The number of superhelical turns in native virion SV40 DNA and minicol DNA determined by the band counting method.

By a method of overlapping the results obtained after agarose gel electrophoresis under two different sets of conditions, it has become possible to determine the number of superhelical turns in a given DNA by counting the bands present after partially relaxing the DNA (Keller and Wendel, 1974) with highly purified nicking-closing (N-C) enzyme from LA9 mouse cell nuclei. Because native supercoiled DNA is heterogeneous with respect to superhelix density, an average number of superhelical turns was determined. Virion SV40 DNA contains 26 +/- 0.5 superhelical turns, and native Minicol DNA contains 19 +/- 0.5 superhelical turns. The above are values at 0.2 M NaCl and at 37 degrees C, the condition under which the enzymatic relaxations were performed. The superhelix densities determined by the band counting method have been compared with superhelix densities determined by buoyant equilibrium in PDl-CsCl gradients. The Gray, Upholt, and Vinograd (1971) calculation procedure has been used for evaluating the superhelix densities by the latter method with the new statement, however, that relaxed DNA has zero superhelical turns. Comparison of the superhelix densities obtained by both methods permits a calculation of an unwinding angle for ethidium. The mean value from experiments with SV40 DNA is 23 +/- 3 degree. The average number of superhelical turns in SV40, 26, combined with the value, 21, obtained by both Griffith (1975) and Germond et al. (1975) for the average number of nucleosomes per SV40 genome, yields an average of 1.25 superhelical turns per 1/21 of the SV40 genome. If the regions of internucleosomal DNA are fully relaxed, 1.25 correesponds to the average number of superhelical turns with a nucleosome. When analyzed under identical conditions, the limit product generated by ligating a nicked circular substrate in the presence of 0.001 M Mg2+ at 37 degrees C (ligation conditions) is slightly more positively supercoiled than the limit product obtained when the N-C reaction is performed in 0.2 M NaCl at 37 degrees C. The difference in superhelix density as measured in gels between the two sets of limit products for both Minicol and SV40 DNAs is 0.0059 +/- 0.0005. This result indicates that the DNA duplex is overwound in the ligation solvent relative to its state in 0.2 M NaCl.     

The use of Haemophilus gallinarum DNA-relaxing enzyme to investigate the relationship between the number of superhelical turns and the molecular weight in a negatively twisted DNA.

Covalently closed-circular, superhelical DNAs, including viral DNAs, bacterial plasmid DNAs, and bacteriophage replicative-form DNA, were treated with a small amount of Haemophilus gallinarum DNA-relaxing enzyme to generate incompletely relaxed DNA molecules. Each sample consisted of a set of closed-circular DNA molecules differing by one turn in their number of superhelical turns. The DNA samples were analyzed by agarose gel electrophoresis under conditions such that the electrophoretic mobility was a function of the number of turns. The numbers of superhelical turns (at 37 degrees C in 20 mM Tris-HCl (pH 7.5)-5 mM MgCl2) in the DNAs of pSC101 (5.8 megadaltons), Colicin E1 (4.2 megadaltons), pMR4 (4.0 megadaltons; recombinant between pBR322 and lambda DNA fragment), phi X174 replicative-form (RF) I, Simian virus 40 (SV40), and polyoma virus (3.4--3.6 megadaltons each), and lambda dv021 (2.05 megadaltons) were estimated to be 36, 27, 23--24, 20--21, 20--21, 20--21, and 11--13, respectively. It appears that the number of superhelical turns is mainly a function of the molecular weight of the DNA, at least in the substrates tested here.     

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.     

A sedimentation study of the interaction of superhelical SV40 DNA with H1 histone.

By moving boundary sedimentation it is shown that the interaction of H1 histone with superhelical circular SV40 DNA results in the formation of giant heterogeneous aggregates. The size of these aggregates grows with increasing H1 concentration. s20,w values of some 10 000 S were measured. As compared with open relaxed circular DNA a preferential interaction of superhelical DNA with H1 histone is observed, irrespective of the sign of the superhelical turns which was reversed by the addition to DNA of ethidium bromide. The addition to the H1 complexed aggregates of ethidium bromide effects a progressive breakdown of the aggregates. Furthermore, the superhelicity of DNA is not changed by the addition of small amounts of H1 histone.     

A specific DNA unwinding activity associated with SV40 large T antigen

The incubation of highly purified large T antigen with relaxed, circular SV40 DNA in the presence of topoisomerase I (nicking closing enzyme) resulted in the introduction of negative superhelical turns in the DNA. ATP was not required for this reaction. A similar introduction of superhelical turns could also be obtained when a recombinant plasmid DNA (Y182), which contains sequences from both SV40 DNA and pBR322, was used. However, no effect was observed when relaxed pBR322 DNA, which does not contain SV40 DNA sequences, was incubated with T antigen in the presence of topoisomerase. These results are consistent with the hypothesis that large T antigen can recognize and unwind specific sequences on SV40 DNA.     

Isolation,characterization, and structure of the folded interphase genome of Drosophila melanogaster

The intact interphase genome of Drosophila melanogaster has been isolated by sucrose gradient centrifugation after gentle lysis of tissue culture cells in 0.9 M NaCl-0.4% Nonidet P40. The nonviscous folded DNA sediments as a single broad 5000S peak in a complex with RNA (a fraction of the nuclear nascent RNA) and protein (all of the four intranucleosome histones: H2A, H2B, H3, and H4).The folded DNA is supercoiled and can be relaxed to slower sedimenting forms either by intercalating ethidium or by nicking with DNAase I. Incomplete DNAase treatment gives partially relaxed complexes, indicating that each nick relaxes only a stretch of DNA (defined as a supercoiled DNA loop) without affecting the superhelical content of the rest of the genome. The concentration of superhelices in the Drosophila folded DNA is the same as in the E. coli and SV40 closed circular DNAs—that is, about one negative turn every 200 base pairs (bp) in 0.15 M NaCl at 26°C. The estimated average size of the supercoiled DNA loops, about 85,000 bp, equals the size of the larger Drosophila chromomeres.Ethidium intercalation in 0.9 M NaCl both removes the negative superhelical turns and dissociates the four histones from the DNA. The four histones are dissociated in equimolar concentrations, and the relative proportion of histones displaced from the DNA is a function of ethidium concentration. The histones are completely dissociated from the folded DNA at the ethidium concentration which removes all of the negative superhelices. Thus the data strongly suggest that the rotation of the Watson Crick helix which accompanies ethidium intercalation causes the loss of nucleosomes from the DNA.The results are interpreted in terms of a model for the folded Drosophila genome which has the DNA constrained (by both protein-DNA and RNA-DNA interactions) into independent supercoiled loops containing on the average 400 nucleosomes per loop. Each nucleosome is composed of a histone core with the DNA wound around it in a 360° left-handed toroidal supercoil; each nucleosome toroidal supercoil plus its relaxed internucleosome DNA contains, on the average, 200 bp.     

Joint molecule formation following conjugation in wild type and mutant Escherichia coli recipients

The sedimentation coefficients of closed circular Simian virus (SV40) DNA, phage PM2 DNA and animal mitochondrial DNAs in alkaline NaCl and alkaline CsCl were found to decrease by about 5% as the initial superhelix densities decreased from 0.0 to ?0.10, corresponding to a decrease in the degree of strand interwinding from 1.0 to 0.9 net turns per ten base pairs. The small dependence of the appropriately normalized sedimentation coefficients on the degree of strand interwinding is taken to indicate that fully titrated and denatured closed circular DNA is highly supercoiled in a positive sense. This supercoiling results from the spontaneous decrease in the number of secondary turns in the no longer ordered pairs of polynucleotide strands.The measured sedimentation coefficients form a smoothly connected monotonie curve when plotted along with the sedimentation coefficients in alkali (Sebring et al., 1971) of parental closed circles derived from closed circular SV40 DNA replicating intermediates. These DNAs have degrees of strand interwinding that range from 0.6 to 0.15.The possibility raised by Paoletti &; LePecq (1971) that closed circular duplex DNAs contain positive supercoils, i.e. have degrees of strand interwinding greater than 1.0, has been ruled out in a series of ethidium bromide titrations of partially replicated mitochondrial DNA before and after removal of the progeny strand. More ethidium bromide was required in the latter case for relaxation, a result which shows that intercalated ethidium and a displacing strand act on the duplex in the same way, and that both unwind the duplex. This result requires the supercoils of naturally closed circular DNAs to be negative.     

E. coli DNA binding protein HU forms nucleosomelike structure with circular double-stranded DNA.

The incubation of the E coli DNA binding protein HU with relaxed circular SV40 DNA in the presence of pure nicking-closing enzyme introduces up to 18 negative superhelical turns in the DNA molecules as measured by agarose gel electrophoresis. The maximal density of supercoiling is obtained at a HU-DNA mass ratio of 1. Reconstituted DNA-HU complexes prefixed with glutaraldehyde appear as condensed circular structures having an average of 14 "beads" per circular SV40 DNA molecule, with a "bead" diameter of 180 +/- 23 A. The circular SV40 DNA is condensed by a ratio of 2.0-2.5 relative to naked DNA. This is similar to the ratio (2.4) measured for chromatin formed by reassociation of relaxed SV40 DNA with the four core histones.     

The effect of H1 histone on the action of DNA-relaxing enzyme.

The action of DNA-relaxing enzyme on H1-DNA complexes was investigated. Complexes of superhelical and relaxed closed circular duplex DNA with H1 were treated with mammalian relaxing enzyme, deproteinized, and electrophoresed on agarose gels. At relatively low ratios of H1 to superhelical DNA, molecules of superhelical density intermediate between those of the starting material and relaxed DNA, the normal product, were generated. At relatively high H1 histone concentrations (H1:DNA greater than 0.4 w/w), the superhelical DNA was not relaxed. Further, no superhelical turns were introduced into relaxed closed duplex DNA at any concentration of H1 tested. Thus, the binding of H1 histone to DNA prevents the action of the relaxing enzyme. Moreover, H1 histone does not appear to unwind the DNA duplex upon binding. The implications of these observations and the previously demonstrated specificity of H1 histone for superhelical DNA are discussed in relation to the structure of chromatin.     

Molecular interactions between DNA, poly(ADP-ribose) polymerase, and histones

Molecular interactions between purified poly(ADP-ribose) polymerase, whole thymus histones, histone H1, rat fibroblast genomic DNA, and closed circular and linearized SV40 DNA were determined by the nitrocellulose filter binding technique. Binding of the polymerase protein or histones to DNA was augmented greatly when both the enzyme protein and histones were present simultaneously. The polymerase protein also associated with histones in the absence of DNA. The cooperative or promoted binding of histones and the enzyme to relaxed covalently closed circular SV40 DNA was greater than the binding to the linearized form. Binding of the polymerase to SV40 DNA fragments in the presence of increasing concentrations of NaCl indicated a preferential binding to two restriction fragments as compared to the others. Polymerase binding to covalently closed relaxed SV40 DNA resulted in the induction of superhelicity. The simultaneous influence of the polymerase and histones on DNA topology were more than additive. Topological constraints on DNA induced by poly(ADP-ribose) polymerase were abolished by auto ADP-ribosylation of the enzyme. Benzamide, by inhibiting poly(ADP-ribosylation), reestablished the effect of the polymerase protein on DNA topology. Polymerase binding to in vitro-assembled core particle-like nucleosomes was also demonstrated.     

Dye titrations of covalently closed supercoiled DNA analyzed by agarose gel electrophoresis.

We have developed a rapid electrophoretic technique for performing ethidium bromide dye titrations in cylindrical 0.7% agarose gels. The technique was used to analyze the extent of supercoiling in circular covalently closed SV40, Co1E1, and pSC101 DNA. We have estimated the superhelical densities of SV40, Co1E1, and pSC101 DNA to be ?0.050, ?0.078, and ?0.085 respectively. The results obtained for native SV40 DNA correlate well with previously published values for the superhelical density of this DNA when these values are corrected to reflect a 26° duplex unwinding angle for ethidium bromide. Ethidium bromide concentrations sufficient to partially relax a supercoiled DNA allow the DNA to be resolved into a series of discrete bands in agarose gels. The distribution of bands represents a natural heterogeneity in the superhelical densities of the DNA molecules in the population.     

Replication of SV40 minichromosomes in vitro

We operationally define two forms of SV40 minichromosomes, a 75S-form, prepared at low salt concentration, referred to as native minichromosomes, and a 50S-form, obtained after treatment with 0.5M potassium acetate, the salt-treated minichromosomes. Both preparations of minichromosomes serve well as templates for replication in vitro. Their respective replication products are strikingly different: replicated native minichromosomes contain a densely packed array of the maximal number of nucleosomes whereas replicated salt-treated minichromosomes carry, on average, half of the maximal number. We conclude that in both cases parental nucleosomes are transferred to progeny DNA, and, in addition, that an assembly of new nucleosomes occurs during the replication of native minichromosomes. This is apparently due to the presence of a nucleosome assembly factor as a constituent of native minichromosomes that dissociates upon treatment with salt. We further show that preparations of minichromosomes usually contain significant amounts of copurifying hnRNP particles and SV40 virion precursor particles. However, these structures do not detectably affect the replication and the chromatin assembly reactions.     

Extracellular nucleases of Alteromonas espejiana BAL 31.IV. The single strand-specific deoxyriboendonuclease activity as a probe for regions of altered secondary structure in negatively and positively supercoiled closed circular DNA.

The dependence of the initial rate of introduction of the first single-chain scission (initial nicking rate) into covalently closed circular phage PM2 DNA by the single strand-specific nuclease from Alteromonas espejiana BAL 31 upon the superhelix density (sigma) of the DNA has been examined. The initial nicking rate decreases with decreasing numbers of negative superhelical turns (decreasing values of -sigma), which behavior is characteristic of other single strand-specific nucleases as reported earlier. In contrast to earlier work, the initial nicking rates of closed circular DNAs by the action of the Alteromonas nuclease have been shown to be readily measurable at values of -sigma as low as 0.02. However, even at the elevated concentrations of enzyme and extended digestion periods required to cause nicking at an appreciable rate at near-zero values of sigma, closed circular DNA containing very few superhelical turns (form IO DNA) is not cleaved at a detectable rate. When this DNA is rendered positively supercoiled by ethidium bromide (EtdBr), it is not affected by the nuclease until very high positive values of sigma are attained, at which low rates of cleavage can be detected at elevated enzyme concentrations. The effects of EtdBr on the enzyme activity have been tested and are entirely insufficient to allow the interpretation of zero nicking rates as the result of inhibition of the nuclease activity by the dye. Positively supercoiled DNA is concluded not to contain regions having significant single-stranded character until values of sigma are reached which are very much higher than the values of -sigma for which negatively supercoiled DNAs behave as if they contain unpaired or weakly paired bases.     

The viscometric behavior of native and relaxed closed circular PM2 DNAs at intermediate and high ethidium bromide concentrations

We have measured the specific viscosity of closed circular PM2 DNA in the presence of concentrations of ethidium bromide ranging up to 5 mg/ml. Both native viral PM2 DNA I and enzymatically prepared relaxed, closed circular PM2 DNA I₀ exhibit a complex dependence of the specific viscosity upon the extent of supercoiling. As the number of superhelical turns is increased in the positive sense from zero, the viscosity first decreases to a minimum, then passes through a secondary maximum, and eventually again increases as the dye-induced duplex unwinding proceeds. In the case of DNA I, a corresponding behavior is mirrored in the negative sense as dye is removed from the principal viscometric maximum (complete relaxation of the DNA by dye). The shape of the curve relating specific viscosity to extent to supercoiling is similar for superhelical DNAs of either handedness, a result which we interpret to mean that the influence of any regions of special secondary structure (such as denatured loops) upon the viscosity is minimal. At very high dye concentrations the specific viscosity decreases dramatically. This effect might arise either from intermolecular aggregation or from a dye-induced collapse in the DNA secondary structure.     

The effect of divalent cations on the mode of action of DNase I. The initial reaction products produced from covalently closed circular DNA

The effect of different divalent metal ions on the hydrolysis of DNA by DNase I was studied with an assay which distinguishes between cleavage of one or both strands of the DNA substrate during initial encounters between enzyme and DNA. Using covalently closed superhelical SV40(I) DNA as substrate, initial reaction products consisting of relaxed circles or unit-length linears are resolved by electrophoresis of radioactively labeled DNA in agarose gels. Only in the presence of a transition metal ion, such as Mn2+ or Co2+, and only under certain reaction conditions, is DNase I able to cut both DNA strands at or near the same point, generating unit-length linears. This ability to cut both DNA strands is inhibited by such factors as temperature decrease, the addition of a monovalent ion or another divalent cation which is not a transition metal ion, or a reduction in the number of superhelical turns in the DNA substrate. All of these factors lead to a winding of the duplex helix and antagonize the unwinding of the duplex promoted by transition metal ion binding. Transition metal ions may thus convert the DNA substrate locally to a form in which DNase I can introduce breaks into both strands. In the presence of Mg2+, DNase I introduces single strand nicks into SV40(I), generating exclusively the covalently open, relaxed circular SV40(II) as the initial product of the reaction. In the presence of Mn2+, DNase I generates as initial products a mixture of SV40(II) and unit-length SV40 linear DNA molecules, formed by two nicks in opposite strands at or near the same point in the duplex. These circular SV40(II) molecules consist of two types. A minority class is indistinguishable from the nicked SV40(II) produced by DNase I in the presence of Mg2+. The majority class consists of molecules containing a gap in one of the two strands, the mean length of the gap being 11 nucleotides. The SV40(L) molecules produced in the presence of Mn2+ appear to have single strand extensions at one or both ends.     

Specific folding and contraction of DNA by histones H3 and H4.

We demonstrate that the arginine-rich histones H3 and H4 can introduce torsional constraints on closed circular DNA with a concomitant compaction of the nucleic acid. SV40 DNA I complexed with H3 and H4 appears relaxed in electron micrographs and contains particles of 75 +/- 10 A in diameter along the DNA. SV40 DNA I is contracted 2.75 +/- 0.25 fold by all the four smaller histones and 2.6 +/- 0.4 fold by H3 and H4 alone. The arginine-rich histones can cause the topological equivalent of unwinding the DNA close to one Watson-Crick turn per particle formed. Spherical nucleoprotein complexes morphologically similar to isolated nu bodies or nucleosomes are obtained by association of H3 and H4 with 140 base pair length DNA isolated from chromatin core particles. These reconstituted particles sediment at 9.8S, as compared to 10.8S for native core particles, and contain a tetramer of the arginine-rich histones. None of these specific alterations in DNA structure is seen om complexing the slightly lysine rich-histones H2A and H2B to DNA. Our data provide further evidence indicating that the arginine-rich histones are the major determinants of the architecture of DNA within the chromatin core particle.     

Addition of extra DNA sequences to simian virus 40 DNA in vivo.

The possible addition of extra sequences to simian virus 40 (SV40) DNA was analyzed by electron microscopy in two different cell systems, productively infected monkey cells and activated heterokaryons on monkey and transformed mouse 3T3 cells. We found that the closed circular DNA fraction, extracted from monkey cells at 70 h after infection with nondefective SV40 at a multiplicity of infection of 6 PFU/cell, contained oversized molesules (1.1 to 2.0 fractional lengths of SV40 DNA) constituting about 8% of the molecules having lengths equal to or shorter than SV40 dinner DNA. The oversized molecules had the entired SV40 sequences. The added DNA was heterogeneous in length. The sites of addition were not specific with reference to the EcoRi site. These results suggest that recombination between monkey and SV40 DNAs or partial duplication of SV40 DNA occurs at many sites on the SV40 chromosome. The integrated SV40 DNA is excised and replicates in activated heterokaryons. In this system, besides SV40 DNA we found heterogeneous undersized and oversized molecules containing SV40 sequences in the closed circular DNA population. Additions differeing in size appeared to be overlapping and to have occurred at a preferential site on the SV40 chromosome. These results support the hypothesis that host DNA can be added to SV40 DNA at the site of integration at the time of excision.