Resolution of Holliday junctions in genetic recombination: RuvC protein nicks DNA at the point of strand exchange.

The RuvC protein of Escherichia coli catalyzes the resolution of recombination intermediates during genetic recombination and the recombinational repair of damaged DNA. Resolution involves specific recognition of the Holliday structure to form a complex that exhibits twofold symmetry with the DNA in an open configuration. Cleavage occurs when strands of like polarity are nicked at the sequence 5'-WTT decreases S-3' (where W is A or T and S is G or C). To determine whether the cleavage site needs to be located at, or close to, the point at which DNA strands exchange partners, Holliday structures were constructed with the junction points at defined sites within this sequence. We found that the efficiency of resolution was optimal when the cleavage site was coincident with the position of DNA strand exchange. In these studies, junction targeting was achieved by incorporating uncharged methyl phosphonates into the DNA backbone, providing further evidence for the importance of charge-charge repulsions in determining DNA structure.     

Resolution of Holliday junctions in vitro requires the Escherichia coli ruvC gene product.

In previous studies, Holliday junctions generated during RecA-mediated strand-exchange reactions were resolved by fractionated Escherichia coli extracts. We now report the specific binding and cleavage of synthetic Holliday junctions (50 base pairs long) by a fraction purified by chromatography on DEAE-cellulose, phosphocellulose, and single-stranded DNA-cellulose. The cleavage reaction provided a sensitive assay with which to screen extracts prepared from recombination/repair-deficient mutants. Cells with mutations in ruvC lack the nuclease activity that cleaves synthetic Holliday junctions in vitro. This deficiency was restored by a multicopy plasmid carrying a ruvC+ gene that overexpressed junction-resolving activity. The UV sensitivity and deficiency in recombinational repair of DNA exhibited by ruv mutants lead us to suggest that RuvC resolves Holliday junctions in vivo.     

Phosphorylation of DNA topoisomerase II by casein kinase II: modulation of eukaryotic topoisomerase II activity in vitro.

The phosphorylation of Drosophila melanogaster DNA topoisomerase II by purified casein kinase II was characterized in vitro. Under the conditions used, the kinase incorporated a maximum of 2-3 molecules of phosphate per homodimer of topoisomerase II. No autophosphorylation of the topoisomerase was observed. The only amino acid residue modified by casein kinase II was serine. Apparent Km and Vmax values for the phosphorylation reaction were 0.4 microM topoisomerase II and 3.3 mumol of phosphate incorporated per min per mg of kinase, respectively. Phosphorylation stimulated the DNA relaxation activity of topoisomerase II by 3-fold over that of the dephosphorylated enzyme, and the effects of modification could be reversed by treatment with alkaline phosphatase. Therefore, this study demonstrates that post-translational enzymatic modifications can be used to modulate the interaction between topoisomerase II and DNA.     

Inhibition of Micrococcus luteus DNA topoisomerase I by UV photoproducts.

The activity of Micrococcus luteus DNA topoisomerase I on UV-irradiated supercoiled DNA was studied under either processive or distributive reaction conditions. Changes in DNA structure caused by UV irradiation reduce the rate of DNA relaxation at very low concentration of photoproducts. Under processive conditions the inhibition of the topoisomerase I by photoproducts can be quantitated by measuring the amount of substrate left in the replicative form I band. The mode of action of DNA topoisomerase I was affected by the presence of photoproducts in the DNA substrate, although the ability of the enzyme to form a covalent complex with UV-irradiated supercoiled DNA was not changed. The inhibition of topoisomerase I by UV photoproducts has been compared to the effects of single-stranded DNA and UV-irradiated duplex linear DNA on the enzyme, and the results suggest that the inhibition by photoproducts is caused by changes in the conformation of the supercoil. Our findings indicate the possibility that DNA topoisomerase I plays a role in repair.     

Bacillus subtilis RecU protein cleaves Holliday junctions and anneals single-stranded DNA

Bacillus subtilis RecU protein is involved in homologous recombination, DNA repair, and chromosome segregation. Purified RecU binds preferentially to three- and four-strand junctions when compared to single-stranded DNA (ssDNA) and double-stranded DNA (dsDNA) ( approximately 10- and approximately 40-fold lower efficiency, respectively). RecU cleaves mobile four-way junctions but fails to cleave a linear dsDNA with a putative cognate site, a finding consistent with a similar genetic defect observed for genes classified within the epsilon epistatic group (namely ruvA, recD, and recU). In the presence of Mg(2+), RecU also anneals a circular ssDNA and a homologous linear dsDNA with a ssDNA tail and a linear ssDNA and a homologous supercoiled dsDNA substrate. These results suggest that RecU, which cleaves recombination intermediates with high specificity, might also help in their assembly.     

Expression of yeast DNA topoisomerase I can complement a conditional-lethal DNA topoisomerase I mutation in Escherichia coli.

We show that, despite differences in primary structure, substrate preference, and mechanism of catalysis, yeast DNA topoisomerase I can functionally substitute for Escherichia coli DNA topoisomerase I. A family of plasmids expressing the yeast TOP1 gene or 5'-deletion mutations of it were used to complement the temperature-sensitive phenotype of an E. coli topA mutant. These plasmids were then isolated from the cells by a rapid lysis procedure and examined for their degrees of supercoiling. Functional complementation of a conditional-lethal mutation in topA, which encodes E. coli DNA topoisomerase I, correlates with the expression of a catalytically active yeast enzyme that reduces the degree of negative supercoiling of intracellular DNA. We also show that approximately 130 amino acids of the amino-terminal portion of the yeast enzyme can be deleted without affecting its activity in vitro; activity of the enzyme inside E. coli, however, is more sensitive to such deletions.     

Cloning of yeast TOP1, the gene encoding DNA topoisomerase I, and construction of mutants defective in both DNA topoisomerase I and DNA topoisomerase II.

Rabbit antibodies specific to yeast DNA topoisomerase I were used in immunological screening of a Saccharomyces cerevisiae genomic DNA library in Escherichia coli. One of the clones identified by its expression of antigenic determinants of the yeast enzyme is shown to contain the coding sequence of the enzyme: no active DNA topoisomerase I is detectable in cell extracts when insertion or deletion mutations are introduced into a 2-kilobase-pair (kb) region of the sequence in a haploid yeast genome. Blot hybridizations show that there is a single copy of the cloned sequence per haploid and that the sequence is transcribed to give a 2.7-kb poly(A)+ message. Mutants in which 1.7 kb of the sequence is deleted are viable. Temperature-shift experiments using synchronously grown cells of a delta top1 top2 temperature-sensitive (ts) double mutant and its isogenic top2 ts strain show that, whereas mitotic blocks can prevent killing of the top2 ts mutant at a nonpermissive temperature, the same treatments are ineffective in preventing cell death of the delta top1 top2 ts double mutant. These experiments suggest that in yeast DNA topoisomerase I serves a role auxiliary to DNA topoisomerase II.     

Holliday junctions in FLP recombination: resolution by step-arrest mutants of FLP protein.

The FLP "recombinase" of the 2-micron circle yeast plasmid can resolve synthetic FLP site-Holliday junctions. Mutants of the FLP protein that are blocked in recombination but are normal in substrate cleavage can also mediate resolution. The products of resolution by these mutants are almost exclusively nicked molecules with a protein-bound 3' end. There is no significant asymmetry in strand cleavage (top versus bottom) by the mutants in linear or in circular FLP substrates; nor is there a bias in resolution (toward parentals or toward recombinants) of Holliday junctions (corresponding to top- or to bottom-strand exchange) by wild-type FLP. During normal FLP recombination, a small amount of the expected Holliday intermediate can be detected.     

Single-molecule measurements of the opening and closing of the DNA gate by eukaryotic topoisomerase II

Type II DNA topoisomerases are essential and ubiquitous enzymes that perform important functions in chromosome condensation and segregation and in regulating intracellular DNA supercoiling. Topoisomerases carry out these DNA transactions by passing one segment of DNA through the other by using a reversible, enzyme-bridged double strand break. The transient enzyme/DNA adduct is mediated by a phosphodiester bond between the active-site tyrosine and a backbone phosphate of DNA. The opening and closing of the DNA gate, a critical step for strand passage during the catalytic cycle, is coupled to this cleavage/religation. We designed a unique oligonucleotide substrate with a pair of fluorophores straddling the topoisomerase II cleavage site, allowing the use of FRET to monitor the opening of the DNA gate. The DNA substrate undergoes an enzyme-mediated transition between a closed and open state in the presence of ATP, similar to the overall topoisomerase II catalyzed reaction. Single-molecule fluorescence microscopy measurements demonstrate that the transition has comparable rate constants for both the opening and closing reaction during steady-state ATP hydrolysis, with an apparent equilibrium constant near unity. In the presence of AMPPNP, a reduction in FRET occurs, suggesting an opening or partial opening of the DNA gate. However, the single-molecule experiments indicate that the open and closed states do not interconvert at a measurable rate.     

Mapping the active-site tyrosine of vaccinia virus DNA topoisomerase I.

Site-directed mutagenesis of the vaccinia virus gene encoding a type I DNA topoisomerase implicates Tyr-274 as the active-site residue that forms a covalent adduct with DNA during cycles of DNA-strand breakage and reunion. Replacement of Tyr-274 by phenylalanine results in loss of the ability of the enzyme to relax negatively supercoiled DNA as well as to form the covalent DNA-protein intermediate. Substitution of phenylalanine for tyrosine at nine other sites in the protein has no apparent effect on enzyme activity. Amino acid sequence alignment reveals Tyr-274 to be homologous to Tyr-727 and Tyr-771, respectively, of the type I topoisomerases from Saccharomyces cerevisiae and Saccharomyces pombe; Tyr-727 and Tyr-771 have been shown to represent the active-site tyrosines of those enzymes. Sequence comparison of the active-site regions defines a motif Ser-Lys-Xaa-Xaa-Tyr common to the viral and cellular type I topoisomerases, including the human enzyme.     

The RecA/RAD51 protein drives migration of Holliday junctions via polymerization on DNA

The Holliday junction (HJ), a cross-shaped structure that physically links the two DNA helices, is a key intermediate in homologous recombination, DNA repair, and replication. Several helicase-like proteins are known to bind HJs and promote their branch migration (BM) by translocating along DNA at the expense of ATP hydrolysis. Surprisingly, the bacterial recombinase protein RecA and its eukaryotic homologue Rad51 also promote BM of HJs despite the fact they do not bind HJs preferentially and do not translocate along DNA. RecA/Rad51 plays a key role in DNA double-stranded break repair and homologous recombination. RecA/Rad51 binds to ssDNA and forms contiguous filaments that promote the search for homologous DNA sequences and DNA strand exchange. The mechanism of BM promoted by RecA/RAD51 is unknown. Here, we demonstrate that cycles of RecA/Rad51 polymerization and dissociation coupled with ATP hydrolysis drives the BM of HJs.     

Elongation of primed DNA templates by eukaryotic DNA polymerases.

The combined action of DNA polymerase alpha and DNA polymerase beta leads to the synthesis of full-length linear DNA strands with phi X174 DNA templates containing an RNA primer. The reaction can be carried out in two stages. In the first stage, DNA polymerase alpha catalyzes the synthesis of a chain that averaged 230 deoxynucleotides long and was covalently linked to the RNA primer. In the second stage, DNA polymerase beta elongates the DNA strand covalently attached to the RNA primer to full length. With DNA primers, DNA polymerase alpha catalyzes only limited deoxynucleotide addition whereas DNA polymerase beta alone elongates DNA primed templates to full length. DNA polymerase beta can also stimulate the synthesis of adenovirus DNA in vitro in the presence of a cytosol extract from adenovirus-infected cells. In all of these systems, dNMP incorporation catalyzed by DNA polymerase beta was sensitive to N-ethylmaleimide; however, this polymerase activity was resistant to N-ethylmaleimide with poly(rA) x (dT) as the primer template.     

Recombination mediated by vaccinia virus DNA topoisomerase I in Escherichia coli is sequence specific.

Specialized type I topoisomerases catalyze DNA strand transfer during site-specific recombination in prokaryotes and fungi. As a rule, the site specificity of these systems is determined by the DNA binding and cleavage preference of the topoisomerase per se. The Mr 32,000 topoisomerase I encoded by vaccinia virus (a member of the eukaryotic family of "general" type I enzymes) is also selective in its interaction with DNA; binding and cleavage occur in vitro at a pentameric motif 5'-(C or T)CCTT in duplex DNA. Expression of vaccinia virus DNA topoisomerase I in a lambda lysogen of Escherichia coli promotes int-independent excisive recombination of the prophage. To address whether the topoisomerase directly catalyzes DNA strand transfer in vivo, the recombination junctions of plaque-purified progeny phage were cloned and sequenced. In five of six distinct excision events examined, a topoisomerase cleavage sequence is present in one strand of the DNA duplex of both recombining partners. Recombination entails no duplication, insertion, or deletion of nucleotides at the crossover points, consistent with excision via conservative strand exchange at sites of topoisomerase cleavage. Three of these five recombination events are distinguished by the presence of direct repeats at the parental half-sites that extend beyond the pentameric cleavage motif, suggesting that sequence homology may facilitate excision. The data are consistent with a model in which vaccinia topoisomerase catalyzes reciprocal strand transfer, leading to the formation of a nonmigrating Holliday junction, the resolution of which can lead to excisive recombination.     

Characterization of a mammalian mutant with a camptothecin-resistant DNA topoisomerase I.

DNA topoisomerase I was purified to near homogeneity from a clonal line of human lymphoblastic leukemia cells, RPMI 8402, that is resistant to camptothecin, a cytotoxic alkaloid from Camptotheca acuminata, and compared with that of the parent wild-type cells. As assayed by relaxation of the supercoiled plasmid DNA and by formation of enzyme-linked DNA breaks, the purified enzyme from the resistant cells was shown to be greater than 125-fold as resistant to camptothecin as the wild-type enzyme, comparable to a cellular resistance index of about 300. Therefore, the cellular resistance appears to be due to the resistance of the enzyme. The amount of the immunoreactive enzyme protein in whole extract appeared to be reduced to less than half that of the wild-type enzyme. These results establish that DNA topoisomerase I is the cellular target of camptothecin and that DNA topoisomerase I is essential for the survival of mammalian cells.     

Partial purification of an enzyme from Saccharomyces cerevisiae that cleaves Holliday junctions.

An enzyme from Saccharomyces cerevisiae that cleaves Holliday junctions was partially purified approximately 500- to 1000-fold by DEAE-cellulose chromatography, gel filtration on Sephacryl S300, and chromatography on single-stranded DNA-cellulose. The partially purified enzyme did not have any detectable nuclease activity when tested with single-stranded or double-stranded bacteriophage T7 substrate DNA and did not have detectable endonuclease activity when tested with bacteriophage M13 viral DNA or plasmid pBR322 covalently closed circular DNA. Analysis of the products of the cruciform cleavage reaction by electrophoresis on polyacrylamide gels under denaturing conditions revealed that the cruciform structure was cleaved at either of two sites present in the stem of the cruciform and was not cleaved at the end of the stem. The cruciform cleavage enzyme was able to cleave the Holliday junction present in bacteriophage G4 figure-8 molecules. Eighty percent of these Holliday junctions were cleaved in the proper orientation to generate intact chromosomes during genetic recombination.     

DNA minor groove-binding ligands: a different class of mammalian DNA topoisomerase I inhibitors.

A number of DNA minor groove-binding ligands (MGBLs) are known to exhibit antitumor and antimicrobial activities. We show that DNA topoisomerase (Topo) I may be a pharmacological target of MGBLs. In the presence of calf thymus Topo I, MGBLs induced limited but highly specific single-strand DNA breaks. The 3' ends of the broken DNA strands are covalently linked to Topo I polypeptides. Protein-linked DNA breaks are readily reversed by a brief heating to 65 degrees C or the addition of 0.5 M NaCl. These results suggest that MGBLs, like camptothecin, abort Topo I reactions by trapping reversible cleavable complexes. The sites of cleavage induced by MGBLs are distinctly different from those induced by camptothecin. Two of the major cleavage sites have been sequenced and shown to be highly A + T-rich, suggesting the possible involvement of a Topo I-drug-DNA ternary complex at the sites of cleavage. Different MGBLs also exhibit varying efficiency in inducing Topo I-cleavable complexes, and the order of efficiency is as follows: Hoechst 33342 and 33258 >> distamycin A > berenil > netropsin. The lack of correlation between DNA binding and cleavage efficiency suggest that, in addition to binding to the minor grooves of DNA, MGBLs must also interact with Topo I in trapping Topo I-cleavable complexes.     

Interaction of Escherichia coli RuvA and RuvB proteins with synthetic Holliday junctions.

The RuvA, RuvB, and RuvC proteins of Escherichia coli are required for the recombinational repair of ultraviolet light- or chemical-induced DNA damage. In vitro, RuvC protein interacts with Holliday junctions in DNA and promotes their resolution by endonucleolytic cleavage. In this paper, we investigate the interaction of RuvA and RuvB proteins with model Holliday junctions. Using band-shift assays, we show that RuvA binds synthetic Holliday structures to form specific protein-DNA complexes. Moreover, in the presence of ATP, the RuvA and RuvB proteins act in concert to promote dissociation of the synthetic Holliday structures. The dissociation reaction requires both RuvA and RuvB and a nucleotide cofactor (ATP or dATP) and is rapid (40% of DNA molecules dissociate within 1 min). The reaction does not occur when ATP is replaced by either ADP or the nonhydrolyzable analog of ATP, adenosine 5'-[gamma-thio]triphosphate. We suggest that the RuvA and RuvB proteins play a specific role in the branch migration of Holliday junctions during postreplication repair of DNA damage in E. coli.