 72-base-pair repeat enhancer sequence

In a previous study in our laboratory, the effect of the reiteration frequency of the simian virus 40 (SV40) 72-base-pair (bp) repeat enhancer on transcription from the proximal SV40 early promoter was investigated (R. Kumar, T. A. Firak, C. T. Schroll, and K. N. Subramanian, Proc. Natl. Acad. Sci. USA 83:3199-3203, 1986). Increasing the enhancer copy number to four increased transcription proportionately; further increments in enhancer copy number reversed this effect, resulting in a decrease in the transcriptional activation. In the present study, the effect of enhancer reiteration on the replication efficiency of plasmids containing the SV40 origin of replication was investigated in transient replication assays in vivo in COS-1 monkey kidney cells producing the SV40 large tumor antigen required for replication. A plasmid containing the SV40 core origin and three copies of the replication-activating, G+C-rich 21-bp repeat promoter element replicated efficiently. Plasmids containing multiple copies of the 72-bp repeat enhancer cloned in head-to-tail linkage adjacent to the 21-bp repeat and the core origin replicated less efficiently; the decrease in replication efficiency could be correlated with the number of copies of the 72-bp repeat; replication was severely curtailed when 10 or more copies of the 72-bp repeat were present. Replication was not significantly inhibited by an increase in the number of copies of the 21-bp repeat to 15 or by the presence of three copies of a 360-bp pBR322 sequence in the immediate vicinity. Multiple copies of the 72-bp enhancer in cis were unable to inhibit replication from a second SV40 origin of replication situated 2 kilobase pairs away from the enhancer reiteration. Replication of four different test plasmids was not inhibited in trans by cotransfection of an excess of a potential competitor plasmid containing a 24-copy reiteration of the 72-bp enhancer. These results indicate that multiple tandem reiterations of the 72-bp enhancer inhibit replication only when they are present in cis adjacent to the origin of replication. Possible explanations for this inhibitory effect, such as an unfavorable local chromatin structure induced by the multimeric enhancer region or reduced or improper communications between factors bound to the multimeric region and the adjacent replication origin, are discussed.

Role for DNA replication in beta-globin gene activation

Transcriptional activation of the Xenopus laevis beta-globin gene requires the synergistic action of the simian virus 40 enhancer and DNA replication in DEAE-dextran-mediated HeLa cell transfections. Replication does not act through covalent modification of the template, since its requirement was not obviated by the prior replication of the transfected DNA in eucaryotic cells. Transfection of DNA over a 100-fold range demonstrates that replication does not contribute to gene activation simply increasing template copy number. Furthermore, in cotransfections of replicating and nonreplicating constructs, only replicating templates were transcribed. Replication is not simply a requirement of chromatin assembly, since even unreplicated templates generated nucleosomal ladders. Stimulation of beta-globin transcription by DNA replication, though less marked, was also observed in calcium phosphate transfections. We interpret these results as revealing a dynamic role for replication in gene activation.

Both upstream and intron sequence elements are required for elevated expression of the rat somatic cytochrome c gene in COS-1 cells

To investigate the transcriptional control of nuclear-encoded respiratory genes in mammals, we have performed a deletional analysis of cis-acting regulatory sequences in the rat somatic cytochrome c gene. Three major regions are required for maximal expression of the transfected gene in kidney cell lines CV-1 and COS-1. One of these, region III (+71 to +115 from the transcription initiation site), is an unusual intragenic controlling element found in the 5' end of the first intron, while the other two, region I (-191 to -165) and region II (-139 to -84), define the upstream promoter. Region II contains two consensus CCAAT boxes and mediates a constitutive level of expression in both cell lines. In contrast, regions I and III are both required for the increased promoter activity observed in COS-1 cells compared with promoter activity observed in CV-1 cells, and the regions function individually as competitors with the full promoter for trans-acting factors or complexes. Region III contains a perfect octanucleotide homology with region I in addition to a consensus Sp1-transcription-factor-binding site. Promoter stimulation in COS-1 cells can be duplicated in CV-1 cells by cotransfecting with a T-antigen-producing vector, but purified T antigen does not bind anywhere in the cytochrome c promoter. A control promoter from the mouse metallothionein I gene is similarly activated in T-antigen-producing cells only in the presence of zinc, which activates its upstream regulatory sites. We conclude that T antigen stimulates these cellular promoters through the activation or induction of cellular factors or complexes that mediate their effects through promoter-specific regulatory elements. Cytochrome c promoter regions activated in this system may play a physiological role in controlling gene expression.

Carboxyl-terminal mutants of the large tumor antigen of simian virus 40: a role for the early protein late in the lytic cycle

Simian virus 40 (SV40) mutants dl1066 and dl1140 contain deletions within the region encoding the carboxyl terminus of the large tumor (T) antigen. Although these mutations have little effect on the efficiency of viral DNA replication, they decrease the yield of infectious virus particles by 3-4 orders of magnitude [Pipas, J. (1985) J. Virol. 54, 569-575]. Here we show that the level of late RNA is lower by a factor of 5-15 in CV-1P monkey cells infected with these mutants compared to cells infected with wild-type SV40. Consistent with this decrease in RNA, synthesis of late viral structural proteins VP1 and VP3 decreases by a factor of 5-15. In contrast, the synthesis of SV40 agnoprotein decreases by a factor greater than 100. Intercistronic complementation of these mutants with pm1493 and dl121, two SV40 mutants that are defective in agnoprotein but encode wild-type T antigen, results in an increased synthesis of agnoprotein in the infected cells. These results suggest that the carboxyl-terminal portion of T antigen participates in the posttranscriptional regulation of agnoprotein.