Functional anatomy of the simian virus 40 late promoter

Directed Nucleosome Sliding during the Formation of the Simian Virus 40 Particle Exposes DNA Sequences Required for Early Transcription

Simian virus 40 (SV40) exists as chromatin throughout its life cycle and undergoes typical epigenetic regulation mediated by changes in nucleosome location and associated histone modifications. In order to investigate the role of epigenetic regulation during the encapsidation of late-stage minichromosomes into virions, we mapped the locations of nucleosomes containing acetylated or methylated lysines in the histone tails of H3 and H4 present in the chromatin from 48-h-postinfection minichromosomes and disrupted virions. In minichromosomes obtained late in infection, nucleosomes were found carrying various histone modifications primarily in the regulatory region, with a major nucleosome located within the enhancer and other nucleosomes at the early and late transcriptional start sites. The nucleosome found in the enhancer would be expected to repress early transcription by blocking access to part of the SP1 binding sites and the left side of the enhancer in late-stage minichromosomes while also allowing late transcription. In chromatin from virions, the principal nucleosome located in the enhancer was shifted ∼70 bases in the late direction from what was found in minichromosomes, and the level of modified histones was increased throughout the genome. The shifting of the enhancer-associated nucleosome to the late side would effectively serve as a switch to relieve the repression of early transcription found in late minichromosomes while likely also repressing late transcription by blocking access to necessary regulatory sequences. This epigenetic switch appeared to occur during the final stage of virion formation.IMPORTANCE For a virus to complete infection, it must produce a new virus particle in which the genome is able to support a new infection. This is particularly important for viruses like simian virus 40 (SV40), which exist as chromatin throughout their life cycles, since chromatin structure plays a major role in the regulation of the life cycle. In order to determine the role of SV40 chromatin structure late in infection, we mapped the locations of nucleosomes and their histone tail modifications in SV40 minichromosomes and in the SV40 chromatin found in virions using chromatin immunoprecipitation-DNA sequencing (ChIP-Seq). We have identified a novel viral transcriptional control mechanism in which a nucleosome found in the regulatory region of the SV40 minichromosome is directed to slide during the formation of the virus particle, exposing transcription factor binding sites required for early transcription that were previously blocked by the presence of the nucleosome.

Genetic analysis of the human papillomavirus type 31 differentiation-dependent late promoter

Human papillomaviruses infect stratifying squamous epithelia, causing benign and malignant lesions. Upon differentiation of the host keratinocyte, the virus undergoes a dramatic increase in both DNA replication and transcription from the late promoter, leading to expression of late genes and virion morphogenesis. In human papillomavirus type 31 (HPV31), the late promoter is designated p742 and includes multiple start sites embedded within the E7 gene. In this report, we mapped viral DNA elements that control transcriptional activity from p742. Enhancer elements in the viral upstream regulatory region positively regulate this promoter. The region containing the transcriptional start sites is dispensable for activity, and at least two separate elements in the E6/E7 region are capable of supporting transcription. Of these, we mapped one to a 150-bp region of the E7 open reading frame and designate it the core p742 promoter. Using GF109203X, an inhibitor of protein kinase C signaling, we show that p742 activation is independent of viral genome amplification. Finally, we mapped elements in the region of p742 that confer responsiveness to differentiation and show that the upstream regulatory region does not contribute to the differentiation response of p742. These studies are an important step toward understanding the functioning and regulation of this multiple-start promoter.

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.

Two synthetic Sp1-binding sites functionally substitute for the 21-base-pair repeat region to activate simian virus 40 growth in CV-1 cells

The 21-bp repeat region of simian virus 40 (SV40) activates viral transcription and DNA replication and contains binding sites for many cellular proteins, including Sp1, LSF, ETF, Ap2, Ap4, GT-1B, H16, and p53, and for the SV40 large tumor antigen. We have attempted to reduce the complexity of this region while maintaining its growth-promoting capacity. Deletion of the 21-bp repeat region from the SV40 genome delays the expression of viral early proteins and DNA replication and reduces virus production in CV-1 cells. Replacement of the 21-bp repeat region with two copies of DNA sequence motifs bound with high affinities by Sp1 promotes SV40 growth in CV-1 cells to nearly wild-type levels, but substitution by motifs bound less avidly by Sp1 or bound by other activator proteins does not restore growth. This indicates that Sp1 or a protein with similar sequence specificity is primarily responsible for the function of the 21-bp repeat region. We speculate about how Sp1 activates both SV40 transcription and DNA replication.

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

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

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.

Characterization of SV40 enhancer motifs involved in positive and negative regulation of the constitutive late promoter activity; effect of T-antigen

By analyzing the late promoter activity of a series of nonreplicative recombinants mutated within the different enhancer motifs of SV40 we identified both positive and negative regulatory elements. In the absence of T-antigen, the motifs Sph and/or octamer, and to a lesser extent the motifs GTI and P, account for the constitutive expression of the late promoter. The motif GTII overlaps elements that negatively regulate the expression of the late promoter. These results indicate that the late promoter is down-regulated not only at the level of the GC motifs but also at the enhancer level. Moreover, we showed that T-antigen interacts with both positive and negative regulatory elements.

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.

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.

Inhibition of SV40 DNA replication by Rous sarcoma virus LTR enhancer

Simian virus 40 (SV40) late region recombinant constructs containing the Rous sarcoma virus (RSV) src gene along with RSV enhancer stimulated expression but completely abolished SV40 DNA replication. Constructs, in which the heterologous enhancer sequences were omitted, did replicate normally in African green monkey kidney cells and, in the presence of helper virus, gave rise to infectious progeny. Inhibition of SV40 DNA replication follows a cis-acting mechanism and is most likely due to a conformational change of the SV40 chromatin structure.

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.

Unidirectional deletion and linker scan analysis of the late promoter of the human papovavirus BK

We have previously shown that the late promoter of the human papovavirus BK (prototype) is contained within the three 68-bp repeats and a 66-bp region to the late side of the repeats which together constitute the early promoter enhancer. We have now carried out unidirectional deletion and linker scan analyses of these sequences to identify the major elements of the late promoter in human and monkey cells. Several important sequence motifs involved in late promoter function are found throughout this region. The most active ones correspond to previously defined binding sites for the transcription factors NF1 and Sp1 and a GC-rich region known to be important for early promoter function. The NF1 sequences may also be involved in negative regulation in some situations.