Recognition of single-stranded DNA by the bacteriophage T4-induced type II topoisomerase

The bacteriophage T4-induced type II DNA topoisomerase has been shown previously to make a reversible double strand break in DNA double helices. In addition, this enzyme is shown here to bind tightly and to cleave single-stranded DNA molecules. The evidence that the single-stranded DNA cleavage activity is intrinsic to the topoisomerase includes: 1) protein linkage to the 5' ends of the newly cleaved DNA; 2) coelution of essentially homogeneous topoisomerase and the DNA cleavage activity; 3) inhibition of both single-stranded DNA cleavage and double-stranded DNA relaxation by oxolinic acid; and 4) inhibition of duplex DNA relaxation by single-stranded DNA. The major cleavage sites on phi X174 viral DNA substrates have been mapped, and several cleavage sites analyzed to determine the exact nucleotide position of cleavage. Major cleavage sites are found very near the base of predicted hairpin helices in the single-stranded DNA substrates, suggesting that DNA secondary structure recognition is important in the cleavage reaction. On the other hand, there are also many weaker cleavage sites with no obvious sequence requirements. Many of the properties of the single-stranded DNA cleavage reaction examined here differ from those of the oxolinic acid-dependent, double-stranded DNA cleavage reaction catalyzed by the same enzyme.     

Structural studies of E. coli topoisomerase III-DNA complexes reveal a novel type IA topoisomerase-DNA conformational intermediate

Escherichia coli DNA topoisomerase III belongs to the type IA family of DNA topoisomerases, which transiently cleave single-stranded DNA (ssDNA) via a 5' phosphotyrosine intermediate. We have solved crystal structures of wild-type E. coli topoisomerase III bound to an eight-base ssDNA molecule in three different pH environments. The structures reveal the enzyme in three distinct conformational states while bound to DNA. One conformation resembles the one observed previously with a DNA-bound, catalytically inactive mutant of topoisomerase III where DNA binding realigns catalytic residues to form a functional active site. Another conformation represents a novel intermediate in which DNA is bound along the ssDNA-binding groove but does not enter the active site, which remains in a catalytically inactive, closed state. A third conformation shows an intermediate state where the enzyme is still in a closed state, but the ssDNA is starting to invade the active site. For the first time, the active site region in the presence of both the catalytic tyrosine and ssDNA substrate is revealed for a type IA DNA topoisomerase, although there is no evidence of ssDNA cleavage. Comparative analysis of the various conformational states suggests a sequence of domain movements undertaken by the enzyme upon substrate binding.     

Nuclease protection by Drosophila DNA topoisomerase II. Enzyme/DNA contacts at the strong topoisomerase II cleavage sites

A DNA consensus sequence for topoisomerase II cleavage sites was derived previously based on a statistical analysis of the nucleotide sequences around 16 sites that can be efficiently cleaved by Drosophila topoisomerase II (Sander, M., and Hsieh, T. (1985) Nucleic Acids Res. 13, 1057-1072). A synthetic 21-mer DNA sequence containing this cleavage consensus sequence was cloned into a plasmid vector, and DNA topoisomerase II can cleave this sequence at the position predicted by the cleavage consensus sequence. DNase I footprint analysis showed that topoisomerase II can protect a region of approximately 25 nucleotides in both strands of the duplex DNA, with the cleavage site located near the center of the protected region. Similar correlation between the DNase I footprints and strong topoisomerase II cleavage sites has been observed in the intergenic region of the divergent HSP70 genes. This analysis therefore suggests that the strong DNA cleavage sites of Drosophila topoisomerase II likely correspond to specific DNA-binding sites of this enzyme. Furthermore, the extent of DNA contacts made by this enzyme suggests that eucaryotic topoisomerase II, in contrast to bacterial DNA bacterial DNA gyrase, cannot form a complex with extensive DNA wrapping around the enzyme. The absence of DNA wrapping is probably the mechanistic basis for the lack of DNA supercoiling action for eucaryotic 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.     

Single-strand DNA cleavages by eukaryotic topoisomerase II

A new purification method for eukaryotic type II DNA topoisomerase (EC 5.99.1.3) is described, and the avian enzyme has been purified and characterized. An analysis of the cleavage reaction has revealed that topoisomerase II can be trapped as a DNA-enzyme covalent complex containing DNA with double-stranded and single-stranded breaks. The data indicate that DNA cleavage by topoisomerase II proceeds by two asymmetric single-stranded cleavage and resealing steps on opposite strands (separated by 4 bp) with independent probabilities of being trapped upon addition of a protein denaturant. Single-strand cleavages were directly demonstrated at both strong and weak topoisomerase II sites. Thus, a match to the vertebrate topoisomerase II consensus sequence (sequence; see text) (N is any base, and cleavage occurs between -1 and +1) [Spitzner, J.R., & Muller, M.T. (1988) Nucleic Acids Res. 16, 5533-5556)] does not predict whether a cleavage site will be single stranded or double stranded; however, sites cleaved by topoisomerase II that contain two conserved consensus bases (G residue at +2 and T at +4) generally yield double-strand cleavage whereas recognition sites lacking these two consensus elements yield single-strand cleavages. Finally, single-strand cleavages with topoisomerase II do not appear to be an artifact caused by damaged enzyme molecules since topoisomerase II in freshly prepared, crude extracts also shows the property of single-strand cleavages.     

Mechanism of strand passage by Escherichia coli topoisomerase I. The role of the required nick in catenation and knotting of duplex DNA

We studied the interaction between topoisomerase I and a nicked DNA substrate to determine how the nick permits Escherichia coli topoisomerase I to catenate and knot duplex DNA rings. The presence of just a single nick in a 6600-base pair DNA increased the amount of DNA bound to topoisomerase I by 6-fold. The enzyme acts at the nick, as shown by linearization of nicked circles and covalent attachment of an enzyme molecule opposite the nick. DNA breaks are also introduced by the enzyme at sites not opposite to a nick, but three orders of magnitude less efficiently. The break induced by the enzyme is within several base pairs of the nick and on the complementary strand, but the exact site cut is dictated by DNA sequence requirements. Because these sequence requirements are identical to those for cutting of single-stranded DNA, we conclude that the enzyme stabilizes a denatured region at the nick. Breaks in single-stranded DNA occur 98% of the time when a C residue is four bases to the 5' side unless G is adjacent and 5' to the break. For a DNA circle nicked at a unique location, the efficiency of DNA breakage opposite the nick correlates with the rate of catenation. We present a unified model for the relaxation, catenation, and knotting reactions of topoisomerase I in which the enzyme induces a break in a single-stranded region, but bridges that break with covalent and noncovalent interactions and allows passage of one duplex or single-stranded DNA segment.     

Minimal DNA duplex requirements for topoisomerase I-mediated cleavage in vitro

The minimal DNA duplex requirements for topoisomerase I-mediated cleavage at a specific binding sequence were determined by analyzing the interaction of the enzyme with sets of DNA substrates varying successively by single nucleotides at the 5'- or 3' end of either strand. Topoisomerase I cleavage experiments showed a minimal region of nine nucleotides on the scissile strand and five nucleotides on the noncleaved strand. On the scissile strand, seven of the nine nucleotides were situated upstream to the cleavage site, while all five nucleotides required on the non-cleaved strand were located to this side. The results suggested that topoisomerase I bound tightly to this region, stabilizing the DNA duplex extensively. On minimal substrates which were partially single-stranded downstream to the cleavage site, cleavage was suicidal, that is, the enzyme was able to cleave the substrates, but unable to perform the final religation.     

Strand specificity of the topoisomerase II mediated double-stranded DNA cleavage reaction

The strand specificity of topoisomerase II mediated DNA cleavage was analyzed at the nucleotide level by characterizing the enzyme's interaction with a strong DNA recognition site. This site was isolated from the promoter region of the extrachromosomal rRNA genes of Tetrahymena thermophila and was recognized by type II topoisomerases from a variety of phylogenetically diverse eukaryotic organisms, including Drosophila, Tetrahymena, and calf thymus. When incubated with this site, topoisomerase II was found to introduce single-stranded breaks (i.e., nicks) in addition to double-stranded breaks in the nucleic acid backbone. Although the nucleotide position of cleavage on both the noncoding and coding strands of the rDNA remained unchanged, the relative ratios of single- and double-stranded DNA breaks could be varied by altering reaction conditions. Under all conditions which promoted topoisomerase II mediated DNA nicking, the enzyme displayed a 3-10-fold specificity for cleavage at the noncoding strand of its recognition site. To determine whether this specificity of topoisomerase II was due to a faster forward rate of cleavage of the noncoding strand or a slower rate of its religation, a DNA religation assay was performed. Results indicated that both the noncoding and coding strands were religated by the enzyme at approximately the same rate. Therefore, the DNA strand preference of topoisomerase II appears to be embodied in the enzyme's forward cleavage reaction.     

Does topoisomerase II specifically recognize and cleave hairpins,cruciforms and crossovers of DNA?

DNA topoisomerase II is an enzyme that specializes in DNA disentanglement. It catalyzes the interconversion of DNA between different topological states. This event requires the passage of one duplex through another one via a transient double-strand break. Topoisomerase II is able to process any type of DNA, including structures such as DNA juxtapositions (crossovers), DNA hairpins or cruciforms, which are recognized with high specificity. In this review, we focused our attention on topoisomerase II recognizing DNA substrates that possess particular geometries. A strong cleavage site, as we identified in pBR322 DNA in the presence of ellipticine (site 22), appears to be characterized by a cruciform structure formed from two stable hairpins. The same sequence could also constitute a four-way junction structure stabilized by interactions involving ATC sequences. The latter have been shown to be able to promote Holliday junctions. We reviewed the recent literature that deals with the preferential recognition of crossovers by various topoisomerases. The single molecule relaxation experiments have demonstrated the differential abilities of the topoisomerases to recognize crossovers. It appears that enzymes, which distinguish the chirality of the crossovers, possess specialized domains dedicated to this function. We also stress that the formation of crossovers is dependent on the presence of adequate stabilizing sequences. Investigation of the impact of such structures on enzyme activity is important in order to both improve our knowledge of the mechanism of action of the topoisomerase II and to develop new inhibitors of this enzyme.     

Generation of a catalytic sequence-specific hybrid DNase

Hybrid nucleases consisting of an oligonucleotide fused to a unique site on the relatively nonspecific phosphodiesterase staphylococcal nuclease have been shown to sequence specifically cleave DNA. We have introduced mutations into the binding pocket of the nuclease which lower the kcat/Km of the enzyme. Hybrid nucleases generated from these mutants sequence selectively hydrolyze single-stranded DNA in a catalytic fashion, and under a much wider range of conditions than was previously possible. One such hybrid nuclease (Y113A, K116C) was able to site selectively cleave single-stranded M13mp7 DNA (7214 nt), primarily at one phosphodiester bond. Another hybrid nuclease (Y113A, L37A, K116C) catalyzed the hydrolysis of a 78-nt DNA substrate with a kcat of 1.2 min-1 and a Km of 120 nM. The effects of variations in the length and sequence of the oligonucleotide binding region were examined, as were changes in the length of the tether between the oligonucleotide and the enzyme. Cleavage specificity was also assayed as a function of substrate DNA primary and secondary structure and added poly(dA).     

Aggregates of oligo(dG) bind and inhibit topoisomerase II activity and induce formation of large networks.

DNA cleavage by eukaryotic type II DNA topoisomerase (EC 5.99.1.3) was strongly inhibited by an oligonucleotide containing 10 dGua residues. Catalytic activities of topoisomerase II, as measured by relaxation and decatenation reactions, were also inhibited by oligo(dG)10. Inhibition was specific to oligo(dG)10; other oligonucleotides, nucleotides, or single-stranded DNAs tested did not influence the activity of topoisomerase II. Oligo(dG)10 did not inhibit other activities such as restriction enzymes. Although the enzyme neither binds nor cleaves oligo(dG)10, inhibition can be explained by the finding that topoisomerase II binds tightly with aggregated oligo(dG) structures (estimated to contain between 20 and 30 molecules of monomeric oligo(dG)10) that form spontaneously prior to addition of enzyme. These aggregated oligo(dG)-topoisomerase complexes are large networks that can be pelleted by a 20-min centrifugation step in a Microfuge. Western blotting with a monoclonal antibody confirmed that topoisomerase II is trapped in these pellets. The ability of the enzyme to form large DNA-protein networks could be a biochemical mechanism by which topoisomerase II might promote or participate in chromosome condensation in vivo prior to mitosis.     

Universal restriction endonucleases: designing novel cleavage specificities by combining adapter oligodeoxynucleotide and enzyme moieties

Class IIS restriction endonucleases cleave double-stranded (ds) DNA at precise distances from their recognition sequences. A method is proposed which utilizes this separation between the recognition site and the cut site to allow a class IIS enzyme, e.g., FokI, to cleave practically any predetermined sequence by combining the enzyme with a properly designed oligodeoxynucleotide adapter. Such an adapter is constructed from the constant recognition site domain (a hairpin containing the ds sequence, e.g., GGATG CCTAC for FokI) and a variable, single-stranded (ss) domain complementary to the ss sequence to be cleaved (at 9 and 13 nucleotides on the paired strands from the recognition sequence in the example of FokI). The ss sequence designated to be cleaved could be provided by ss phage DNA (e.g., M13), gapped ds plasmids, or supercoiled ds plasmids that were alkali denatured and rapidly neutralized. Combination of all three components, namely the class IIS enzyme, the ss DNA target sequence, and the complementing adapter, would result in target DNA cleavage at the specific predetermined site. The target ss DNA could be converted to the precisely cleaved ds DNA by DNA polymerase, utilizing the adapter oligodeoxynucleotide as primer. This novel procedure represents the first example of changing enzyme specificity by synthetic design. A practically unlimited assortment of new restriction specificities could be produced. The method should have many specific and general applications when its numerous ramifications are exploited.     

Uncoupling the DNA cleavage and religation activities of topoisomerase II with a single-stranded nucleic acid substrate: evidence for an active enzyme-cleaved DNA intermediate

Following its cleavage of double-stranded DNA, topoisomerase II is covalently bound to the 5'-termini of both nucleic acid strands. However, in order to isolate this enzyme-cleaved DNA complex in the presence of magnesium (the enzyme's physiological divalent cation), reactions must be terminated by the addition of a strong protein denaturant such as sodium dodecyl sulfate (SDS). Because of the requirement for a protein denaturant, it is unclear whether DNA cleavage in this in vitro system takes place prior to or is induced by the addition of SDS. To distinguish between these two possibilities, experiments were carried out to determine whether topoisomerase II bound DNA contains 3'-OH termini prior to denaturation. This was accomplished by using circular single-stranded phi X174 DNA as a model substrate for the enzyme. As found previously for topoisomerase II mediated cleavage of double-stranded DNA, the enzyme was covalently linked to the 5'-termini of cleaved phi X174 molecules. Moreover, optimal reaction pH as well as optimal salt and magnesium concentrations was similar for the two substrates. In contrast to results with double-stranded molecules, single-stranded DNA cleavage increased with time, was not salt reversible, and did not require the presence of SDS. Furthermore, cleavage products generated in the absence of protein denaturant could be labeled at their 3'-OH DNA termini by incubation with terminal deoxynucleotidyltransferase and [alpha-32P]ddATP. Finally, cleaved phi X174 molecules could be joined to a radioactively labeled double-stranded oligonucleotide by a topoisomerase II mediated intermolecular ligation reaction.(ABSTRACT TRUNCATED AT 250 WORDS)     

Recognition sites of eukaryotic DNA topoisomerase I: DNA nucleotide sequencing analysis of topo I cleavage sites on SV40 DNA.

Eukaryotic DNA topoisomerase I introduces transient single-stranded breaks on double-stranded DNA and spontaneously breaks down single-stranded DNA. The cleavage sites on both single and double-stranded SV40 DNA have been determined by DNA sequencing. Consistent with other reports, the eukaryotic enzymes, in contrast to prokaryotic type I topoisomerases, links to the 3'-end of the cleaved DNA and generates a free 5'-hydroxyl end on the other half of the broken DNA strand. Both human and calf enzymes cleave SV40 DNA at the identical and specific sites. From 827 nucleotides sequenced, 68 cleavage sites were mapped. The majority of the cleavage sites were present on both double and single-stranded DNA at exactly the same nucleotide positions, suggesting that the DNA sequence is essential for enzyme recognition. By analyzing all the cleavage sequences, certain nucleotides are found to be less favored at the cleavage sites. There is a high probability to exclude G from positions -4, -2, -1 and +1, T from position -3, and A from position -1. These five positions (-4 to +1 oriented in the 5' to 3' direction) around the cleavage sites must interact intimately with topo I and thus are essential for enzyme recognition. One topo I cleavage site which shows atypical cleavage sequence maps in the middle of a palindromic sequence near the origin of SV40 DNA replication. It occurs only on single-stranded SV40 DNA, suggesting that the DNA hairpin can alter the cleavage specificity. The strongest cleavage site maps near the origin of SV40 DNA replication at nucleotide 31-32 and has a pentanucleotide sequence of 5'-TGACT-3'.     

Zinc (II) coordination in Escherichia coli DNA topoisomerase I is required for cleavable complex formation with DNA.

Escherichia coli DNA topoisomerase I catalyzes relaxation of negatively supercoiled DNA. The reaction proceeds through a covalent intermediate, the cleavable complex, in which the DNA is cleaved and the enzyme is linked to the DNA via a phosphotyrosine linkage. Each molecule of E. coli DNA topoisomerase I has been shown to have three tightly bound zinc(II) ions required for relaxation activity (Tse-Dinh, Y.-C., and Beran-Steed, R.K. (1988) J. Biol. Chem. 263, 15857-15859). It is shown here that Cd(II) could replace Zn(II) in reconstitution of active enzyme from apoprotein. The role of metal was analyzed by studying the partial reactions. The apoenzyme was deficient in sodium dodecyl sulfate-induced cleavage of supercoiled PM2 phage DNA. Formation of covalent complex with linear single-stranded DNA was also reduced in the absence of metal. However, the cleavage of small oligonucleotide was not affected, and the apoenzyme could religate the covalently bound oligonucleotide to another DNA molecule. Assay of noncovalent complex formation by retention of 5'-labeled DNA on filters showed that the apoenzyme was not inhibited in noncovalent binding to DNA. It is proposed that zinc(II) coordination in E. coli DNA topoisomerase I is required for the transition of the noncovalent complex with DNA to the cleavable state.     

Bacterial DNA topoisomerase I can relax positively supercoiled DNA containing a single-stranded loop

Using heteroduplex molecules formed from a pair of plasmids, one of which contains a small deletion relative to the other, it is shown that bacterial topoisomerase I can relax a positively supercoiled DNA if a short single-stranded loop is placed in the DNA. This result supports the postulate that the specificity of bacterial DNA topoisomerase I for negatively supercoiled DNA in its relaxation reaction derives from the requirement of a short single-stranded DNA segment in the active enzyme-substrate complex. Nucleolytic and chemical probing of complexes between bacterial DNA topoisomerase I and heteroduplex DNA molecules containing single-stranded loops ranging from 13 to 27 nucleotides in length suggests that the enzyme binds specifically to the region containing a single-stranded loop; the site of DNA cleavage by the topoisomerase appears to lie within the single-stranded loop, with the enzyme interacting with nucleotides on both sides of the point of cleavage.     

Effect of local DNA sequence on topoisomerase I cleavage in the presence or absence of camptothecin.

In order to investigate the mechanism of topoisomerase I inhibition by camptothecin, we studied the induction of DNA cleavage by purified mammalian DNA topoisomerase I in a series of oligonucleotides and analyzed the DNA sequence locations of preferred cleavage sites in the SV40 genome. The oligonucleotides were derived from the sequence of the major camptothecin-induced cleavage site in SV40 DNA (Jaxel, C., Kohn, K. W., and Pommier, Y. (1988) Nucleic Acids Res. 16, 11157 to 11170) with the cleaved bond in their center. DNA length was critical since cleavage was detectable only in 30 and 20 base pair-(bp) oligonucleotides, but not in a 12-bp oligonucleotide. Cleavage was at the same position in the oligonucleotides as in SV40 DNA. Its intensity was greater in the 30- than in the 20-bp oligonucleotide, indicating that sequences more than 10 bp away from the cleavage site may influence intensity. Camptothecin-induced DNA cleavage required duplex DNA since none of the single-stranded oligonucleotides were cleaved. Analysis of base preferences around topoisomerase I cleavage sites in SV40 DNA indicated that camptothecin stabilized topoisomerase I preferentially at sites having a G immediately 3' to the cleaved bond. Experiments with 30-bp oligonucleotides showed that camptothecin produced most intense cleavage in a complementary duplex having a G immediately 3' to the cleavage site. Weaker cleavage was observed in a complementary duplex in which the 3'G was replaced with a T. The identity of the 3' base, however, did not affect topoisomerase I-induced DNA cleavage in the absence of drug. These results indicate that camptothecin traps preferentially a subset of the enzyme cleavage sites, those having a G immediately 3' to the cleaved bond. This strong preference suggests that camptothecin binds reversibly to the DNA at topoisomerase I cleavage sites, in analogy to a model previously proposed for inhibitors of topoisomerase II (Capranico, G., Kohn, K.W., and Pommier, Y. (1990) Nucleic Acids Res. 18, 6611-6619).     

DNA abasic lesions in a different light: solution structure of an endogenous topoisomerase II poison

Topoisomerase II is the target for several anticancer drugs that "poison" the enzyme and convert it to a cellular toxin by increasing topoisomerase II-mediated DNA cleavage. In addition to these "exogenous topoisomerase II poisons," DNA lesions such as abasic sites act as "endogenous poisons" of the enzyme. Drugs and lesions are believed to stimulate DNA scission by altering the structure of the double helix within the cleavage site of the enzyme. However, the structural alterations that enhance cleavage are unknown. Since abasic sites are an intrinsic part of the genetic material, they represent an attractive model to assess DNA distortions that lead to altered topoisomerase II function. Therefore, the structure of a double-stranded dodecamer containing a tetrahydrofuran apurinic lesion at the +2 position of a topoisomerase II DNA cleavage site was determined by NMR spectroscopy. Three major features distinguished the apurinic structure ( = 0.095) from that of wild-type ( = 0.077). First, loss of base stacking at the lesion collapsed the major groove and reduced the distance between the two scissile phosphodiester bonds. Second, the apurinic lesion induced a bend that was centered about the topoisomerase II cleavage site. Third, the base immediately opposite the lesion was extrahelical and relocated to the minor groove. All of these structural alterations have the potential to influence interactions between topoisomerase II and its DNA substrate.     

DNA topoisomerase VI generates ATP-dependent double-strand breaks with two-nucleotide overhangs

A key step in the DNA transport by type II DNA topoisomerase is the formation of a double-strand break with the enzyme being covalently linked to the broken DNA ends (referred to as the cleavage complex). In the present study, we have analyzed the formation and structure of the cleavage complex catalyzed by Sufolobus shibatae DNA topoisomerase VI (topoVI), a member of the recently described type IIB DNA topoisomerase family. A purification procedure of a fully soluble recombinant topoVI was developed by expressing both subunits simultaneously in Escherichia coli. Using this recombinant enzyme, we observed that the formation of the double-strand breaks on supercoiled or linear DNA is strictly dependent on the presence of ATP or AMP-PNP. This result suggests that ATP binding is required to stabilize an enzyme conformation able to cleave the DNA backbone. The structure of cleavage complexes on a linear DNA fragment have been analyzed at the nucleotide level. Similarly to other type II DNA topoisomerases, topoVI is covalently attached to the 5'-ends of the broken DNA. However, sequence analysis of the double-strand breaks revealed that they are all characterized by staggered two-nucleotide long 5' overhangs, contrasting with the four-base staggered double-strand breaks catalyzed by type IIA DNA topoisomerases. While no clear consensus sequences surrounding the cleavage sites could be described, interestingly A and T nucleotides are highly represented on the 5' extensions, giving a first insight on the preferred sequences recognized by this type II DNA topoisomerase.     

Double-stranded DNA cleavage/religation reaction of eukaryotic topoisomerase II: evidence for a nicked DNA intermediate

The DNA cleavage reaction of eukaryotic topoisomerase II produces nicked DNA along with linear nucleic acid products. Therefore, relationships between the enzyme's DNA nicking and double-stranded cleavage reactions were determined. This was accomplished by altering the pH at which assays were performed. At pH 5.0 Drosophila melanogaster topoisomerase II generated predominantly (greater than 90%) single-stranded breaks in duplex DNA. With increasing pH, less single-stranded and more double-stranded cleavage was observed, regardless of the buffer or the divalent cation employed. As has been shown for double-stranded DNA cleavage, topoisomerase II was covalently bound to nicked DNA products, and enzyme-mediated single-stranded cleavage was salt reversible. Moreover, sites of single-stranded DNA breaks were identical with those mapped for double-stranded breaks. To further characterize the enzyme's cleavage mechanism, electron microscopy studies were performed. These experiments revealed that separate polypeptide chains were complexed with both ends of linear DNA molecules generated during cleavage reactions. Finally, by use of a novel religation assay [Osheroff, N., & Zechiedrich, E. L. (1987) Biochemistry 26, 4303-4309], it was shown that nicked DNA is an obligatory kinetic intermediate in the topoisomerase II mediated reunion of double-stranded breaks. Under the conditions employed, the apparent first-order rate constant for the religation of the first break was approximately 6-fold faster than that for the religation of the second break. The above results indicate that topoisomerase II carries out double-stranded DNA cleavage/religation by making two sequential single-stranded breaks in the nucleic acid backbone, each of which is mediated by a separate subunit of the homodimeric enzyme.