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.     

Electrophoretic analysis of covalently closed SV40 DNA: Boltzmann distributions of DNA species.

Covalently closed relaxed SV40 DNA [SV40(I')] generated by polynucleotide ligase closure of nicked circular SV40 DNA was analyzed by agarose gel electrophoresis. The DNA can be resolved into a series of bands differing in superhelical density whose intensities are approximately symmetrical about a central most intense band. Densitometric analysis of the gel pattern has revealed that the distribution of DNA species conforms to a Boltzmann distribution and has enabled us to derive an equation for the free energy of superhelix formation for SV40 DNA. We believe the observed bands reflect the time-averaged distribution of thermally induced fluctuations in DNA chain conformation in solution at the time of ligase catalyzed phosphodiester bond formation. Densitometric analysis of native supercoiled SV40 DNA, partially unwound in the presence of ethidium bromide, demonstrates that the separation between adjacent bands is approximately half that seen with SV40(I'). Agarose gel electrophoresis was also used to measure the change in average base rotation angle as a function of temperature by a procedure independent of ethidium dye binding.     

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.     

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.     

Comparison of ethidium bromide and 4′,6-diamidino-2-phenylindole as quantitative fluorescent stains for DNA in agarose gels

Two methods of quantitative, fluorescent detection of DNA bands in agarose gels separated by electrophoresis were evaluated for sensitivity and linearity of response. Comparisons of ethidium bromide staining with a method using 4′,6-diamidino-2-phenylindole (DAPI) developed in this work showed that DAPI is several times more sensitive than ethidium bromide in conditions of comparable background flourescence. Optimum flourescent staining and detection conditions for DNA bands in agarose gels using DAPI are desctribed, and advantages of this method over other fluorescent detection methods are discussed.     

Unwinding of Parental Strands During Simian Virus 40 DNA Replication

Pools of young (less than 60% replicated) and mature (60-90% replicated) replicating molecules of simian virus 40 (SV40) DNA have been treated at pH 12.2 in order to dissociate growing chains from the parental strands. The molecules are neutralized so that the parental strands can reassociate and they have then been isolated. They are covalently closed structures which sediment rapidly in alkaline sucrose gradients; however, the sedimentation rates are less than the sedimentation rate of SV40 DNA I. Isopycnic banding in CsCl-ethidium bromide and sedimentation velocity studies in the presence of various amounts of ethidium bromide indicate that these structures contain negative superhelical turns and several-fold-higher superhelix densities than SV40 DNA I (the covalently closed DNA molecule). These structures are those that would be predicted if nicking, unwinding, and sealing of the parental strands occurred as replication proceeded. These experiments provide a direct demonstration that there is a progressive decrease in the topological winding number which accompanies SV40 DNA replication.     

Interaction between SV40 DNA and camptothecin, an antitumor alkaloid

Camptothecin specifically interacted with closed superhelical circular SV40 DNA during incubation in 1.0 M NaCl at 37 degrees C and induced an alkali-labile linkage in the E strand. No interaction occurred in the reaction mixture containing 0.1 M NaCl, or at 4 degrees C. As camptothecin did not affect linear SV40 DNA, the superhelical structure of DNA appeared to be essential. The site of the alkali-labile linkage induced in SV40 DNA I through interaction with camptothecin was near the origin of replication on the basis of the results of experiments with restriction enzymes. Neither sulfhydryl reagents nor EDTA affected the interaction between camptothecin and SV40 DNA I, so the action of camptothecin is different from those of antitumor antibiotics, bleomycin or neocarzinostatin. Analysis of the s20,0w value of SV40 DNA I after the interaction with camptothecin and the sedimentation profiles of DNA after heating in the reaction mixture indicated that the interaction between camptothecin and SV40 DNA I was different from those of intercalating or alkylating agents such as ethidium bromide and methylmethanesulfonate. Replacement of the OH group at C-20 in the E ring of camptothecin by H-, CH3-, and Cl- resulted in the reduction, in this order, of the potency for interaction with SV40 DNA I to induce an alkali-labile linkage.     

Inhibition of DNA synthesis by aphidicolin induces supercoiling in simian virus 40 replicative intermediates.

Highly torsionally stressed replicative intermediate SV40 DNA molecules are produced when ongoing replicative DNA synthesis is inhibited by aphidicolin, a specific inhibitor of DNA polymerase alpha. The high negative superhelical density of these molecules can be partially released by intercalating drugs such as chloroquine or ethidium bromide. The torsionally stressed replicative intermediates bind to monoclonal anti-Z-DNA antibodies. Electron microscopy of anti-Z-DNA cross-linked to torsionally stressed replicative intermediates shows that the antibody specifically binds close to the replication forks. The superhelical structures are not formed when SV40 DNA replication is inhibited by both aphidicolin and novobiocin, suggesting that a topoisomerase type II-like enzyme is somehow involved in the introduction of torsional strain in replicative intermediate DNA. One interpretation of our data is that fork movement continues to some rather limited extent when SV40 DNA synthesis in replicative chromatin is blocked by aphidicolin. After deproteinization, the exposed single-stranded DNA branches reassociate to form paranemic DNA structures with left-handed helical stretches, while the reduced linking number of the parental strands induces a high negative superhelical density.     

Comparison of JC and BK Human Papovaviruses with Simian Virus 40: Restriction Endonuclease Digestion and Gel Electrophoresis of Resultant Fragments

JC virus was found to have a buoyant density of 1.20 g/cm(3) in linear sucrose-D(2)O and 1.35 g/cm(3) in cesium chloride isopycnic gradients. DNA extracted either from JC-infected cultures or from gradient-purified virions occupied a dense position relative to linear DNA in cesium chloride/ethidium bromide gradients, and the circular configuration of the extracted DNA was confirmed by electron microscopy, with a measured molecular weight of 2.93 x 10(6). DNA from BK virus was similarly prepared and compared to JC and to an SV40 DNA standard by digestion with restriction endonuclease preparations from Haemophilus influenzae, Haemophilus parainfluenzae, and Escherichia coli. Digests were electrophoretically analyzed on gradient polyacrylamide slab gels or agarose gels, and the three viruses were found to have distinctly different cleavage patterns by this form of analysis: JC and BK viruses were almost entirely different from SV40 and significantly different from each other. Thus, JC and BK human papovaviruses appear to be discrete new members of the papovavirus group, rather than SV40 variants.     

Interaction of histone H1 with superhelical DNA. Sedimentation and electron microscopical studies at low salt concentration

Complexes of histones H1 with superhelical SV40 DNA obtained by direct mixing were studied in 0.1 SSC buffer corresponding to 0.02 M Na+. Depending on the molar input ratio H1/DNA three classes of sedimenting species were observed: (1) a component sedimenting similar to superhelical DNA with a sedimentation coefficient s2o,w of 25 S observable up to 335 Mol H1/Mol DNA (w/w = 2); (2) a component with s2o,w = 120 S appearing at 135 Mol H1/Mol DNA and (3) growing amounts of heterogeneous aggregates greater than 1000 S. Electron micrographs revealed the 25 S component to consist of double-fibers formed from one DNA molecule and the 120 S component to consist of bundles of several such double-fibers. The aggregates represent cable-like structures. The addition of ethidium bromide to 25 S complexes induces the formation of bundles, if H1 is present in a quantity which alone is not sufficient to bring about this effect. This result indicates that ethidium bromide effects a redistribution of H1 molecules and that H1 is responsible for the bundle formation.     

DNA staining in agarose gels with Zn²+-cyclen-pyrene

A pyrene-labeled Zn2+-cyclen complex for the staining of DNA in agarose gels is reported. The metal chelate coordinates reversibly to the DNA phosphate backbone, which induces the formation of pyrene excimers. The typical pyrene excimer emission is used for the detection of the DNA. Staining is limited to agarose gels and is less sensitive than ethidium bromide, but DNA amounts as low as 10 ng and short DNA strands (～300 b.p.) are detectable. Gel extraction as a standard technique in molecular biology was successfully performed after staining with Zn2+-cyclen-pyrene. Cytotoxicity tests on HeLa and V-79 cells reveal that the zinc-cyclen pyrene probe is significant less toxic compared to ethidium bromide.     

Effects of the pSC101 partition (par) locus on in vivo DNA supercoiling near the plasmid replication origin.

Previous work has shown that deletion of the partition (par) locus of plasmid pSC101 results in decreased overall superhelical density of plasmid DNA and concommitant inability of the plasmid to be stably inherited in populations of dividing cells. We report here that the biological effects of par correlate specifically with its ability to generate supercoils in vivo near the origin of pSC101 DNA replication. Using OsO4 reactivity of nucleotides adjoining 20 bp (G-C) tracts introduced into pSC101 DNA to measure local DNA supercoiling, we found that the wild type par locus generates supercoiling near the plasmid's replication origin adequate to convert a (G-C) tract in the region to Z form DNA. A 4 bp deletion that decreases par function, but produces no change in the overall superhelicity of pSC101 DNA as determined by chloroquine/agarose gel analysis, nevertheless reduced (G-C) tract supercoiling sufficiently to eliminate OsO4 reactivity. Mutation of the bacterial topA gene, which results in stabilized inheritance of par-deleted plasmids, restored supercoiling of (G-C) tracts in these plasmids and increased OsO4 reactivity in par+ replicons. Removal of par to a site more distant from the origin decreased supercoiling in a (G-C) tract adjacent to the origin and diminished par function. Collectively, these findings indicate that par activity is dependent on its ability to produce supercoiling at the replication origin rather than on the overall superhelical density of the plasmid DNA.     

DNA Staining in Agarose Gels with ZN2+-Cyclen-Pyrene

A pyrene-labeled Zn²⁺-cyclen complex for the staining of DNA in agarose gels is reported. The metal chelate coordinates reversibly to the DNA phosphate backbone, which induces the formation of pyrene excimers. The typical pyrene excimer emission is used for the detection of the DNA. Staining is limited to agarose gels and is less sensitive than ethidium bromide, but DNA amounts as low as 10 ng and short DNA strands (～300 b.p.) are detectable. Gel extraction as a standard technique in molecular biology was successfully performed after staining with Zn²⁺-cyclen-pyrene. Cytotoxicity tests on HeLa and V-79 cells reveal that the zinc-cyclen pyrene probe is significant less toxic compared to ethidium bromide.     

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.     

DNA staining in agarose and polyacrylamide gels by methyl green

ABSTRACT

Methyl green (MG) is an inexpensive, nonproprietary, traditional histological stain for cell nuclei. When bound to DNA and upon excitation with orange-red light, it fluoresces brightly in the far red region. We compared MG with ethidium bromide (EtBr), the conventional stain for DNA in gels, and Serva DNA stain G? (SDsG), a proprietary stain marketed as a safer alternative to EtBr for staining of electrophoresed DNA bands in agarose and polyacrylamide gels. DNA-MG fluorescence was recorded and 2.4 μg/ml MG produced crisp images of electrophoresed DNA after incubation for 10 min. Stain solutions were stable and detection limits for faint bands as well as relative densitometric quantitation were equivalent to EtBr. MG, EtBr and SDsG cost 0.0192, 0.024 and 157.5 US cents/test, respectively. MG is an effective stain for visualizing DNA in agarose and polyacrylamide gels. Its major advantages including low cost, comparable quality of staining, storage at room temperature, photo-resistance and low mutagenic profile outweigh its disadvantages such as staining of tracking dye and requirement for a gel documentation system with a red filter.     

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.     

Structural state of newly replicated closed circular simian virus 40 DNA.

We have studied the early transition of newly replicated, segregated daughter molecules of simian virus 40 (SV40) into their mature, fully supercoiled state. The DNA of SV40 replicating in African green monkey kidney CV1 cells was chronically labeled with [14C]thymidine and pulse-labeled with [3H]thymidine. The cells were lysed and the viral DNA was isolated. Density gradient centrifugation of viral DNA in cesium chloride revealed that the pulse-labeled, newly synthesized, closed circular supercoiled DNA molecules banded at a slightly higher density (delta sigma = 0.0025) than the chronically labeled DNA, suggesting that the newly completed molecules were in a different structural state. Electrophoresis of DNA in agarose gels at appropriate chloroquine concentrations demonstrated that the mobility of the pulse-labeled closed, superhelical DNA was retarded relative to that of the chronically labeled DNA. These observations indicated that the newly completed SV40 DNA molecules existed in a structural state more relaxed than that of mature DNA by one or two linking numbers.     

Determination of plasmid copy number by fluorescence densitometry

A simple and reliable method for the determination of plasmid copy numbers by direct fluorescence densitometry of ethidium bromide-stained electrophoretic gels was developed. In developing the method, the following parameters were evaluated and controlled: plasmid DNA trapping in the linear chromosomal DNA, staining-destaining kinetics for ethidium bromide, linearity of the fluorescence response, and the effect of the molecular topology of DNA on ethidium bromide binding to DNA in agarose.     

Hybridization of labeled RNA to DNA in agarose gels.

Specific DNA restriction endonuclease fragments can be identified after electrophoresis in agarose gels by hybridization in the gel (in situ) to radioactive homologous RNA. RNA-DNA hybrids are detected by autoradiography of the gel. Comparison of band patterns of the autoradiogram and the ethidium bromide stained gel allows the identification of the DNA fragment which is complementary to the RNA probe. The technique is rapid, easy and inexpensive. It is sensitive enough to detect individual genes in a mixture of fragments produced by restriction enzyme digestion of complex cellular DNA. We have used this technique to determine which of the Hin III and Eco R1 fragments of phi80d3ilv+su+7 and E. coli DNAs contain the 5S, 16S and 23S ribosomal RNA (rRNA) genes of E. coli.