Correlation of enzyme-induced cleavage sites on negatively superhelical DNA between prokaryotic topoisomerase I and S1 nuclease

Negatively superhelical pNS1 DNA with a molecular weight of 2.55 MDa (4 kbp) was found to contain 13 specific, unbasepaired sites that are sensitive to a single-strand-specific S1 nuclease cleavage. The S1-cleavage occurred once at these sites. In the absence of added Mg2+, the topoisomerase I purified from Haemophilus gallinarum formed a complex with the superhelical pNS1 DNA which has a hidden strand cleavage. Extensive proteinase K digestion of the complex led to cleavage of the DNA chain. Then the proteinase K-cleaved product was digested with S1, which can cut the opposite strand at the preexisting strand cleavage to generate unit-length linear DNA. Restriction endonuclease analysis of the linear DNA shows that the topoisomerase-induced cleavage occurred once at ten specific sites on the DNA. The topoisomerase caused mainly single-strand cleavage at these sites, but infrequently also caused double-strand cleavage at the same sites. Of interest is the fact that these sites considerably coincide with the S1-cleavable, unbasepaired sites.     

Enhancement of S1 nuclease-susceptibility of negatively superhelical DNA by netropsin

It was evidenced that the antibiotic netropsin enhances the single-strand-specific nuclease S1-susceptibility of negatively superhelical DNA. In contrast, an intercalating drug inhibited S1 action on the superhelical DNA. Negatively superhelical DNA is known to possess several (or a number of) unbasepaired sites sensitive to S1 cleavage. S1 cleaves generally the DNA once at these sites to result in production of the full-length linear form. However netropsin-bound DNA had a tendency to be cleaved by S1 simultaneously at plural sites producing several species of linear DNAs smaller than full-length size.     

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.     

Mapping Topoisomerase Sites in Mitochondrial DNA with a Poisonous Mitochondrial Topoisomerase I (Top1mt)

Mitochondrial topoisomerase I (Top1mt) is a type IB topoisomerase present in vertebrates and exclusively targeted to mitochondria. Top1mt relaxes mitochondrial DNA (mtDNA) supercoiling by introducing transient cleavage complexes wherein the broken DNA strand swivels around the intact strand. Top1mt cleavage complexes (Top1mtcc) can be stabilized in vitro by camptothecin (CPT). However, CPT does not trap Top1mtcc efficiently in cells and is highly cytotoxic due to nuclear Top1 targeting. To map Top1mtcc on mtDNA in vivo and to overcome the limitations of CPT, we designed two substitutions (T546A and N550H) in Top1mt to stabilize Top1mtcc. We refer to the double-mutant enzyme as Top1mt*. Using retroviral transduction and ChIP-on-chip assays with Top1mt* in Top1mt knock-out murine embryonic fibroblasts, we demonstrate that Top1mt* forms high levels of cleavage complexes preferentially in the noncoding regulatory region of mtDNA, accumulating especially at the heavy strand replication origin O_H, in the ribosomal genes (12S and 16S) and at the light strand replication origin O_L. Expression of Top1mt* also caused rapid mtDNA depletion without affecting mitochondria mass, suggesting the existence of specific mitochondrial pathways for the removal of damaged mtDNA.     

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.     

Uptake of homologous single-stranded fragments by superhelical DNA: II. Characterization of the reaction

We have studied the association of superhelical DNA (RFI)³ of phage G4 with defined single-stranded fragments isolated after cleavage of viral (+) strands by endonuclease R · HaeIII. The sedimentation rates of complexes formed by uptake of different single-stranded restriction fragments by G4 RFI were consistent with the view that base-pairing between the two components causes unwinding of superhelical turns, with one negative superhelical turn removed for every ten nucleotide residues of third strand taken up. The combining ratio of superhelical DNA and a single specific fragment was close to unity.At high concentrations of salt, nitrocellulose filters efficiently retained complexes of superhelical DNA and homologous fragments, which provided the basis for a rapid assay, and permitted the estimation of the thermodynamic and kinetic parameters of strand uptake in vitro. The reaction is reversible, with an apparent K_eq of approximately 10⁶m^?1. Apparent rate constants, k₁, for uptake of different fragments (85 to 1100 nucleotides long) varied about fourfold, with no obvious relationship to the length of the fragment. In 10 mm-Tris · HCl (pH 7.5), 200 mm-NaCl, fragments were taken up most rapidly at about 75 °C. Under these conditions, the apparent k₁ for a fragment 250 nucleotides long was approximately 600 m^?1s^?1, which is two or three orders of magnitude slower than the calculated rate of association of complementary strands of that length. At physiological temperatures, appreciable rates of strand uptake were seen only at low concentrations of salt (4 mm-Na⁺ in 10 mm-Tris · HCl), and were one or two orders of magnitude less than the rate at 75 °C in 200 mm-NaCl. At a given concentration of counterion a threshold temperature exists above which the rate of reaction rises sharply from an undetectable level.Thermodynamic calculations indicate that the reaction is entropically driven, and that the rate is limited by a step exhibiting a positive entropy and enthalpy of activation. The data are consistent with a model for strand uptake in which the rate-limiting step is the unstacking of a small number of base-pairs in the superhelical DNA. Stabilization and extension of the nucleus of base-pairs formed with the incoming strand is favored by the decrease in free energy associated with removal of superhelical turns.     

Critical roles of tyrosyl‐DNA phosphodiesterases in cell tolerance to carnosol‐induced DNA damage

Carnosol is a natural compound with pharmacological action due to its anti‐cancer properties. However, the precise mechanism for its anti‐carcinogenic effect remains elusive. In this study, we used lymphoblastoid TK6 cell lines to identify the DNA damage and repair mechanisms of carnosol. Our results showed that carnosol induced DNA double‐strand breaks (DSBs). We also found that cells lacking tyrosyl‐DNA phosphodiesterase 1 (TDP1), an enzyme related to topoisomerase 1 (TOP1), and tyrosyl‐DNA phosphodiesterase 2 (TDP2), an enzyme related to topoisomerase 2 (TOP2), were supersensitive to carnosol. Carnosol was found to induce the formation of the TOP1‐DNA cleavage complex (TOP1cc) and TOP2‐DNA cleavage complex (TOP2cc). When comparing the accumulation of γ‐H2AX foci and the number of chromosomal aberrations (CAs) with wild‐type (WT) cells, the susceptivity of the TDP1^?/? and TDP2^?/? cells were associated with an increased DNA damage. Our results provided evidence of carnosol inducing DNA lesions in TK6 cells and demonstrated that the damage induced by carnosol was associated with abnormal topoisomerase activity. We conclude that TDP1 and TDP2 play important roles in the anti‐cancer effect of carnosol.     

Human DNA topoisomerase IIbeta binds and cleaves four-way junction DNA in vitro.

We have used gel retardation analysis to show that human DNA topoisomerase IIbeta can bind a 40 bp linear duplex containing a single DNA topoisomerase IIbeta cleavage site. Furthermore, we demonstrate for the first time that human DNA topoisomerase IIbeta binds to four-way junction DNA. This supports previous suggestions that topoisomerase II may be targeted to supercoiled DNA through the recognition of DNA cruciforms, helix-helix crossovers and hairpins. DNA topoisomerase IIbeta had a 4-fold higher affinity for the four-way junction than for the linear duplex, as demonstrated by protein titration and competition analysis. Furthermore, the DNA topoisomerase IIbeta:four-way junction complex was significantly more salt stable than the complex with linear DNA. The four-way junction contained potential topoisomerase IIbeta cleavage sites straddling the points of strand exchange, and indeed, topoisomerase IIbeta was able to cleave three of these four predicted sites. This indicates that topoiso-merase IIbeta can bind to the centre of the junction. Topoisomerase II has to bind both the transported and the gated DNA helices prior to strand passage, and it is possible that both helices are provided by the four-way junction in this case. The stable complex of DNA topoisomerase IIbeta with four-way junction DNA may provide an ideal substrate for further studies into the mechanism of substrate recognition and binding by DNA topoisomerase II.     

Base mutation analysis of topoisomerase II-idarubicin-DNA ternary complex formation. Evidence for enzyme subunit cooperativity in DNA cleavage.

Antitumor drugs, such as anthracyclines, interfere with mammalian DNA topoisomerase II by forming a ternary complex, DNA-drug-enzyme, in which DNA strands are cleaved and covalently linked to the enzyme. In this work, a synthetic 36-bp DNA oligomer derived from SV40 and mutated variants were used to determine the effects of base mutations on DNA cleavage levels produced by murine topoisomerase II with and without idarubicin. Although site competition could affect cleavage levels, mutation effects were rather similar among several cleavage sites. The major sequence determinants of topoisomerase II DNA cleavage without drugs are up to five base pairs apart from the strand cut, suggesting that DNA protein contacts involving these bases are particularly critical for DNA site recognition. Cleavage sites with adenines at positions -1 were detected without idarubicin only under conditions favouring enzyme binding to DNA, showing that these sites are low affinity sites for topoisomerase II DNA cleavage and/or binding. Moreover, the results indicated that the sequence 5'-(A)TA/(A)-3' (the slash indicates the cleaved bond, parenthesis indicate conditioned preference) from -3 to +1 positions constitutes the complete base sequence preferred by anthracyclines. An important finding was that mutations that improve the fit to the above consensus on one strand can also increase cleavage on the opposite strand, suggesting that a drug molecule may effectively interact with one enzyme subunit only and trap the whole dimeric enzyme. These findings documented that DNA recognition by topoisomerase II may occur at one or the other strand, and not necessarily at both of them, and that the two subunits can act cooperatively to cleave a double helix.     

Topological complexes between DNA and topoisomerase II and effects of polyamines

The polyamines spermine and spermidine were found to enhance the formation of a stable noncovalent complex between mammalian topoisomerase II and DNA. This complex is not associated with DNA strand breaks and forms to a greater extent with supercoiled than with relaxed circular or with linear DNA. Polyamine-induced complex formation is associated with a stimulation of the enzymatic relaxation of DNA supercoils. In these respects, the polyamine-enhanced complex differs from the covalent cleavable complexes stabilized by DNA intercalators such as amsacrine (m-AMSA) or epipodophylotoxins such as teniposide (VM-26). In the polyamine-enhanced complex, the topoisomerase II may be a donutlike structure topologically bound to the DNA and able to migrate and dissociate from the ends of linear DNA molecules. At relatively high concentrations, spermine (1 mM) enhances topoisomerase II induced cleavage at certain sites on the SV40 genome that could have regulatory significance.     

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.     

Structure of F-actin needles from extracts of sea urchin oocytes

The mouse L-cell line LD maintains its mitochondrial DNA genome in the form of a head-to-tail unicircular dimer of the monomeric 16,000 base-pair species. This situation permits a comparison of the mechanism of replication of this dimeric molecule with our previous studies of replication of monomeric mouse L-cell mitochondrial DNA. Whereas monomeric mitochondrial DNA requires about one hour for a round of replication, the dimeric molecule requires almost three hours. Denaturing agarose gel electrophoretic analyses of replicative intermediates reveals several discrete size classes of partially replicated daughter strands of dimeric mitochondrial DNA. This suggests that replication occurs with specific discontinuities in the rate of daughter strand synthesis. The strand specificity of these daughter strands was determined by hybridization with ³²P-labeled DNA representing either the heavy or light strand mitochondrial DNA sequence. The sizes and strand specificities of these discrete daughter strands indicate that the same set of control sequences is functional in both dimer and monomer mitochondrial DNA replication.Immediately following a round of replication, the majority of dimeric mitochondrial DNA molecules contain displacement loops, as assessed by their sensitivity to nicking within the displaced DNA strand by single-strand DNA specific S₁ nuclease under conditions which leave supercoiled DNA intact. This result is in contrast with the conformation of newly replicated monomeric mitochondrial DNA molecules, which lack both superhelical turns and displacement loops. This indicates that dimeric mitochondrial DNA proceeds through a different series of post-replicative processing steps than does monomeric mitochondrial DNA. We postulate that intermediates at late stages of dimeric mitochondrial DNA replication contain displacement loops which remain intact following closure of the full-length daughter strands.     

Patterns of strongly protein-associated simian virus 40 DNA replication intermediates resulting from exposures to specific topoisomerase poisons

Exposure of infected CV-1 cells to specific type I and type II topoisomerase poisons caused strong protein association with distinct subsets of simian virus 40 (SV40) DNA replication intermediates. On the basis of the known specificity and mechanisms of action of these drugs, the proteins involved are assumed to be the respective topoisomerases. Camptothecin, a topoisomerase I poison, caused strong protein association with form II (relaxed circular) and form III (linear) viral genomes and replication intermediates having broken DNA replication forks but not with form I (superhelical) viral DNA or normal late replication intermediates which were present. In contrast, type II topoisomerase poisons caused completely replicated forms and late viral replication forms to be tightly bound to protein--some to a greater extent than others. Different type II topoisomerase inhibitors caused distinctive patterns of protein association with the replication intermediates present. Both intercalating and nonintercalating type II topoisomerase poisons caused a small amount of form I (superhelical) SV40 DNA to be protein-associated in vivo. The protein complex with form I viral DNA was entirely drug-dependent and strong, but apparently noncovalent. The protein associated with form I DNA may represent a drug-stabilized "topological complex" between type II topoisomerase and SV40 DNA.     

Characterization of a rearrangement in viral DNA: mapping of the circular simian virus 40-like DNA containing a triplication of a specific one-third of the viral genome

Serial passage of the non-defective form of a simian virus 40-like virus (DAR) isolated from human brain results in the appearance of three distinct classes of supercoiled DNAs: R_I resistant, R_I sensitive (one cleavage site) and R_I “supersensitive” (three cleavage sites). The R_I cleavage product of the “super sensitive” form is one-third the physical size of simian virus 40 DNA (10.4 S) and reassociates about three times more rapidly than “standard” viral DNA. To identify the portions of the DAR genome present in the 10.4 S segment, the plus strand of each of the 11 fragments of ³²P-labeled simian virus 40 DNA, produced by cleavage with the Hemophilus influenzae restriction endonuclease, was hybridized in solution with the sheared R_I cleavage product of the “supersensitive” class of viral DNA. Reaction was observed with fragments located in two distinct regions of the simian virus 40 genome: (1) Hin-A and C; (2) Hin-G, J, F and K.Further studies indicated that simian virus 40 complementary RNA transcribed in vitro with Escherichia coli RNA polymerase from one strand of simian virus 40 DNA reacts with both strands of the denatured 10.4 S cleavage product when hybridization is monitored with hydroxyapatite. Treatment of the 10.4 S DNA-simian virus 40 cRNA hybrid with the single-strand spcific nuclease, S₁, converted approximately 50% of the radioactive counts to an acid-soluble product. These results indicate that the 10.4 S product contains a transposition of sequences originally present on one of the DAR DNA strands to the other strand. Examination of heteroduplexes formed between the 10.4 S segment and unique linear forms of DAR DNA produced with the R · Eco RI restriction endonuclease have confirmed these observations. Thus it appears that a molecular rearrangement(s) has resulted in the recombination and inversion of viral DNA sequences from two separate loci on the parental DAR genome. This 1.1 × 10⁶ dalton segment is reiterated three times in a supercoiled molecule equivalent in physical size to parental DAR DNA.     

Specificity of the S1 nuclease from Aspergillus oryzae.

Conditions are described for digesting single-stranded DNA by S1 nuclease without introducing breaks in double-stranded DNA. The enzyme is inhibited by low concentrations of various compounds of phosphate. Under certain conditions S1 nuclease cleaves the strand opposite a nick in bacteriophage T5 DNA; under other conditions, the enzyme cleaves a loop in one strand of heteroduplex lambdaDNA while leaving the opposite strand intact. S1 nuclease makes many single strand breaks in ultraviolet-irradiated duplex lambdaDNA. Superhelical DNA of phiX174 (Form I) is converted first to a relaxed circular molecule (Form II), and then to a linear molecule (Form III) by cleavage at one site per molecule. Since the cleavage occurs at many sites in the population of molecules, the partially single-stranded regions in phiX174 superhelical DNA are not determined by specific nucleotide sequences.     

Uptake of homologous single-stranded fragments by superhelical DNA. III. The product and its enzymic conversion to a recombinant molecule

When superhelical DNA (RFI)² of phages φX174 or G4 takes up a homologous single-stranded fragment, RF DNA and fragment are linked by as many as 300 base-pairs, and a corresponding length of one strand of the RFI is displaced, forming a displacement loop (D-loop). The length of the base-paired region was estimated from the fraction of the associated ³²P-labeled fragment that was resistant to digestion by exonuclease VII, as well as by electron microscopy. Dissociation of the fragment by heating was characterized by a sharp melting curve. The displaced strand of the RF DNA was digested by two endonucleases that act on single-stranded DNA, the S₁ nuclease of Aspergillus oryzae and the recBC DNAase of Escherichia coli. Acting on complexes, both enzymes converted the form I [³H]DNA into form II DNA, and left some of the associated ³²P-labeled fragment undigested. The remaining ³²P-labeled fragment could no longer be displaced by branch migration, as expected if the displaced strand of the RF DNA were digested. The action of S₁ nuclease also produced the amount of acid-soluble ³H expected from digestion of the D-loop. Treatment of such digested complexes with polynucleotide ligase covalently linked about 35% of the remaining ³²P-labeled fragment to ³H-labeled strands, which proves that S₁ nuclease digested the D-loop.     

Basic residues at the C-gate of DNA gyrase are involved in DNA supercoiling

DNA gyrase is a type II topoisomerase that is responsible for maintaining the topological state of bacterial and some archaeal genomes. It uses an ATP-dependent two-gate strand-passage mechanism that is shared among all type II topoisomerases. During this process, DNA gyrase creates a transient break in the DNA, the G-segment, to form a cleavage complex. This allows a second DNA duplex, known as the T-segment, to pass through the broken G-segment. After the broken strand is religated, the T-segment is able to exit out of the enzyme through a gate called the C-gate. Although many steps of the type II topoisomerase mechanism have been studied extensively, many questions remain about how the T-segment ultimately exits out of the C-gate. A recent cryo-EM structure of Streptococcus pneumoniae GyrA shows a putative T-segment in close proximity to the C-gate, suggesting that residues in this region may be important for coordinating DNA exit from the enzyme. Here, we show through site-directed mutagenesis and biochemical characterization that three conserved basic residues in the C-gate of DNA gyrase are important for DNA supercoiling activity, but not for ATPase or cleavage activity. Together with the structural information previously published, our data suggest a model in which these residues cluster to form a positively charged region that facilitates T-segment passage into the cavity formed between the DNA gate and C-gate.