Sequences locating the 5' ends of the major simian virus 40 late mRNA forms

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.

Experimentally determined weight matrix definitions of the initiator and TBP binding site elements of promoters

The basal elements of class II promoters are: (i) a-30 region, recognized by TATA binding protein (TBP); (ii) an initiator (Inr) surrounding the start site for transcription; (iii) frequently a downstream (+10 to +35) element. To determine the sequences that specify an Inr, we performed a saturation mutagenesis of the Inr of the SV40 major late promoter (SV40-MLP). The transcriptional activity of each mutant was determined both in vivo and in vitro. An excellent correlation between transcriptional activity and closeness of fit to the optimal Inr sequence, 5'-CAG/TT-3', was found to exist both in vivo and in vitro. Employing a neural network technique we generated from these data a weight matrix definition of an Inr that can be used to predict the activity of a given sequence as an Inr. Using saturation mutagenesis data of TBP binding sites we likewise generated a weight matrix definition of the -30 region element. We conclude the following: (i) Inrs are defined by the nucleotides immediately surrounding the transcriptional start site; (ii) most, if not all, Inrs are recognized by the same general transcription factor(s). We propose that the mechanism of transcription initiation is fundamentally conserved, with the formation of pre-initiation complexes involving the concurrent binding of general transcription factors to the -30, Inr and, possibly, downstream elements of class II promoters.

A downstream-element-binding factor facilitates assembly of a functional preinitiation complex at the simian virus 40 major late promoter

Recent work has shown that many promoters recognized by eucaryotic RNA polymerase II contain essential sequences located downstream of the transcriptional initiation site. We show here that the activity of a promoter element centered 28 base pairs downstream of the simian virus 40 major late initiation site appears to be mediated by a DNA-binding protein, which was isolated by affinity chromatography from HeLa cell nuclear extracts. In the absence of the other components of the transcriptional machinery, the protein bound specifically but weakly to its recognition sequence, with a Kd of approximately 10(-8) M. Analysis of kinetic data showed that mutation of the downstream element decreased the number of functional preinitiation complexes assembled at the promoter without significantly altering the time required for half the complexes to assemble. This suggests that in the absence of the downstream activating protein, preinitiation complexes are at least partially assembled but are not transcriptionally competent.

A downstream-element-binding factor facilitates assembly of a functional preinitiation complex at the simian virus 40 major late promoter

Recent work has shown that many promoters recognized by eucaryotic RNA polymerase II contain essential sequences located downstream of the transcriptional initiation site. We show here that the activity of a promoter element centered 28 base pairs downstream of the simian virus 40 major late initiation site appears to be mediated by a DNA-binding protein, which was isolated by affinity chromatography from HeLa cell nuclear extracts. In the absence of the other components of the transcriptional machinery, the protein bound specifically but weakly to its recognition sequence, with a Kd of approximately 10(-8) M. Analysis of kinetic data showed that mutation of the downstream element decreased the number of functional preinitiation complexes assembled at the promoter without significantly altering the time required for half the complexes to assemble. This suggests that in the absence of the downstream activating protein, preinitiation complexes are at least partially assembled but are not transcriptionally competent.

Transcription factor LSF binds two variant bipartite sites within the SV40 late promoter

The HeLa transcription factor LSF has been purified by heparin-agarose and DNA affinity chromatography, and its DNA binding and transcription properties have been characterized. LSF is a 63-kD polypeptide that binds to two distinct bipartite sites within the SV40 promoter region. One binding site consists of GC motifs 2 and 3 within the 21-bp repeats (LSF-GC site), and the other consists of sequences centered 44 bp upstream of the major late initiation site, L325 (LSF-280 site). Four guanine residues within the LSF-GC site, when methylated, strongly interfere with LSF binding. Alteration of the spacing, but not the sequence, between the two directly repeated GC motifs dramatically reduces the binding affinity of LSF for the site. Thus, LSF appears to recognize directly repeated GC motifs, when their center-to-center distance is 10 bp. The LSF-GC and LSF-280 sites share limited sequence homology. Only half of the LSF-280 site contains a short GC-rich sequence homologous to the GC motif. However, the binding affinity of LSF to the two sites is similar. LSF activates transcription from the SV40 late promoter in vitro from initiation site L325, via its binding to the template DNA.

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.

Translational control of synthesis of simian virus 40 late proteins from polycistronic 19S late mRNA

The simian virus 40 (SV40) 19S late mRNA is polycistronic, encoding multiple late proteins: agnoprotein, VP2, and VP3. We constructed a chloramphenicol acetyltransferase (CAT) transient expression vector in which the SV40 sequences between nucleotides 5171 and 1046 (via the SV40 origin of replication and including the late promoter) were inserted 5' to the cat gene; therefore, the AUG for CAT expression occurs after the AUGs for agnoprotein, VP2, and VP3. CAT enzyme activity assayed after transfection of these constructions indicates the level of CAT AUG utilization and, therefore, can be used as a measure of the ability of prior AUGs to intercept scanning ribosomes. Specifically, deletions and point mutations of the viral AUGs resulted in increased CAT enzyme activity owing to increased utilization of the downstream CAT AUG. To compare a variety of mutants, we used the levels of increase to calculate the translational efficiency of the viral AUGs. Some of our data agree with predictions of the modified scanning model (MSM). Little variation in downstream CAT AUG utilization was noted regardless of whether the VP2 AUG (in a weak MSM sequence context) was intact or removed. Hence, a scanning ribosome may easily bypass it. Similar analysis of the VP3 AUG (in a favorable MSM sequence context) demonstrated that it could efficiently intercept ribosomes prior to the downstream AUG. Overall, these data indicate that the structure of the 19S late mRNA and the relative efficiency of translational start codon utilization can account for the VP3/VP2 ratio found in infected cells. The agnoprotein reading frame, depending on how the mRNA precursor is spliced, is either not contained in the mRNA or is terminated near the VP2 AUG. Under these conditions, the ability of the agnoprotein AUG to block downstream CAT AUG utilization was found to be minimal in our assay. However, we directly tested the blocking ability of the agnoprotein AUG under conditions in which the reading frame terminated well after the CAT AUG. Although the agnoprotein AUG lies in a very good sequence context, this direct analysis showed that it interfered minimally with utilization of the CAT AUG when under the control of the SV40 late promoter. However, expected high levels of interference were regained when the late promoter was replaced with the Rous sarcoma virus long terminal repeat.(ABSTRACT TRUNCATED AT 400 WORDS)

Binding of cellular proteins to the regulatory region of BK virus DNA

The human papovavirus BK has a noncoding regulatory region located between the divergently transcribed early and late coding regions. Many strains of BK virus (BKV) have direct DNA sequence repeats in the regulatory region, although the number and extent of these repeats varies widely between independent isolates. Until recently, little was known about the individual functional elements within the BKV regulatory region, and the biological significance of the variable repeat structure has been unclear. To characterize the interaction between sequences in the BKV regulatory region and host cell transcription factors, we have carried out DNase I footprinting and competitive binding experiments on three strains of BKV, including one strain that does not contain direct sequence repeats. We have used relatively crude fractions from HeLa cell nuclear extracts, as well as DNA affinity-purified preparations of proteins. Our results demonstrate that BK(Dunlop), BK(WW), and BK(MM) each contain multiple binding sites for a factor, NF-BK, that is a member of the nuclear factor 1 family of transcription factors. We predict the presence of three to eight binding sites for NF-BK in the other strains of BKV for which a DNA sequence is available. This suggests that the binding of this protein is likely to be required for biological activity of the virus. In addition to NF-BK sites, BK(WW) and BK(MM) each contain a single binding site for transcription factor Sp1, and BK(Dunlop) contains two binding sites for transcription factor AP-1. The AP-1 sites in BK(Dunlop) span the junction of adjacent direct repeats, suggesting that repeat formation may be an important mechanism for de novo formation of binding sites not present in a parental strain.

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

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

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

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

The late spliced 19S and 16S RNAs of simian virus 40 can be synthesized from a common pool of transcripts

The late transcripts from the simian virus 40 (SV40) are alternatively spliced into two classes of spliced RNAs, 19S and 16S in size. We are interested in understanding the precursor-product relationships that result in the excision of different intervening sequences (introns) from the late transcripts. SV40 mutants containing precise deletions of the introns for each of the spliced 19S and 16S RNA species, including a previously undetected doubly spliced 19S RNA species, were isolated. Analysis by S1 mapping and a modified primer extension technique of the viral RNAs made in monkey cells transfected with each of these mutants led to the following conclusions. (i) Spliced late 19S RNA is not an intermediate in the synthesis of the late 16S RNAs. (ii) The 3' splice site used in the synthesis of the late 16S RNAs can join, albeit inefficiently, with alternative 5' splice sites in the absence of the 5' splice site normally used to synthesize 16S RNA. (iii) There is no obligatory order of excision of introns in the formation of the doubly spliced SV40 late 19S and 16S RNA species. A mutant was constructed by site-directed mutagenesis in which the 5'-proximal 3' splice site used in the synthesis of the doubly spliced RNAs is inactive. Cells transfected with this mutant processed transcripts into 19S RNA which, in wild-type-transfected cells, would have become doubly spliced 16S RNA. Therefore, we conclude that some of the spliced late 19S and 16S RNA can be synthesized from a common pool of transcripts.

72-bp element contains a critical control region for SV40 late expression in Xenopus laevis oocytes

The SV40 late promoter is transcribed at least 10-fold more efficiently than the SV40 early promoter when SV40 DNA is injected into the germinal vesicle of Xenopus laevis oocytes. Late expression in the oocyte is independent of T antigen and does not require DNA replication. To identify DNA sequences required for SV40 late gene expression, 12 mutants spanning nucleotide position (np) 5187 to np 304 were injected into the germinal vesicles of X. laevis oocytes, and RNA was extracted 18 to 24 hr later. S1 nuclease analysis of the 5' ends of SV40 late mRNA revealed that mutations in the origin of replication had no quantitative or qualitative effect on the 5' late start sites. Mutants which deleted the 21-bp repeats did not reduce or alter use of the major RNA initiation site (np 295), but did reduce use of a minor initiation site within the 72-bp repeats. In contrast, deletion of or certain point mutations in the 72-bp repeat decreased initiation from the major late start site. An 85-bp insertion containing a complete set of the 21-bp repeats positioned to the late side of the enhancer elements also decreased initiation from the major late start site. Thus, an element in the 72-bp repeat appears to be the major promoter element for late SV40 transcription in the oocyte.

Simian virus 40 agnoprotein facilitates normal nuclear location of the major capsid polypeptide and cell-to-cell spread of virus

The simian virus 40 agnoprotein is a 61-amino-acid, highly basic polypeptide that is coded within the 5' leader of late 16S mRNAs. To better understand agnoprotein function and to more effectively differentiate cis-from trans-acting effects of an agnogene mutation, we constructed a mutant virus that carries a single-base-pair substitution and fails to produce agnoprotein. pm 1493 contains a T/A to A/T transversion at sequence position 335. This mutation converts the agnoprotein initiation codon from ATG to TTG, preventing synthesis of the protein. The mutant displays only a modest growth defect in CV-1P and AGMK cells and no defect in BSC-1 cells. Early-gene expression, DNA replication, synthesis of late viral products, and the kinetics of virion assembly all appear normal in pm 1493-infected CV-1P cells. Immunofluorescent studies, however, indicate that localization of the major capsid polypeptide VP1 is different in mutant- than wild-type virus-infected cells. Furthermore, the lack of agnoprotein led to inefficient release of mature virus from the infected cell. Agnogene mutants could be severely compromised in their ability to propagate in monkeys given their reduced capacity for cell-to-cell spread.

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.

Saccharomyces cerevisiae CYC1 mRNA 5'-end positioning: analysis by in vitro mutagenesis, using synthetic duplexes with random mismatch base pairs

Expression of the Saccharomyces cerevisiae CYC1 gene produces mRNA with more than 20 different 5' ends. A derivative of the CYC1 gene (CYC1-157) was constructed with a deletion of a portion of the CYC1 5'-noncoding region, which includes the sites at which many of the CYC1 mRNAs 5' ends map. A 54-mer double-stranded oligonucleotide homologous with the deleted sequence of CYC1-157 and which included a low level of random base pair mismatches (an average of two mismatches per duplex) was used to construct mutants of the CYC1 gene and examine the role of the DNA sequence at and immediately adjacent to the mRNA 5' ends in specifying their locations. The effect of these mutations on the site selection of mRNA 5' ends was examined by primer extension. Results indicate that there is a strong preference for 5' ends which align with an A residue (T in the template DNA strand) preceded by a short tract of pyrimidine residues.

Virus deletion mutants that affect a 3' splice site in the E3 transcription unit of adenovirus 2

Five viable virus mutants were constructed with deletions near a 3' splice site located at nucleotide 2157 in the E3 transcription unit of adenovirus 2. The mutants were examined for splicing activity at the 2157 3' splice site in vivo by nuclease-gel analysis of steady-state cytoplasmic mRNA. Splicing was not prevented by an exon deletion (dl719) that leaves 16 5'-proximal exon nucleotides intact or by intron deletions that leave 34 (dl717, dl712) or 18 (dl716) 3'-proximal intron nucleotides intact. The sequences deleted in one of these intron mutants (dl716) include the putative branchpoint site used in lariat formation during splicing. Thus, a surrogate branchpoint site apparently can be used for splicing. Another intron mutant (dl714) has a deletion that leaves 15 3'-proximal intron nucleotides intact; remarkably, this deletion virtually abolished splicing, even though the deletion is only 3 nucleotides closer to the splice site than is the deletion in dl716 which splices normally. The three nucleotides deleted in dl714 that are retained by dl716 are the sequence TGT. The TGT sequence is located on the 5' boundary of the pyrimidine-rich region upstream of the nucleotide 2157 3' splice site. Such pyrimidine-rich regions are ubiquitous at 3' splice sites. Most likely, the TGT is required for splicing at the nucleotide 2157 3' splice site. The TGT may be important because of its specific sequence or because it forms the 5' boundary of the pyrimidine-rich region.

Nucleotide sequences of mRNAs encoding Epstein-Barr virus nuclear proteins: a probable transcriptional initiation site

Three cDNA clones of the second Epstein-Barr virus nuclear antigen (EBNA2) mRNA and two of the EBNA1 mRNA were analyzed. Two EBNA2 clones begin 42 bases 3' to a promoter in the Epstein-Barr virus long internal repeat, which is likely to be the EBNA2 promoter. Surprisingly, the first splice creates an AUG at the beginning of the first of two nonoverlapping open reading frames. The second open reading frame encodes EBNA2. Two incomplete EBNA1 mRNA cDNA clones begin with parts of two of the EBNA2 exons and contain two other exons that map 19 and 59 kilobases 3' to the EBNA2 coding domain. The 3' exon of this mRNA encodes EBNA1. A model for regulation of transcription of these RNAs is presented.

Polyomavirus late leader region serves an essential spacer function necessary for viability and late gene expression

All three polyomavirus late mRNAs contain multiple tandem copies of the same nontranslated 57-nucleotide sequence, the late leader, at their 5' ends. We show here that a polyoma variant (ALM) lacking 48 central bases of the 57-base leader unit is nonviable by plaque assay and by a new method for testing virus viability, an immunofluorescence burst assay. ALM is, however, unaffected in early gene expression as measured both by indirect immunofluorescence of large T antigen and by transformation levels of rat F-111 cells. DNA replication in mouse cells is also as wild type, and the defect in ALM is complemented by an early-defective helper virus DNA. ALM does not make detectable levels of late viral proteins and is minimally 200-fold depressed in the accumulation of cytoplasmic polyadenylated late RNA. When the deleted leader sequence of ALM is replaced by a variety of procaryotic sequences, viability almost always returns. Some of the substituted leader variants produce plaques with the same apparent kinetics as wild-type viral DNA. The indication is that the sequence of the polyoma late leader is not important for late gene expression but that it has an essential spacer function on the RNA or DNA level. This spacer function is apparently necessary for late viral RNA transcription, processing, or stability.

Spontaneous deletion mutants resulting from a frameshift insertion in the simian virus 40 agnogene

The 61-amino-acid agnoprotein is a nonessential polypeptide encoded by the late leader region of simian virus 40 which appears to play a role in viral assembly. A 2-base-pair (bp) insertion mutant (in2379) was created by altering the coding region of this protein. This mutation prevents the synthesis of the agnoprotein and, in contrast to the more extensive deletion mutations previously described in this region, might be expected to have a lesser effect on the template for late viral transcription. In fact, the 2-bp insertion mutant grew significantly less well than most mutants containing larger deletions in the agnoprotein region and frequently gave rise to stock containing second-site alterations in the same region. These observations suggested that the defect in mutant in2379 extends beyond the loss of the agnoprotein. Characterization of a number of second-site mutants indicated that all of them grew more efficiently than the original 2-bp insertion mutant. Based on the nucleotide sequence of these mutants, we suggest possibilities for the deleterious effect induced by the insertion in mutant in2379.

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.

Effects of the adenovirus 2 late promoter on simian virus 40 transcription and replication

A 100-base-pair fragment of adenovirus 2 (Ad2) DNA encompassing the major late transcriptional promoter was inserted into the simian virus 40 (SV40) late promoter region at SV40 nucleotide 294 to study the effects of a strong TATA box-containing promoter on SV40 late transcription. pSVAdE contains the insert in an orientation such that it would promote transcription towards the origin and early region of SV40, while the insert is in the opposite orientation in pSVAdL. Nuclease S1 analysis with 5'-end-labeled probes showed that in cells transfected with pSVAdE, the late mRNA initiation sites are essentially the same as in wild type, demonstrating that an insert of 100 base pairs can have no effect on utilization of the SV40 late start sites. In pSVAdL-transfected cells, however, the major late viral initiation site is now in the insert at +1 with respect to the Ad2 major late cap site. However, all of the SV40 initiation sites are still utilized and with the same efficiency relative to each other as in wild type. Thus, it appears that the Ad2 late promoter and the SV40 late promoter can function independently on the same DNA molecule, even when one promoter is embedded within the other. By using cytosine arabinoside to block DNA replication and thereby inhibit the onset of late expression, it has been shown that both the Ad2 late promoter and the SV40 late promoter have similar requirement for DNA replication in this context. In addition, pSVAdL showed dramatically diminished virus viability and VPI expression compared with both wildtype and pSVAdE. Possible explanations for this unexpected finding are discussed.

Saccharomyces cerevisiae CYC1 mRNA 5'-end positioning: analysis by in vitro mutagenesis, using synthetic duplexes with random mismatch base pairs

Expression of the Saccharomyces cerevisiae CYC1 gene produces mRNA with more than 20 different 5' ends. A derivative of the CYC1 gene (CYC1-157) was constructed with a deletion of a portion of the CYC1 5'-noncoding region, which includes the sites at which many of the CYC1 mRNAs 5' ends map. A 54-mer double-stranded oligonucleotide homologous with the deleted sequence of CYC1-157 and which included a low level of random base pair mismatches (an average of two mismatches per duplex) was used to construct mutants of the CYC1 gene and examine the role of the DNA sequence at and immediately adjacent to the mRNA 5' ends in specifying their locations. The effect of these mutations on the site selection of mRNA 5' ends was examined by primer extension. Results indicate that there is a strong preference for 5' ends which align with an A residue (T in the template DNA strand) preceded by a short tract of pyrimidine residues.

Sequences involved in determining the locations of the 5' ends of the late RNAs of simian virus 40

The 5' ends of the simian virus 40 (SV40) late RNAs are heterogeneous in location, spanning a 300-nucleotide region from residues 28 to 325. To examine whether upstream or downstream measuring functions analogous to the TATA box play roles in positioning the 5' ends of these RNAs, we determined by S1 and primer extension mapping the locations of the 5' ends of the late viral RNAs made in monkey cells infected with: (i) three wild-type strains of SV40 that contain tandem duplications of the enhancer region that are 64, 85, and 91, rather than 72, base pairs in length; (ii) four viable mutants that contain alterations in the 21-base-pair tandem repeats; and (iii) four viable mutants that possess small deletions or insertions at or near the major cap site at residue 325. Most of the 5' ends of the RNAs were identical in location to those seen with wild-type strain 776. The only exceptions were the absence of RNAs whose 5' ends mapped to within three bases upstream or downstream of a sequence alteration. In addition, the sequences within residues 251 to 277 that function as transcriptional initiation sites in wild-type strain 776 also did so in their second locations in the wild-type strains in which these sequences are duplicated. Differences were noted in the relative abundances of the numerous 5' ends of the late RNAs, even among the wild-type strains. These findings indicate that many (and likely all) of the approximately two dozen locations of 5' ends of SV40 late RNAs are each determined largely by sequences within their immediate vicinity. However, sequences somewhat removed from these transcriptional initiation sites may modulate the efficiencies with which they are utilized.

Virus deletion mutants that affect a 3' splice site in the E3 transcription unit of adenovirus 2

Five viable virus mutants were constructed with deletions near a 3' splice site located at nucleotide 2157 in the E3 transcription unit of adenovirus 2. The mutants were examined for splicing activity at the 2157 3' splice site in vivo by nuclease-gel analysis of steady-state cytoplasmic mRNA. Splicing was not prevented by an exon deletion (dl719) that leaves 16 5'-proximal exon nucleotides intact or by intron deletions that leave 34 (dl717, dl712) or 18 (dl716) 3'-proximal intron nucleotides intact. The sequences deleted in one of these intron mutants (dl716) include the putative branchpoint site used in lariat formation during splicing. Thus, a surrogate branchpoint site apparently can be used for splicing. Another intron mutant (dl714) has a deletion that leaves 15 3'-proximal intron nucleotides intact; remarkably, this deletion virtually abolished splicing, even though the deletion is only 3 nucleotides closer to the splice site than is the deletion in dl716 which splices normally. The three nucleotides deleted in dl714 that are retained by dl716 are the sequence TGT. The TGT sequence is located on the 5' boundary of the pyrimidine-rich region upstream of the nucleotide 2157 3' splice site. Such pyrimidine-rich regions are ubiquitous at 3' splice sites. Most likely, the TGT is required for splicing at the nucleotide 2157 3' splice site. The TGT may be important because of its specific sequence or because it forms the 5' boundary of the pyrimidine-rich region.

Exon mutations that affect the choice of splice sites used in processing the SV40 late transcripts

The spliced species of late SV40 RNAs present in the cytoplasm of cells infected with various wild-type and mutant strains of SV40 that differ in their leader regions were determined using a novel modification of the primer extension method and the S1 nuclease mapping technique. These data indicated that mutations within the first exon of the late RNAs can affect dramatically the utilization of downstream donor and acceptor splice sites. In one instance, a ten base pair insertion within the predominant first exon increased utilization of an infrequently utilized donor splice site such that the small alteration became part of an intervening sequence, thereby suggesting a novel mechanism for regulation of gene expression. In addition, our method enabled detection of a previously unidentified spliced species, representing less than one percent of the SV40 late 19S RNA present in cells infected with wild-type virus, that may be an intermediate in the synthesis of a known doubly spliced 16S RNA species of SV40.

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.

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.

Mapping in vivo initiation sites of RNA transcription and determining their relative use

Runoff transcripts were generated on viral transcriptional complexes cleaved with restriction enzymes and incubated in vitro with [alpha-32P]UTP under pulse-chase conditions. As viral transcriptional complexes in vitro elongated the nascent RNA preinitiated in vivo, size analysis by gel electrophoresis of the runoff transcripts allowed identification of the in vivo initiation sites. Moreover, scanning the intensities of the runoff bands as they appeared in the autoradiogram of the gel allowed determination of the relative use of these sites. A model system in which the initiation sites of simian virus 40 late RNA were identified and their relative use determined is presented.

SV40 deletion mutant (d1861) with agnoprotein shortened by four amino acids

d1861 is an SV40 deletion mutant which was thought to lack the agnoprotein coding region and was used to verify the role of agnoprotein in the life cycle of SV40. In the present study the region flanking the deletion was sequenced and, in contrast to the available information, it was found that d1861 lacks 12 nt in phase, downstream from the AUG start codon of agnoprotein (residues 347-358). Using the runoff protocol with viral transcriptional complexes (VTC), that in vitro elongate the in vivo preinitiated nascent RNA, it was found that in vivo the major initiation site for late transcription is at residue 325, the same as in wild type (WT). In comparison with WT, d1861 encodes information for agnoprotein shortened by four amino acids and it has been identified in d1861 infected cells. However, pulse-chase experiments indicated that the rate of synthesis of d1861 agnoprotein is slower than that of WT agnoprotein and that it has a turnover rate of 1 hr as compared to 3 hr of WT agnoprotein. The reduced rate of synthesis of d1861 agnoprotein can be explained by nuclease S1 analyses in which the major leader of d1861 16 S RNA, that encodes the agnoprotein, appeared in significantly lower amounts as compared to the major leader of WT 16 S RNA. Furthermore, analysis of the potential secondary structures at the 5' end of the leader of d1861 16 S RNA has revealed stable structures in which the start codon of agnoprotein is sequestered in a stem. The involvement of RNA secondary structures in regulating the synthesis of agnoprotein is discussed.