Structural changes in simian virus 40 chromatin as probed by restriction endonucleases.

The structure of simian virus 40 (SV40) chromatin was probed by treatment with single- and multiple-site bacterial restriction endonucleases. Approximately the same fraction of the chromatin DNA was cleaved by each of three different single-site endonucleases, indicating that the nucleosomes do not have unique positions with regard to specific nucleotide sequences within the population of chromatin molecules. However, the extent of digestion was found to be strongly influenced by salt concentration. At 100 mM NaCl-5 mM MgCl2, only about 20% of the simian virus 40 (SV40) DNA I in chromatin was converted to linear SV40 DNA III. In contrast, at lower concentrations of NaCl (0.05 or 0.01 M), an additional 20 to 30% of the DNA was cleaved. These results suggest that at 100 mM NaCl only the DNA between nucleosomes was accessible to the restriction enzymes, whereas at the lower salt concentrations, DNA within the nucleosome regions became available for cleavage. Surprisingly, when SV40 chromatin was digested with multiple-site restriction enzymes, less than 2% of the DNA was digested to limit digest fragment, whereas only a small fraction (9 to 15%) received two or more cuts. Instead, the principal digest fragment was full-length linear SV40 DNA III. The failure to generate limit digest fragments was not a consequence of reduced enzyme activity in the reaction mixtures or of histone exchange. When the position of the principal cleavage site was mapped after HpaI digestion, it was found that this site was not unique. Nevertheless, all sites wree not cleaved with equal probability. An additional finding was that SV40 chromatin containing nicked-circular DNA II produced by random nicking of DNA I was also resistant to digestion by restriction enzymes. These results suggest that the initial cut which causes relaxation of topological constraint in SV40 chromatin DNA imparts resistance to further digestion by restriction enzymes. We propose that this may be accomplished by either "winding" of the internucleosomal DNA into the body of the nucleosome, or as suggested by others, by successive right-hand rotation of nucleosomes.     

Mapping the in vivo arrangement of nucleosomes on simian virus 40 chromatin by the photoaddition of radioactive hydroxymethyltrimethylpsoralen.

Intracellular simian virus 40 (SV40) chromatin was photoreacted with a 3H-labeled psoralen derivative, hydroxymethyltrimethylpsoralen (HMT), at 48 h postinfection. Psoralen compounds have been shown to readily penetrate intact cells and, in the presence of long-wavelength UV light, form covalent adducts to DNA, preferentially at regions unprotected by nucleosomes. The average distribution pattern of [3H]HMT on the SV40 genome was determined by specific activity measurements of the DNA fragments generated by HindIII plus HpaII or by AtuI restriction enzyme digestion. At levels of 1 to 10 [3H]HMT photoadducts per SV40 molecule, the radiolabel was found to be distributed nonrandomly. Comparison of the labeling pattern in vivo with that of purified SV40 DNA labeled in vitro revealed one major difference. A region of approximately 400 base pairs, located between 0.65 and 0.73 on the physical map, was preferentially labeled under in vivo conditions. This finding strongly suggests that the highly accessible region near the origin of replication, previously observed on isolated SV40 "minichromosomes," exists on SV40 chromatin in vivo during a lytic infection.     

The effect of supercoil and temperature on the recognition of palindromic and non-palindromic regions in phi X174 replicative form DNA by S1 and Bal31

The effect of supercoil and temperature on the topology of phi X174 replicative form (RF) DNA was studied using single-strand specific endonucleases S1 and Bal31 as probes for cruciform extrusion and other structural perturbations of the B-helix. Both enzymes were found to recognize specifically and reproducibly over 30 sites, most of which were cleaved by both enzymes independent of the superhelicity of the genome. A negative superhelical density exceeding 0.06 stabilized a transition in the DNA conformation that generated several new cleavage sites for Bal31. The underlying structures appeared to be only transiently stable and were lost from in vitro supercoiled DNA during brief incubation at 65 degrees C. They were generally absent from in vivo supercoiled RF DNA of equal superhelicity as a consequence of the extraction and storage procedure. Mapping of the cleavage sites suggested that they were preferentially located near the beginnings and ends of genes and that the structural basis for at least some of them was the extrusion of relatively small palindromes into the cruciform state. Insertion of a short synthetic palindromic sequence into the phi X174 genome generated a supercoil-dependent, temperature-sensitive secondary structure that was cleaved in the Bal31 but not the S1 reaction, further supporting the hypothesis that even small cruciforms with stem size of 7 or less base pairs may be transiently stable. Subjecting supercoiled RF DNA to the typical S1 reaction conditions induced a topological shift that diminished all but one of the supercoil-induced Bal31 recognition sites and promoted the formation of one major new site.     

Sites in simian virus 40 chromatin which are preferentially cleaved by endonucleases.

Simian virus 40 (SV40) chromatin isolated from infected BSC-1 cell nuclei was incubated with deoxyribonuclease I, staphylococcal nuclease or an endonuclease endogenous to BSC-1 cells under conditions selected to introduce one doublestrand break into the viral DNA. Full-length linear DNA was isolated, and the distribution of sites of initial cleavage by each endonuclease was determined by restriction enzyme mapping. Initial cleavage of SV40 chromatin by deoxyribonuclease I or by endogenous nuclease reduced the recovery of Hind III fragment C by comparison with the other Hind III fragments. Similarly, Hpa I fragment B recovery was reduced by comparison with the other Hpa I fragments. When isolated SV40 DNA rather than SV40 chromatin was the substrate for an initial cut by deoxyribonuclease I or endogenous nuclease, the recovery of all Hind III or Hpa I fragments was approximately that expected for random cleavage. Initial cleavage by staphylococcal nuclease of either SV40 DNA or SV40 chromatin occurred randomly as judged by recovery of Hind III or Hpa I fragments. These results suggest that, in at least a portion of the SV40 chromatin population, a region located in Hind III fragment C and Hpa I fragment B is preferentially cleaved by deoxyribonuclease I or by endogenous nuclease but not by staphylococcal nuclease.Complementary information about this nuclease-sensitive region was provided by the appearance of clusters of new DNA fragments after restriction enzyme digestion of DNA from viral chromatin initially cleaved by endogenous nuclease. From the sizes of new fragments produced by different restriction enzymes, preferential endonucleolytic cleavage of SV40 chromatin has been located between map positions 0.67 and 0.73 on the viral genome.     

Localization of T-antigen on simian virus 40 minichromosomes by immunoelectron microscopy.

SV40 chromatin extracted from 42 h post-infected cells by a modification of the standard Triton X-100-EDTA procedure and purified on neutral sucrose gradients was partially immunoprecipitable by a specific SV40 T-antigen (T-Ag) antiserum. Electron microscopic observations of spread minichromosomes were made after labelling by the indirect colloidal gold immunological method using monoclonal antibodies specific for the SV40 T-Ag. In 1-2% of morphologically mature minichromosomes the labelling corresponding to tightly bound T-Ag was localized within the nucleosome-free region near one of its borders. Mapping with three single-cut restriction endonucleases: BamHI, EcoRI and BglI localized the labelling near to, or at the origin of, replication. In addition, we observed that the T-Ag specific antibodies were linked to a DNA-bound particle when the region was not masked by a large clump of antibodies. The variable size of this particle led us to suggest that it might be a complex of T-Ag with other proteins.     

High resolution psoralen mapping reveals an altered DNA helical structure in the SV40 regulatory region.

Preferential psoralen photobinding sites have been mapped in vitro on restriction fragments spanning the SV40 origin region and surrounding sequences by a new fine structure analysis technique. Purified DNA fragments were photoreacted with 3H-5-methylisopsoralen (3H-5-MIP), a psoralen derivative which forms only monoadducts. Fragments were then end-labeled and digested with lambda exonuclease, a 5' processive enzyme which we have determined pauses at 5-MIP monoadducts. When photobinding sites were mapped on denaturing sequencing gels, it was observed that 5-MIP binds preferentially to 5'-TA sites, and to a lesser degree to 5'-AT sites. Utilizing this approach, we have identified a psoralen hypersensitive region in which the binding sites were much stronger than those in the surrounding sequences. This region extends from 150 base pairs (bp) to the late side of the enhancers to the early enhancer/promoter boundary. We suggest that this region contains a sequence directed structural alteration of the DNA helix which can be detected by the psoralen mapping approach described.     

Deletion mutants which affect the nuclease-sensitive site in simian virus 40 chromatin.

A short segment of simian virus 40 (SV40) chromatin on the late side of the origin of replication is hypersensitive to nuclease cleavage. The role of DNA sequence information in this nuclease-sensitive feature was examined by constructing deletion mutations in this region. Deletions were introduced into the inserted segment of in(Or)-1411 (a viable, partially duplicated variant of SV40), and nuclease sensitivity of the inserted segment was compared with that of the unaltered sequences in their normal location in the viral genome. Extended deletions (118 to 161 base pairs) essentially abolished nuclease sensitivity within the inserted segment. Shorter deletions (21 to 52 base pairs) at separate locations retained the nuclease-sensitive feature. In some short-deletion mutants nuclease susceptibility was substantially reduced. We conclude that more than one genetic element in this region contributes to the organization of the nuclease-sensitive feature and that the SV40 72-base repeat is not, in itself, sufficient signal for this feature.     

P1 nuclease defines a subpopulation of active SV40 chromatin--a new nuclease hypersensitivity assay.

Under exhaustive digestion conditions P1 nuclease was found to cleave a subpopulation of intracellular SV40 chromatin only once. The major P1 cleavage site in SV40 DNA was mapped at the origin of DNA replication, and the two minor sites at the SV40 enhancers. The P1-sensitive SV40 chromatin subpopulation was found to have higher superhelical density than the bulk of the intracellular SV40 chromatin. Furthermore, pulse labeled SV40 DNA which had higher superhelical density than that of the steady state viral DNA (S.S.Chen and M.T.Hsu, J.Virol 51:14-19, 1984) was also found to be preferentially cleaved by P1 nuclease. These results are consistent with a supercoil-dependent alteration of chromatin conformation near the regulatory region of the viral genome that can be recognized by P1 nuclease. Since P1 nuclease cleaves the subpopulation of SV40 chromatin only once without further degradation, this nuclease can be used as a general tool to define viral or cellular chromatin fraction with altered chromatin conformation and to map nuclease hypersensitive sites. Preliminary studies indicate that P1 makes limited double stranded cleavages in cellular chromatin to generate large DNA fragments.     

Role of specific simian virus 40 sequences in the nuclease-sensitive structure in viral chromatin.

A nuclease-sensitive region forms in chromatin containing a 273-base-pair (bp) segment of simian virus 40 DNA encompassing the viral origin of replication and early and late promoters. We have saturated this region with short deletion mutations and compared the nuclease sensitivity of each mutated segment to that of an unaltered segment elsewhere in the partially duplicated mutant. Although no single DNA segment is required for the formation of a nuclease-sensitive region, a deletion mutation (dl45) which disrupted both exact copies of the 21-bp repeats substantially reduced nuclease sensitivity. Deletion mutations limited to only one copy of the 21-bp repeats had little, if any, effect. A mutant (dl135) lacking all copies of the 21- and 72-bp repeats, while retaining the origin of replication and the TATA box, did not exhibit a nuclease-sensitive region. Mutants which showed reduced nuclease sensitivity had this effect throughout the nuclease-sensitive region, not just at the site of the deletion, indicating that although multiple determinants must be responsible for the nuclease-sensitive chromatin structure they do not function with complete independence. Mutant dl9, which lacks the late portion of the 72-bp segment, showed reduced accessibility to BglI, even though the BglI site is 146 bp away from the site of the deletion.     

DNase I sensitivity of integrated simian virus 40 DNA.

We undertook an analysis of integrated simian virus 40 (SV40) DNA to learn whether the DNase I-sensitive region is retained in the integrated array of mouse transformants. Our results indicate that full-length integrated SV40 chromatin retains a DNase I-hypersensitive region at the same point as in nonintegrated SV40 chromatin. Thus, the lack of a DNase I-hypersensitive region is not likely to be the reason for nonpermissivity of SV40 in mouse cells. In addition, results reported here indicate that a deletion of about 200 base pairs of DNA in the region of the DNase I-hypersensitive site severely reduces the sensitivity of integrated SV40 chromatin. This result is similar to a previously reported result obtained with deletion mutants of SV40 analyzed in the lytic cycle. It is the first report of a DNA lesion affecting DNase I hypersensitivity of a mammalian chromosome.     

Cleavage of Circular, Superhelical Simian Virus 40 DNA to a Linear Duplex by S1 Nuclease

S(1) nuclease, the single-strand specific nuclease from Aspergillus oryzae can cleave both strands of circular covalently closed, superhelical simian virus 40 (SV40) DNA to generate unit length linear duplex molecules with intact single strands. But circular, covalently closed, nonsuperhelical DNA, as well as linear duplex molecules, are relatively resistant to attack by the enzyme. These findings indicate that unpaired or weakly hydrogen-bonded regions, sensitive to the single strand-specific nuclease, occur or can be induced in superhelical DNA. Nicked, circular SV40 DNA can be cleaved on the opposite strand at or near the nick to yield linear molecules. S(1) nuclease may be a useful reagent for cleaving DNAs at regions containing single-strand nicks. Unlike the restriction endonucleases, S(1) nuclease probably does not cleave SV40 DNA at a specific nucleotide sequence. Rather, the sites of cleavage occur within regions that are readily denaturable in a topologically constrained superhelical molecule. At moderate salt concentrations (75 mM) SV40 DNA is cleaved once, most often within either one of the two following regions: the segments defined as 0.15 to 0.25 and 0.45 to 0.55 SV40 fractional length, clockwise, from the EcoR(I) restriction endonuclease cleavage site (defined as the zero position on the SV40 DNA map). In higher salt (250 mM) cleavage occurs preferentially within the 0.45 to 0.55 segment of the map.     

Random cleavage of superhelical SV 40 DNA S1 nuclease.

SV40 DNA FO I is randomly cleaved by S1 nuclease both at moderate (50 mM) and higher salt concentrations (250 mM NaC1). Full length linear S1 cleavage products of SV40 DNA when digested with various restriction endonucleases revealed fragments that were electrophoretically indistinguishable from the products found after digestion of superhelical SV40 DNA FO I with the corresponding enzyme. Concordingly, when the linear S1 generated duplexes were melted and renatured, circular duplexes were formed in addition to complex larger structures. This indicated that cleavage must have occurred at different sites. The double-strand-cleaving activity present in S1 nuclease preparations requires circular DNA as a substrate, as linear SV40 DNA is not cleaved. With regard to these properties S1 nuclease resembles some of the complex type I restriction nucleases from Escherichia coli which also cleave SV40 DNA only once, and, completely at random.     

A stretch of "late" SV40 viral DNA about 400 bp long which includes the origin of replication is specifically exposed in SV40 minichromosomes.

Examination of DNA fragments produced from either formaldehyde-fixed or unfixed SV40 minichromosomes by multiple-cut restriction endonucleases has led to the following major results: Exhaustive digestion of unfixed minichromosomes with Hae III generated all ten major limit-digest DNA fragments as well as partial cleavage products. In striking contrast to this result, Hae III acted on formaldehyde-fixed minichromosomes to yield only one of the limit-digest fragments, F, which is located in the immediate vicinity of the origin of replication, spanning nucleotides 5169 and 250 on the DNA sequence map of Reddy et al. (1978). This 300 base pair (bp) fragment was released as naked DNA from formaldehyde-fixed, Hae III-digested minichromosomes following treatment either by pronase-SDS or by SDS alone. In the latter case, the remainder of the minichromosome retained its compact configuration as assayed by both sedimentational and electrophoretic methods. In minichromosomes, the F fragment is therefore not only accessible to Hae III at its ends, but is also neither formaldehyde cross-linked into any SDS-resistant nucleoprotein structure nor topologically "locked" within the compact minichromosomal particle. This same fragment was preferentially produced during the early stages of digestion of unfixed minichromosomes with Hae III, and its final yield in the exhaustive Hae III digest was significantly higher than that of other limit-digest fragments. Similar results were obtained upon digestion of either unfixed or formaldehyde-fixed minichromosomes with Alu I. In particular, of approximately twenty major limit-digest DNA fragments, only two fragments (F and P, encompassing nucleotides 5146 to 190, and 190 to 325, respectively) were produced by Alu I from the formaldehyde-fixed minichromosomes. All other restriction endonucleases tested (Mbo I, Mbo II, Hind III, Hin II+III and Hinf I), for which there are no closely spaced recognition sequences in the above mentioned regions of the SV40 genome, did not produce any significant amount of limit-digest DNA fragments from formaldehyde-fixed minichromosomes. These findings, taken together with our earlier data on the preferential exposure of the origin of replication in SV40 minichromosomes (Varshavsky, Sundin and Bohn, 1978), strongly suggest that a specific region of the "late" SV40 DNA approximately 400 bp long is uniquely exposed in the compact minichromosome. It is of interest that, in addition to the origin of replication, this region contains binding sites for T antigen (Tjian, 1977), specific tandem repeated sequences and apparently also the promoters for synthesis of late SV40 mRNAs (Fiers et al., 1978; Reddy et al., 1978).     

Specific association of simian virus 40 tumor antigen with simian virus 40 chromatin

Simian virus 40 tumor antigen (SV40 T antigen) was bound to both replicating and fully replicated SV40 chromatin extracted with a low-salt buffer from the nuclei of infected cells, and at least a part of the association was tight specific. T antigen cosedimented on sucrose gradients with SV40 chromatin, and T antigen-chromatin complexes could be precipitated from the nuclear extract specifically with anti-T serum. From 10 to 20% of viral DNA labeled to steady state with [3H]thymidine for 12 h late in infection or 40 to 50% of replicating viral DNA pulse-labeled for 5 min was associated with T antigen in such immunoprecipitates. After reaction with antibody, most of the T antigen-chromatin complex was stable to washing with 0.5 M NaCl, but only about 20% of the DNA label remained in the precipitate after washing with 0.5 M NaCl-0.4% Sarkosyl. This tightly bound class of T antigen was associated preferentially with a subfraction of pulse-labeled replicating DNA which comigrated with an SV40 form I marker. A tight binding site for T antigen was identified tentatively by removing the histones with dextran sulfate and heparin from immunoprecipitated chromatin labeled with [32P]phosphate to steady state and then digesting the DNA with restriction endonucleases HinfI and HpaII. The site was within the fragment spanning the origin of replication, 0.641 to 0.725 on the SV40 map.