Common regulatory elements control gene expression from polyoma early and late promoters in cells transformed by chimeric plasmids

Replication of damaged DNA in vitro is blocked by p53

The tumor suppressor protein p53 may have other roles and functions in addition to its well-documented ability to serve as a sequence-specific transcriptional activator in response to DNA damage. We showed previously that p53 can block the replication of polyomavirus origin-containing DNA (Py ori-DNA) in vitro when p53 binding sites are present on the late side of the Py ori. Here we have both further extended these observations and have also examined whether p53 might be able to bind directly to and inhibit the replication of damaged DNA. We found that p53 strongly inhibits replication of gamma-irradiated Py ori-DNA and such inhibition requires both the central DNA binding domain and the extreme C-terminus of the p53 protein. An endogenous p53 binding site lies within the Py origin and is required for the ability of p53 to block initiation of replication from gamma-irradiated Py ori-DNA, suggesting the possibility of DNA looping caused by p53 binding both non-specifically to sites of DNA damage and specifically to the endogenous site in the polyomavirus origin. Our results thus suggest the possibility that under some circumstances p53 might serve as a direct regulator of DNA replication and suggest as well an additional function for cooperation between its two autonomous DNA binding domains.

Role of middle T-small T in the lytic cycle of polyomavirus: control of the early-to-late transcriptional switch and viral DNA replication

A comparative analysis of the lytic cycle of wild-type polyomavirus and middle T and small T defective mutants was carried out in the A2 genetic background. The results contrast with those obtained in comparisons between the hr-t type and their middle-T small-T-producing partners as previously described (20). The A2-derived mutants were found to share the maturation defect previously described for the hr-t mutants. However, their defect in DNA replication was more acute, resulting in a 5- to 100-fold decrease in the accumulation of viral genomes. Furthermore, their gene expression pattern was affected. A2-derived mutants displayed an early defect resulting in a 4- to 16-h delay in the expression of large T, and an alteration of the early-to-late transcriptional switch. In wild-type A2 infection, this switch is characterized by a large increase in the accumulation of early transcripts followed by late transcripts after the appearance of middle T and small T proteins and the onset of viral DNA replication (L. Chen and M. M. Fluck, J. Virol. 75: 8368-8379, 2001). In the mutant infection, increases in both classes of transcripts were delayed and reduced, but the effect on early transcripts was more pronounced. As has been described previously for the hr-t mutants (E. Goldman, J. Hattori, and T. Benjamin, Cell 13:505-513, 1979), the magnitude of these defects depended upon experimental conditions. Experiments using cytosine beta-arabinofuranoside to reduce genome amplification suggest that the effect of middle T-small T on the transcriptional switch is not solely mediated by the effect of these protein(s) on increasing the number of templates. These data provide the first direct demonstration of an effect of middle T and/or small T in the viral transcription pattern during viral infection. The results agree with previous results obtained with plasmid reporters and with our understanding that the downstream targets of the middle T signaling pathway include three transcription factors that have binding sites in the enhancer domain that play a key regulatory role in the expression of the viral genes.

Cyclin-dependent kinase regulation of the replication functions of polyomavirus large T antigen

The amino-terminal portion of polyomavirus (Py) large T antigen (T Ag) contains two phosphorylation sites, at T187 and T278, which are potential substrates for cyclin-dependent kinases (CDKs). Our experiments were designed to test whether either or both of these sites are involved in the origin DNA (ori DNA) replication function of Py T Ag. Mutations were generated in Py T Ag whereby either or both threonines were replaced with alanine, generating T187A, T278A, and double-mutants (DM [T187A T278A]) mutant T Ags. We found that the Py ori DNA replication functions of T278A and DM, but not T187A, mutant T Ags were abolished both in vivo and in vitro. Consistent with this finding, it was shown that the ori DNA binding and unwinding activities of mutant T278A Py T Ag were greatly impaired. Moreover, whereas wild-type Py T Ag is an efficient substrate for phosphorylation by cyclin A-CDK2 and cyclin B-cdc2 complexes, it is phosphorylated poorly by a cyclin E-CDK2 complex. In contrast to mutant T187A, which behaved similarly to the wild-type protein, T278A was only weakly phosphorylated by cyclin B-cdc2. These data thus suggest that T278 is an important site on Py T Ag for phosphorylation by CDKs and that loss of this site leads to its various defects in mediating ori DNA replication. S- and G2-phase-specific CDKs, but not a G1-specific CDK, can phosphorylate wild-type T Ag, which suggests yet another reason why DNA tumor viruses require actively cycling host cells.

Cell-type specific activation of the polyomavirus F9-1 regulatory region in transgenic mice

To characterize the activity of the polyomavirus regulatory region, two hybrid marker genes were constructed. In the first construct, the early promoter regulates expression of the CAT gene and the late promoter regulates expression of the lacZ gene. In the second construct, the lacZ gene was placed under the control of the early promoter. The fusion constructs were introduced into the mouse germline. Gene expression was analysed in the generated transgenic mice. A pronounced cell-type specific activation of the transcriptional control region was found in different tissues of the developing embryo and in the adult animal. The control region is recognized and activated in early preimplantation embryos. Around the time of implantation, sequential activation of the Py regulatory region was first observed in differentiating cells. Stage- and tissue-specific expression were noted later in embryonic development. Comparing reporter gene expression on the single-cell level, the different viral promoters display identical expression patterns throughout ontogenesis. Quantitative analysis revealed that marker gene expression from the late promoter was significantly higher than from the early promoter. Furthermore, the cell-type specificity of the control region is not altered in the presence of its regulatory protein, the LT.

Murine polyomavirus and simian virus 40 large T antigens produce different structural alterations in viral origin DNA

Murine polyomavirus (Py) and simian virus (SV40) encode homologous large T antigens (T Ags) and also have comparable sequence motifs in their core replication origins. While the ability of SV40 T Ag to produce specific distortions within the SV40 core replication origin (ori) in a nucleotide-dependent fashion has been well documented, little is known about related effects of Py T Ag on Py ori DNA. Therefore, we have examined viral origin DNA binding in the presence of nucleotide and the resulting structural changes induced by Py and SV40 T Ags by DNase I footprinting and KMnO4 modification assays. The structural changes in the Py ori induced by Py T Ag included sites within both the A/T and early side of the core origin region, consistent with what has been shown for SV40. Interestingly, however, Py T Ag also produced sites of distortion within the center of the origin palindrome and at several sites within both the early and late regions that flank the core ori. Thus, Py T Ag produces a more extensive and substantially different pattern of KMnO4 modification sites than does SV40 T Ag. We also observed that both T Ags incompletely protected and distorted the reciprocal ori region. Therefore, significant differences in the interactions of Py and SV40 T Ags with ori DNA may account for the failure of each T Ag to support replication of the reciprocal ori DNA in permissive cell extracts.

A unique subpopulation of murine DNA polymerase alpha/primase specifically interacts with polyomavirus T antigen and stimulates DNA replication

Murine cells or cell extracts support the replication of plasmids containing the replication origin (ori-DNA) of polyomavirus (Py) but not that of simian virus 40 (SV40), whereas human cells or cell extracts support the replication of SV40 ori-DNA but not that of Py ori-DNA. It was shown previously that fractions containing DNA polymerase alpha/primase from permissive cells allow viral ori-DNA replication to proceed in extracts of nonpermissive cells. To extend these observations, the binding of Py T antigen to both the permissive and nonpermissive DNA polymerase alpha/primase was examined. Py T antigen was retained by a murine DNA polymerase alpha/primase but not by a human DNA polymerase alpha/primase affinity column. Likewise, a Py T antigen affinity column retained DNA polymerase alpha/primase activity from murine cells but not from human cells. The murine fraction which bound to the Py T antigen column was able to stimulate Py ori-DNA replication in the nonpermissive extract. However, the DNA polymerase alpha/primase activity in this murine fraction constituted only a relatively small proportion (approximately 20 to 40%) of the total murine DNA polymerase alpha/primase that had been applied to the column. The DNA polymerase alpha/primase purified from the nonbound murine fraction, although far more replete in this activity, was incapable of supporting Py DNA replication. The two forms of murine DNA polymerase alpha/primase also differed in their interactions with Py T antigen. Our data thus demonstrate that there are two distinct populations of DNA polymerase alpha/primase in murine cells and that species-specific interactions between T antigen and DNA polymerases can be identified. They may also provide the basis for initiating a novel means of characterizing unique subpopulations of DNA polymerase alpha/primase.

A unique subpopulation of murine DNA polymerase alpha/primase specifically interacts with polyomavirus T antigen and stimulates DNA replication

Murine cells or cell extracts support the replication of plasmids containing the replication origin (ori-DNA) of polyomavirus (Py) but not that of simian virus 40 (SV40), whereas human cells or cell extracts support the replication of SV40 ori-DNA but not that of Py ori-DNA. It was shown previously that fractions containing DNA polymerase alpha/primase from permissive cells allow viral ori-DNA replication to proceed in extracts of nonpermissive cells. To extend these observations, the binding of Py T antigen to both the permissive and nonpermissive DNA polymerase alpha/primase was examined. Py T antigen was retained by a murine DNA polymerase alpha/primase but not by a human DNA polymerase alpha/primase affinity column. Likewise, a Py T antigen affinity column retained DNA polymerase alpha/primase activity from murine cells but not from human cells. The murine fraction which bound to the Py T antigen column was able to stimulate Py ori-DNA replication in the nonpermissive extract. However, the DNA polymerase alpha/primase activity in this murine fraction constituted only a relatively small proportion (approximately 20 to 40%) of the total murine DNA polymerase alpha/primase that had been applied to the column. The DNA polymerase alpha/primase purified from the nonbound murine fraction, although far more replete in this activity, was incapable of supporting Py DNA replication. The two forms of murine DNA polymerase alpha/primase also differed in their interactions with Py T antigen. Our data thus demonstrate that there are two distinct populations of DNA polymerase alpha/primase in murine cells and that species-specific interactions between T antigen and DNA polymerases can be identified. They may also provide the basis for initiating a novel means of characterizing unique subpopulations of DNA polymerase alpha/primase.

Production of polyomavirus late mRNAs requires sequences near the 5' end of the leader but does not require leader-to-leader splicing

Polyomavirus late mRNAs contain multiple copies of a 57-nucleotide leader sequence derived by splicing from multigenome-length late transcripts. Inefficient termination of transcription and inefficient polyadenylation allow accumulation of these giant transcripts. In this report, we show that a viable mutant virus, ins5, which contains an efficient rabbit beta-globin polyadenylation signal, produced late mRNAs whose vast majority contains only one leader. ins5 virus nevertheless produced as much late mRNA as did wild-type virus and grew as well as did wild-type virus in mouse cells. These results demonstrate that leader-to-leader splicing per se is not required for efficient production of late mRNAs or for efficient virus replication. However, we also found that RNAs lacking critical sequences near the 5' end of the leader did not accumulate as mRNAs and that most late transcripts made during the early part of the late phase, when few late mRNAs are produced, initiated downstream of the 5' end of the leader. These results indicate that a sequence element near the 5' end of the leader is required for proper processing, transport, or stability of late mRNAs and that the control of late mRNA production depends in part on the choice of transcription initiation sites at the late promoter.

Assembly of nascent DNA into nucleosome structures in simian virus 40 chromosomes by HeLa cell extract

A soluble system was developed that could support DNA replication in simian virus 40 (SV40) chromosomes. DNA synthesis in this system required the presence of purified SV40 large tumor antigen, SV40 chromosomes prepared from virus-infected monkey cells, a crude extract from HeLa cells, and several low-molecular-weight components. In comparison to the replication of purified SV40 form I DNA, the rate of DNA synthesis was 15 to 20% in this system. DNA synthesis started near the replication origin of SV40 and proceeded bidirectionally in a semiconservative manner. Micrococcal nuclease digestion experiments revealed that the replicated DNA produced in this system became organized into a regularly spaced array of nucleosome core particles when an appropriate amount of purified HeLa core histones was added to the reaction mixture. SV40 form I DNA replicating under the same conditions was also assembled into nucleosomes, which were arranged in a rather dispersed manner and formed an aberrant chromatin structure.

Enhancer and promoter elements from simian virus 40 and polyomavirus can substitute for an upstream activation sequence in Saccharomyces cerevisiae

Ten fragments of higher eucaryotic DNA were tested for upstream activation sequence activity in Saccharomyces cerevisiae by inserting them upstream of a CYC1::lacZ promoter lacking an upstream activation sequence. Fragments containing the 21-base-pair repeat region, the enhancer of simian virus 40 or both strongly stimulated beta-galactosidase synthesis, and three fragments from the polyomavirus enhancer region stimulated moderate levels. Three of the four controls of random DNA sequences failed to stimulate significant levels, and the fourth stimulated moderate levels. The stimulation in all cases was independent of the orientation of the inserted fragment. Two series of clones were examined in which between one and six tandemly arranged copies of a fragment were inserted into the XhoI site of the vector. Very interestingly, we detected an apparent exponential relationship between the number of copies of a fragment and the amount of beta-galactosidase produced. Southern analysis showed that increases in enzyme activity were not a result of increased plasmid copy number. Rather, quantitative S1 nuclease analysis demonstrated that the increases were correlated with steady-state levels of lacZ-specific mRNA. We suggest that there may be an evolutionary relationship between some transcriptional activation sequences in yeast cells and the higher eucaryotic regulatory elements that we tested.

Enhancer and promoter elements from simian virus 40 and polyomavirus can substitute for an upstream activation sequence in Saccharomyces cerevisiae

Ten fragments of higher eucaryotic DNA were tested for upstream activation sequence activity in Saccharomyces cerevisiae by inserting them upstream of a CYC1::lacZ promoter lacking an upstream activation sequence. Fragments containing the 21-base-pair repeat region, the enhancer of simian virus 40 or both strongly stimulated beta-galactosidase synthesis, and three fragments from the polyomavirus enhancer region stimulated moderate levels. Three of the four controls of random DNA sequences failed to stimulate significant levels, and the fourth stimulated moderate levels. The stimulation in all cases was independent of the orientation of the inserted fragment. Two series of clones were examined in which between one and six tandemly arranged copies of a fragment were inserted into the XhoI site of the vector. Very interestingly, we detected an apparent exponential relationship between the number of copies of a fragment and the amount of beta-galactosidase produced. Southern analysis showed that increases in enzyme activity were not a result of increased plasmid copy number. Rather, quantitative S1 nuclease analysis demonstrated that the increases were correlated with steady-state levels of lacZ-specific mRNA. We suggest that there may be an evolutionary relationship between some transcriptional activation sequences in yeast cells and the higher eucaryotic regulatory elements that we tested.

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.

Binding of nuclear factor EF-C to a functional domain of the hepatitis B virus enhancer region

Nuclear factor EF-C is present in extracts prepared from human HepG2 liver cells and from other, nonliver cell lines and binds to the hepatitis B virus and polyomavirus transcriptional enhancer regions in vitro. An inverted repeat (5'-GTTGCNNNGCAAC-3') is located within both binding regions. Diethyl pyrocarbonate interference binding assays and competition binding experiments using altered binding sites demonstrated that EF-C contacts symmetrical nucleotides within the inverted repeat. Mutations that changed the length of the spacer region between the arms of the inverted repeat were introduced in the hepatitis enhancer region. Introduction of 1 or 2 base pairs between the repeats did not affect EF-C binding, but deletion of 1 base pair or introduction of 3 to 9 base pairs reduced binding dramatically. Introduction of 10 base pairs restored partial EF-C binding ability. These and other results suggest that EF-C binding is stabilized by dimerization. In vivo assays for enhancer function using these mutants demonstrated that the EF-C binding site is a functional and important component of the hepatitis B virus enhancer region.

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.

Binding of nuclear factor EF-C to a functional domain of the hepatitis B virus enhancer region

Nuclear factor EF-C is present in extracts prepared from human HepG2 liver cells and from other, nonliver cell lines and binds to the hepatitis B virus and polyomavirus transcriptional enhancer regions in vitro. An inverted repeat (5'-GTTGCNNNGCAAC-3') is located within both binding regions. Diethyl pyrocarbonate interference binding assays and competition binding experiments using altered binding sites demonstrated that EF-C contacts symmetrical nucleotides within the inverted repeat. Mutations that changed the length of the spacer region between the arms of the inverted repeat were introduced in the hepatitis enhancer region. Introduction of 1 or 2 base pairs between the repeats did not affect EF-C binding, but deletion of 1 base pair or introduction of 3 to 9 base pairs reduced binding dramatically. Introduction of 10 base pairs restored partial EF-C binding ability. These and other results suggest that EF-C binding is stabilized by dimerization. In vivo assays for enhancer function using these mutants demonstrated that the EF-C binding site is a functional and important component of the hepatitis B virus enhancer region.

DNA sequence requirements for replication of polyomavirus DNA in vivo and in vitro

Cell extracts of FM3A mouse cells replicate polyomavirus (Py) DNA in the presence of immunoaffinity-purified Py large T antigen, deoxynucleoside triphosphates, ATP, and an ATP-generating system. This system was used to examine the effects of mutations within or adjacent to the Py core origin (ori) region in vitro. The analysis of plasmid DNAs containing deletions within the early-gene side of the Py core ori indicated that sequences between nucleotides 41 and 57 define the early boundary of Py DNA replication in vitro. This is consistent with previously published studies on the early-region sequence requirements for Py replication in vivo. Deleting portions of the T-antigen high-affinity binding sites A and B (between nucleotides 57 and 146) on the early-gene side of the core ori led to increased levels of replication in vitro and to normal levels of replication in vivo. Point mutations within the core ori region that abolish Py DNA replication in vivo also reduced replication in vitro. A mutant with a reversed orientation of the Py core ori region replicated in vitro, but to a lesser extent that wild-type Py DNA. Plasmids with deletions on the late-gene side of the core ori, within the enhancer region, that either greatly reduced or virtually abolished Py DNA replication in vivo replicated to levels similar to those of wild-type Py DNA plasmids in vitro. Thus, as has been observed with simian virus 40, DNA sequences needed for Py replication in vivo are different from and more stringent than those required in vitro.

DNA sequence requirements for replication of polyomavirus DNA in vivo and in vitro

Cell extracts of FM3A mouse cells replicate polyomavirus (Py) DNA in the presence of immunoaffinity-purified Py large T antigen, deoxynucleoside triphosphates, ATP, and an ATP-generating system. This system was used to examine the effects of mutations within or adjacent to the Py core origin (ori) region in vitro. The analysis of plasmid DNAs containing deletions within the early-gene side of the Py core ori indicated that sequences between nucleotides 41 and 57 define the early boundary of Py DNA replication in vitro. This is consistent with previously published studies on the early-region sequence requirements for Py replication in vivo. Deleting portions of the T-antigen high-affinity binding sites A and B (between nucleotides 57 and 146) on the early-gene side of the core ori led to increased levels of replication in vitro and to normal levels of replication in vivo. Point mutations within the core ori region that abolish Py DNA replication in vivo also reduced replication in vitro. A mutant with a reversed orientation of the Py core ori region replicated in vitro, but to a lesser extent that wild-type Py DNA. Plasmids with deletions on the late-gene side of the core ori, within the enhancer region, that either greatly reduced or virtually abolished Py DNA replication in vivo replicated to levels similar to those of wild-type Py DNA plasmids in vitro. Thus, as has been observed with simian virus 40, DNA sequences needed for Py replication in vivo are different from and more stringent than those required in vitro.

Replicative cis-advantage of polyomavirus regulatory region mutants in different murine cell lines

To determine the relative growth advantages of polyomavirus regulatory region mutants selected from Friend leukemic and neuroblastoma cells persistently infected with polyomavirus A2 wild type, different murine cell lines, some of which are capable of further differentiation in vitro, were used as hosts in mixed infection and transfection. The tests allowed the determination, through the measurement of cis-advantage in replication, of the most effective polyomavirus regulatory region constitutions for a given cell line and, in some cases, for specific stages of cell differentiation. Furthermore, different domains of the viral regulatory region were shown to have different effects--positive, neutral, or negative--depending on the host analyzed.

Adenovirus E1a proteins repress expression from polyomavirus early and late promoters

We have examined the effects of the E1a products of adenovirus types 5 and 12 on the expression of polyomavirus early and late promoters. In cotransfection experiments in HeLa cells, plasmids expressing the E1a region of adenovirus type 5 or 12 repressed both the early and late promoters of polyomavirus, and deletion analysis indicates that the polyomavirus enhancers were the target of the E1a repression. With mutants lacking enhancer sequences, the polyomavirus early promoter but not the late promoter was trans-activated by E1a. Chimeric mutant plasmids with deletions in the regulatory region that contained either the A enhancer or the B enhancer were repressed to the same extent, indicating that E1a can repress both elements. Polyomavirus variant plasmids with rearrangements in the regulatory region conferring activity in embryonal carcinoma stem cells were repressed by E1a as was the wild type, suggesting that the repressor function is quite general. We discuss a model in which the influence of E1a on the transcriptional activity of a gene is the sum of positive and negative effects on promoter and enhancer elements and discuss possible mechanisms of negative regulation of enhancer function.

Adenovirus E1a proteins repress expression from polyomavirus early and late promoters

We have examined the effects of the E1a products of adenovirus types 5 and 12 on the expression of polyomavirus early and late promoters. In cotransfection experiments in HeLa cells, plasmids expressing the E1a region of adenovirus type 5 or 12 repressed both the early and late promoters of polyomavirus, and deletion analysis indicates that the polyomavirus enhancers were the target of the E1a repression. With mutants lacking enhancer sequences, the polyomavirus early promoter but not the late promoter was trans-activated by E1a. Chimeric mutant plasmids with deletions in the regulatory region that contained either the A enhancer or the B enhancer were repressed to the same extent, indicating that E1a can repress both elements. Polyomavirus variant plasmids with rearrangements in the regulatory region conferring activity in embryonal carcinoma stem cells were repressed by E1a as was the wild type, suggesting that the repressor function is quite general. We discuss a model in which the influence of E1a on the transcriptional activity of a gene is the sum of positive and negative effects on promoter and enhancer elements and discuss possible mechanisms of negative regulation of enhancer function.

Interaction of a nuclear factor with the polyomavirus enhancer region

We have identified a factor present in nuclear extracts of undifferentiated F9 murine embryonal carcinoma cells that specifically interacts with the polyomavirus enhancer region. Nuclease "footprint" analysis was used to define the binding site that corresponds precisely to the boundaries of polyoma enhancer element C defined by Veldman et al. [Veldman, G. M., Lupton, S. & Kamen, R. (1985) Mol. Cell. Biol. 5, 649-658] that is required as an enhancer for efficient viral DNA replication and early and late region transcription. The region of nuclease protection contains a 6-base-pair inverted repeat, separated by 3 base pairs, and symmetrical flanking DNase I hypersensitive cleavage sites, suggesting that this factor may bind as a dimer. A cloned 29-base-pair polyoma DNA fragment contains an intact binding domain. Similar levels of binding activity were found in nuclear extracts prepared from differentiated murine F9 cells, as well as murine L cells and human HeLa cells. The factor has been termed "EF-C" for enhancer binding factor to polyoma element C.

Regulation of polyomavirus late promoter activity by viral early proteins

To assess the effect of the polyomavirus (Py) early proteins, the large T (LT), middle T (MT), and small T (ST) antigens, on gene expression from the Py late promoter, replication-defective plasmid constructs with the bacterial chloramphenicol acetyltransferase (cat) gene linked to this promoter were cotransfected into mouse or rat cells with plasmids capable of producing either LT, MT, or all three early proteins. When target CAT plasmids contained a truncated early region and thus had the coding potential for MT and ST, base-line CAT activities were low, whereas cotransfection with an LT plasmid resulted in up to 70-fold stimulation of CAT activity that was also reflected in similar increases in the level of steady-state mRNA. Studies with target plasmids with deletions within the Py regulatory region indicated that at least the major LT-binding site C and a functional enhancer region were both required for maximal stimulation of CAT activity. However, although enhancer deletions totally suppressed the ability of target plasmids to be trans activated, a consistent two- to fourfold stimulation of CAT activity by LT was still observed with a plasmid in which all three major LT-binding sites were deleted. Of four mutant LTs incapable of binding Py DNA but retaining immortalization potential, only one showed a low but significant trans-activating ability. When the early coding region was completely eliminated from the target plasmid, base-line CAT activity was increased 10-fold. LT failed to stimulate CAT activity to the same levels observed with target plasmid containing the truncated early region, but this limited response could be enhanced by supplying, in addition, MT and ST. Our results suggest that LT trans activation may involve the formation of a complex of transcriptional factors which interacts with the enhancer, an interaction that is facilitated both by the binding of LT to the Py regulatory region and by the presence of MT or ST or both, and that a significant portion of LT stimulation of late gene expression is a result of the removal of the competing early transcriptional unit via autoregulation. In addition, our results suggest that LT trans activation involves a second indirect component acting independently of LT binding and that the immortalization and trans activation functions of LT can be dissociated.