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.     

Synthesis of Superhelical Simian Virus 40 Deoxyribonucleic Acid in Cell Lysates*.

In vivo-labeled SV40 replicating DNA molecules can be converted into covalently closed superhelical SV40 DNA (SV40(I) using a lysate of sv40-infected monkey cells containing intact nuclei. Replication in vitro occurred at one-third the in vivo rate for 30 min at 30 degrees. After 1 hour of incubation, about 54% of the replicating molecules had been converted to SV40(I), 5% to nicked, circular molecules (SV40(II), 5% to covalently closed dimers; the remainder failed to complete replication although 75% of the prelabeled daughter strands had been elongated to one-genome length. Density labeling in vitro showed that all replicating molecules had participated during DNA synthesis in vitro. Velocity and equilibrium sedimentation analysis of pulse-chased and labeled DNA using radioactive and density labels suggested that SV40 DNA synthesis in vitro was a continuation of normal ongoing DNA synthesis. Initiation of new rounds of SV40 DNA replication was not detectable.     

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.     

Construction and analysis of viable deletion mutants of simian virus 40.

Viable mutants of simian virus 40 (SV40), with deletions ranging in size from 15 to 200 base pairs, have been obtained by infecting CV-1P cells with circularly permuted linear SV40 DNA. The linear DNA was produced by cleavage of closed circular DNA with DNase I in the presence of Mn2+, followed, in some cases, by mild digestion with lambda 5'-exonuclease. The SV40 map location and the size of each deletion were determined by using the S1 nuclease mapping procedure (Shenk et al., 1975) and the change in size of fragments produced by Hind II + III endonuclease cleavage. Deletions in at least three regions of the SV40 chromosome have slight or no effect on the rate or yield of viral multiplication and on vira-induced cellular transformation. These regions are located at the following coordinates on the SV40 physical map: 0.17 to 0.18; 0.54 to 0.59; and 0.68 to 0.74.     

Maturation of replicating simian virus 40 DNA molecules in isolated nuclei by continued bidirectional replication to the normal termination region.

Mature SV40 DNA synthesized for different periods of time either in isolated nuclei or in intact cells was highly purified and then digested with restriction endonucleases in order to relate the time of synthesis of newly replicated viral DNA to its location in the genome. Replication in nuclei supplemented with a cytosol fraction from uninfected cells was a faithful continuation of the bidirectional process observed in intact cells, but did not exhibit significant initiation of new replicons. SV40 DNA replication in cells at 37 degrees C proceeded at about 145 nucleotides/min per replication fork. In the absence of cytosol, when DNA synthesis was limited and joining of Okazaki fragments was retarded, bidirectional SV40 DNA replication continued into the normal region where separation yeilded circular duplex DNA molecules containing one or more interruptions in the nascent DNA strands. In the presence of cytosol, this type of viral DNA was shown to be a precursor of covalently closed, superhelical SV40 DNA, the mature from of viral DNA.     

Homologous pairing and topological linkage of DNA molecules by combined action of E. coli recA protein and topoisomerase I

E. coil RecA protein and topolsomerase I, acting on superhelical DNA and circular single strands in the presence of ATP and Mg²⁺, topologically link single-stranded molecules to one another, and single-stranded molecules to duplex DNA. When super-helical DNA is relaxed by prior incubation with topoisomerase, it is a poor substrate for catenation. Extensive homology stimulates the catenation of circular single-stranded DNA and superhelical DNA, whereas little reaction occurs between these forms of the closely related DNAs of phages φX174 and G4, indicating that, in conjunction with topoisomerase I, RecA protein can discriminate perfect or nearly perfect homology from a high degree of relatedness. Circular single-stranded G4 DNA reacts with superhelical DNA of a chimeric phage, M13Goril, to form catenanes, at least half of which survive heating at 80°C following restriction cleavage in the M13 region, but few of which survive following restriction cleavage in the G4 region. Electron microscopic examination of catenated molecules cleaved in the M13 region reveals that in most cases the single-stranded G4 DNA is joined to the linear duplex M13(G4) DNA in the homologous G4 region. The junction frequently has the appearance of a D loop, with an extent equivalent to 100 or more bp. We conclude that a significant fraction of catenanes were hemicatenanes, in which the single-stranded circle was topologically linked, probably by multiple turns, to its complementary strand in the duplex DNA. These observations support the previous conclusion that RecA protein can pair a single strand with its complementary strand in duplex DNA in a side-by-side fashion without a free end in any of the three strands.     

Action of the S1 endonuclease from Aspergillus oryzae on simian virus 40 supercoiled component I DNA

The digestion products of superhelical component I of SV40 DNA incubated with various concentrations of nuclease S₁ from $\text{Aspergillus Oryzae}$, an enzyme specific for single-stranded nucleic acid, were studied. The enzyme shows a preference for supercoiled DNA I as opposed to relaxed DNA II molecules, and converts SV40 DNA I into linear molecules. Conditions have been developed under which the majority of SV40 DNA I molecules is converted into form II DNA. By using high concentrations of enzyme, it was possible to introduce further breaks in the DNA molecule; by increasing ionic strengh or using SDS this activity was not eliminated.     

Interaction of the UvrABC endonuclease with DNA containing a psoralen monoadduct or cross-link. Differential effects of superhelical density and comparison of preincision complexes.

The effect of negative supercoiling on UvrABC incision of covalently closed duplex DNA circles containing either a furan-side monoadduct or a cross-link of 4'-hydroxymethyl-4,5',8-trimethylpsoralen at a unique site was examined. The rate of UvrABC incision of these DNA substrates was measured as a function of superhelical density, sigma, for values of sigma between 0 and -0.050. The monoadducted DNA substrate was incised at close to the maximum rate at all superhelical densities, with only a slight stimulation of activity between sigma = 0 and -0.035. In contrast, efficient UvrABC incision of the cross-linked DNA substrate required the DNA to be underwound, and activity showed a linear dependence on superhelical density up to sigma = -0.035. DNase I protection studies show that in the presence of both UvrA and UvrB a protein complex binds to the site of a psoralen monoadduct or cross-link in linear DNA. This UvrA-UvrB-dependent complex binds with similar affinity to both the monoadducted and the cross-linked DNA helices. However, differences in the DNase I footprint on these two DNA substrates indicate that the interaction of this protein complex is different at these two lesions. The addition of UvrC to linear DNA molecules that are saturated at the site of the lesion with the UvrA-UvrB-dependent complex resulted in efficient nicking of the monoadducted DNA, but not the cross-linked DNA. Thus, the properties of a DNA lesion site that lead to UvrAB recognition and binding are not necessarily sufficient to allow incision when all three Uvr subunits are present. We propose that after recognition and binding of a lesion site by the UvrAB complex and prior to incision, the damaged DNA helix undergoes a conformational change such as unwinding or melting that is induced by the lesion-bound Uvr complex.     

Action of S1 nuclease on nicked circular simian virus 40 DNA.

SV40 DNA form II (FO II) containing on average more than one single strand nick per molecule was treated with S₁ nuclease. Linear duplex molecules of unit length (FO III) were generated at enzyme concentrations sufficient to achieve 95% hydrolysis of at least 100 times the amount of single-stranded DNA. Therefore, S₁ nuclease introduces under the described conditions only one double strand break per molecule despite the presence of several single strand nicks.     

Nuclease S1 cleavage and the primary structure of mitochondrial DNA.

The single-strand-specific nuclease S1 from Aspergillus oryzae rapidly converts superhelical mitochondrial DNA (African Green Monkey cells, Vero ATCC; CCL 81) into nicked circular DNA. These nicked mitochondrial DNA molecules contain two nicks, one in each strand. The phosphodiester backbones are cleaved during this reaction at or near sites that are alkali-labile. In a second slow reaction the circular mitochondrial DNA is converted into a linear duplex DNA. Permutation tests indicate that this linear DNA represents a nonpermutated collection of DNA molecules. These results suggest that two of the alkai-labile sites in the phosphodiester backbones of the mitochondrial chromosome are closely spaced on opposite strands and at specific positions.     

Purification and properties of extracellular nuclease from tobacco pollen

Proteins diffusing from tobacco pollen grains exhibit different phosphohydrolytic activities. Molecular sieving produces nuclease fractionation into forms I, II and III with apparent molecular masses ≥ 60 × 10³, 32.9 × 10³ and 24.6 × 10³, respectively, and separation of principal forms II and III from phosphatase and major part of 5′- and 3′-nucleotidase activities. These forms did not differ in the mode of substrate attack and were combined for further enzyme characterization. The preparation had 3′-nueleotidase activity even after further purification by DEAE-cellulose chromatography. The enzyme is an endonuclease with preference for single stranded molecules. The endolytical cleavage of native DNA occurs simultaneously in both strands and generates limit products of about 58 pairs of nucleotides. DNA duplex polymers are also cleaved by a terminally-directed, exonuclease-like process. The products of DNA degradation are oligonucleotides and 5′-mononucleotides. In the presence of NaCl, both endolytical and exonucleaselike activities on bihelical DNA are inhibited and the proportion of mono-to oligonucleotides produced increases. The enzyme can rapidly convert superhelical plasmid DNA to a nicked open circular form, and then to a unit-length linear molecule. On the basis of these properties and of those found earlier (sugar-unspecificity, acidic pH optimum, activation by Zn²⁺ ions), the extracellular nuclease of tobacco pollen can be classified as plant nuclease I (EC 3.1.30.x).     

SV40 chromatin structure is not essential for viral gene expression

The biological activity and the fate of SV40 DNA (minichromosomes, DNA I, DNA II, DNA III) were tested in culture cells by immunofluorescence staining and blot analysis. Following microinjection of 2-4 circular SV40 molecules (minichromosomes, DNA I, DNA II) into the cytoplasm or the nuclei of monkey and rat cells, T- and V-antigen synthesis was demonstrable in nearly every recipient cell. Only linear DNA induced T-antigen synthesis with a very low efficiency after cytoplasmic injection. This low activity correlates with a rapid degradation of DNA III in the recipient cells. Further modifications observed immediately after injection are relaxation of superhelical molecules and formation of high-Mr DNA. Assembly of the injected DNA into SV40 chromatin-like structure, however, occurred only late after early viral gene expression.     

Structure of Replicating Simian Virus 40 Deoxyribonucleic Acid Molecules

Properties of replicating simian virus 40 (SV40) deoxyribonucleic acid (DNA) have been examined by sedimentation analysis and by direct observation during a lytic cycle of infection of African green monkey kidney cells. Two types of replicating DNA molecules were observed in the electron microscope. One was an open structure containing two branch points, three branches, and no free ends whose length measurements were consistent with those expected for replicating SV40 DNA molecules. A second species had the same features as the open structure, but in addition it contained a superhelix in the unreplicated portion of the molecule. Eighty to ninety per cent of the replicative intermediates (RI) were in this latter configuration, and length measurements of these molecules also were consistent with replicating SV40 DNA. Replicating DNA molecules with this configuration have not been described previously. RI, when examined in ethidium bromide-cesium chloride (EB-CsCl) isopycnic gradients, banded in a heterogeneous manner. A fraction of the RI banded at the same density as circular SV40 DNA containing one or more single-strand nicks (component II). The remaining radioactive RI banded at densities higher than that of component II, and material was present at all densities between that of supercoiled double-stranded DNA (component I) and component II. When RI that banded at different densities in EB-CsCl were examined in alkaline gradients, cosedimentation of parental DNA and newly replicated DNA did not occur. All newly replicated DNA sedimented more slowly than did intact single-stranded SV40 DNA, a finding that is inconsistent with the rolling circle model of DNA replication. An inverse correlation exists between the extent of replication of the SV40 DNA and the banding density in EB-CsCl. Under alkaline conditions, the parental DNA strands that were contained in the RI sedimented as covalently closed structures. The sedimentation rates in alkali of the covalently closed parental DNA decreased as replication progressed. Based on these observations, some possible models for replication of SV40 DNA are proposed.     

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.     

DNA strand scission by the antitumor protein neocarzinostatin

The antibiotic protein, neocarzinostatin, induces the scission of DNA strands $\text{in vivo}$ and $\text{in vitro}$. HeLa cell DNA prelabelled with [¹⁴C] thymidine is cut into large pieces with a peak at 80–90S when cells are incubated with 0.5 to 5.0 μg/ml of highly purified neocarzinostatin. Incubation of the antibiotic (0.5 μg/ml) with [³H] SV40 DNA in the presence of 2-mercaptoethanol results in the conversion of superhelical DNA I to nicked circular duplex DNA II. At high levels of drug, smaller fragments of linear DNA are produced. Strand breaks are detected in both neutral and alkaline sucrose gradients, indicating that drug susceptibility is not due to alkali-labile bonds.     

Infectious linear DNA sequences replicating in simian virus 40-infected cells.

A new class of linear duplex DNA structures that contain simian virus 40 (SV40) DNA sequences and that are replicated during productive infection of cells with SV40 is described. These structures comprise up to 35% of the radioactively labeled DNA molecules that can be isolated by selective extraction. These molecules represent a unique size class corresponding to the length of an open SV40 DNA molecule (FO III), and they contain a heterogeneous population of DNA sequences either of host or of viral origin, as shown by restriction endonuclease analysis and nucleic acid hybridization. Part of the FO III DNA molecules contain viral-host DNA sequences covalently linked with each other. They start to replicate with the onset of SV40 superhelix replication 1 day after infection. Their rate of synthesis is most pronounced 3 days after infection when superhelix replication is already declining. Furthermore, they cannot be chased into other structures. At least a fraction of these molecules is infectious when administered together with DEAE-dextran to permissive cells. After intracellular circularization, superhelical DNA FO I with an aberrant cleavage pattern accumulates. In addition, tumor and viral capsid antigen are induced, and infectious viral progeny is obtained. Infection of cells with purified SV40 FO I DNA does not result in FO III DNA molecules in the infected cells or in the viral progeny. It is suggested, therefore, that these FO III DNA molecules are perpetuated within SV40 virus pools by encapsidation into pseudovirions.     

Agarose gel electrophoretic analysis of damage to supercoiled DNA by adriamycin in the presence of beta-NADH dehydrogenase

In a cell-free system, the anticancer anthracycline antibiotic adriamycin was able to convert purified covalently closed circular, superhelical, form I bacteriophage PM2 DNA to relaxed circular form II DNA in the presence of either sodium borohydride (NaBH4), NADPH cytochrome P-450 reductase or beta-NADH dehydrogenase isolated from myocardial cells. There was no detectable increase in the amount of form III linear duplex DNA formed during the reaction even at high drug concentrations. Less drug was required for the conversion of form I to form II DNA in the presence of the enzymic reducing agents than in the presence of NaBH4. Form II DNA, prepared by irradiation using a Cs-137 source, was not degraded to form III linear duplex DNA. However, form I0 DNA, covalently closed circular DNA without superhelical turns, freshly prepared using topoisomerase I, was converted to form II DNA similar to the conversion of superhelical form I to form II DNA. Again, no increase in the amount of form III linear duplex DNA could be detected.     

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.     

Base-unpaired regions in supercoiled replicative form DNA of coliphage M13.

Superhelical covalently closed circular replicative form DNA (RF I) of coliphage M13 appears as a relaxed molecule that has a base-unpaired region in the form of a bubble (100 to 200 base pairs long) seen in electron micrographs when spread in the presence of formaldehyde and formamide or after pretreatment with glyoxal. S1 endonuclease, specific for single-stranded DNA, converts superhelical M13 RF I DNA, but not nonsuperhelical M13 RF I to a significant extent, into unit-length linear molecules by sequential nicking of two strands. The locations of S1 nuclease-susceptible sites and glyoxal-fixed base-unpaired regions were both related to the five A-T-rich regions in M13 RF DNA. While S1 nuclease does not show preference for any of these sites, glyoxal-fixed bubbles occur predominantly at the major A-T-rich region in M13 RF DNA.