Both trans-acting factors and chromatin structure are involved in the regulation of transcription from the early and late promoters in simian virus 40 chromosomes

Hormone response element in SV40 late promoter directly affects synthesis of early as well as late viral RNAs

We previously demonstrated that the presence of a hormone response element surrounding the transcription initiation site of the SV40 major late promoter (+1 HRE) confers a replication advantage to the virus in a cell-type-specific manner. We determine here the mechanism by which the +1 HRE confers this advantage by analyzing in detail the various stages of the viral life cycle of wild-type versus a +1 HRE mutant in MA-134 cells. We show that the mutant overexpresses late genes at the expense of early genes at early times after infection. This initial underproduction of early RNA leads, subsequently, to an underproduction of large T-antigen, viral DNA, and infectious virions. We conclude that the +1 HRE is necessary for the proper initial regulation of transcription from the early as well as late promoter so the cascade of subsequent events can be executed for the optimal production of virions.

Differentiation-dependent chromatin rearrangement coincides with activation of human papillomavirus type 31 late gene expression

The life cycle of human papillomaviruses (HPVs) is tightly linked to the differentiation status of the host cell. While early genes are expressed during the initial stages of viral infection, late gene expression occurs in the suprabasal layers of the cervical epithelium. Late genes encode E1-E4, a cytosolic protein, and capsid proteins L1 and L2. We have mapped over 30 initiation sites for late transcripts and show that the transcripts initiate in a 200-nucleotide region within the E7 open reading frame. The mechanisms regulating the activation of late gene expression, however, are not yet understood. DNase I hypersensitivity analysis of HPV-31 chromatin in cell lines that maintain viral genomes extrachromosomally indicates that a major shift in nuclease digestion occurs upon differentiation. In undifferentiated cells, hypersensitive regions exist in the upstream regulatory region proximal to the E6 open reading frame. Upon differentiation, a region between nucleotides 659 and 811 in the E7 open reading frame becomes accessible to DNase I. These results indicate that the late transcript initiation region becomes accessible to transcription factor binding upon differentiation. Several complexes mediate chromatin rearrangement, and we tested whether histone acetylation was sufficient for late transcript activation. Treatment with the histone deacetylase inhibitor trichostatin A was found to be insufficient to activate late gene expression in undifferentiated cells. However, it did activate expression of early transcripts. These results suggest that chromatin remodeling around the late promoter occurs upon epithelial differentiation and that mechanisms in addition to histone deacetylation contribute to activation of late gene expression.

Infectious human papillomavirus type 18 pseudovirions

Human papillomavirus type 18 (HPV18) capsid proteins L1 and L2, synthesised in mammalian cells using recombinant vaccinia viral expression vectors, are transported to the nucleus and assembled into virus-like particles. When 293T cells, which express SV40 T antigen, were transfected with plasmid DNAs containing an SV40 origin of replication then infected with vaccinia viral vectors encoding L1 and L2, plasmid DNA was encapsidated into the particles. The DNAs ranged in size from 5.4 to 7.9 kb. By encapsidating plasmids containing either the beta-galactosidase gene or the puromycin-resistance gene, the pseudovirions were shown to be infectious in that they could transfer beta-galactosidase activity or confer resistance to puromycin to a number of cell types, indicating that the uptake and decapsidation of HPV particles are not the main determinants of cell type specificity of HPV. Episomal HPV16 DNA in a cervical keratinocyte line could also be encapsidated. Further investigation showed that DNA encapsidation is independent of HPV DNA sequences and of T antigen-mediated plasmid DNA replication. Instead, the minor capsid protein, L2, was found to be attached to plasmid mini-chromosomes extracted from these cells, suggesting a role for L2 in encapsidation. Consistent with this, the L1 protein alone was unable to encapsidate DNA, although it was able to form virus-like particles. The results suggest that intracellular episomal DNAs of suitable size can be encapsidated by the HPV18 L1 and L2 proteins without the need of any HPV packaging signal, and reintroduced into cells.

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

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

SV40 early-to-late switch involves titration of cellular transcriptional repressors

We have purified factors from HeLa cell nuclear extracts that bind to the transcriptional initiation site of the SV40 major late promoter (SV40-MLP). The resulting fraction consists predominantly of three proteins, collectively called initiator-binding protein of SV40 (IBP-s) with electrophoretic mobilities of approximately 45-55 kD. Gel mobility-shift and DNase I-protection analyses indicate that each of these three proteins associates with high affinity to sequences located at the initiation site and 55 bp downstream of it. IBP-s-binding sites with lower affinities are located at +5 and +30. Addition of purified IBP-s to a cell-free transcription system represses transcription from the SV40-MLP, but not the SV40 early promoter. SV40 mutants lacking the two strongest IBP-s-binding sites (1) are not repressed by the addition of IBP-s in vitro, (2) overproduce late RNA (relative to wild-type SV40) at low, but not high, template copy number in vitro, and (3) exhibit increased levels of late RNA at early, but not late, times after transfection into CV-1 cells. Therefore, IBP-s is a cellular repressor of transcription of the SV40-MLP that may, in large part, be responsible for the replication-dependent component of the early-to-late shift in SV40 gene expression. Partial amino acid sequence data obtained from the approximately 55-kD component of IBP-s indicate that it is hERR1, an orphan member of the steroid-thyroid hormone receptor superfamily. These findings suggest simple molecular mechanisms by which hormones may modulate expression of viral late genes. We speculate that activation of expression of the late genes of other viruses may occur by similar mechanisms.

Identification and characterization of novel promoters in the genome of human papillomavirus type 18

Most studies on the regulation of gene expression in human papillomaviruses (HPV) have focused on the promoter for the early genes E6 and E7. This promoter is located at the junction between the long control region and the E6 open reading frame. RNA mapping studies have suggested that additional promoters may exist in other parts of the genome. In this study, we used a combination of transcription in vitro and an analysis of RNA produced in vivo in transfected cells to identify three novel promoters in the genome of human papillomavirus type 18. These promoters are located in front of the E2 gene (P2598), within the E2 coding sequences (P3036), and at the end of the L2 open reading frame (P5600). They were active in HeLa cells, as shown by a chloramphenicol acetyltransferase assay. The activity of the P3036 promoter was stimulated by the bovine papillomavirus type 1 E2 protein.

Opening and refolding of simian virus 40 and in vitro packaging of foreign DNA

Simian virus 40 (SV40) can be disassembled under mild conditions by reducing disulfide bonds in the capsid and removing calcium ions. The nucleoprotein complexes formed, analyzed by electron microscopy, were circular and made up of 59 +/- 4 subunits, each with a diameter of about 10 nm. The complexes contained the viral DNA, histones, and the viral capsid proteins. The complexes had much-reduced infectivities compared with intact SV40. Addition of calcium ions to the disrupted virus caused the nucleoprotein complexes to refold into virus-like structures which sedimented at the same rate as intact SV40 and regained infectivity. Treatment of the disrupted SV40 with a high concentration of salt dissociated the viral proteins from the DNA. Lowering stepwise the salt concentration, removing the reducing agent, and adding calcium ions allowed structures to be reformed, and these structures sedimented, like SV40, at 240S and were infectious. The plaque-forming ability of the reconstituted particles was between that of the dissociated components and that of intact SV40. The addition of purified DNA of polyomavirus to the dissociated SV40 before the lowering of the salt concentration showed that virus-like structures could be formed from SV40 proteins and a foreign DNA.

In vitro initiation of transcription by RNA polymerase II on in vivo-assembled chromatin templates

We have studied the initiation of transcription in vitro by RNA polymerase II on simian virus 40 (SV40) minichromosomal templates isolated from infected cells. The efficiency and pattern of transcription from the chromatin templates were compared with those from viral DNA templates by using two in vitro transcription systems, either HeLa whole-cell extract or basal transcription factors, RNA polymerase II, and one of two SV40 promoter-binding transcription factors, LSF and Sp1. Dramatic increases in numbers of transcripts upon addition of transcription extract and different patterns of usage of the multiple SV40 initiation sites upon addition of Sp1 versus LSF strongly suggested that transcripts were being initiated from the minichromosomal templates in vitro. That the majority of transcripts from the minichromosomes were due to initiation de novo was demonstrated by the efficient transcription observed in the presence of alpha-amanitin, which inhibited minichromosome-associated RNA polymerase II, and an alpha-amanitin-resistant RNA polymerase II, which initiated transcription in vitro. The pattern of transcription from the SV40 late and early promoters on the minichromosomal templates was similar to the in vivo pattern of transcription during the late stages of viral infection and was distinct from the pattern of transcription generated from viral DNA in vitro. In particular, the late promoter of the minichromosomal templates was transcribed with high efficiency, similar to viral DNA templates, while the early-early promoter of the minichromosomal templates was inhibited 10- to 15-fold. Finally, the number of minichromosomes competent to initiate transcription in vitro exceeded the amount actively being transcribed in vivo.

In vitro initiation of transcription by RNA polymerase II on in vivo-assembled chromatin templates

We have studied the initiation of transcription in vitro by RNA polymerase II on simian virus 40 (SV40) minichromosomal templates isolated from infected cells. The efficiency and pattern of transcription from the chromatin templates were compared with those from viral DNA templates by using two in vitro transcription systems, either HeLa whole-cell extract or basal transcription factors, RNA polymerase II, and one of two SV40 promoter-binding transcription factors, LSF and Sp1. Dramatic increases in numbers of transcripts upon addition of transcription extract and different patterns of usage of the multiple SV40 initiation sites upon addition of Sp1 versus LSF strongly suggested that transcripts were being initiated from the minichromosomal templates in vitro. That the majority of transcripts from the minichromosomes were due to initiation de novo was demonstrated by the efficient transcription observed in the presence of alpha-amanitin, which inhibited minichromosome-associated RNA polymerase II, and an alpha-amanitin-resistant RNA polymerase II, which initiated transcription in vitro. The pattern of transcription from the SV40 late and early promoters on the minichromosomal templates was similar to the in vivo pattern of transcription during the late stages of viral infection and was distinct from the pattern of transcription generated from viral DNA in vitro. In particular, the late promoter of the minichromosomal templates was transcribed with high efficiency, similar to viral DNA templates, while the early-early promoter of the minichromosomal templates was inhibited 10- to 15-fold. Finally, the number of minichromosomes competent to initiate transcription in vitro exceeded the amount actively being transcribed in vivo.

SV40 large T antigen trans-activates the long terminal repeats of a large family of human endogenous retrovirus-like sequences

The Simian Virus 40 (SV40) large T antigen (T) is required for the initiation of viral replication, the autoregulation of early gene expression, and the activation of late gene expression in productively infected cells. In addition to these roles, T has been implicated in the transcriptional activation of a variety of viral and cellular promoters. We have used the chloramphenicol acetyltransferase (CAT) reporter gene system to study the effect of T on the long terminal repeats (LTRs) of a large family of human endogenous retrovirus-like sequences, RTVL-H. Here we show that T can activate expression from certain RTVL-H LTRs 5- to 30-fold. Competition experiments in which an excess of plasmid containing only an RTVL-H LTR was cotransfected with an LTR-CAT reporter gene construct confirmed that this effect is specific for RTVL-H sequences. Restriction enzyme analysis using methylation-sensitive enzymes has shown that this activation is not due to plasmid replication. We have also observed this trans-activation effect in two CV-1 cells lines containing stably integrated LTR-CAT constructs. These results demonstrate that a known transforming protein can alter the transcriptional capabilities of RTVL-H LTRs. As there are approximately 3000 related LTRs in the genomes of humans and other primates, these findings suggest that a large number of these promoters and their associated transcripts may be transcriptionally stimulated by this and other oncogens.

SV40 activates transcription from the transferrin receptor promoter by inducing a factor which binds to the CRE/AP-1 recognition sequence

During the course of lytic infection by simian virus 40 (SV40), expression of both the viral late genes and certain host cellular genes is induced. The promoter of the cellular transferrin receptor (TR) gene contains a DNA sequence which is similar to the AP-1- and AP-4-binding region in SV40 which has been implicated in the control of the viral late promoter. Expression of TR is needed for cells to enter S-phase and is therefore expected to be important for the SV40 lytic cycle. Here we show that the level of TR mRNA in vivo was increased by SV40 infection. A factor which activates transcription from the TR promoter in vitro was specifically induced in SV40-infected cells. Gel mobility shift assays with an oligonucleotide comprising this part of the TR promoter showed three nucleoprotein complexes to be formed with proteins from CV-1 cells. Following SV40 infection, one of the complexes was increased ten-fold. Formation of this complex was specifically reduced by competition with the phorbol ester-responsive element of the collagenase gene, implying that the factor is a member of the AP-1/Jun/Fos family. Cross-linking of the complex by ultraviolet light showed major DNA-binding components to be proteins of about 55 kD and 47 kD. Removal of this factor by adding the oligonucleotide to in vitro transcription reactions with the TR promoter, abolished the activation of TR transcription. The factor which binds to the TR promoter co-sedimented with SV40 chromosomes extracted late in infection. This suggests that similar transcriptional regulatory proteins are involved in controlling transcription from both the SV40 and the TR promoters, and that the virus can use a common mechanism to induce viral and host cellular transcription.

A member of the activator protein 1 family found in keratinocytes but not in fibroblasts required for transcription from a human papillomavirus type 18 promoter

Papillomaviruses are tissue specific and replicate in differentiating keratinocytes. We are interested in the question of tissue specificity at the level of transcription. We used extracts from human keratinocytes and human fibroblasts at low passage number and from HeLa cells to look for factors binding to the E6 promoter of human papillomavirus type 18 (HPV-18) DNA by footprint and gel mobility shift experiments. We found a factor present in HeLa and keratinocyte extracts but not in fibroblast extracts which bound about 160 base pairs upstream from the start of E6. The binding site included the sequence TGACTAAG, which resembles the consensus binding site for the AP-1 family of proteins. Synthetic oligonucleotides containing this binding site specifically competed with factor binding to HPV-18 DNA, as did the AP-1 sequence of simian virus 40. They also inhibited transcription from the E6 promoter in vitro in extracts from HeLa cells. Thus, the presence of this keratinocyte-specific factor seems to be important for HPV-18 transcription.

T-antigen is not bound to the replication origin of the simian virus 40 late transcription complex

Simian virus 40 tumor antigen (T-antigen) plays a central role in determining which gene is transcribed from viral DNA late in infection. Results from several studies have led to a model in which the binding of T-antigen to the viral origin of replication results in repression of transcription from the stronger early gene promoter and stimulation of transcription from the late gene promoter. We have tested this model by determining directly the occupancy of the T-antigen binding site in the origin of replication of the late transcription complex. Thus, viral transcription complexes were digested with BglI, a restriction enzyme that cuts in the viral replication origin. The enzyme cleaved 78(+/- 12)% of the late transcription complexes. Control experiments demonstrated that cleavage is blocked when T-antigen is bound to the origin site, that exogenously added T-antigen can bind to the site in the transcription complex, and that T-antigen is not released during isolation of the complex. These results indicate that most of the late transcription complexes do not have T-antigen bound to the origin site, and are therefore inconsistent with models that require this site to be occupied by T-antigen to maintain proper regulation of gene transcription late in infection.

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.

Locations of nucleosomes on the regulatory region of simian virus 40 chromatin

We have asked where the nucleosomes are located with respect to the replication origin and regulatory region of simian virus 40 DNA, what would be the possible functional consequences of the identified locations, and to what extent these locations correlate with the current views on mechanisms involved in establishing nucleosome-free regions in chromatin. To identify the precise location of nucleosomes, we have shot-gun cloned and sequenced nucleosomal DNA obtained from micrococcal nuclease digestion of wt776 chromatin prepared late in infection. Our results indicate that nucleosomes do not occupy unique positions over the replication origin or the elements involved in transcriptional control. However, it appears that the nucleosome distribution is not random, since several nucleosomes are represented by two or more independently generated clones. Two nearly identical cloned fragments map over the replication origin; five include 1.5 copies of the 72 base-pair enhancer sequences; and eight map to a region that spans a DNA bending locus and the major transcription initiation site of the late genes. The complex nucleosome distribution pattern observed in our direct analysis suggests that disparate nucleosome-free regions may be involved in controlling replication, and selective expression of the viral early or late genes.

Molecular control of tissue-specific expression at the mouse TNF locus

We have examined the patterns of mRNA accumulation and transcription of the tandemly linked genes for tumor necrosis factor (TNF)-beta and TNF-alpha. In spite of their tandem arrangement and close linkage, the two TNF genes utilize separate promoters. Our results show that, while levels of mRNA correlate with patterns of TNF-alpha and TNF-beta secretion by lymphocytes and macrophages, the transcriptional levels of the corresponding genes do not. The TNF-alpha gene is transcribed much more heavily than the TNF-beta gene in T lymphocytes, even though the TNF-beta mRNA is more abundant. Resting T lymphocytes and macrophages, which do not accumulate any TNF mRNA, nevertheless transcribe the TNF-alpha gene actively. On the other hand, the TNF-beta gene is transcriptionally silent in macrophages. Our results are consistent with a model where tissue specificity is controlled transcriptionally, whereas post-transcriptional events differentially control mRNA abundance.

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

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

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

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

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

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

Characterization of simian virus 40 large T antigen by using different monoclonal antibodies: T-p53 complexes are preferentially ATPase active and adenylylated

We used 21 monoclonal antibodies (PAbs 100 to 117, 405, 419, and KT3) specific for different determinants in simian virus 40 (SV40) large T antigen (T) and one antibody specific for p53 that coprecipitates T complexed with p53 (T-p53) to analyze T in SV40-infected CV1 cells. We measured the ATPase specific activity, extent of adenylylation, and p53 content of T precipitated by antibodies directed against the N-terminal region I (0.65 to 0.62 map units), the midregion III (0.43 to 0.28 map units) containing both the ATPase- and nucleotide-binding sites, and the C-terminal region IV (0.28 to 0.17 map units) of T. Lytic T appeared to exist in three different forms with respect to p53 binding and ATPase activity. The most ATPase-active form of T was that precipitated by PAb 122. This T-p53 complex contained only 6% of the total T but contributed 35% of the ATPase activity, on average. Free p53 isolated from 3T6, Ann-1, or L929 cells had no apparent ATPase activity. A second form of T precipitated by several antibodies had little associated p53 but appreciable ATPase activity, accounting for 15 to 20% of total T and 60 to 70% of the ATPase activity. The rest of T constituted the third form and was also depleted in p53 but had a decreased ATPase specific activity. Thus, the remaining 75 to 80% of T had 15 to 20% of the ATPase specific activity. Antibodies specific for region III precipitated T with both altered ATPase activity and altered amounts of bound p53. PAbs 104 and 114 reacted with ATPase-active T but inhibited ADP hydrolysis, suggesting that they were inactivating antibodies. T that was preferentially adenylylated in vitro corresponded to T that was also preferentially ATPase active. T bound to p53 was adenylylated to a higher specific activity than total T. In addition, p53 itself was significantly adenylylated under these conditions. The results suggest that ATPase activity and p53 binding are structurally and functionally related and that p53 alters biochemical activities of T and plays a role in productive infection.

Transcription elements and factors of RNA polymerase B promoters of higher eukaryotes

The promoter for eukaryotic genes transcribed by RNA polymerase B can be divided into the TATA box (located at -30) and startsite (+1), the upstream element (situated between -40 and about -110), and the enhancer (no fixed position relative to the startsite). Trans-acting factors, which bind to these elements, have been identified and at least partially purified. The role of the TATA box is to bind factors which focus the transcription machinery to initiate at the startsite. The upstream element and the enhancer somehow modulate this interaction, possibly through direct protein-protein interactions. Another class of transcription factors, typified by viral proteins such as the adenovirus EIA products, do not appear to require binding to a particular DNA sequence to regulate transcription. The latest findings in these various subjects are discussed.

Restriction enzyme accessibility and RNA polymerase localization on transcriptionally active SV40 minichromosomes isolated late in infection

The transcriptionally active SV40 minichromosomes isolated late in infection contain a nucleosome-free ORI region or gap. To analyze the chromatin structure of this subpopulation of minichromosomes extracted at different ionic strengths in the early and late coding regions, minichromosomes were isolated in the presence of a 5, 50, or 130 mM concentration of monovalent cations and subjected to in vitro RNA elongation in either the presence or the absence of high salt and anionic detergent. The minichromosomes isolated at low ionic strength were transcriptionally more active than those isolated at physiological ionic strength. Nevertheless, in each case, the in vitro elongation complexes were present essentially on the late strand of the SV40 genome and localized preferentially in the late and 3' early coding regions. These regions were transcribed similarly in either the presence or the absence of chromatin denaturing agents. In contrast, the in vitro elongation activity of the RNA polymerase molecules present on the late strand in the middle and 5' end of the early coding region was inhibited in the absence of treatments to disrupt chromatin structure. In addition, as probed by restriction enzyme digestion, the ORI and late coding regions of the transcriptionally active minichromosomes were found to be more sensitive than the 5' region of the early genes. Taken together, these results suggest that the 5' and middle regions of the early genes of the SV40 transcriptional complexes isolated late in infection at low or physiological ionic strength are packaged in a more compact conformation than the rest of the genome.

A transcriptional promoter of the human parvovirus B19 active in vitro and in vivo

The human parvovirus B19 causes aplastic crises in sickle cell anemia patients and the disease erythema infectiosum. So far, it has not been possible to grow B19 virus in cultured cells. Here we report the use of in vitro transcription in HeLa cell extracts and transient expression of cloned DNA transfected into HeLa cells to detect and map a strong transcriptional promoter on the B19 genome. The promoter is located near the left end of the B19 genome, at position 6 map units in the clone pYT103 (approximately 280 bp upstream of the first HindIII site), and directs transcription to the right. These results suggest that the strictly limited host range of B19 does not operate at the level of transcription from the promoter at the left end of the genome.

Characterization of the simian virus 40 late promoter: relative importance of sequences within the 72-base-pair repeats differs before and after viral DNA replication

We examined sequences involved in the simian virus 40 (SV40) late promoter in vivo, by using quantitative S1 nuclease analysis of a series of deletion mutants within the SV40 regulatory region. These mutants were constructed so as to place the altered promoter region in its normal position relative to the SV40 late genes. The effects of the deletions on late transcriptional activity were analyzed before and after viral DNA replication, by omitting or including SV40 large T antigen. The data show that (i) in the absence of large T antigen, the deletion of the 21-base-pair (bp) repeats results in a fourfold increase in late transcription, and (ii) the sequences within the 72-bp repeats are a component of the SV40 late promoter, acting not only before, but also after viral DNA replication. We identified two domains which contain sequences important for efficient late transcription. Domain I, at the late proximal end of each 72-bp repeat, was found to function before replication and was possibly also involved after replication. The contribution of domain II, at the late distal end of each 72-bp repeat, was much more significant after replication but only of minor importance before replication.

Regulation of transcription in vitro from herpes simplex virus genes

In vitro transcription assays were carried out by using as templates DNAs cut from the herpes simplex virus early glycoprotein D gene, the late glycoprotein C gene, the late VP5 gene, and the immediate-early ICP22 gene. Nuclear extracts from suspension cultures of uninfected HeLa cells effectively synthesized RNAs from genes of the immediate-early and delayed-early classes. To a lesser extent, the extracts also used DNAs cut from the late genes as templates. Transcription from the immediate-early gene was inhibited in extracts prepared from infected cells. Analysis of the proteins in infected-cell extracts by gel electrophoresis, transfer to nitrocellulose, and probing with specific antibody demonstrated the presence of the viral regulatory protein ICP4. Chromatographic fractionation of nuclear extract from infected cells yielded a mixture of proteins (fraction VIII) enriched in ICP4 (S.W. Faber and K.W. Wilcox, Nucleic Acids Res., 14:6067-6083, 1986). Addition of fraction VIII to the in vitro assay affected transcription. Depending on the DNA in the assay, an inhibitory or stimulatory effect was observed. Inhibition of RNA synthesis was found when DNA from the immediate-early gene was used as a template, and stimulation was found when DNA from the early or late gene was used.

Activity of simian virus 40 late promoter elements in the absence of large T antigen: evidence for repression of late gene expression

We used chloramphenicol acetyltransferase transient expression to examine the activity of the promoter elements of the simian virus 40 late promoter in the absence of large T antigen. Since the experiments were done in permissive CV-1 cells, these conditions mimic the state which exists early in the viral lytic cycle before the onset of replication and T-antigen-mediated trans activation. Our data, using deletion analysis, indicate that removal of the 21-base-pair (bp) repeat region causes as much as a 10-fold increase in activity of the late promoter elements. This result suggests that the 21-bp repeat sequences may be involved in repression of the late promoter elements during the early phase of the lytic infection. This is supported by competition analysis which indicates that increasing amounts of competitor containing only the 21-bp repeat region results in increased activity of the intact promoter. A model for the activity of the late promoter through the course of lytic infection is presented.

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

The late promoter of simian virus 40 (SV40) is activated in trans by the viral early gene product, T antigen. We inserted the wild-type late-promoter region, and deletion mutants of it, into chloramphenicol acetyltransferase transient expression vectors to identify promoter sequences which are active in the presence of T antigen. We defined two promoter activities. One activity was mediated by a promoter element within simian virus 40 nucleotides 200 to 270. The activity of this element was detectable only in the presence of an intact, functioning origin of replication and accounted for 25 to 35% of the wild-type late-promoter activity in the presence of T antigen. The other activity was mediated by an element located within a 33-base-pair sequence (simian virus nucleotides 168 to 200) which spans the junction of the 72-base-pair repeats. This element functioned in the absence of both the origin of replication and the T-antigen-binding sites and appeared to be responsible for trans-activated gene expression. When inserted into an essentially promoterless plasmid, the 33-base-pair element functioned in an orientation-dependent manner. Under wild-type conditions in the presence of T antigen, the activity of this element accounted for 65 to 75% of the late-promoter activity. The roles of the 33-base-pair element and T antigen in trans-activation are discussed.

Herpes simplex virus immediate early infected-cell polypeptide 4 binds to DNA and promotes transcription

In herpes simplex virus (HSV)-infected cells, there is a sequential expression of viral genes. In vivo experiments have implicated the Mr 175,000 immediate early protein ICP4 (infected-cell polypeptide 4) in the regulation of viral RNA synthesis, but the mechanism whereby ICP4 regulates transcription of viral genes is at present unknown. In this report we describe experiments with an in vitro transcription system and a purified preparation of ICP4 (estimated 5% of total protein). Using DNA from the HSV glycoprotein D gene (gD) as the template, we have observed that specific binding occurs between ICP4 and DNA sequences adjacent to the gD gene promoter and ICP4 stimulates initiation of transcription from the gD gene. The degree of stimulation depends on the amount of ICP4 present in the incubation. The kinetics of RNA synthesis demonstrate that the protein acts at the initiation step of transcription. These results identify ICP4 as a viral transcription factor whose presence on DNA facilitates the formation of transcription complexes.

Free and viral chromosome-bound simian virus 40 T antigen: changes in reactivity of specific antigenic determinants during lytic infection

Simian virus 40 (SV40) large T antigen (TAg), both free and bound to mature 70S and replicating 90S SV40 chromosomes, was prepared from lytically infected cells. The relative reactivity of the different TAg-containing fractions toward 10 monoclonal antibodies directed against three different regions in SV40 TAg and toward an antibody against the p53 protein was measured. The results for free TAg indicated that all of the determinants in both the amino-terminal (0.65 to 0.62 map units) and carboxy-terminal (0.28 to 0.17 map units) regions were highly reactive, whereas all five determinants located between 0.43 and 0.28 map units in the midregion of TAg were poorly reactive. For TAg bound to replicating chromosomes, all but one of the antibodies specific for TAg were highly reactive. Thus, antigenic sites in the middle of TAg, the region important for nucleotide binding and ATP hydrolysis (an activity required for viral DNA replication), were more accessible in TAg-replicating DNA complexes. As replicating molecules matured into 70S chromosomes, three or more determinants at different locations in TAg bound to chromatin became two- to fivefold less reactive, indicating other changes in TAg structure. Overall, at least nine different antigenic determinants in the TAg molecule were identified. Anti-p53 was reactive with about 10% of the free TAg and the same amount of SV40 chromosomes of all ages, suggesting that p53-TAg complexes are not preferentially associated with either replicating or mature viral chromosomes. When the reactivity of both mature and replicating labeled SV40 chromosomes with polyclonal tumor anti-T was measured as a function of time after purification, TAg bound to mature chromosomes appeared to dissociate about fourfold faster than that bound to replicating chromosomes. The relative amount of TAg in various subcellular fractions was measured by an enzyme-linked immunosorbent assay. Approximately 1.3% of the total TAg was estimated to be associated with SV40 chromosomes in infected cells. Based on the relative amounts of TAg and viral DNA in the 70S and 90S fractions, replicating chromosome-TAg complexes were estimated to bind 4.8 times more TAg per DNA molecule, on the average, than mature chromosome-TAg complexes. Together, these results are consistent with major differences in TAg structure when free and associated with replicating and nonreplicating SV40 chromosomes.

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

The late promoter of simian virus 40 (SV40) is activated in trans by the viral early gene product, T antigen. We inserted the wild-type late-promoter region, and deletion mutants of it, into chloramphenicol acetyltransferase transient expression vectors to identify promoter sequences which are active in the presence of T antigen. We defined two promoter activities. One activity was mediated by a promoter element within simian virus 40 nucleotides 200 to 270. The activity of this element was detectable only in the presence of an intact, functioning origin of replication and accounted for 25 to 35% of the wild-type late-promoter activity in the presence of T antigen. The other activity was mediated by an element located within a 33-base-pair sequence (simian virus nucleotides 168 to 200) which spans the junction of the 72-base-pair repeats. This element functioned in the absence of both the origin of replication and the T-antigen-binding sites and appeared to be responsible for trans-activated gene expression. When inserted into an essentially promoterless plasmid, the 33-base-pair element functioned in an orientation-dependent manner. Under wild-type conditions in the presence of T antigen, the activity of this element accounted for 65 to 75% of the late-promoter activity. The roles of the 33-base-pair element and T antigen in trans-activation are discussed.