Recombination promoted by superhelical DNA and the recA gene of Escherichia coli

New RAD51 Inhibitors to Target Homologous Recombination in Human Cells

Targeting DNA repair proteins with small-molecule inhibitors became a proven anti-cancer strategy. Previously, we identified an inhibitor of a major protein of homologous recombination (HR) RAD51, named B02. B02 inhibited HR in human cells and sensitized them to chemotherapeutic drugs in vitro and in vivo. Here, using a medicinal chemistry approach, we aimed to improve the potency of B02. We identified the B02 analog, B02-isomer, which inhibits HR in human cells with significantly higher efficiency. We also show that B02-iso sensitizes triple-negative breast cancer MDA-MB-231 cells to the PARP inhibitor (PARPi) olaparib.

Cooperative DnaA Binding to the Negatively Supercoiled datA Locus Stimulates DnaA-ATP Hydrolysis

Timely initiation of replication in Escherichia coli requires functional regulation of the replication initiator, ATP-DnaA. The cellular level of ATP-DnaA increases just before initiation, after which its level decreases through hydrolysis of DnaA-bound ATP, yielding initiation-inactive ADP-DnaA. Previously, we reported a novel DnaA-ATP hydrolysis system involving the chromosomal locus datA and named it datA-dependent DnaA-ATP hydrolysis (DDAH). The datA locus contains a binding site for a nucleoid-associating factor integration host factor (IHF) and a cluster of three known DnaA-binding sites, which are important for DDAH. However, the mechanisms underlying the formation and regulation of the datA-IHF·DnaA complex remain unclear. We now demonstrate that a novel DnaA box within datA is essential for ATP-DnaA complex formation and DnaA-ATP hydrolysis. Specific DnaA residues, which are important for interaction with bound ATP and for head-to-tail inter-DnaA interaction, were also required for ATP-DnaA-specific oligomer formation on datA Furthermore, we show that negative DNA supercoiling of datA stabilizes ATP-DnaA oligomers, and stimulates datA-IHF interaction and DnaA-ATP hydrolysis. Relaxation of DNA supercoiling by the addition of novobiocin, a DNA gyrase inhibitor, inhibits datA function in cells. On the basis of these results, we propose a mechanistic model of datA-IHF·DnaA complex formation and DNA supercoiling-dependent regulation for DDAH.

Genome scale patterns of supercoiling in a bacterial chromosome

DNA in bacterial cells primarily exists in a negatively supercoiled state. The extent of supercoiling differs between regions of the chromosome, changes in response to external conditions and regulates gene expression. Here we report the use of trimethylpsoralen intercalation to map the extent of supercoiling across the Escherichia coli chromosome during exponential and stationary growth phases. We find that stationary phase E. coli cells display a gradient of negative supercoiling, with the terminus being more negatively supercoiled than the origin of replication, and that such a gradient is absent in exponentially growing cells. This stationary phase pattern is correlated with the binding of the nucleoid-associated protein HU, and we show that it is lost in an HU deletion strain. We suggest that HU establishes higher supercoiling near the terminus of the chromosome during stationary phase, whereas during exponential growth DNA gyrase and/or transcription equalizes supercoiling across the chromosome.

Bacterial DNA primarily exists in a negatively supercoiled or under-wound state. Here, by mapping the supercoiling state, the authors show that there is a gradient of supercoiling across the bacterial chromosome with the terminus being more negatively supercoiled than the origin.

Rad54, the motor of homologous recombination

Homologous recombination (HR) performs crucial functions including DNA repair, segregation of homologous chromosomes, propagation of genetic diversity, and maintenance of telomeres. HR is responsible for the repair of DNA double-strand breaks and DNA interstrand cross-links. The process of HR is initiated at the site of DNA breaks and gaps and involves a search for homologous sequences promoted by Rad51 and auxiliary proteins followed by the subsequent invasion of broken DNA ends into the homologous duplex DNA that then serves as a template for repair. The invasion produces a cross-stranded structure, known as the Holliday junction. Here, we describe the properties of Rad54, an important and versatile HR protein that is evolutionarily conserved in eukaryotes. Rad54 is a motor protein that translocates along dsDNA and performs several important functions in HR. The current review focuses on the recently identified Rad54 activities which contribute to the late phase of HR, especially the branch migration of Holliday junctions.

Rad52 promotes second-end DNA capture in double-stranded break repair to form complement-stabilized joint molecules

Saccharomyces cerevisiae Rad52 performs multiple functions during the recombinational repair of double-stranded DNA (dsDNA) breaks (DSBs). It mediates assembly of Rad51 onto single-stranded DNA (ssDNA) that is complexed with replication protein A (RPA); the resulting nucleoprotein filament pairs with homologous dsDNA to form joint molecules. Rad52 also catalyzes the annealing of complementary strands of ssDNA, even when they are complexed with RPA. Both Rad51 and Rad52 can be envisioned to promote "second-end capture," a step that pairs the ssDNA generated by processing of the second end of a DSB to the joint molecule formed by invasion of the target dsDNA by the first processed end. Here, we show that Rad52 promotes annealing of complementary ssDNA that is complexed with RPA to the displaced strand of a joint molecule, to form a complement-stabilized joint molecule. RecO, a prokaryotic homolog of Rad52, cannot form complement-stabilized joint molecules with RPA-ssDNA complexes, nor can Rad52 promote second-end capture when the ssDNA is bound with either human RPA or the prokaryotic ssDNA-binding protein, SSB, indicating a species-specific process. We conclude that Rad52 participates in second-end capture by annealing a resected DNA break, complexed with RPA, to the joint molecule product of single-end invasion event. These studies support a role for Rad52-promoted annealing in the formation of Holliday junctions in DSB repair.

Double displacement loops (double d-loops) are templates for oligonucleotide-directed mutagenesis and gene repair

Appreciable levels of gene repair result from the hybridization of two oligonucleotides at a specific site in a mutated gene and subsequent correction by a form of oligonucleotide-directed mutagenesis known as gene repair. The incorporation of the two oligonucleotides into superhelical plasmid DNA leads to the formation of double d-loops, structures shown to be templates for the repair of both frameshift and point mutations. Structural limitations placed on the template indicate that correction is influenced significantly by the positioning of the second oligonucleotide, known as the annealing oligonucleotide. Complexes constructed with two oligonucleotides directly opposite each other exhibit the highest levels of gene repair activity. Blocking the 3'-end of either oligonucleotide with an amino C7 group does not diminish the performance of the double d-loop as a template for correction of the point mutation, suggesting that primer extension does not play a pivotal role in the mechanism of gene repair.

DNA pairing is an important step in the process of targeted nucleotide exchange

Modified single-stranded DNA oligonucleotides can direct the repair of genetic mutations in yeast, plant and mammalian cells. The mechanism by which these molecules exert their effect is being elucidated, but the first phase is likely to involve the homologous alignment of the single strand with its complementary sequence in the target gene. In this study, we establish the importance of such DNA pairing in facilitating the gene repair event. Oligonucleotide-directed repair occurs at a low frequency in an Escherichia coli strain (DH10B) lacking the RECA DNA pairing function. Repair activity can be rescued by using purified RecA protein to catalyze the assimilation of oligonucleotide vectors into a plasmid containing a mutant kanamycin resistance gene in vitro. Electroporation of the preformed complex into DH10B cells results in high levels of gene repair activity, evidenced by the appearance of kanamycin-resistant colonies. Gene repair is dependent on the formation of a double-displacement loop (double-D-loop), a recombination intermediate containing two single-stranded oligonucleotides hybridized to opposite strands of the plasmid at the site of the point mutation. The heightened level of stability of the double-D-loop enables it to serve as an active template for the DNA repair events. The data establish DNA pairing and the formation of the double-D-loop as important first steps in the process of gene repair.

The DNA binding and pairing preferences of the archaeal RadA protein demonstrate a universal characteristic of DNA strand exchange proteins

The archaeal RadA protein is a homologue of the Escherichia coli RecA and Saccharomyces cerevisiae Rad51 proteins and possesses the same biochemical activities. Here, using in vitro selection, we show that the Sulfolobus solfataricus RadA protein displays the same preference as its homologues for binding to DNA sequences that are rich in G residues, and under-represented in A and C residues. The RadA protein also displays enhanced pairing activity with these in vitro-selected sequences. These parallels between the archaeal, eukaryal and bacterial proteins further extend the universal characteristics of DNA strand exchange proteins.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.

Purification and some of the functions of the products of bacteriophage T4 recombination genes, uvsX and uvsY

The nonessential T4 genes uvsX and uvsY are involved in DNA repair and general recombination. Using newly isolated amber mutants of these genes, we have identified the gene products (gp) by sodium dodecyl sulfate (SDS)/polyacrylamide gel electrophoresis. Their relative molecular masses are 39 000 and 16 000, respectively. In the normal wild-type infection process they are produced early but not late in infection. Their synthesis continues for a longer period when DNA synthesis is blocked. We have developed procedures to isolate these gene products at a purity of more than 95% for gpuvsX and at 70% for gpuvsY, as judged by SDS/polyacrylamide gel electrophoresis and staining with Coomassie brilliant blue dye. The purification procedures suggest that these products may be membrane proteins. Using both an agarose gel assay and electron microscopy, we find that the product of the gene uvsX catalyzes the assimilation of a linear single-stranded fd DNA fragment into superhelical double-stranded fd DNA (RFI). The reaction requires ATP and Mg2+ besides substrate DNAs and uvsX protein. The T4 uvsX protein therefore is similar to the Escherichia coli recA protein in molecular size and function, but differs in antigenic property.

Role of RecA protein spiral filaments in genetic recombination

Physical and enzymatic studies on RecA protein from Escherichia coli provide the basis for a molecular model of general genetic recombination, a novel feature of which is the role attributed to spiral filaments of RecA protein.

Involvement of single-strand breaks in complex formation between single-stranded DNA and nucleoids of Bacillus subtilis

RNase-unfolded chromosomes of competent Bacillus subtilis are able to take up single-stranded homologous donor DNA fragments in vitro to form donor-recipient DNA complexes (Van Randen and Venema 1981). The unfolded chromosomes behave as supercoiled DNA molecules. X-irradiation increased the formation of unstable and stable complexes between donor and recipient DNA during incubation at 37 degrees C. The complex-forming ability of the unfolded chromosomes increased linearly with increasing X-ray dose, even after complete relaxation of the unfolded chromosomes had occurred. Limited DNase I action increased the complex-forming ability of the chromosomes as effectively as X-irradiation. Unstable donor-recipient DNA complexes can be distinguished from stable ones by their dissociation upon density gradient centrifugation in CsCl at pH 11.2. They are stable at pH 10 (Van Randen et al. 1982a). At an intermediate pH value during isopycnic centrifugation, a fraction of the unstable complexes were stable, suggesting that a range of stabilities existed among the unstable complexes. The donor moiety of the stable donor-recipient DNA complexes was far more resistant to nuclease S1 treatment than that of the unstable ones.

Biologically active recombinant formed through DNA pairing by purified recA protein in vitro

We have detected in vitro homologous recombination mediated by purified recA protein of Escherichia coli as a recombinant phage produced by using the DNA packaging system of phage lambda. When double-stranded DNA of phage lambda carrying amber mutations is incubated with double-stranded DNA carrying the wild-type genes in the presence of recA protein, Mg++ and ATP, and the DNA packaged, amber+ recombinant phage is produced at a high frequency. This reaction depends completely upon the function of the wild-type recA protein. After incubation of 32P-labeled linear DNA (Form III) with bromouracil-labeled circular DNA (Form I-Form II mixture) in the presence of recA protein, Mg++ and ATP, about 10% of the 32P-counts band at an intermediate density in CsCl equilibrium gradient. This fraction yields a high percentage of the recombinant phage after DNA packaging and shows the alpha-shaped and sigma-shaped joint molecules of linear and circular DNA under the electron microscope. Furthermore, we demonstrate that a non-homologous region inhibits the recombination reaction when it is between the marker concerned and the closer cos end. Our results indicate that recA protein acts directly in the initial step of recombination to join the homologous double-stranded DNA and that the resulting molecule can be matured into the recombinant DNA.

recA protein of Escherichia coli promotes branch migration, a kinetically distinct phase of DNA strand exchange

The recA protein of Escherichia coli promotes the complete exchange of strands between full-length linear duplex and single-stranded circular DNA molecules of bacteriophage phi X-174, converting more than 50% of the single-stranded DNA into heteroduplex replicative form II-like structures. Kinetically, the reaction can be divided into two phases, formation of short heteroduplex regions (D loops) and extension of the D loops via branch migration. recA protein participates directly in both phases. D loops are formed efficiently in the presence of ATP or the nonhydrolyzable ATP analog adenosine 5'-[gamma-thio]triphosphate, whereas D-loop extension requires continuous ATP hydrolysis. Complete strand exchange requires a stoichiometric amount of recA protein and is strongly stimulated by the single-stranded-DNA-binding protein of E. coli.

Assimilation of single-stranded donor deoxyribonucleic acid fragments by nucleoids of competent cultures of Bacillus subtilis

Lysates containing folded chromosomes of competent Bacillus subtilis were prepared. The chromosomes were supercoiled, as indicated by the biphasic response of their sedimentation rates to increasing concentrations of ethidium bromide. Limited incubation of the lysates with increasing concentrations of ribonucleases resulted in a gradual decrease in the sedimentation velocity of the deoxyribonucleic acid (DNA) until finally a constant S value was reached. Incubation with sonicated, 4,5',8-trimethylpsoralen-monoadducted, denatured, homologous donor DNA molecules at 37 degrees C and concomitant irradiation with long-wave ultraviolet light of the nucleoid-containing lysates resulted in the formation of complexes of the donor DNA molecules and the recipient chromosomes. This complex formation was stimulated when nucleoids were previously (i) unfolded by ribonuclease incubation, (ii) (partially) relaxed by X irradiation, or (iii) subjected to both treatments. Monoadducts were not essential. On the other hand, the complex-forming capacity of recipient chromosomes previously cross-linked by 4,5',8-trimethylpsoralen diadducts was greatly reduced, suggesting that strand separation of the recipient molecule was involved in the formation of the complex. None of these effects has been observed when heterologous (Escherichia coli) donor DNA has been used. When the same kind of experiments were carried out at 70 degrees C, donor-recipient DNA complexes were also formed and required strand separation and homology similar to donor-recipient complex formation at 37 degrees C. However, in contrast to what was found at 37 degrees C, unfolding plus relaxation of the nucleoids, as well as the absence of monoadducts in the donor DNA fragments, resulted in a decrease in complex formation. On the basis of these results, we assume that superhelicity can promote the in vitro assimilation of single-stranded donor DNA fragments by nucleoids of competents B. subtilis cells at 70 degrees C, but that at 37 degrees C a different mechanism is involved.

Chromosomes in living Escherichia coli cells are segregated into domains of supercoiling

Torsional tension in the DNA double helix can be detected in living cells of Escherichia coli from measurements of the rate of trimethylpsoralen photobinding to the intracellular DNA. Here we show that this tension is relaxed in vivo when single-strand DNA breaks are introduced by gamma-irradiation and that approximately 160 nicks per genome equivalent of DNA are required to relax greater than 95% of the tension. Chromosomes containing less than 160 nicks per genome equivalent lose only a part of the tension, depending on the number of nicks. The remaining tension is maintained during incubations of cells at 0 degrees C. Chromosomes with tension relaxed by incubation of cells with inhibitors of DNA gyrase interact with the trimethylpsoralen probe independently of the number of nicks introduced by gamma-irradiation. The results fit a model in which the chromosome in growing E. coli cells (mean generation time, 30 min) is segregated into 43 +/- 10 domains of supercoiling per genome equivalent of DNA or 120 +/- 30 domains per nucleoid. The number of domains is unchanged in cells depleted of nascent RNA by growth with rifampicin, but varies somewhat in cells growing at different rates in different media.

Targeted deletions of sequences from closed circular DNA

Closed circular DNA interacts with complementary sequences of single-stranded DNA to form displacement loop (D loop) structures in vitro. The site of D-loop formation can be directed by using single-stranded DNA derived from a selected restriction fragment. Circular DNA containing a D loop can then be linearized by cleavage with endonuclease S1. This cleavage appears to remove a limited number of nucleotides from each strand of the circular DNA substrate. Incubation with polynucleotide ligase followed by propagation in vivo leads to circular DNA molecules that bear small, single deletions in the region of the single-stranded DNA sequence chosen for the formation of the D loops. We have utilized these manipulations of DNA to construct tetracycline-sensitive deletion mutants of plasmid pBR322. The level of mutagenesis obtained by the procedure is sufficiently high that selective growth and screening procedures are not necessary for the isolation or identification of mutants. The frequency, variety, and small size of the deletions obtained within the selected target regions present considerable advantage for genetic and biochemical analysis. The method is quite general in rationale and should be immediately applicable to phage and viruses having infectious circular DNA genomes or recombinant DNA species propagated in circular plasmid vectors.

Evidence of RNA in D loops of intracellular lambda DNA

If lambda DNA replication is blocked by mutation in any one of several genes essential for replication, intracellular lambda DNA often shows short three-stranded regions called D loops. In this report we show that one arm of a D loop is an RNA . DNA hybrid, whereas the remaining arm is made up of single-stranded DNA. The RNA can be partially removed by RNase A and totally removed by RNase H. Also, D loops do not appear if infections are made in cells treated with rifampin, a potent inhibitor of transcription by Escherichia coli RNA polymerase. Several genes associated with recombination, including the host recA gene, are not essential for D-loop formation.

Supercoils in prokaryotic DNA restrained in vivo

Cells of Escherichia coli containing the plasmid F were gamma-irradiated with various doses to introduce determined numbers of single-strand breaks in the F DNA. The cells were then incubated to permit repair of the breaks while DNA gyrase was inhibited with coumermycin to limit restoration of any relaxed supercoil. Repaired, covalently continuous F DNA was isolated and its superhelical density was measured by two different methods. Both indicated that a major part (50-60%) of the negative superhelical turns were maintained in the repaired molecules, suggesting that the supercoils are restrained in vivo.

recA protein-catalyzed strand assimilation: stimulation by Escherichia coli single-stranded DNA-binding protein

The single-stranded DNA-binding protein of Escherichia coli significantly alters the strand assimilation reaction catalyzed by recA protein [McEntee, K., Weinstock, G. M. & Lehman, I. R. (1979) Proc. Natl. Acad. Sci. USA 76, 2615--2619]. The binding protein (i) increases the rate and extent of strand assimilation into homologous duplex DNA, (ii) enhances the formation of a complex between recA protein and duplex DNA in the presence of homologous or heterologous single-stranded DNA, (iii) reduces the rate and extent of ATP hydrolysis catalyzed by recA protein in the presence of single-stranded DNA, (iv) reduces the high concentration of recA protein required for strand assimilation, and (v) permits detection of strand assimilation in the presence of the ATP analog, adenosine 5'-O-(O-thiotriphosphate). Single-stranded DNA-binding protein purified from a binding protein mutant (lexC) is considerably less effective than wild-type binding protein in stimulating strand assimilation, a result which suggests that single-stranded DNA-binding protein participates in general recombination in vivo.

Four proteins synthesized in response to deoxyribonucleic acid damage in Micrococcus radiodurans

Four proteins, alpha beta, gamma, and delta, preferentially synthesized in ultraviolet light-treated cells of Micrococcus radiodurans, were characterized in terms of their molecular weights and isoelectric points. Within the sublethal-dose range, the differential rate of synthesis for these proteins increased linearly with the inducing UV dose. The degree of induction reached 100-fold, and the most abundant protein beta, amounted to approximately 2% of the total newly synthesized protein after irradiation. Damage caused by ionizing radiation or by treatment with mitomycin C also provoked the synthesis of the four proteins. The proportions between the individual proteins, however, varied strikingly with the damaging agent. In contrast to treatments which introduced damage in the cellular deoxyribonucleic acid, the mere arrest of deoxyribonucleic acid replication, caused by nalidixic acid or by starvation for thymine, failed to elicit the synthesis of either protein. Repair of deoxyribonucleic acid damage requires that a number of versatile and efficient processes by employed. It is proposed that the induced proteins participate in deoxyribonucleic acid repair in M. radiodurans. Mechanisms are discussed which would allow a differentiated cellular response to damages of sufficiently distinctive nature.

Requirement of DNA gyrase for the initiation of chromosome replication in Escherichia coli K-12

It has been found that strains carrying mutations in the dnaA gene are unusually sensitive to COU, NAL or NOV, which are known to inhibit DNA gyrase activities. The delay in the initiation of chromosome replication after COU treatment has been observed in cells with chromosomes synchronized by amino acid starvation or by temperature shift-up (dnaA46). The unusual sensitivity of growth to COU of the initiation mutant runs parallel to a higher sensitivity to the drug of the initiation of chromosome replication. The double mutant, dnaA46, cou-110 has been isolated and mutation cou-110 conferring resistance of growth, initiation and elongation of chromosome replication to COU was mapped in the gene coding for the subunit of DNA gyrase. The reduced frequency of appearance of the mutants resistant to COU, NAL, or NOV in the initiation mutant suggests that some mutations in genes coding for DNA gyrase subunits cannot coexist with the dnaA46 mutation. The possible mechanisms of the requirement of DNA gyrase for dnaA-dependent initiation of E. coli chromosome are discussed.

Chromosome aberration formation and sister chromatid exchange in relation to DNA repair in human cells

Apparent association between the ability to induce chromosome aberrations and sister chromatid exchanges and mutagenic-carcinogenic potential found in a variety of physical and chemical agents has led us to speculate that these cytogenetic changes might be reflection of DNA damage and repair and might provide induces of mutagenic changes. However, the mechanisms of their formation and their relation to DNA repair as well as the mechanism of their linking to mutation are by no means well understood. Studies in some human genetic mutant cells defective in their ability to repair DNA damage indicate, as a testable proposition, that sister chromatid exchanges and chromosome aberrations are cytological manifestations of replication-mediated dual-step repair pathways that are in operation to tolerate DNA damage when damage-bearing DNA enters and passes through semiconservative replication. The observations are also in line with idea that the majority of sister chromatid exchanges can arise when damage DNA attempts replication possibly by a process relating with the replicative bypass repair mechanisms such as those proposed by Fujiwara and Tatsumi [34] and Higgins et al. [54], while chromosome aberration formation and some fraction of sister chromatid exchanges are related with the post-replication repair processes which attempt to rescue damaged template post-replicationally by de novo synthesis or recombination type repair systems. The former sister chromatid exchange-relating process seems to link mutation to less extent, if any, than the latter process, which is caffeine sensitive and likely to be error-prone.

Electrophoretic characterization of intracellular forms of bacteriophage phi X174 DNA: identification of novel intermediate of altered superhelix density

The replication cycle of bacteriophage phi X174 DNA has been analyzed by agarose gel electrophoresis. The electrophoretic behavior of the predominant species of parental and progeny DNA molecules formed between 5 and40 min after infection was deduced and quantitated. Migration through 1.4% agarose at 5 and 10 V/cm resolved all known viral DNA species as well as fragments of host chromosomal DNA. Among parental replicative form(RF) molecules synthesized, 1 to 3% were full length linear duplexes (RFIII) and approximately 65% were closed circular duplexes (RFI). Most of the input viral strands remained in a duplex structure throughout the period of infection studied here. Among progeny molecules, RFIII was not readily detected unless viral DNA synthesis was inhibited by chloramphenicol. Late in infection, 20% of the progeny RF were found to exist as form I dna. in addition, approximately 1% of the viral DNA was found as unit length linear single strands. Electrophoretic analysis of RF DNA after controlled denaturation suggests the existence of four populations of closed circular RF: (i) molecules of native superhelix density (RFI); (ii) a population of molecules of altered topological linking number, alpha, differing in increments of one superhelical turn (tau) between tau values of 0 and approximately -31; (iii) a superimposed population of topological isomers which under electrophoresis conditions have mean tau value (tau) equal to +5; and (iv) a population of "complexed" molecules with a reduced number of superhelical turns due to their association with single-stranded DNA and RNA. Complexed parental molecules isolated from cells infected at high multiplicity released FRI and homologous single-stranded DNA upon denaturation and are postulated to be intermediates in genetic recombination. Complexed RF DNA isolated from cells infected at low multiplicity release native supercoils upon reaction with RNase H and are observed by electron microscopy to contain displacement loops. Such molecules are likely intermediates in transcription. Our results are consistent with a structure of complexed RFI involving a partially triple-stranded helix in which a covalently closed circular duplex molecule contains a reduced number of superhelical turns due to the unwinding produced by base pairing between one strand of the supercoil and an associated homologous single strand of DNA or RNA.

Homologous pairing in genetic recombination: complexes of recA protein and DNA

recA protein, which is essential for general genetic recombination in Escherichia coli, promotes the homologous pairing of single-stranded DNA with double-stranded DNA to form a D loop. The amount of recA protein required for the reaction was directly proportional to the amount of single stranded DNA and was unaffected by similar variations in the amount of double-stranded DNA. The ATP analog, adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S), which was not rapidly hydrolyzed by recA protein, blocked the formation of D loops but promoted the formation of stable complexes of recA protein and single-stranded DNA. These complexes, in turn, bound homologous or heterologous double-stranded DNA and partially unwound it. Because ATP gamma S competitively inhibited the ATPase activity of recA protein (Km/Ki approximately 300), we infer that ATP gamma S binds at a site that overlaps the site for ATP and that the functional complexes formed in the presence of the analog probably represent partial steps in the overall reaction. If the complexes formed in the presence of ATP gamma S reflect natural intermediates in the formation of D loops, recA protein must promote homologous pairing either by moving juxtaposed single-stranded and double-stranded DNA relative to one another or by forming and dissociating complexes reiteratively until a homologous match occurs.

Single strands induce recA protein to unwind duplex DNA for homologous pairing

Single-stranded DNA, whether homologous or not, stimulates purified Escherichia coli recA protein to unwind duplex DNA. This helps to explain how recA promotes a search for homology in genetic recombination. As oligodeoxynucleotide also stimulate unwinding, a common mechanism may relate the function of recA protein in recombination to other functions (SOS) induced by oligonucleotides.

Functional relationship between bacteriophages G4 and phi X174

Mutants of bacteriophage G4 were isolated and characterized, and their mutations were mapped. They constitute six different genes, namely, A, B, E, F, G, and H. The functional relationship with bacteriophage phi X174 was determined by complementation experiments using amber mutants of phi X and amber mutants of G4. Bacteriophage phi X was able to use the products of G4 genes E, F, G, and H. In bacteriophage G4, however, only the phi X gene H product was functional.

Initiation of general recombination catalyzed in vitro by the recA protein of Escherichia coli

Homogeneous recA protein catalyzes the hybridization of single-stranded DNA to homologous regions in duplex DNA. The products are D-loops, which are formed with equal efficiency in linear and supercoiled molecules. This assimilation reaction can be separated into two partial reactions. In the first, recA protein binds to duplex DNA and produces a reA protein-DNA complex. The binding shows a sigmoidal dependence on recA protein concentration, requires ATP, GTP or the gamma-thio analog of ATP, and Mg2+, but does not require hydrolysis of the nucleoside triphosphate. In the second reaction, single-stranded regions of the recA protein-ATP-duplex DNA intermediate hybridize with free complementary single strands to produce D-loop structures. This reaction is coupled to ATP hydrolysis and is analogous to the renaturation of single-stranded DNA catalyzed by the recA protein [Weinstrock, G.M., McEntee, K. & Lehman, I.R. (1979) Proc. Natl. Acad. Sci. USA 76, 126-130]. Hydrolysis of ATP appears to be required in these reactions for dissociation of recA protein from the DNA.

Enhanced transformability with heterospecific deoxyribonucleic acid upon removal of nascent ribonucleic acid from the Streptococcus sanguis genome

Treatment of Streptococcus sanguis recipient cells with rifampin (RIF) at the time of deoxyribonucleic acid (DNA) addition was an effective means of reducing discrimination, that is, of causing an increase in the number of transformants induced by irreversibly bound heterospecific DNA without significantly changing the number induced by bound homospecific DNA. RIF was unable to reduce discrimination when the recipient cells were RIF resistant due to an altered ribonucleic acid (RNA) polymerase. When recipient cells were treated at the time of DNA addition with concentrations of streptolydigin (STG) as inhibitory of RNA synthesis as RIF, discrimination was not reduced. The kinetics of RNA synthesis inhibition with these inhibitors indicated that, as reported for other bacterial species, RIF inhibited the initiation of transcription by RNA polymerase, whereas STG inhibited the progression of RNA polymerase at any point. Pulse-labeling of RNA immediately before STG addition showed that, if cells were incubated under STG inhibition for 10 to 15 min, their nascent RNA was degraded. Genome-bound RNA polymerase was not released under these conditions. When recipient cells were incubated with STG until nascent RNA was degraded and then exposed to transforming DNA, STG was as effective as RIF in reducing discrimination. The presence of nascent RNA was thereby implicated in the transforming inefficiency of incompletely homologous DNA.

Purified Escherichia coli recA protein catalyzes homologous pairing of superhelical DNA and single-stranded fragments

Purified Escherichia coli recA protein catalyzed ATP-dependent pairing of superhelical DNA and homologous single-stranded fragments. The product of the reaction: (i) was retained by nitrocellulose filters in 1.5 M NaCl/0.15 M Na citrate at pH 7, (ii) was dissociated at pH 12.3 but was not dissociated by heating at 55 degrees C for 4 min or by treatment with 0.2% sodium dodecyl sulfate and proteinase K, (iii) contained covalently closed circular double-stranded DNA (form I DNA), (iv) contained single-stranded fragments associated with replicative form (RF) DNA, and (v) contained a significant fraction of D-loops as judged by electron microscopy. Linear and nicked circular double-stranded DNA did not substitute well for superhelical DNA; intact circular single-stranded DNA did not substitute well for single-stranded fragments. Homologous combinations of single-stranded fragments and superhelical DNA from phages phiX174 and fd reacted, whereas heterologous combinations did not. The reaction required high concentrations of protein and MgCl2. The ATPase activity of purified recA protein was more than 98% dependent on the addition of single-stranded DNA. In 1 mM MgCl2, the ability of superhelical DNA to support the ATPase activity was two-thirds as good as that of single-stranded DNA.

ATP-dependent renaturation of DNA catalyzed by the recA protein of Escherichia coli

The product of the recA gene of Escherichia coli has been purified to near-homogeneity by a simple three-step procedure. Incubation of the recA protein with complementary single strands of DNA, Mg2+, and ATP results in the rapid formation of large DNA aggregates containing many branched structures. As judged by resistance to S1 nuclease and by electron microscopy, these aggregates contain both duplex and single-stranded regions. The renaturation and aggregation of DNA catalyzed by the recA protein is coupled to the hydrolysis of ATP. The recA protein purified from a cold-sensitive recA mutant does not catalyze DNA renaturation or aggregation at 28 degrees C, but does so at 37 degrees C, a finding which correlates with the recombination defect observed in vivo and indicates that this activity is an intrinsic function of the recA protein. These results suggest that the recA protein plays a specific role in strand transfer during recombination and possibly in postreplication repair of damaged DNA.

Repair of cross-linked DNA and survival of Escherichia coli treated with psoralen and light: effects of mutations influencing genetic recombination and DNA metabolism

Repair of cross-linked DNA was studied in Escherichia coli strains carrying mutations affecting DNA metabolism. In wild-type cells, DNA strands cut during cross-link removal were rejoined during a subsequent incubation into high-molecular-weight molecules. This rejoining was dependent on gene products involved in genetic recombination. A close correlation was found relating recombination proficiency, the rate of strand rejoining, and formation of viable progeny after DNA cross-linking by treatment with psoralen and light. Wild-type cells and other mutants which were Rec+ (sbcB, recL, recL sbcB, recB recC sbcA, recB recC sbcB, xthA1, and xthA11) rejoined cut DNA strands at a rate of 0.8 +/- 0.1 min -1 at 37 degrees C and survived 53 to 71 cross-links per chromosome. recB, recC, recB recC, recF, or polA strains showed reduced rates of strand rejoining and survived 4 to 13 cross-links per chromosome. Recombination-deficient strains (recA, recB recC sbcB recF, recB recL) and lexA failed to rejoin DNA strands after crosslink removal and were unable to form colonies after treatments producing as few as one to two cross-links per chromosome. Strand rejoining occurred normally in cells with mutations affecting DNA replication (dnaA, danB, dnaG, and dnaE) under both permissive and nonpermissive conditions for chromosome replication. In a polA polB dnaE strain strand rejoining occurred at 32 degree C but not at 42 degree C, indicating that some DNA synthesis was required for formation of intact recombinant molecules.

Topography and kinetics of genetic recombination in Escherichia coli treated with psoralen and light

Genetic exchanges appear to be involved in repair of cross-linked DNA. Kinetics for completion of repair and strand rejoining controlled by the recA(+) gene were examined in Escherichia coli treated with psoralen and light. The results suggest the following model for genetic recombination. After cross-linking treatment, cells in a population initiate repair in near synchrony. Removal of DNA cross-links, preparation of substrate for recombination, and initiation of the first recA-dependent event are completed in less than 1 min. Recombination events occur singly in each cell or chromosome, and require 2.3 +/- 0.4 min at 32 degrees for the recA(+)-dependent step. After completion of the first event, subsequent recombination events occur in a sequential or progressive fashion around the chromosome or in clusters which may consist of one or more domains of the folded chromosome. The time required to proceed to successive sites is either a constant, independent of the distance on the chromosome, or is quite small compared to 2.3 min. DNA substrate for recombination decays with approximate first-order kinetics and the rate is dependent on the number of unrepaired sites. Cell survival can be expressed as a competition between completion of all repair events and the simultaneous decay of chromosomes to forms not reparable by recombination.Equations relating kinetics for completion of repair, the size distribution of DNA molecules, and cell survival are derived for the above model, using as parameters only rate constants for recombination and decay of substrate, and number of events per chromosome. An excellent correlation is found between experimentally determined and theoretical values.

Homology-dependent cutting in trans of DNA in extracts of Escherichia coli: an approach to the enzymology of genetic recombination

An in vitro system is described in which the cutting of crosslinked phiX replicative form (RF) I DNA molecules by the uvr system of Escherichia coli induces the cutting of homologous undamaged DNA during incubation with crude extracts of thermally induced E. coli (lambda precA+) lysogens. This reaction, which has also been observed in intact E. coli lysogens infected with lambda phages, is dependent on the presence of functional recA+ and uvrB+ gene products. Extracts from thermally induced lambda precA+ lysogens of E. coli proved to be substantially more active than extracts from nonlysogenic cells of the same strain. The results provide preliminary evidence for an endonuclease activity that cuts intact superhelical DNA in response to interaction with homologus damaged DNA. In the present paper, we describe an in vitro system in which both the endonucleolytic cutting of DNA containing crosslinks and the induced cutting of undamaged DNA can be studied without purification of the participating enzymes. Although the information obtained is fragmentary and often puzzling, we feel that this system can contribute to an understanding of the complex mechanisms involved in repair and recombination.

Renaturation of complementary single-stranded DNA circles: complete rewinding facilitated by the DNA untwisting enzyme

Renaturation of two complementary single-stranded circles should be limited by topological constraints against the rewinding of the DNA helix. If a mixture of complementary single-stranded rings is annealed and then treated with the DNA untwisting enzyme, the DNA circles completely renature as judged by (i) the presence of interlocked rings that sediment at 53 S in alkali, (ii) the buoyant density of the renatured DNA in CsCl gradients containing ethidium bromide, and (iii) the resistance of the product to the single-strand-specific S1 nuclease. Therefore, the DNA untwisting enzyme is able to provide a transient single-strand break that is sufficient to allow the two strands to completely rewind. The possibility that the untwisting enzyme might facilitate the initiation of the process of genetic recombination is discussed.