DNase I footprinting analysis of RecA protein polymerized on DNA during strand exchange reaction between a gapped circle and a linear duplex.

RecA protein mediates homologous pairing and strand exchange reactions between a circular duplex with a single strand gap and a linear duplex. We have used the DNase I footprinting method to analyze processes involving four strands during these reactions. We asked how the length of DNA protected by RecA protein changes as these reactions proceed. We compared two kinds of gapped DNAs. We found that RecA protein polymerizes rapidly in the forward direction (5' to 3' with respect to the single strand). We found, however, that polymerization in the reverse direction was more prominent with a duplex carrying a longer gap than one carrying a shorter gap. DNase I footprints showing protection by RecA protein were obtained only at limited nuclease concentrations, which in turn depended on the position of the end label and the stage of the strand exchange reaction. As judged by the concentrations of DNase I good for footprinting, the extent of protection by RecA protein was greatest for (+) single-stranded DNA at its first binding site, next highest for heteroduplex containing this (+) strand, and least for the gapped homoduplex DNA. These differences in DNase I sensitivity can be explained in terms of differences in the accessibility of various strands on the basis of a three-dimensional model for the strand exchange reaction.

RecA-ssDNA interaction: induced strand cleavage by hydroxyl radical at a defined distance from the 5' end.

Interaction of the RecA protein with single-stranded DNA (ssDNA) was analyzed by challenge with the hydroxyl radical, which can cleave the DNA backbone. We found that RecA protein induces cleavage by the radical at a defined distance from the 5' end. The cleavage was at the 11th nucleotide in many oligodeoxynucleotides. Cleavage may be intermittent since a second cleavage was induced at the 22nd or 21st site. This specific cleavage was observed under optimal conditions for filament formation, homologous pairing and strand exchange. Specificity in cleavage was, however, decreased by replacement of ATP by adenosine 5'-(gamma-thio)triphosphate (ATP gamma S), replacement of RecA protein by a mutant (RecA1) protein, or an increase in Mg2+ concentration. We propose that RecA protein induces a special structural alteration, such as bending, perhaps sequentially, on ssDNA and that this altered site plays an important role in homologous pairing and strand exchange.

Proteins induced by DNA-damaging agents in cultured Drosophila cells.

In Drosophila cultured cells, the effects of several DNA-damaging agents on the expression of proteins were investigated. Poly(A+) RNA prepared from both untreated cells and cells treated with DNA-damaging agents was translated in vitro. The translation products were analyzed by two-dimensional electrophoresis. Methyl methanesulfonate, the most potent agent used, induced about 25 proteins, some new and some enhanced pre-existing proteins. Angelicin plus near UV irradiation, 4-nitroquinoline N-oxide and ethyl methanesulfonate were efficient inducers. Mitomycin C, UV irradiation and hydrogen peroxide were poor inducers, inducing only a few proteins at low levels. A tumor promoter, 12-O-tetradecanoylphorbol-13-acetate, and a DNA gyrase inhibitor, nalidixic acid, also were used. In this system they were weak inducers of new proteins. Several of the new or enhanced proteins were common to several agents, but others were agent specific. The distribution of mutagen-induced proteins was compared with that of proteins induced in cells heated at 37 degrees C. Some of the proteins induced by DNA-damaging agents were found to overlap heat-shock proteins. These results suggest that there are sets of induced genes that are regulated differently.

Incision by UvrABC excinuclease is a step in the path to mutagenesis by psoralen crosslinks in Escherichia coli.

4,5',8-Trimethylpsoralen (psoralen) plus near UV light produces interstrand crosslinks and monoadducts in DNA, both of which are mutagenic. In Escherichia coli, crosslinks are incised by UvrABC excinuclease, an event that can lead to homologous recombination and repair. To determine whether UvrABC incision of crosslinks is a step in the path to mutagenesis as well as repair, the effect of DNA homologous to a target gene on a plasmid was determined. pSV2-gpt DNA was treated with psoralen and transformed into a pair of hosts: one was gpt+, the other was delta (gpt-lac)5. The DNA was extracted and transformed into a tester strain [delta (gpt-lac)5] in which Gpt- mutations in the plasmid were scored. The results show that psoralen-induced mutations were reduced to background levels by the presence of the gpt+ homolog in the host chromosome. delta gpt hosts that were constitutively induced for the SOS response yielded point mutations, whereas noninduced hosts yielded almost exclusively large deletions. Since crosslinks were estimated to be responsible for most of the mutations observed, we conclude that the premutagenic lesion of psoralen crosslinks is recombinagenic and therefore very likely to be the product of UvrABC incision.

In vitro repair of psoralen-DNA cross-links by RecA, UvrABC, and the 5'-exonuclease of DNA polymerase I.

Psoralens produce DNA interstrand cross-links which are thought to be repaired via a sequential excision and recombination mechanism in Escherichia coli. The first round of incision by UvrABC has been characterized: it results in 11-base oligonucleotide cross-linked to an intact DNA strand (Van Houten, B., Gamper, B., Holbrook, S.R., Hearst, J.E., and Sancar, A. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 8077-8081). In the present work, DNA substrates containing 4'-hydroxymethyl-4,5',8-trimethylpsoralen (HMT) cross-links in defined positions are constructed and used to analyze the other steps in repair. It is shown that RecA protein mediates strand transfer past an oligonucleotide cross-linked to a single-stranded DNA circle and that the resulting heteroduplex is a substrate for the UvrABC complex: it excises a double-stranded oligonucleotide which contains the HMT cross-link. It is also found that the first round of UvrABC incision does not lead directly to strand exchange but that an intervening step is needed. That step is carried out in vitro by the 5'-exonuclease activity of DNA polymerase I (pol I) which creates a single-stranded DNA region (a gap) at an incised cross-link such that RecA can initiate strand exchange. Studies using cross-linked oligonucleotides showed that the gap produced by pol I results from the inability of the polymerase to add nucleotides to a 3'-OH end two to three nucleotides away from the furan side of an HMT cross-link. Pol I can, however, extend a 3'-OH end next to the pyrone side of the cross-link. Since UvrABC incises predominantly the furan side of psoralen cross-links in duplex DNA, this discrepancy has important consequences for repair.

Structure of helical RecA-DNA complexes. III. The structural polarity of RecA filaments and functional polarity in the RecA-mediated strand exchange reaction.

The RecA protein of Escherichia coli has been used in vitro to mediate a strand-exchange reaction between homologous DNA molecules. A three-dimensional reconstruction of a RecA filament on double-stranded DNA has been previously determined from electron micrographs, and the reconstruction displays a clear axial polarity. The RecA-mediated strand-exchange reaction between a double-stranded DNA and a homologous single-stranded DNA that is complexed with a RecA helical polymer proceeds with a known polarity. Using image analysis of electron micrographs, we have determined the relation between the structural polarity of RecA filaments and the 3' and 5' polarity of single-stranded DNA. Thus, the structural polarity of RecA filaments can now be related to the direction in which the RecA-mediated strand-exchange reaction advances along the complexed single-stranded DNA.

RecA-mediated strand exchange reactions between duplex DNA molecules containing damaged bases, deletions, and insertions.

RecA protein from Escherichia coli promotes homologous pairing and strand exchange between duplex DNA molecules if one is partially single-stranded. Using linear duplexes and circles with a single-stranded gap as the substrates, this reaction generates nicked circular heteroduplex DNA and linear molecules with single-stranded ends. The completion of strand exchange can be demonstrated by the production of nicked circular heteroduplex DNA detected by gel electrophoresis and autoradiography using radiolabeled linear molecules. When the effect of ultraviolet damage to the substrate DNA was tested, strand exchange was found to pass 30 or more pyrimidine dimers in each duplex. In contrast, exchanges were blocked or severely slowed by interstrand cross-links and monoadducts produced by psoralen and 360 nm light. Deletions and insertions of from 4 to 38 base pairs in the DNA substrates had little effect on the production of nicked circular heteroduplex DNA. However, those of 120 base pairs, or greater, reduced the product yield to a level below the threshold of detection. These results contrast with those obtained in related three-stranded reactions (Bianchi, M. E., and Radding, C. M. (1984) Cell 35, 511-520), in which stable heteroduplex products with 500 or 1300 unpaired bases were obtained when the insert was located within a single-stranded circular substrate.

Partial purification of an activity from human cells that promotes homologous pairing and the formation of heteroduplex DNA in the presence of ATP.

An activity that can promote homologous pairing and strand transfer between suitable DNA substrates has been partially purified from human skin fibroblasts and from HeLa cells. The strand transfer reaction was investigated with DNA substrates consisting of single-stranded circular and duplex linear phage DNA. It requires ATP, and under optimal conditions yields heteroduplex molecules containing one strand from each parental DNA substrate. The reactions appears to be of the same general nature as those mediated by RecA proteins of Escherichia coli and the Rec1 protein of Ustilago maydis.

The binding of RecA protein to duplex DNA molecules is directional and is promoted by a single stranded region.

RecA protein from E. coli binds more strongly to single stranded DNA than to duplex molecules. Using duplex DNA that contains single stranded gaps, we have studied the protection by RecA protein at various concentrations, of restriction sites as a function of their distance from the single stranded region. We show that the binding of RecA protein, initiated in the single stranded region, extends progressively along the adjoining duplex in the 5' to 3' direction with respect to the single stranded region. The strand exchange reaction is known to proceed in the same direction.

Hexamine cobalt chloride promotes intermolecular ligation of blunt end DNA fragments by T4 DNA ligase.

Hexamine cobalt chloride (HCC) increases the efficiency of blunt end ligation by T4 DNA ligase about 50 fold. Maximum stimulation occurs when standard buffers for ligation are supplemented with 1 mM HCC. All the ligation events are intermolecular regardless of the initial DNA concentration. In the presence of monovalent cations (eg. 25 mM KCl) HCC still increases the extent of T4 catalyzed ligation but intramolecular ligation products are also formed. Therefore, intermolecular ligation can be performed rapidly and at low DNA concentrations.

Isolation of altered recA polypeptides and interaction with ATP and DNA.

In this paper we describe the partial proteolytic digestion of recA proteins from Escherichia coli and Proteus mirabilis and the production and isolation of truncated recA polypeptides. A proteolytic fragment of the P. mirabilis recA protein bound single-strand DNA and ATP normally but has altered duplex DNA binding properties. This protein was shown to initiate but not complete DNA strand transfer from a DNA duplex to a complementary single strand. The product of the E. coli recA1 allele bound but could not hydrolyze ATP and the protein bound single-strand but not double-strand DNA. This protein did not appear to initiate the transfer of a strand from a linear duplex to a single-strand circle and inhibited the wild-type recA protein from performing strand transfer. We report that recA protein binds linear duplex DNA in a manner that enhances the rate of ligation by T4 DNA ligase. When heterologous single-strand DNA was added in addition to the duplex DNA large stable aggregates of protein and DNA were formed that could easily be sedimented from solution.

Duplex-duplex interactions catalyzed by RecA protein allow strand exchanges to pass double-strand breaks in DNA.

Using gapped circular DNA and homologous duplex DNA cut with restriction nucleases, we show that E. coli RecA protein promotes strand exchanges past double-strand breaks. The products of strand exchange are heteroduplex DNA molecules that contain nicks, which can be sealed by DNA ligase, thereby effecting the repair of double-strand breaks in vitro. These results show that RecA protein can promote pairing interactions between homologous DNA molecules at regions where both are duplex. Moreover, pairing leads to strand exchanges and the formation of heteroduplex DNA. In contrast, strand exchanges are unable to pass a double-strand break in the gapped substrate. This apparent paradox is discussed in terms of a model for RecA-DNA interactions in which we propose that each RecA monomer contains two nonequivalent DNA-binding sites.

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.

Purification and properties of the recA protein of Proteus mirabilis. Comparison with Escherichia coli recA protein; specificity of interaction with single strand binding protein.

The product of the cloned recA+ gene of Proteus mirabilis substitutes for a defective recA protein in Escherichia coli recA- mutants and restores recombination, repair, and prophage induction functions to near normal levels (Eitner, G., Adler, B., Lanzov, V. A., and Hofemeister, J. (1982) Mol. Gen. Genet. 185, 481-486). In this paper, we report the purification to near homogeneity of the P. mirabilis recA protein (recApm). The polypeptide has a molecular weight similar to that of E. coli recA protein (recAec) and shows partial identity with recAec when reacted against antibodies specific for the E. coli recA protein. recApm catalyzes the hydrolysis of ATP in the presence of single-stranded but not double-stranded DNA. We have compared the recombination-like activities of recApm with those of recAec and found them to be similar. In the presence of ATP and Mg2+, stoichiometric amounts of recApm promote the complete reciprocal exchange of strands between gapped circular and linear duplex DNA molecules. The enzyme also efficiently promotes the formation of D-loops from circular duplex DNA and homologous single-stranded fragments. However, although recApm and recAec share the above physical and functional similarities, they differ in their ability to interact with the E. coli single strand binding protein to catalyze the transfer of one DNA strand from a linear duplex to a single-stranded circle.

Enzymatic formation of biparental figure-eight molecules from plasmid DNA and their resolution in E. coli.

A key intermediate in general genetic recombination is a structure in which two double-stranded DNA molecules are covalently linked by a single-strand crossover characteristic of a Holliday junction. When the DNA molecules are circular, the recombinant structures take the form of a figure eight. We have used purified E. coli enzymes to construct biparental figure-eight DNA molecules in vitro from the DNA of two partially homologous plasmids. When purified figure-eight structures are transfected into recA- E. coli cells, they are resolved to produce monomeric or dimeric plasmid progeny, apparently by the cutting and joining of the Holliday crossover. The maturation of figure-eight molecules in bacteria is characterized by the formation and recovery of both parental and recombinant types, cross-over at a frequency of up to 50% and the capability for mismatch repair at regions of hybrid DNA. In these three regards, the products of figure-eight maturation resemble recombinant chromosomes formed at meiosis. These observations show that biparental figure eights behave as recombination intermediates that can be resolved into mature recombinants without need for a functional recA+ gene product.

Role of SSB protein in RecA promoted branch migration reactions.

The RecA protein of Escherichia coli is essential for genetic recombination and postreplicational repair of DNA. In vitro, RecA protein promotes strand transfer reactions between full length linear duplex and single stranded circular DNA of phi X174 to form heteroduplex replicative form II-like structures (Cox and Lehman 1981 a0. In a similar way, it transfers one strand of a short duplex restriction fragment to a single stranded circle. Both reactions require RecA and single strand binding protein (SSB) in amounts sufficient to saturate the ssDNA. The rate and extent of strand transfer is enhanced considerably when SSB is added after preincubation of the DNA with RecA protein. In contrast, SSB protein is not required for RecA protein catalysed reciprocal strand exchanges between regions of duplex DNA. These results indicate that while SSB is necessary for efficient transfer between linear duplex and ssDNA to form a single heteroduplex, it is not required for branch migration reactions between duplex molecules that form two heteroduplexes.

Can recA protein promote homologous pairing between duplex regions of DNA?

RecA protein has been shown to promote the formation of joint molecules between intact duplex DNA and homologous gapped DNA. When examined by electron microscopy, such joint molecules display a junction that is, in most cases, distant from the site of the gap. This led us to test whether the observed location of the joint was due to pairing at the gap followed by branch migration, or whether recA-promoted pairing could also take place between duplex homologous regions away from the gap. To test the latter possibility, intact duplex DNA was incubated with DNA which contained a gap in a region of non-homology. Joint molecules were detected by filter binding assay and by electron microscopy at about one-third of the yield observed for fully homologous molecules. These results indicate that initial homologous pairing promoted by recA protein is not restricted to the single-stranded region in the gap but can also take place in regions where both molecules are duplex.

Postreplication repair in E. coli: strand exchange reactions of gapped DNA by RecA protein.

We have used a sensitive gel electrophoresis assay to detect the products of Escherichia coli RecA protein catalysed strand exchange reactions between gapped and duplex DNA molecules. We identify structures that correspond to joint molecules formed by homologous pairing, and show that joint molecules are converted by RecA protein into heteroduplex monomers by reciprocal strand exchanges. However, strand exchanges only occur when there is a 3'-terminus complementary to the single stranded DNA in the gap. In the absence of a complementary free end, the two DNA molecules pair and short heteroduplex regions are formed by localised interwinding.