Transcription from the SV40 early-early and late-early overlapping promoters in the absence of DNA replication

Differential SP1 interactions in SV40 chromatin from virions and minichromosomes

SP1 binding in SV40 chromatin in vitro and in vivo was characterized in order to better understand its role during the initiation of early transcription. We observed that chromatin from disrupted virions, but not minichromosomes, was efficiently bound by HIS-tagged SP1 in vitro, while the opposite was true for the presence of endogenous SP1 introduced in vivo. Using ChIP-Seq to compare the location of SP1 to nucleosomes carrying modified histones, we found that SP1 could occupy its whole binding site in virion chromatin but only the early side of its binding site in most of the minichromosomes carrying modified histones due to the presence of overlapping nucleosomes. The results suggest that during the initiation of an SV40 infection, SP1 binds to an open region in SV40 virion chromatin but quickly triggers chromatin reorganization and its own removal.

An RNA structure-mediated, posttranscriptional model of human α-1-antitrypsin expression

Protein and mRNA expression are in most cases poorly correlated, which suggests that the posttranscriptional regulatory program of a cell is an important component of gene expression. This regulatory network is still poorly understood, including how RNA structure quantitatively contributes to translational control. We present here a series of structural and functional experiments that together allow us to derive a quantitative, structure-dependent model of translation that accurately predicts translation efficiency in reporter assays and primary human tissue for a complex and medically important protein, α-1-antitrypsin. Our model demonstrates the importance of accurate, experimentally derived RNA structural models partnered with Kozak sequence information to explain protein expression and suggests a strategy by which α-1-antitrypsin expression may be increased in diseased individuals.

Chronic obstructive pulmonary disease (COPD) affects over 65 million individuals worldwide, where α-1-antitrypsin deficiency is a major genetic cause of the disease. The α-1-antitrypsin gene, SERPINA1, expresses an exceptional number of mRNA isoforms generated entirely by alternative splicing in the 5′-untranslated region (5′-UTR). Although all SERPINA1 mRNAs encode exactly the same protein, expression levels of the individual mRNAs vary substantially in different human tissues. We hypothesize that these transcripts behave unequally due to a posttranscriptional regulatory program governed by their distinct 5′-UTRs and that this regulation ultimately determines α-1-antitrypsin expression. Using whole-transcript selective 2′-hydroxyl acylation by primer extension (SHAPE) chemical probing, we show that splicing yields distinct local 5′-UTR secondary structures in SERPINA1 transcripts. Splicing in the 5′-UTR also changes the inclusion of long upstream ORFs (uORFs). We demonstrate that disrupting the uORFs results in markedly increased translation efficiencies in luciferase reporter assays. These uORF-dependent changes suggest that α-1-antitrypsin protein expression levels are controlled at the posttranscriptional level. A leaky-scanning model of translation based on Kozak translation initiation sequences alone does not adequately explain our quantitative expression data. However, when we incorporate the experimentally derived RNA structure data, the model accurately predicts translation efficiencies in reporter assays and improves α-1-antitrypsin expression prediction in primary human tissues. Our results reveal that RNA structure governs a complex posttranscriptional regulatory program of α-1-antitrypsin expression. Crucially, these findings describe a mechanism by which genetic alterations in noncoding gene regions may result in α-1-antitrypsin deficiency.

Nucleosome positioning in the regulatory region of SV40 chromatin correlates with the activation and repression of early and late transcription during infection

The location of nucleosomes in SV40 virions and minichromosomes isolated during infection were determined by next generation sequencing (NGS). The patterns of reads within the regulatory region of chromatin from wild-type virions indicated that micrococcal nuclease-resistant nucleosomes were specifically positioned at nt 5223 and nt 363, while in minichromosomes isolated 48 h post-infection we observed nuclease-resistant nucleosomes at nt 5119 and nt 212. The nucleosomes at nt 5223 and nt 363 in virion chromatin would be expected to repress early and late transcription, respectively. In virions from the mutant cs1085, which does not repress early transcription, we found that these two nucleosomes were significantly reduced compared to wild-type virions confirming a repressive role for them. In chromatin from cells infected for only 30min with wild-type virus, we observed a significant reduction in the nucleosomes at nt 5223 and nt 363 indicating that the potential repression by these nucleosomes appeared to be relieved very early in infection.

Emergence of infectious simian virus 40 whose AT tract in the replication origin/early promoter region is substituted by cellular or viral DNAs

In simian virus 40 (SV40) and several other polyomaviruses, the TATA box of the early promoter is embedded in an AT tract that is also an essential part of the replication origin. We generated an 'AT trap', an SV40 genome lacking the AT tract and unable to grow in CV-1 monkey cells. Co-transfection of the AT trap with oligonucleotides containing AT tracts of human polyomaviruses, a poly(A : T) tract or variants of the SV40 WT sequence all restored infectious virus. In a transfection of the AT trap without a suitable oligonucleotide, an AT-rich segment was incorporated, stemming either from bovine (calf serum) or monkey (host cell) DNA. Similarly, when cells were grown with human serum, a human DNA segment was captured by SV40 to substitute for the missing AT stretch. We conclude that the virus is quite opportunistic in accepting heterologous substitutes, and that even low-abundance DNA from serum can be incorporated into the viral genome.

Direct regulation of an oncogenic micro-RNA cluster by E2F transcription factors

Micro-RNAs (miRNAs) are a class of non-coding RNAs that post-transcriptionally regulate gene expression via the RNA interference pathway. In addition to roles in normal development, miRNAs have recently been implicated in a range of human diseases, including cancer. We recently demonstrated that a polycistronic cluster of miRNAs, miR-17-92, is oncogenic in a mouse model for Burkitt's lymphoma. This is due, in part, to a reduced apoptotic program. In an effort to understand the regulation of miR-17-92, we have studied the promoter structure of this miRNA cluster. The primary transcript initiates from a consensus initiator sequence downstream of a nonconsensus TATA box. The core promoter region contains two functional E2F transcription factor binding sites. Chromatin immunoprecipitation demonstrates that E2F3 is the primary E2F family member that occupies the promoter. These data place miR-17-92 in a regulatory loop between E2F3 and the miR-17 target E2F1. We propose a model whereby miR-17-92 promotes cell proliferation by shifting the E2F transcriptional balance away from the pro-apoptotic E2F1 and toward the proliferative E2F3 transcriptional network.

Interaction between T antigen and TEA domain of the factor TEF-1 derepresses simian virus 40 late promoter in vitro: identification of T-antigen domains important for transcription control

The large tumor antigen (TAg) of simian virus 40 regulates transcription of the viral genes. The early promoter is repressed when TAg binds to the origin and DNA replication begins, whereas the late promoter is activated by TAg through both replication-dependent and -independent mechanisms. Previously it was shown that activation is diminished when a site in the viral enhancer to which the factor TEF-1 binds is disrupted. We show here that the NH2-terminal region of TAg binds to the TEA domain of TEF-1, a DNA binding domain also found in the Drosophila scalloped and the Saccharomyces cerevisiae TEC1 proteins. The interaction inhibits DNA binding by TEF-1 and activates transcription in vitro from a subset of naturally occurring late start sites. These sites are also activated by mutations in the DNA motifs to which TEF-1 binds. Therefore, TEF-1 appears to function as a repressor of late transcription, and its involvement in the early-to-late shift in viral transcription is discussed. The mutation of Ser-189 in TAg, which reduces transformation efficiency in certain assays, disrupts the interaction with TEF-1. Thus, TEF-1 might also regulate genes involved in growth control.

A novel sequence-specific DNA-binding protein, LCP-1, interacts with single-stranded DNA and differentially regulates early gene expression of the human neurotropic JC virus

We have identified a novel brain-derived single-stranded-DNA-binding protein that interacts with a region of the human neurotropic JC virus enhancer designated the lytic control element (LCE). This nuclear factor, LCP-1 (for lytic control element-binding protein 1), specifically recognizes the LCE, as determined by gel retardation assays. Alkylation interference showed that specific nucleotides within the LCE were contacted by LCP-1. Subsequent experiments revealed that point mutations within the LCE differentially affected LCP-1 binding. UV cross-linking and competition analysis suggested that the LCP-1 DNA-protein complexes were 50 to 52 and 100 to 120 kDa in size. Promoter mutations that affected LCP-1 binding reduced early mRNA transcription during the early phase of the lytic cycle. However, upon DNA replication in the presence of JC virus T antigen, when early mRNA initiation shifts to new locations indicative of the late phase, the LCP-1 mutations had no effect. We suggest that the JC virus early transcription unit is differentially regulated by LCP-1 prior to but not after DNA replication, suggesting a novel mechanism by which DNA structure regulates eukaryotic gene expression.

Comeasurement of simian virus 40 early and late promoter activity in HeLa and 293 cells in the presence of T antigen

Transcription of the simian virus 40 (SV40) late promoter is strongly activated by SV40 T antigen. We were interested in examining this process in relation to other T-antigen functions such as replication and repression of early transcription. To quantitate the various T-antigen effects, we used a vector which has a promoterless beta-globin gene flanking the early and late sides of the SV40 promoter region. Following cotransfection with a plasmid encoding T antigen, transcription from the two promoters can be measured with a single S1 mapping probe and replication can be assayed by Southern blot analysis of DNA recovered in Hirt extracts. In this study, transactivation was examined in HeLa and 293 cells, since these cells differ in their ability to support SV40 replication. The strength of the late promoter relative to the early promoter was approximately three- to fourfold higher in 293 cells. Replication in 293 cells was also more efficient, by the same margin. In both cell lines, late promoter transactivation was barely detectable on replication-defective templates. Taken together, the results suggest that T-antigen activation of late transcription occurs only on replicated, or replicating, DNA. T antigen also activated the late-early start sites, and while in HeLa cells they were seen to be only 30% as strong as the late promoter, in 293 cells late and late-early activities were almost equal.

Promoter sequence and cell type can dramatically affect the efficiency of transcriptional activation induced by herpes simplex virus type 1 and its immediate-early gene products Vmw175 and Vmw110

The activation of transcription of the early and late classes of viral genes during infection by herpes simplex virus type 1 (HSV-1) requires the prior expression of immediate-early (IE) gene products. The IE gene products can also activate certain cellular and heterologous viral promoters. This paper presents a thorough analysis of transactivation of the HSV-1 glycoprotein gD and simian virus 40 early promoters, and two other promoters that are hybrids of both, under a variety of experimental conditions. Two methods of transactivation (superinfection with virus and co-transfection with isolated IE genes) have been used with all four target promoters in a variety of cell types. The conclusions are: (1) promoter sequence affects the efficiency of promoter activation by infectious HSV-1 virus, but this activation is not restricted to HSV promoters; (2) cell type affects the efficiency of promoter activation by HSV-1, and this can lead to a failure to activate a promoter in one cell type but not in others in which activation is generally more efficient; (3) a promoter can be activated to different extents in co-transfection experiments using plasmids carrying isolated IE genes that express Vmw110 or Vmw175 or when both are used together; (4) the pattern of activation of a promoter by the IE gene products in cotransfection experiments varies in different cell types; (5) changes in promoter sequence can alter the pattern of activation by the different IE polypeptides, and this pattern can again differ in different cell types; (6) other apparently minor experimental variables, as might exist between the standard methods used in different laboratories, can also affect the patterns of activation observed. The results are discussed in terms of the mechanism of action of the HSV-1 IE gene products and the limitations of the co-transfection assay.

The enhancer elements and GGGCGG boxes of SV40 provide similar functions in bidirectionally promoting transcription

The early and the late genes of simian virus 40 (SV40) are transcribed in opposite directions from a shared promoter region. The 72- and the 21-bp repeat regions of the SV40 genome contain the transcriptional enhancer and six copies of the Sp 1-binding GGGCGG box, respectively. SV40 mutants lacking various parts of these regions were examined in COS cells to determine the importance of these sequences for transcription in each direction. We made the following observations. (i) The 72-bp repeat region was required for efficient transcription of both the early and the late genes. (ii) The 21-bp repeat region was required for efficient early-gene transcription, but not for efficient late-gene transcription; however, it was able to supply some late-promoter activity when the 72-bp repeat region was missing. (iii) The ability of either of these regions to promote transcription was gradually reduced as the number of promoter elements within each was decreased. (iv) Mutations in these regions always decreased early-gene transcription more than late-gene transcription. These results indicate that both regions are made up of multiple bidirectional promoter elements, but that the 72-bp repeat region is more effective at inducing transcription than the 21-bp repeat region. Since each region can also (i) satisfy a need for promoter elements in the replication of viral DNA and (ii) induce a region of open chromatin, we conclude that the promoter elements within the enhancer and the GGGCGG boxes probably provide similar functions.

Constraints on spacing between transcription factor binding sites in a simple adenovirus promoter

The adenovirus 2 E1B transcription unit has an extremely simple promoter consisting of a TATA box and a closely situated GC box. The interaction between the TATA box and the GC box was analyzed using insertion mutations which expand the distance between the two elements. We observed that the E1B promoter has an unusually rigid architecture. When the GC box, which is a binding site for transcription factor Sp1, was separated further from the TATA box than in the wild-type promoter, in vivo transcription quickly diminished to a level comparable to the elimination of the Sp1 site. Yet all the insertion mutants bound Sp1 factor in vitro with an affinity approximately equal to that of the wild-type promoter. From these results, we argue that Sp1 binding alone is not sufficient to stimulate transcription. The increased distance might disrupt direct contacts between Sp1 and transcription factors bound at the TATA box, contacts required for transcription stimulation by Sp1. The insertion mutations do not interfere with the transcription activation process mediated by the adenovirus large E1A protein or the pseudorabies virus immediate early protein.

The A+T-rich sequence of the simian virus 40 origin is essential for replication and is involved in bending of the viral DNA

The origin-promoter region of simian virus 40 contains a 17-base-pair sequence composed exclusively of adenine (A) and thymine (T). We constructed a linker replacement mutant in which this stretch of A's and T's was reduced to 11 base pairs. While not affecting the level of early gene transcription, this mutation reduced the accumulation of viral DNA in COS cells at least 10(4) fold. In addition, a restriction fragment containing the wild-type A + T-rich region migrated in nondenaturing polyacrylamide gels with an anomalous mobility characteristic of bent DNA; however, the corresponding fragment from the mutant migrated less anomalously. Therefore, bending of the DNA in this region may play a role in some step in viral DNA replication.

Spacing between simian virus 40 early transcriptional control sequences is important for regulation of early RNA synthesis and gene expression

We have analyzed the effect of insertion mutants between the simian virus 40 (SV40) 21-base pair (bp) repeats and the early-early (EE) TATA sequence. Insertion of 4, 42, or 90 bp of DNA at the SV40 NcoI site (map position 37) has been analyzed for its effect on expression of the SV40 early gene and positioning of the RNA 5' ends. Insertion of 4 bp reduced SV40 early promoter-dependent chloramphenicol acetyltransferase (CAT) expression by six- to eightfold. Increasing the size of the insertion to 42 or 90 bp resulted in a further drop in early gene expression to basal levels. At the RNA level, the 4-bp insertion reduced EE RNA synthesis approximately 10-fold. No concomitant increase in late-early (LE) RNA synthesis was observed. Insertion of 42 or 90 bp of DNA resulted in a decrease of EE RNA synthesis and a stimulation of LE RNA synthesis. Deletion of the SV40 72-bp repeats from the insertion mutants demonstrated that some, but not all, of the LE RNA depends upon the presence of these sequences. These studies suggest that the ability of RNA polymerase II to utilize the EE (TATA-directed) transcriptional control sequence requires an interaction with the upstream 21-bp repeats or the 72-bp repeats or both. That LE RNA levels in pJI1-in42 CAT and pJI1-in90 CAT were equivalent to the level of EE RNA in pJI1-CAT, yet the level of CAT gene expression was decreased greater than 10-fold, suggests that LE mRNA is under translational control and probably prefers a 5' initiation codon proximal to that of the CAT gene.

Structural features of the DNA template required for transcription in vitro by yeast RNA polymerase B (II)

Yeast RNA polymerase II initiates in vitro transcription at two sites located within the vector DNA and the cloned promoter, on a recombinant plasmid DNA containing the yeast iso1 cytochrome c promoter. Both initiation sites are found within a DNA fragment hypersensitive to osmium tetroxide modification. Using a series of yeast iso1 cytochrome c promoter deletions, we have characterized an upstream DNA sequence required for optimal transcription from this site and shown in this case a correlation between osmium sensitivity and the capacity of RNA polymerase to initiate. However, perturbation of the double helix is not sufficient to generate a transcription initiation site. Insertion of 28 alternating AT residues at the EcoRV site of pBR322 generates an site hypersensitive to osmium tetroxide modification, that does not serve as a transcription start site.

Functional mapping of a trans-activating gene required for expression of a baculovirus delayed-early gene

The temporal regulation of an early gene of the baculovirus Autographa californica nuclear polyhedrosis virus was examined. We constructed a plasmid (plasmid 39CAT) in which the bacterial gene for chloramphenicol acetyltransferase was placed under the control of the promoter for the gene for a A. californica nuclear polyhedrosis virus 39,000-dalton protein (39K). A transient expression assay of plasmid 39CAT revealed that the 39K gene was expressed in infected cells but not in uninfected cells, indicating that the 39K gene should be classified as a delayed-early gene. The 39K promoter also efficiently directed the synthesis of chloramphenicol acetyltransferase when the plasmid was cotransfected with viral DNA which had been restricted with several restriction enzymes. To map the location of the gene(s) required for the synthesis of 39K, plasmid 39CAT was cotransfected with purified restriction fragments of A. californica nuclear polyhedrosis virus DNA. Fragments which mapped between 90.7 and 100.8 map units induced plasmid 39CAT. Plasmid pEcoRI-B, containing EcoRI fragment B (90 to 100 map units), activated plasmid 39CAT. Functional mapping of plasmid pEcoRI-B indicated that the essential region was located between 95.0 and 97.5 map units. The 5' end of this gene was mapped, and the chloramphenicol acetyltransferase gene was inserted under the control of its promoter. Transient assay experiments indicated that the trans-acting regulatory gene was expressed in uninfected cells and is therefore an immediate-early gene. This gene was named IE-1.

Multiple sequence motifs are involved in SV40 enhancer function

A systematic mutagenesis of the SV40 enhancer indicates that it spans approximately 100 bp and is composed of at least two distinct DNA domains which exhibit very little enhancing activity on their own. Their association results in a 400-fold enhancement of transcription, virtually irrespective of their relative orientation and, to some extent, of the distance between them. Enhancer activity can also be generated by duplication of either domain. We show also that the activity of each domain is due to the presence of several specific sequence motifs. These motifs are found assorted in different combinations in other viral and cellular enhancers.

Requirement of stereospecific alignments for initiation from the simian virus 40 early promoter

The distance between the simian virus 40 early promoter elements has been altered by inserting either odd or even multiples of half a DNA turn. There are marked differences in the in vivo effects of these two types of insertions on initiation of transcription from this promoter.

Expression of the late gene of simian virus 40 under the control of the simian virus 40 early-region promoter in monkey and mouse cells

We constructed a recombinant plasmid (pVNR4) with the simian virus 40 (SV40) early promoter positioned 30 nucleotides upstream from the major SV40 late transcription initiation site at residue 325. After transfection of the recombinant plasmid DNA into COS and mouse L cells, the transcripts of the SV40 late region were analyzed by S1 nuclease and primer extension analysis. The following are the principal findings. (i) The 16S and 19S late RNAs used the characteristic wild-type splice; no detectable levels of 19S unspliced RNA were observed. (ii) The majority of the late RNAs were heterogeneous and initiated in the early region (upstream and downstream from the Hogness-Goldberg sequence), and a minor population initiated at residue 325, the principal 5' terminus of the wild-type late RNA. (iii) During SV40 lytic infection there was a shift in initiation sites used to transcribe the early region from sites that are downstream to sites which are upstream (up RNA) of the origin of DNA replication. We observed that unlike lytic infection, T antigen and viral DNA replication were not needed for the appearance of up RNA in mouse L cells. (iv) In mouse L cells late RNAs were made, and the residue 325 5' end was utilized in the absence of T antigen or DNA replication. (v) In COS cells we found down RNA and up RNA transcribed from the extrachromosomally replicating plasmid but only down RNA produced by the integrated SV40 genome.

Functional interactions of the simian virus 40 core origin of replication with flanking regulatory sequences

We constructed a matched set of plasmids to investigate the interactions of essential core sequences of the simian virus 40 replication origin with flanking regulatory sequences. Deletions of either T-antigen-binding region I or the 21-base-pair repeated promoter elements reduced replication to 50 to 70% of wild-type levels. The simultaneous deletion of both regions decreased replication to less than 5% of wild-type levels. Thus, the double deletion greatly amplified the defects of the single deletions. We conclude that region I and the 21-base-pair repeats have related rather than independent functions in DNA synthesis. Insertion of a synthetic region I or the adenovirus 2 major late promoter at the late side of isolated core sequences in place of the 21-base-pair repeats failed to restore replication. In contrast, insertion of a single 72-base-pair enhancer element stimulated replication of the core origin more than fivefold. Thus, three distinct regulatory elements appear to facilitate core DNA replication by related mechanisms. Flanking sequences have only a small direct effect on T-antigen binding to naked core DNA. Possible mechanisms of action include the regulation of transcription or of chromatin structure.

T antigen and template requirements for SV40 DNA replication in vitro

A cell-free system for replication of SV40 DNA was used to assess the effect of mutations altering either the SV40 origin of DNA replication or the virus-encoded large tumor (T) antigen. Plasmid DNAs containing various portions of the SV40 genome that surround the origin of DNA replication support efficient DNA synthesis in vitro and in vivo. Deletion of DNA sequences adjacent to the binding sites for T antigen either reduce or prevent DNA synthesis. This analysis shows that sequences that had been previously defined by studies in vivo to constitute the minimal core origin sequences are also necessary for DNA synthesis in vitro. Five mutant T antigens containing amino acid substitutions that affect SV40 replication have been purified and their in vitro properties compared with the purified wild-type protein. One protein is completely defective in the ATPase activity of T antigen, but still binds to the origin sequences. Three altered proteins are defective in their ability to bind to origin DNA, but retain ATPase activity. Finally, one of the altered T antigens binds to origin sequences and contains ATPase activity and thus appears like wild-type for these functions. All five proteins fail to support SV40 DNA replication in vitro. Interestingly, in mixing experiments, all five proteins efficiently compete with the wild-type protein and reduce the amount of DNA replication. These data suggest that an additional function of T antigen other than origin binding or ATPase activity, is required for initiation of DNA replication.

T-antigen is the only detectable protein on the nucleosome-free origin region of isolated simian virus 40 minichromosomes

A nucleosome-free region or nucleosome gap, containing the origin of replication and the transcriptional promoter elements, is observed on 20%-25% of the SV40 minichromosomes isolated at physiological ionic strength at late time during the infectious cycle. We found that this subpopulation of gapped minichromosomes was more sensitive to digestion with a variety of single-cut restriction enzymes than the rest of the minichromosomes. This increased digestibility of gapped minichromosomes allowed us to excise the gap region by concomitant digestion with Bgl I and Msp I. T-antigen was the only detectable protein bound to this isolated chromatin fragment. In particular no histones could be detected. The presence of T-antigen on the gap region was confirmed by immunoelectron microscopy. Most of the T-antigen appeared to be located on the late side of the Bgl I restriction enzyme site.

Simian virus 40 early promoter mutations that affect promoter function and autoregulation by large T antigen

A set of nine mutants containing point mutations, and small deletions or insertions, were constructed in the early promoter region of simian virus 40 (SV40) to determine the role of the DNA sequences between the TATA box and the six upstream G + C-rich clusters in early transcription. The mutant templates were tested for transcription activity in vitro in HeLa cell extracts and in vivo in CV-1 and COS cells using the chloramphenicol acetyl transferase gene (CAT) assay. Both in vitro and in vivo results show that the narrow region from nucleotide positions 38 to 41 is an important domain of the early promoter. Deletion and insertion mutations most strongly affect the level of transcription. Specifically a four base-pair deletion in the promoter region enhances the level of transcription four- to sixfold in vitro, but causes a fourfold suppression of CAT gene expression in the in vivo assay. These opposite effects may result from changes in spacing under in vitro and in vivo conditions between the TATA box and the G + C-rich motifs where transcription factors may make simultaneous contact. Of the three T antigen binding sites (I, II and III), sites I and II have already been shown to be involved in the autoregulation of early transcription. Our mutational analyses demonstrate the role of site III, which partially overlaps with nucleotide positions 38 to 41, in the autoregulation of the SV40 early promoter.

Streptomyces contain Escherichia coli-type A + T-rich promoters having novel structural features

We describe here the isolation and characterization of a class of A + T-rich transcriptionally active sequences in the filamentous antibiotic-producing Gram-positive bacterial genus Streptomyces. These regions, which digress dramatically in base composition from the 73% G + C composition characteristic of the Streptomyces genome, promote gene expression in both Escherichia coli and Streptomyces lividans and contain the major elements that determine promoter strength in E. coli. The Streptomyces-E. coli-type promoters (SEP) also show novel structural features that include multiple direct repeats within the promoter region as well as a specific hexameric sequence in the vicinity of the mRNA start point.

Attenuation may regulate gene expression in animal viruses and cells

In eukaryotes, an abundant population of promoter-proximal RNA chains have been observed and studied, mainly in whole nuclear RNA, in denovirus type 2, and in SV40. On the basis of these results it has been suggested that a premature termination process resembling attenuation in prokaryotes occurs in eukaryotes. Moreover, these studies have shown that the adenosine analog 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) enhances premature termination, but its mode of action is not understood. The determination of the nucleotide sequences of SV40 and other viruses and cellular genes provide means for elucidating the nucleotide sequences involved in the attenuation mechanism. A model has recently been described in which attenuation and mRNA modulation in a feedback control system quantitatively regulate SV40 gene expression. The suggested mechanism described in this model opens up approaches to the investigation of attenuation and mRNA modulation as a possible mechanism whereby eukaryotes may regulate transcription in a variety of different circumstances.

Effect of the 21-bp repeat upstream element on in vitro transcription from the early and late SV40 promoters

The role of the 21-bp repeat region [simian virus 40 (SV40) coordinates 40-103] on early and late SV40 promoter functions has been investigated in vitro using a variety of mutated templates. Using either a HeLa whole cell extract or a S100 extract, we analyzed the transcripts by quantitative S1 nuclease mapping. GC-rich motifs contained in the 21-bp direct repeat constituted an essential element for efficient early transcription in vitro in agreement with previous in vivo results. These GC-rich motifs act in a non-polar fashion, since inversion of the 21-bp region did not reduce early transcription. Some point mutations in the 22-bp imperfectly repeated sequence, that drastically reduce initiations from the early promoter in vivo, had little effect in vitro, indicating that all the functions of these GC-rich motifs cannot be reproduced in vitro at present. The requirement for the 21-bp repeat region was less stringent when the concentration of the early promoter sequence was increased, which suggests that its function may be to facilitate the recognition of the 'weak' SV40 early TATA box. The multiple late start sites were accurately used in vitro and the GC-rich motifs contained in the 21-bp repeat region were an important element for efficient in vitro initiation of transcription from the late promoter, irrespective of their orientation. However, the effect of the 21-bp repeat region on late initiations decreased strikingly with increasing distance to the start sites, although it was still detectable over a distance of 220 bp. Under the present in vitro conditions, the 72-bp repeat region stimulates weakly both early and late transcription.

Induction of altered chromatin structures by simian virus 40 enhancer and promoter elements

Two simian virus 40 transcriptional promoter elements, the 72-base pair (bp) repeat and the 21-bp repeat region, induce chromatin structures of increased DNase I sensitivity when transposed elsewhere in the viral genome. The induction of a sufficiently long stretch of DNase I-sensitive chromatin leads to the appearance of a visible nucleosome-free region.