Quantitation of transcribing native simian virus 40 minichromosomes extracted from CV1 cells late in infection

Purification and Characterization of the Simian Virus 40 Transcription Elongation Complex

The transcriptional regulatory region of the simian virus 40 minichromosome that is being transcribed in the cell is nucleosome-free, while that of the non-transcribed minichromosome is nucleosome covered. Although additional studies have shown that the two structures are otherwise similar, the precision of these indirect studies has not been sufficient to determine if the transition between the two involves nucleosome displacement or nucleosome sliding. In order to address this question directly, we have developed a new function-based affinity isolation method that is capable of purifying the native transcription elongation complex of a single gene from mammalian cells. The simian virus 40 transcription elongation complex was purified by this method and the topological linking number of its DNA was compared directly to that of the bulk, non-transcribed minichromosome. The results show that the two types of minichromosome contain the same number of nucleosomes as well as nucleosomal structure. These findings indicate that interconversion between the non-transcribing and transcribing states is accomplished by a remodeling event involving nucleosome sliding rather than nucleosome displacement.

TATA box occupancy in the SV40 transcription elongation complex

In order to gain insight into requirements for template activation and commitment in mammalian transcription, TATA site occupancy was measured in native SV40 viral transcription complexes that were in the process of transcription elongation at the time of cell lysis. This was accomplished by quantifying resistance to restriction enzyme digestion of transcription complexes in nuclear lysate. The rate of cleavage at the TATA site of the late gene in the native complex was slower than that of a bare DNA control, both for wild-type virus and for a virus containing a TATA consensus sequence. These results suggest that the TATA site in the transcription elongation complex in vivo is occupied with transcription factor TBP/TFIID. When considered in light of previous work, these findings support a model in which transcription activation involves reinitiation from a promoter that contains both activator and TFIID bound in a stable complex.

Chromatin structure and factor site occupancies in an in vivo-assembled transcription elongation complex

The chromatin structure specific to the SV40 late transcription elongation complex as well as the occupancy of several sites that bind transcription factors have been examined. These features have been determined by assessing blockage to restriction enzyme digestion. Cleavage specific to the elongation complex has been quantified using ternary complex analysis. This method involves radioactively labeling the complex by in vitro transcription followed by determining the extent of linearization by electrophoresis in an agarose gel. It was found that not only is the origin region devoid of nucleosomes, but there is also no stable factor occupancy at the BglI, SphI, KpnI and MspI restriction enzyme sites within this region. Thus these sites were cleaved to a high degree, meaning that the binding sites for a number of transcription factors, including OBP/TEF-1, TBP, DAP, as well as a proposed positioned nucleosome, are unoccupied in the native viral transcription elongation complex. The absence of these trans-acting factors from their respective binding sites in the elongation complex indicates that they bind only transiently, possibly cycling on and off during the transcription cycle. This finding implies that various forms of transcription complex are assembled and disassembled during transcription and thus supports a 'hit-and-run' model of factor function.

RNA footprint mapping of RNA polymerase II molecules stalled in the intergenic region of polyomavirus DNA

RNA polymerase II molecules that transcribe the late strand of the 5.3-kb circular polyomavirus genome stall just upstream of the DNA replication origin, in a region containing multiple binding sites for polyomavirus large T antigen. Stalling of RNA polymerases depends on the presence of functional large T antigen and on the integrity of large T antigen binding site A. To gain insight into the interaction between DNA-bound large T antigen and RNA polymerase II, we mapped the position of stalled RNA polymerases by analyzing nascent RNA chains associated with these polymerases. Elongation of RNA in vitro, followed by hybridization with a nested set of DNA fragments extending progressively farther into the stalling region, allowed localization of the 3' end of the nascent RNA to a position 5 to 10 nucleotides upstream of binding site A. Ribonuclease treatment of nascent RNAs on viral transcription complexes, followed by in vitro elongation and hybridization, allowed localization of the distal end of stalled RNA polymerases to a position 40 nucleotides upstream of binding site A. This RNA footprint shows that elongating RNA polymerases stall at a site very close to the position of DNA-bound large T antigen and that they protect approximately 30 nucleotides of nascent RNA against ribonuclease digestion.

Association of nucleosome-free regions and basal transcription factors with in vivo-assembled chromatin templates active in vitro

Using SV40 minichromosomes assembled in vivo, we have studied the relationship between a nucleosome-free promoter-region and initiation of transcription by RNA polymerase II on chromatin templates in vitro. Our data suggest that accessibility of DNA to transcription factors, programmed into the structure of the chromatin, is crucial for initiation of transcription. First, minichromosomes competent to be transcribed in vitro contained nucleosome-free promoter regions. Second, tsC219 minichromosomes, most of which contain the nucleosome-free promoter region, supported transcription more efficiently both in vivo and in vitro than wild-type minichromosomes, in which only a subset contain the nucleosome-free region. We have also identified basal transcription factors associated with the in vivo-assembled chromatin templates. A striking correlation was observed between minichromosomes associated with in vivo initiated RNA polymerases and those associated with the basal transcription factors TFIID and TFIIE/F, and to a lesser extent, TFIIB. Of these associated factors, only TFIID was poised for ready assembly into preinitiation complexes and therefore for subsequent initiation of transcription. However, an active chromatin template could also be maintained in the absence of the binding of TFIID. Finally, our data are consistent with the presence of TFIIF in elongating ternary complexes on the chromatin templates.

Topoisomerase I is preferentially associated with normal SV40 replicative intermediates, but is associated with both replicating and nonreplicating SV40 DNAs which are deficient in histones

Based on the use of equilibrium centrifugation in CsCl to separate covalent complexes between topoisomerase I and DNA from protein-free DNA, it was concluded previously that the topoisomerase is preferentially associated with replicating SV40 DNA (Champoux, J. J. 1988. J. Virol. 62:3675-3683). One explanation for the failure to find the enzyme associated with nonreplicating viral DNA is that most of the completed DNA is rapidly sequestered for encapsidation and inaccessible to topoisomerase I. This explanation has been ruled out in the present work by the finding that topoisomerase I in COS-1 cells is also preferentially associated with the replicative form of an SV40 origin-containing plasmid that lacks the genes coding for the virion structural proteins and therefore cannot be encapsidated. Thus it appears that some structural feature of the replicating DNA or the replication complex specifically recruits the topoisomerase to the DNA. SV40 DNA which is produced in the presence of the protein synthesis inhibitor, puromycin, is deficient in histones and as a result lacks normal chromatin structure. Topoisomerase I was found to be associated with SV40 DNA under these conditions whether or not it was replicating. This observation is interpreted as an indication that under normal conditions, chromatin structure limits access of topoisomerase I to the nonreplicating viral 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.

Immunoprecipitation of SV40 replicating minichromosomes complexed with bacteriophage T4 gene 32 protein

Simian Virus 40 (SV40) DNA replication is a useful model to study eukaryotic cell DNA replication because it encodes only one replication protein and its genome has a nucleoprotein structure ('minichromosome') indistinguishable from cellular chromatin. Late after infection SV40 replicating DNA molecules represent about 5% of total viral minichromosomes. Since gene 32 protein (P32) from bacteriophage T4 interacts with single-stranded DNA and SV40 replication complexes are expected to contain single-stranded regions at the replication forks, we asked whether P32 might be used to isolate replicating SV40 minichromosomes. When nuclear extracts from SV40 infected cells were treated sequentially with P32 and anti-P32 antibodies, pulse-labeled minichromosomes were selectively immunoprecipitated. Agarose gel electrophoresis analysis confirmed that immunoprecipitated material corresponded to SV40 replicative intermediates. Protein analysis of the pelleted material revealed several proteins of viral and cellular origin. Among them, T antigen and histones were found to be complexed with at least other three proteins from cellular origin, to the replicative complexes. Additionally, anti-P32 antibodies were able to detect three cellular proteins of approximately 70, 32 and 13 kDa in western blots. These proteins could correspond to those found as part of an eukaryotic multisubunit single-stranded DNA binding protein. The use of P32 and anti-P32 antibodies thus allows the separation of replicating from mature SV40 minichromosomes and can constitute a novel method to enrich and to study replicative active chromatin.

Enhancer-activated plasmid transcription complexes contain constrained supercoiling

It has been proposed that transcriptionally active chromatin contains totally unconstrained supercoiling. The results of recent studies have raised the possibility that this topological state is the property of highly transcribed genes. Since the transcription rate of RNA polymerase II genes can be dramatically increased by the presence of an enhancer, we have determined if the transcription complex of an enhancer-activated plasmid contains totally unconstrained supercoils. Following transfection into COS7 cells, the topology of the transcription complex DNA was determined directly by agarose gel electrophoresis. We find that an enhancer-activated plasmid transcription complex is supercoiled, and these supercoils remain following topoisomerase I treatment. Thus the transcribing complexes contain constrained supercoils, and the level of supercoiling suggests a nucleosome-like organization. However, we cannot rule out the possibility that unconstrained supercoils exist in addition to these constrained supercoils in the transcription complex in the cell.

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.

The SV40 nucleosome-free region is detected throughout the virus life cycle

The structures of SV40 intracellular chromatin complexes and of extracellular virus particles were examined by photolabeling with a radioactive psoralen derivative in order to determine the fate of the exposed origin region during the virus life cycle. We have previously shown that the origin region of intracellular SV40 chromatin is preferentially accessible to psoralen derivatives in vivo, whereas psoralen adducts are uniformly distributed when purified virus particles are photoreacted. We demonstrate here that when virion is photoreacted prior to a freeze-thaw cycle, the exposed regulatory region detected in intracellular nucleoprotein complexes is also found in mature virus particles. In contrast, if the virion is frozen and thawed prior to the photoreaction, the origin is not preferentially exposed to photoaddition. Virus particles that have not been subjected to a freeze-thaw cycle were found to exhibit preferential labeling in the origin region whether they were irradiated intracellularly, in culture medium, or following purification. Banding the virus in CsCl had no significant effect on the relative accessibility of the origin region to psorealen. Our findings indicate that the open regulatory region found on intracellular SV40 chromatin persists throughout the virus life cycle.

Thermal unwinding of simian virus 40 transcription complex DNA

Two long-standing questions in the control of eukaryotic gene expression have been how the structure of transcribing chromatin compares with that of nontranscribing chromatin and how chromatin structure differs among various eukaryotic organisms. We have addressed aspects of these two questions by characterizing the rotational flexibility of the DNA of the simian virus 40 (SV40) transcription complex. When transcription complex samples are incubated with topoisomerase at 0 degrees C or 37 degrees C, the DNA of the 37 degrees C sample is unwound by 1.8 turns relative to that of the 0 degrees C sample. This amount of unwinding is similar to that observed for bulk, untranscribed SV40 minichromosome DNA, indicating that the chromatin structure of a transcribed gene resembles that of a nontranscribed gene in the degree of constraint that it imposes on its DNA. However, this amount of unwinding differs substantially from the value observed for yeast plasmid chromatin DNA, suggesting that yeast chromatin differs significantly from mammalian chromatin in this fundamental property.

Mapping in vivo topoisomerase I sites on simian virus 40 DNA: asymmetric distribution of sites on replicating molecules

Complexes between simian virus 40 DNA and topoisomerase I (topo I) were isolated from infected cells treated with camptothecin. The topo I break sites were precisely mapped by primer extension from defined oligonucleotides. Of the 56 sites, 40 conform to the in vitro consensus sequence previously determined for topo I. The remaining 16 sites have an unknown origin and were detectable even in the absence of camptothecin. Only 11% of the potential break sites were actually broken in vivo. In the regions mapped, the pattern of break sites was asymmetric. Most notable are the clustering of sites near the terminus for DNA replication and the confinement of sites to the strand that is the template for discontinuous DNA synthesis. These asymmetries could reflect the role of topo I in simian virus 40 DNA replication and suggest that topo I action is coordinated spatially with that of the replication complex.

Mapping in vivo topoisomerase I sites on simian virus 40 DNA: asymmetric distribution of sites on replicating molecules

Complexes between simian virus 40 DNA and topoisomerase I (topo I) were isolated from infected cells treated with camptothecin. The topo I break sites were precisely mapped by primer extension from defined oligonucleotides. Of the 56 sites, 40 conform to the in vitro consensus sequence previously determined for topo I. The remaining 16 sites have an unknown origin and were detectable even in the absence of camptothecin. Only 11% of the potential break sites were actually broken in vivo. In the regions mapped, the pattern of break sites was asymmetric. Most notable are the clustering of sites near the terminus for DNA replication and the confinement of sites to the strand that is the template for discontinuous DNA synthesis. These asymmetries could reflect the role of topo I in simian virus 40 DNA replication and suggest that topo I action is coordinated spatially with that of the replication complex.

RNA polymerases stall and/or prematurely terminate nearby both early and late promoters on polyomavirus DNA

Levels of transcription within the E and L strands of the five major PstI fragments of polyomavirus (strain AT3) were measured by pulse-labeling RNA both in infected cells and in isolated nuclei or viral transcription complexes during the late phase of infection. Quantification was assured by hybridization to single-stranded DNAs in solution followed by collection of hybrids on nitrocellulose filters and ribonuclease treatment. The level of in vivo transcription in the region of the early (E strand) promoter was two- to threefold higher than that in all other E-strand regions, suggesting that most RNA polymerases prematurely terminate transcription shortly downstream from this promoter during the late phase. In vitro transcription levels in this region were five- to tenfold higher than in the remainder of the E strand, suggesting that many RNA polymerases 'stall' shortly after initiation in vivo but can be reactivated and continue transcription in vitro upon exposure to detergents and high salt solution. Some premature termination nearby the late (L strand) promoter was also detected by the same method. Strikingly, many RNA polymerases also stalled on the L strand in the region of the early promoter, some 5 x 10(3) bases downstream from the late promoter. Treatment of cells with dichlororibofuranosylbenzimidazole did not affect polymerases that stalled or terminated prematurely, but strongly reduced the presence of polymerases that normally transcribed throughout the entire E or L strand. Examination of the size of RNA chains produced during in vitro incubations showed that many polymerases stalled in vivo within 50 to 100 nucleotides downstream from the initiation sites on both DNA strands. The number of polymerases active in vitro at the E strand promoter was similar to the number of polymerases at the L strand promoter. However, in contrast to L-strand transcription, most of the polymerases that initiated at the E-strand promoter were incapable of extended transcription in vivo. These results suggest that large T antigen-mediated repression of E-strand transcription is not simply due to the exclusion of RNA polymerases from the early promoter. Stalling and/or premature termination by RNA polymerases shortly downstream from the early promoter appears to be a mechanism by which temporal regulation of polyomavirus gene expression can be effected.

Capturing nuclear sequence-specific DNA-binding proteins by using simian virus 40-derived minichromosomes

We have used recombinant simian virus 40 (SV40) minichromosomes to retrieve sequence-specific DNA-binding proteins derived from the cell nucleus of COS-7 cells. We showed that the transcription factors AP-1 and Sp1 are stably bound to the SV40 DNA late in viral infection. Under similar conditions, minichromosomes carrying the rat insulin (rINS1) enhancer, which is under negative regulation in COS-7 cells, bound two proteins which mapped to distinct regions of the rINS1 enhancer. The SV40 P element competed for one of these proteins which bound to the region from -198 to -230. This factor may be related to AP-1. The other factor selectively bound a regulatory element in the region from -92 to -124 of the insulin enhancer. These proteins may play a role in regulating the rINS1 enhancer function.

Capturing nuclear sequence-specific DNA-binding proteins by using simian virus 40-derived minichromosomes

We have used recombinant simian virus 40 (SV40) minichromosomes to retrieve sequence-specific DNA-binding proteins derived from the cell nucleus of COS-7 cells. We showed that the transcription factors AP-1 and Sp1 are stably bound to the SV40 DNA late in viral infection. Under similar conditions, minichromosomes carrying the rat insulin (rINS1) enhancer, which is under negative regulation in COS-7 cells, bound two proteins which mapped to distinct regions of the rINS1 enhancer. The SV40 P element competed for one of these proteins which bound to the region from -198 to -230. This factor may be related to AP-1. The other factor selectively bound a regulatory element in the region from -92 to -124 of the insulin enhancer. These proteins may play a role in regulating the rINS1 enhancer function.

Factor interactions at simian virus 40 GC-box promoter elements in intact nuclei

Primer extension footprinting was used to probe late simian virus 40 regulatory elements in intact infected cell nuclei. Specific protection was observed over the viral "GC-box" transcription elements. The participation of the bound templates in gene activation is addressed by quantitation that shows that their abundance greatly exceeds that of transcription complexes but is comparable to that of open chromatin.

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.

Isolation and partial characterization of 2-microns yeast plasmid as a transcriptionally active minichromosome

Yeast cell extracts from 2-microns-containing strains (cir+) showed higher transcriptional activity than their corresponding isogenic sets (cir0). These extracts were used to purify transcriptionally active 2-microns minichromosomes in a sucrose gradient. Minichromosomes were transcribed in vitro and, employing hybridization techniques, the RNA synthesized was shown to present 2-microns-specific sequences. This model system should permit the direct study of transcriptionally active eucaryotic chromatin.

Factor interactions at simian virus 40 GC-box promoter elements in intact nuclei

Primer extension footprinting was used to probe late simian virus 40 regulatory elements in intact infected cell nuclei. Specific protection was observed over the viral "GC-box" transcription elements. The participation of the bound templates in gene activation is addressed by quantitation that shows that their abundance greatly exceeds that of transcription complexes but is comparable to that of open chromatin.

Structure of monkey kidney cell RNA polymerase II: characterization of RNA polymerase associated with SV40 late transcriptional complexes

Three subspecies of RNA polymerase II have been described in eucaryotic cells and designated IIO, IIA, and IIB. Although their relative proportions vary among different sources, RNA polymerases IIA and IIB constitute the bulk of most purified RNA polymerase II preparations. Antibodies against calf thymus RNA polymerase II were used to estimate the amount of polymerase II subspecies in monkey kidney cells, isolated nuclei, and SV40 late transcriptional complexes. We have found that RNA polymerase IIO is present in whole cells and isolated nuclei in higher proportions than previously reported. Subspecies IIO was found associated with SV40 minichromosomes engaged in transcription during late lytic infection. The observation that RNA polymerase IIO is associated with the cellular chromatin and SV40 minichromosomes suggest that this form of the enzyme is the subspecies active in in vivo transcription.

Structure of in-vivo transcribing chromatin as studied in simian virus 40 minichromosomes

In order to study the structure of chromatin during transcription, individual in-vivo transcribing simian virus 40 (SV40) minichromosomes were analyzed in the electron microscope after crosslinking the nascent RNA strands with different psoralen derivatives to the template DNA. Since psoralen crosslinks the DNA between nucleosomes, spreading of the crosslinked DNA and DNA-RNA complexes reveals single-stranded bubbles at positions where nucleosomes were located. We found that the transcribing SV40 minichromosomes contained a similar number of nucleosomes as did the minichromosomes without crosslinked nascent RNA. The nascent RNA was crosslinked in about equal proportions either in single-stranded bubbles of nucleosomal length or in continuously crosslinked regions between bubbles, in contrast with control experiments with ribosomal chromatin of Dictyostelium. Treatment of SV40 minichromosomes with 1.2 M-NaCl before and during photocrosslinking with psoralen led to the disappearance of the single-stranded bubbles. Since no bubbles could be detected at the attachment sites of the RNA molecules when the nucleosomes were disrupted in high salt, and since in about half of the molecules the RNA was attached to fully crosslinked linker DNA, we assume that the single-stranded bubbles with crosslinked RNA are not due to protection by the elongating RNA polymerase II complex, but are rather due to nucleosome-like structures. At the resolution level of single nucleosomes, these results imply for the first time that nucleosome-like structures (perhaps modified compared with "normal" nucleosomes) on SV40 minichromosomes do not prevent transcription elongation by RNA polymerase II.

Simian virus 40 minichromosomes contain torsionally strained DNA molecules

Sundin and Varshavsky (J. Mol. Biol. 132:535-546, 1979) found that nearly two-thirds of simian virus 40 (SV40) minichromosomes obtained from nuclei of SV40-infected cells become singly nicked or cleaved across both strands after digestion with staphylococcal nuclease at 0 degrees C. The same treatment of SV40 DNA causes complete digestion rather than the limited cleavages produced in minichromosomal DNA. We have explored this novel behavior of the minichromosome and found that the nuclease sensitivity is dependent upon the topology of the DNA. Thus, if minichromosomes are pretreated with wheat germ DNA topoisomerase I, the minichromosomal DNA is completely resistant to subsequent digestion with staphylococcal nuclease at 0 degrees C. If the minichromosome-associated topoisomerase is removed, virtually all of the minichromosomes are cleaved to nicked or linear structures by the nuclease treatment. The cleavage sites are nonrandomly located; instead they occur at discrete loci throughout the SV40 genome. SV40 minichromosomal DNA is also cleaved to nicked circles and full-length linear fragments after treatment with the single strand-specific endonuclease S1; this cleavage is also inhibited by pretreatment with topoisomerase I. Thus, it may be that the nuclease sensitivity of minichromosomes is due to the transient or permanent unwinding of discrete regions of their DNA. Direct comparisons of the extent of negative supercoiling of native and topoisomerase-treated SV40 minichromosomes revealed that approximately two superhelical turns were removed by the topoisomerase treatment. The loss of these extra negative supercoils from the DNA probably accounts for the resistance of the topoisomerase-treated minichromosomes to the staphylococcal and S1 nucleases. These findings suggest that the DNA in SV40 intranuclear minichromosomes is torsionally strained. The functional significance of this finding is discussed.

Transcriptionally active SV40 minichromosomes are restriction enzyme sensitive and contain a nucleosome-free origin region

A nucleosome-free region or gap containing the origin of replication and the transcriptional promoter elements is observed on 20 to 25% of the SV40 minichromosomes isolated at physiological ionic strength late in infection. We used the preferential sensitivity of the gapped minichromosomes to restriction enzymes to obtain sucrose gradient fractions containing 50 to 80% of gapped molecules. The same fractions are also enriched in RNA polymerase B (II) molecules engaged in transcription. Using electron microscopy, we demonstrate here that the transcriptional complexes are preferentially sensitive to restriction enzyme digestion, which indicate that they represent a subpopulation of the gapped minichromosomes.

Simian virus 40 minichromosomes contain torsionally strained DNA molecules

Sundin and Varshavsky (J. Mol. Biol. 132:535-546, 1979) found that nearly two-thirds of simian virus 40 (SV40) minichromosomes obtained from nuclei of SV40-infected cells become singly nicked or cleaved across both strands after digestion with staphylococcal nuclease at 0 degrees C. The same treatment of SV40 DNA causes complete digestion rather than the limited cleavages produced in minichromosomal DNA. We have explored this novel behavior of the minichromosome and found that the nuclease sensitivity is dependent upon the topology of the DNA. Thus, if minichromosomes are pretreated with wheat germ DNA topoisomerase I, the minichromosomal DNA is completely resistant to subsequent digestion with staphylococcal nuclease at 0 degrees C. If the minichromosome-associated topoisomerase is removed, virtually all of the minichromosomes are cleaved to nicked or linear structures by the nuclease treatment. The cleavage sites are nonrandomly located; instead they occur at discrete loci throughout the SV40 genome. SV40 minichromosomal DNA is also cleaved to nicked circles and full-length linear fragments after treatment with the single strand-specific endonuclease S1; this cleavage is also inhibited by pretreatment with topoisomerase I. Thus, it may be that the nuclease sensitivity of minichromosomes is due to the transient or permanent unwinding of discrete regions of their DNA. Direct comparisons of the extent of negative supercoiling of native and topoisomerase-treated SV40 minichromosomes revealed that approximately two superhelical turns were removed by the topoisomerase treatment. The loss of these extra negative supercoils from the DNA probably accounts for the resistance of the topoisomerase-treated minichromosomes to the staphylococcal and S1 nucleases. These findings suggest that the DNA in SV40 intranuclear minichromosomes is torsionally strained. The functional significance of this finding is discussed.

Stable transcription complex on a class III gene in a minichromosome

We have constructed recombinant simian virus 40 molecules containing Xenopus 5S RNA and tRNA genes. Recombinant minichromosomes containing these genes were isolated to study the interaction of RNA polymerase III transcription factors with these model chromatin templates. Minichromosomes containing a tRNAMet gene can be isolated in a stable complex with transcription factors (IIIB and IIIC) and are active in vitro templates for purified RNA polymerase III. In contrast, minichromosomes containing a 5S RNA gene are refractory to transcription by purified RNA polymerase III in either the absence or the presence of other factors.

Stable transcription complex on a class III gene in a minichromosome

We have constructed recombinant simian virus 40 molecules containing Xenopus 5S RNA and tRNA genes. Recombinant minichromosomes containing these genes were isolated to study the interaction of RNA polymerase III transcription factors with these model chromatin templates. Minichromosomes containing a tRNAMet gene can be isolated in a stable complex with transcription factors (IIIB and IIIC) and are active in vitro templates for purified RNA polymerase III. In contrast, minichromosomes containing a 5S RNA gene are refractory to transcription by purified RNA polymerase III in either the absence or the presence of other factors.

Unwinding of the DNA helix in simian virus 40 chromosome templates by RNA polymerase

We measured the distortion of the DNA helix by RNA polymerase transcribing simian virus 40 (SV40) chromosome templates and compared it with the distortion caused by the enzymes as it transcribes naked SV40 DNA, using RNA polymerase from Escherichia coli. Purified DNA topoisomerase I was added to the transcription reactions and the number of supercoil turns in DNA, after deproteinising and removal of RNA, was determined by gel electrophoresis and band-counting. The number of polymerase molecules bound per naked DNA molecule was determined by electron microscopy. Each bound RNA polymerase distorted the template in such a way as to lead to on apparent average of 0.6-0.7 negative superhelical turn in the extracted DNA. Thus only few base-pairs are melted per RNA polymerase molecule. When SV40 chromosomes were transcribed the extracted DNA had a higher number of supercoil turns than DNA extracted from the initial chromosomes. We conclude that the polymerase deforms the DNA in chromatin in the same way as it deforms pure DNA. From control experiments with inhibitors of initiation we estimated that on average 9-10 RNA polymerase molecules were bound per SV40 chromosome. This suggests that transcription can proceed while the majority or all the nucleosomal structures are intact on an SV40 DNA molecule. We discuss the implications of these findings for the mechanism of transcription of chromatin.

Barriers to nuclease Bal31 digestion across specific sites in simian virus 40 chromatin

A portion of the nucleoprotein containing viral DNA extracted from cells infected by simian virus (SV40) is preferentially cleaved by endonucleases in a region of the genome encompassing the origin of replication and early and late promoters. To explore this nuclease-sensitive structure, we cleaved SV40 chromatin molecules with restriction enzymes and digested the exposed termini with nuclease Bal31. Digestion proceeded only a short distance in the late direction from the MspI site, but some molecules were degraded 400 to 500 base pairs in the early direction. By comparison, BglI-cleaved chromatin was digested for only a short distance in the early direction, but some molecules were degraded 400 to 450 base pairs in the late direction. These barriers to Bal31 digestion (bracketing the BglI and the MspI sites) define the borders of the same open region in SV40 chromatin that is preferentially digested by DNase I and other endonucleases. In a portion of the SV40 chromatin, Bal31 could not digest through the nuclease-sensitive region and reached barriers after digesting only 50 to 100 base pairs from one end or the other. Chromatin molecules that contain barriers in the BglI to MspI region are physically distinct from molecules that are open in this region as evidenced by partial separation of the two populations on sucrose density gradients.

Barriers to nuclease Bal31 digestion across specific sites in simian virus 40 chromatin

A portion of the nucleoprotein containing viral DNA extracted from cells infected by simian virus (SV40) is preferentially cleaved by endonucleases in a region of the genome encompassing the origin of replication and early and late promoters. To explore this nuclease-sensitive structure, we cleaved SV40 chromatin molecules with restriction enzymes and digested the exposed termini with nuclease Bal31. Digestion proceeded only a short distance in the late direction from the MspI site, but some molecules were degraded 400 to 500 base pairs in the early direction. By comparison, BglI-cleaved chromatin was digested for only a short distance in the early direction, but some molecules were degraded 400 to 450 base pairs in the late direction. These barriers to Bal31 digestion (bracketing the BglI and the MspI sites) define the borders of the same open region in SV40 chromatin that is preferentially digested by DNase I and other endonucleases. In a portion of the SV40 chromatin, Bal31 could not digest through the nuclease-sensitive region and reached barriers after digesting only 50 to 100 base pairs from one end or the other. Chromatin molecules that contain barriers in the BglI to MspI region are physically distinct from molecules that are open in this region as evidenced by partial separation of the two populations on sucrose density gradients.

Chromatin structure of simian virus 40-pBR322 recombinant plasmids in COS-1 cells

To study the nucleoprotein structure formed by recombinant plasmid DNA in mammalian cells, nuclei were isolated from COS-1 cells after transfection with a recombinant (pJI1) containing pBR322 sequences and a segment of simian virus 40 containing information for a nuclease-sensitive chromatin structure. The nuclei were incubated with DNase I. DNA fragments which were the size of linear pJI1 DNA were isolated, redigested with restriction enzymes, fractionated by electrophoresis, and detected by hybridization with nick-translated segments prepared from the plasmid DNA. Two DNase I-sensitive sites were detected in the simian virus 40 portion of the plasmid at the same sites that were DNase I sensitive in simian virus 40 chromatin prepared late after infection of African green monkey kidney (BSC-1) cells. One site extended from the viral origin of replication to approximately nucleotide 40. The 21-base pair repeated sequences were relatively DNase I resistant. A second site occurred over the single copy of the 72-base pair segment present in this plasmid. These results indicate that the nuclease-sensitive chromatin structure does not depend on the presence of viral structural proteins. In addition, late viral proteins added to pJI1-transfected COS-1 cells by superinfection with simian virus 40 caused no change in the distribution of DNase I-sensitive sites in plasmid chromatin. Analysis of transfected plasmid DNA may provide a general method applicable to the study of the chromatin structure of cloned segments of DNA.

Chromatin structure of simian virus 40-pBR322 recombinant plasmids in COS-1 cells

To study the nucleoprotein structure formed by recombinant plasmid DNA in mammalian cells, nuclei were isolated from COS-1 cells after transfection with a recombinant (pJI1) containing pBR322 sequences and a segment of simian virus 40 containing information for a nuclease-sensitive chromatin structure. The nuclei were incubated with DNase I. DNA fragments which were the size of linear pJI1 DNA were isolated, redigested with restriction enzymes, fractionated by electrophoresis, and detected by hybridization with nick-translated segments prepared from the plasmid DNA. Two DNase I-sensitive sites were detected in the simian virus 40 portion of the plasmid at the same sites that were DNase I sensitive in simian virus 40 chromatin prepared late after infection of African green monkey kidney (BSC-1) cells. One site extended from the viral origin of replication to approximately nucleotide 40. The 21-base pair repeated sequences were relatively DNase I resistant. A second site occurred over the single copy of the 72-base pair segment present in this plasmid. These results indicate that the nuclease-sensitive chromatin structure does not depend on the presence of viral structural proteins. In addition, late viral proteins added to pJI1-transfected COS-1 cells by superinfection with simian virus 40 caused no change in the distribution of DNase I-sensitive sites in plasmid chromatin. Analysis of transfected plasmid DNA may provide a general method applicable to the study of the chromatin structure of cloned segments of DNA.

Separation and properties of two kinds of simian virus 40 late transcription complexes

Simian virus 40 (SV40) transcription complexes were labeled in cells with 3-min pulses of [(3)H]uridine 48 h after infection and were extracted from nuclei in isotonic buffer or in a buffer containing Sarkosyl. In sucrose gradients, the labeled complexes sedimented faster than both free RNA and most SV40 nucleoproteins. Most of the pulse-labeled nascent RNA hybridized to the entire late region of SV40, remained bound to viral DNA in Cs(2)SO(4) gradients, and ranged in size from a few nucleotides to about 5,000 nucleotides, with a peak at about 700. In contrast, the SV40-associated RNA polymerase activity in the same preparations sedimented near the major peak of SV40 nucleoproteins and was clearly separated from the transcription complexes bearing pulse-labeled nascent RNA. The two kinds of transcription complexes were released from isolated nuclei at different rates. Complexes bearing pulse-labeled RNA were released immediately when the nuclei were agitated in a Dounce homogenizer in isotonic buffer, whereas most of the complexes bearing RNA polymerase active in vitro were released more slowly, during subsequent incubation of the nuclei at 0 degrees C. Since the complexes bearing pulse-labeled nascent RNA were virtually inactive in vitro, the blocked complexes described by Laub et al. (Proc. Natl. Acad. Sci. U.S.A. 77:3297-3301, 1980) probably account for almost all the SV40-associated RNA polymerase activity studied previously by many investigators. New procedures must be developed to preserve the activity of the pulse-labeled complexes if the many advantages of the SV40 system for studying transcription by nucleoprotein complexes in vitro are to be realized fully.

Two deletions within genes for simian virus 40 structural proteins VP2 and VP3 lead to formation of abnormal transcriptional complexes

The procedure developed by R. M. Fernandez-Muñoz et al. (J. Virol. 29:612-623, 1979) for isolating simian virus 40 (SV 40) chromatin free of disrupted previrions was optimized for preparing late transcriptional complexes, and these complexes were partially characterized. Transcriptional complexes derived from wild-type virus and from several deletion and temperature-sensitive mutants could be activated more than five-fold either by the anionic detergent Sarkosyl or by 300 mM ammonium sulfate, in agreement with the properties of SV40 transcriptional complexes prepared by other procedures. In contrast, complexes from cells infected with deletion mutants dl1261 or dl1262 were not activated at all by a high salt concentration, even though the extent of their activation by Sarkosyl was normal. Mutants dl1261 and dl1262 carry deletions of 54 and 36 base pairs, respectively, at an approximate map position of 0.91, which is within the overlapping genes for the virion proteins VP2 and VP3. The effects of these deletions on transcription in vitro indicate that VP2 or VP3 or both are bound to late transcriptional complexes in a way that affects the progress of initiated RNA polymerase. The properties of late transcriptional complexes derived from wild-type SV40 can be explained by the presence of the following two different kinds of complexes: (i) a minority class (about 20%), which is free of VP2 or VP3, active at low concentrations of ammonium sulfate in vitro, and responsible for late transcription in vivo, and (ii) a majority class (about 80%) with VP2 or VP3 bound, which is inactive at low salt concentrations both in vitro and in vivo but capable of being activated by high salt concentrations or by Sarkosyl. We propose that mutant VP2 and VP3 proteins from dl1261 and dl1262 bind to the majority class of late transcriptional complexes in a way that can be reversed by Sarkosyl but not by a high salt concentration.