Author index

Properties of strand breakage in duplex and single-stranded DNA by the wheat germ type 1 DNA topoisomerase were investigated. Strand breakage in duplex DNA is dependent upon the use of denaturing conditions to inactivate the enzyme and terminate the reaction, whereas breakage of single-stranded DNA occurs under the normal reaction conditions and is not dependent upon denaturation. Breakage generates a free 5′ hydroxyl group and enzyme bound to the 3′ side of the break, presumably via the 3′ phosphate group. The location of sites of breakage with both duplex and single-stranded DNA is not random. In all these respects the wheat germ enzyme closely resembles the rat liver type 1 topoisomerase. A comparison of the locations of the sites of breakage in duplex DNA generated by the topoisomerases from wheat germ and rat liver indicates a number of common sites, although the patterns of breakage are not identical.     

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.     

DNA strand breakage by wheat germ type 1 topoisomerase

Properties of strand breakage in duplex and single-stranded DNA by the wheat germ type 1 DNA topoisomerase were investigated. Strand breakage in duplex DNA is dependent upon the use of denaturing conditions to inactivate the enzyme and terminate the reaction, whereas breakage of single-stranded DNA occurs under the normal reaction conditions and is not dependent upon denaturation. Breakage generates a free 5' hydroxyl group and enzyme bound to the 3' side of the break, presumably via the 3' phosphate group. The location of sites of breakage with both duplex and single-stranded DNA is not random. In all these respects the wheat germ enzyme closely resembles the rat liver type 1 topoisomerase. A comparison of the locations of the sites of breakage in duplex DNA generated by the topoisomerases from wheat germ and rat liver indicates a number of common sites, although the patterns of breakage are not identical.     

An essential role for sodium in the bicarbonate transporting system of the cyanobacterium Anabaena variabilis

The Eco dam methylase is active on denatured DNA and single-stranded synthetic oligonucleotides containing GATC sites. The results suggest that on interaction with single-stranded oligonucleotides the Eco dam methylase is able to form a duplex structure within the GATC site, and that this duplex site is a substrate for enzyme.     

Type I DNA topoisomerases from mammalian cell nuclei interlock strains and promote renaturation of denatured closed circular PM2 DNA

Type I DNA topoisomerases from mouse ascites cell nuclei and from rat liver cell nuclei act on denatured viral closed circular PM2 DNA to produce molecules with a highly contracted structure as well as fully duplex non-supercoiled covalently closed circular molecules. Highly contracted DNA molecules contain a novel type of topological linkage in which a strand in one region of the double-stranded molecule passes between the strands in another region of the circular molecule one or more times. Since it is also found that the action of the topoisomerase promotes renaturation of complementary strands in denatured closed circular DNA, it is suggested that formation of contracted DNA structures proceeds through renatured, duplex intermediates with highly negative superhelix densities that contain small single-stranded regions.     

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).     

Escherichia coli DNA topoisomerase I catalyzed linking of single-stranded rings of complementary base sequences

Eco DNA topoisomerase I (E. coli omega protein) has been observed to catalyze the formation of double-stranded, covalently closed DNA from complementary single-stranded DNA rings, a novel reaction which is topologically forbidden without the enzyme-catalyzed breakage and rejoining of DNA backbone bonds. Incubation of a mixture of single-stranded PM2 DNA rings of complementary base sequences with omega yields a species with a sedimentation coefficient in an alkaline medium characteristic of a covalently closed circular double-stranded DNA. Buoyant density measurements in CsCl at alkaline pH also identify the product as a covalently closed duplex ring. If the omega-catalyzed reaction is stopped short of completion, highly negatively supercoiled molecules are formed which sediment more slowly in an alkaline medium than the final duplex product. As the reaction proceeds the mean sedimentation rate of the intermediates increases. This is in agreement with the expectation that the linking number between the two complementary rings increases gradually during the course of the reaction from zero to that of a relaxed covalently closed circular DNA duplex. The possible role of DNA topoisomerases in genetic recombination is discussed.     

Minimal DNA requirement for topoisomerase II-mediated cleavage in vitro

The minimal DNA requirement for topoisomerase II-mediated DNA cleavage in vitro was determined by analyzing the interaction of the enzyme with sets of DNA substrates varying successively by single bases at the 5'- or 3'-end of either strand. A 16-base pair double-stranded region was established as the minimal duplex region required for topoisomerase II cleavage activity. The region was located symmetrically around the 4-base staggered cleavage site. Topoisomerase II-mediated cleavage within the 16-base pair core duplex, however, required single-stranded regions flanking the duplex to either the 5'- or 3'-sides, or an extension at both ends of the duplex with 1 or more base pairs.     

Molecular mechanisms of the origin of chromosome aberrations and the structural organisation of eukaryotic DNA

Summary A new hypothesis on the appearance of exchange chromosomal aberrations has been suggested. According to this hypothesis, temporal duplex polynucleotide structure should arise during G₁ and G₂ phases during the correction of DNA. The size of the duplex, as a rule, should be restricted to the size of complementary nucleotide sequences in the regions of repetitions. Any polynucleotide break in a duplex zone would result in chromosome breakage and if complementary broken ends interact with each other, then exchange chromosome aberrations may be formed. This hypothesis would explain such previously obscure phenomena as extremely high frequencies of exchanges after mutagen treatment, the nature of mitotic crossing-over, negative interference, change of aberration types before replication, the low frequency of damaged structural genes during aberration formation, etc.     

Nucleotide sequence preference at rat liver and wheat germ type 1 DNA topoisomerase breakage sites in duplex SV40 DNA.

The site specificities of the type 1 DNA topoisomerases (topo 1) from rat liver and wheat germ were investigated. The nucleotide sequence at break sites on duplex SV40 DNA were determined for 245 wheat germ topo 1 sites and 223 rat liver topo 1 sites over a region of 1781 nucleotides. The enzymes from the two different sources show similar, but not identical patterns of DNA strand breakage. The sites occur frequently, but are not broken with equal probabilities. Major sites of breakage occur on the average every one to two turns of the helix, thus if sites of breakage accurately represent topo 1 sites of activity, the DNA sequence alone would appear to place few limits on the access of the enzyme to DNA. Sequences around the strongest sites for both enzymes show a bias in base composition for the four nucleotides immediately 5' to the break site (-4 to -1 positions), but no bias is observed 3' to the site of breakage. Consensus sequences for both enzymes were determined. Variations from the consensus sequence appear to affect the two enzymes differently and may account for the differences observed in the specificity of breakage.     

Titration of integrated simian virus 40 DNA sequences, using highly radioactive, single-stranded DNA probes.

Nick-translated simian virus 40 (SV40) [32P]DNA fragments (greater than 2 X 10(8) cpm/micrograms) were resolved into early- and late-strand nucleic acid sequences by hybridization with asymmetric SV40 complementary RNA. Both single-stranded DNA fractions contained less than 0.5% self-complementary sequences; both included [32P]-DNA sequences that derived from all regions of the SV40 genome. In contrast to asymmetric SV40 complementary RNA, both single-stranded [32P]DNAs annealed to viral [3H]DNA at a rate characteristic of SV40 DNA reassociation. Kinetics of reassociation between the single-stranded [32P]DNAs indicated that the two fractions contain greater than 90% of the total nucleotide sequences comprising the SV40 genome. These preparations were used as hybridization probes to detect small amounts of viral DNA integrated into the chromosomes of Chinese hamster cells transformed by SV40. Under the conditions used for hybridization titrations in solution (i.e., 10- to 50-fold excess of radioactive probe), as little as 1 pg of integrated SV40 DNA sequence was assayed quantitatively. Among the transformed cells analyzed, three clones contained approximately one viral genome equivalent of SV40 DNA per diploid cell DNA complement; three other clones contained between 1.2 and 1.6 viral genome equivalents of SV40 DNA; and one clone contained somewhat more than two viral genome equivalents of SV40 DNA. Preliminary restriction endonuclease maps of the integrated SV40 DNAs indicated that four clones contained viral DNA sequences located at a single, clone-specific chromosomal site. In three clones, the SV40 DNA sequences were located at two distinct chromosomal sites.     

Site-specific DNA cleavage by vaccinia virus DNA topoisomerase I. Role of nucleotide sequence and DNA secondary structure.

Cleavage of linear duplex DNA by purified vaccinia virus DNA topoisomerase I occurs at a conserved sequence element (5'-C/T)CCTT decreases) in the incised DNA strand. Oligonucleotides spanning the high affinity cleavage site CCCTT at nucleotide 2457 in pUC19 DNA are cleaved efficiently in vitro, but only when hybridized to a complementary DNA molecule. As few as 6 nucleotides proximal to the cleavage site and 6 nucleotides downstream of the site are sufficient to support exclusive cleavage at the high affinity site (position +1). Single nucleotide substitutions within the consensus pentamer have deleterious effects on the equilibria of the topoisomerase binding and DNA cleavage reactions. The effects of base mismatch within the pentamer are more dramatic than are the effects of mutations that preserve base complementarity. Competition experiments indicate that topoisomerase binds preferentially to DNA sites containing the wild-type pentamer element. Single-stranded DNA containing the sequence CCCTT in the cleaved stand is a more effective competitor than is single-stranded DNA containing the complementary sequence in the noncleaved strand.     

Topological linkage of circular DNA molecules promoted by Ustilago rec 1 protein and topoisomerase

We studied the formation of linked circular DNA molecules promoted by the combined action of rec 1 protein and type I topoisomerase of Ustilago maydis. When ATP was added as cofactor to reactions containing rec 1 protein, pairs of homologous circular DNA molecules became linked after addition of topoisomerase. Closed circular duplex molecules could be joined at homologous sites with circular single-stranded molecules or with other circular duplex molecules, provided that homologous single-stranded DNA fragments or RNA polymerase and nucleoside triphosphates were also added. Complexes formed were topologically linked through regions of heteroduplex DNA. When the analog adenylyl-imidodiphosphate was substituted for ATP, nonhomologous pairs of circular DNA molecules became linked.     

RecA protein-facilitated DNA strand breaks. A mechanism for bypassing DNA structural barriers during strand exchange

RecA protein promotes an unexpectedly efficient DNA strand exchange between circular single-stranded DNA and duplex DNAs containing short (50-400-base pair) heterologous sequences at the 5' (initiating) end. The major mechanism by which this topological barrier is bypassed involves DNA strand breakage. Breakage is both strand and position specific, occurring almost exclusively in the displaced (+) strand of the duplex within a 15-base pair region of the heterology/homology junction. Breakage also requires recA protein, ATP hydrolysis, and homologous sequences 3' to the heterology. Although the location of the breaks and the observed requirements clearly indicate a major role for recA protein in this phenomenon, the molecular mechanism is not yet clear. The breakage may reflect a DNA structure and/or some form of structural stress within the DNA during recA protein-mediated DNA pairing which either exposes the DNA at this precise position to the action of a contaminating nuclease or induces a direct mechanical break. We also find that when heterology is located at the 3' end of the linear duplex, strand exchange is halted (without DNA breakage) about 500 base pairs from the homology/heterology junction.     

Eukaryotic topoisomerase II cleavage of parallel stranded DNA tetraplexes.

A guanine-rich single-stranded DNA from the human immunoglobulin switch region was shown by Sen and Gilbert [Nature, (1988) 334, 364-366] to be able to self-associate to form a stable four-stranded parallel DNA structure. Topoisomerase II did not cleave the single-stranded DNA molecule. Surprisingly, the enzyme did cleave the same DNA sequence when it was annealed into the four-stranded structure. The two cleavage sites observed were the same as those found when this DNA molecule was paired with a complementary molecule to create a normal B-DNA duplex. These cleavages were shown to be protein-linked and reversible by the addition of salt, suggesting a normal topoisomerase II reaction mechanism. In addition, an eight-stranded DNA molecule created by the association of a complementary oligonucleotide with the four-stranded structure was also cleaved by topoisomerase II despite being resistant to restriction endonuclease digestion. These results suggest that a single strand of DNA may possess the sequence information to direct topoisomerase II to a binding site, but the site must be base paired in a proper manner to do so. This demonstration of the ability of a four-stranded DNA molecule to be a substrate for an enzyme further suggests that these DNA structures may be present in cells.     

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.     

Recognition and cleavage of hairpin structures in nucleic acids by oligodeoxynucleotides.

The possibility of designing antisense oligodeoxynucleotides complementary to non-adjacent single-stranded sequences containing hairpin structures was studied using a DNA model system. The structure and stability of complexes formed by a 17mer oligonucleotide with DNA fragments containing hairpin structures was investigated by spectroscopic measurements (melting curves) and chemical reactions (osmium tetroxide reaction, copper-phenanthroline cleavage). A three-way junction was formed when the oligonucleotide was bound to both sides of the hairpin structure. When the complementary sequences of the two parts of the oligonucleotide were separated by a sequence which could not form a hairpin, the oligonucleotide exhibited a slightly weaker binding than to the hairpin-containing target. An oligodeoxynucleotide-phenanthroline conjugate was designed to form Watson-Crick base pairs with two single-stranded regions flanking a hairpin structure in a DNA fragment. In the presence of Cu2+ ions and a reducing agent, two main cleavage sites were observed at the end of the duplex structure formed by the oligonucleotide-phenanthroline conjugate with its target sequence. Competition experiments showed that both parts of the oligonucleotide must be bound in order to observe sequence-specific cleavage. Cleavage was still observed with target sequences which could not form a hairpin, provided the reaction was carried out at lower temperatures. These results show that sequence-specific recognition and modification (cleavage) can be achieved with antisense oligonucleotides which bind to non-adjacent sequences in a single-stranded nucleic acid.     

Underwound loops in self-renatured DNA can be diagnostic of inverted duplications and translocated sequences

DNA that contains inverted duplications separated by non-inverted sequences often can form characteristic “underwound loops” when it is denatured and reannealed. An underwound loop is a partially double-stranded, partially denatured segment between the inverted duplications and is produced as follows. During the early stages of the reannealing, intrastrand stem-loop structures form with first-order kinetics when the inverted duplications pair. In a slower second-order reaction, complementary strands (each with a stem-loop) reanneal. The stem-loop structures produce a cruciform in the hybrid. Because of the unpaired sequences in the loop, the cruciform is unstable. It can isomerize to a linear duplex by double-strand exchange of complementary sequences in the stems. This process requires co-ordinated axial rotation of the stems and the flanking duplexes as well as rotation of the loops. If, however, complementary sequences in the loops start to pair, axial rotation is prevented and the stem-loop structures are trapped in a metastable state. The strands of separate, closed rings cannot interwind when they pair. Consequently, the loops observed by electron microscopy have variable patterns of single-stranded denaturation bubbles and duplex segments with both right-handed and left-handed winding.We have used underwound loops to identify a short inverted duplication flanking the γδ recombination sequence of Escherichia coli F factor (isolated on φ80 d₃ilv⁺ transducing phage) and to study DNA from phages Mu and P1 in which the G segments are flanked by inverted duplications. When deproteinized adenovirus-2 DNA was denatured and reannealed, some underwound circles the length of the entire chromosome were observed by electron microscopy. These resulted from the restricted interaction of complementary single-stranded rings generated when pairing of the short inverted terminal duplications closed the ends of single strands. Another type of underwound loop was seen in heteroduplexes containing complementary insertion loops located at different positions in the hybridized strands, such as occurs with P1 cam DNAs. All these underwound structures are similar in appearance to the hybrids formed when topologically separate, complementary single-stranded circles of Colicin E₁ DNA were allowed to anneal.