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.     

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.     

Homologous pairing and strand exchange promoted by the Escherichia coli RecT protein.

RecT protein of Escherichia coli promotes the formation of joint molecules between homologous linear double-stranded M13mp19 replicative-form bacteriophage DNA and circular single-stranded M13mp19 DNA in the presence of exonuclease VIII, the recE gene product. The joint molecules were formed by a mechanism involving the pairing of the complementary strand of the linear double-stranded DNA substrate with the circular single-stranded DNA substrate coupled with the displacement of the noncomplementary strand. When the homologous linear double-stranded DNA substrate had homologous 3' or 5' single-stranded tails, then RecT promoted homologous pairing and strand exchange in the absence of exonuclease VIII. Histone H1 could substitute for RecT protein; however, joint molecules formed in the presence of histone H1 did not undergo strand exchange. These results indicate that under the reaction conditions used, the observed strand exchange reaction is promoted by RecT and is not the result of spontaneous branch migration. These results are consistent with the observation that expression of RecE (exonuclease VIII) and RecT substitutes for RecA in some recombination reactions in E. coli.     

Direct observation of DNA rotation during branch migration of Holliday junction DNA by Escherichia coli RuvA-RuvB protein complex

The Escherichia coli RuvA-RuvB complex promotes branch migration of Holliday junction DNA, which is the central intermediate of homologous recombination. Like many DNA motor proteins, it is suggested that RuvA-RuvB promotes branch migration by driving helical rotation of the DNA. To clarify the RuvA-RuvB-mediated branch migration mechanism in more detail, we observed DNA rotation during Holliday junction branch migration by attaching a bead to one end of cruciform DNA that was fixed to a glass surface at the opposite end. Bead rotation was observed when RuvA, RuvB, and ATP were added to the solution. We measured the rotational rates of the beads caused by RuvA-RuvB-mediated branch migration at various ATP concentrations. The data provided a K(m) value of 65 microM and a V(max) value of 1.6 revolutions per second, which corresponds to 8.3 bp per second. This real-time observation of the DNA rotation not only allows us to measure the kinetics of the RuvA-RuvB-mediated branch migration, but also opens the possibility of elucidating the branch migration mechanism in detail.     

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.     

Polarity of heteroduplex formation promoted by Escherichia coli recA protein.

When recA protein pairs circular single strands with linear duplex DNA, the circular strand displaces its homolog from only one end of the duplex molecule and rapidly creates heteroduplex joints that are thousands of base pairs long [DasGupta, C., Shibata, T., Cunningham, R. P. & Radding, C. M. (1980) Cell 22, 437-446]. To examine this apparently polar reaction, we prepared chimeric duplex fragments of DNA that had M13 nucleotide sequences at one end and G4 sequences at the other. Circular single strands homologous to M13 DNA paired with a chimeric fragment when M13 sequences were located at the 3' end of the complementary strand but did not pair when the M13 sequences were located at the 5' end. Likewise circular single-stranded G4 DNA paired with chimeric fragments only when G4 sequences were located at the 3' end of the complementary strand. To confirm these observations, we prepared fd DNA labeled only at the 5' or 3' end of the plus strand, and we examined the susceptibility of these labeled ends to digestion by exonucleases when joint molecules were formed. Eighty percent of the 5' label in joint molecules became sensitive to exonuclease VII. Displacement of that 5' end by recA protein was concerted because it did not occur in the absence of single-stranded DNA or in the presence of heterologous single strands. By contrast, only a small fraction of the 3' label became sensitive to exonuclease VII or exonuclease I. These observations show that recA protein forms heteroduplex joints in a concerted and polarized way.     

Polar branch migration promoted by recA protein: effect of mismatched base pairs.

Escherichia coli recA protein makes joint molecules from single-stranded circular phage DNA (viral or plus strand) and homologous linear duplex DNA by a polar reaction that displaces the 5' end of the plus strand from the duplex molecule [Kahn, R., Cunningham, R. P., DasGupta, C. & Radding, C. M. (1981) Proc. Natl. Acad. Sci. USA 78, 4786-4790]. Growth of the heteroduplex joint, which results from strand exchange or branch migration, stopped at the borders of regions of nonhomologous DNA that were variously located 145, 630, or 1202 nucleotides from the end. Accumulation of migrating branches at heterologous borders demonstrates that their migration is not the result of random diffusion but is actively driven by recA protein. Growth of the heteroduplex joint was blocked even when a heterologous insertion was located in the single-stranded DNA, a case in which the flexible single-stranded region might conceivably fold out of the way under some condition. The recA protein did not make joint molecules from phage phi X174 and G4DNAs, which are 70% homologous, but did join phage fd and M13DNAs, which are 97% homologous. In the latter case, heteroduplex joints extended through regions containing isolated mismatched base pairs but stopped in a region where the fd and M13 sequences differ by an average of 1 base pair in 10. These results suggest that in genetic recombination the discrimination of perfect or near-perfect homology from a high degree of relatedness may be attributable in part to the mechanism by which recA protein promotes strand transfer.     

On the mechanism of renaturation of complementary DNA strands by the recA protein of Escherichia coli.

The renaturation of complementary DNA strands by the recA protein of Escherichia coli has been found to exhibit the following features. (i) Optimal renaturation occurs at recA protein levels below that required to saturate the DNA strands; saturating amounts of recA protein significantly reduce the rate of reaction. (ii) The reaction proceeds in the absence of a nucleotide cofactor but is markedly stimulated by ATP in the presence of 10 mM Mg2+. A similar stimulation occurs in the absence of ATP when the Mg2+ concentration is increased from 10 mM to 30-40 mM. (iii) Both the ATP-stimulated and the Mg2+-stimulated reactions follow apparent first-order kinetics. These results, taken together with the known effects of ATP and Mg2+ on the state of aggregation of recA protein, suggest that the association of recA monomers may play an important role in recA protein-promoted DNA renaturation.     

Cleavage of the Escherichia coli lexA protein by the recA protease.

The recA and lexA proteins of EScherichia coli are involved in a complex regulatory circuit that allows the expression of a diverse set of functions after DNA damage or inhibition of DNA replication. Exponentially growing cells contain a low level of recA protein, and genetic evidence suggests that lexA protein is involved in its regulation, perhaps as a simple repressor. Recent models for recA derepression after DNA damage have suggested that an early event in this process is the proteolytic cleavage of lexA protein, leading to high-level expression of recA. We present several lines of evidence that the specific protease activity of the recA protein, previously described with the lambda repressor as substrate, is capable of cleaving the wild-type lexA+ protein. First, lexA protein can be cleaved in vitro under the same conditions as prevously described for lambda repressor cleavage in a reaction requring both recA protease and ATP or an analogue, adenosine 5'-[lambda-thio]-triphosphate. Second, lexA protein can be observed in vivo as a physical entity after infection with lambda lexA+ transducing phage of host strains containing ittle or no active protease, but not in strains containing high levels of active protease. Finally, infection of host cells containing active protease with a lambda lexA+ transducing phage does not lead to repression of recA, but does so in cells lacking active protease. In all of these conditions the mutant lexA3 protein is largely resistant to inactivation or cleavage; this resistance can explain the dominant phenotype of lexA3 over lexA+. We discuss models for recA derepression and re-establishment of repression which propose that modulation of the protease activity of recA protein regulates both of these transitions.     

recA protein promotes homologous-pairing and strand-exchange reactions between duplex DNA molecules.

Purified recA protein, product of the recA+ gene, promotes homologous pairing between intact covalent circular duplex DNA and circular single-stranded DNA carrying a short hybridized fragment [West, S. C., Cassuto, E. & Howard-Flanders, P. (1981) Nature (London) 290, 29-33.]. In this paper we investigate the interaction of duplex fragments with circular single-stranded DNA carrying the hybridized fragment and find that recA protein promotes an efficient strand-exchange reaction between interacting DNA molecules. The exchange is dependent upon linear duplex DNA fragments that are homologous to, but extend beyond, the short fragment present on the hybridized DNA substrate. The reactions require stoichiometric amounts of recA protein and the presence of ATP.     

Migration of Escherichia coli dnaB protein on the template DNA strand as a mechanism in initiating DNA replication

The first step in conversion of varphiX174 singlestranded DNA to the duplex replicative form in vitro is the synthesis of a nucleoprotein intermediate [Weiner, J. H., McMacken, R. & Kornberg, A. (1976) Proc. Natl. Acad. Sci. USA 73, 752-756]. We now demonstrate that dnaB protein (approximately one molecule per DNA circle) is an essential component of the intermediate and retains its ATPase activity. Synthesis of RNA primers, dependent on dnaG protein (primase), occurred only on DNA that had been converted to the intermediate form. In a coupled RNA priming-DNA replication reaction the first primer synthesized was extended by DNA polymerase III holoenzyme into full-length complementary strand DNA. In RNA priming uncoupled from replication, multiple RNA primers were initiated on a varphiX174 circle. The single dnaB protein molecule present on each DNA circle participated in initiation of each of the RNA primers, which appear to be aligned at regular intervals along the template strand. We propose that dnaB protein, once bound to the template, migrates in a processive fashion along the DNA strand, perhaps utilizing energy released by hydrolysis of ATP for propulsion; in this scheme the actively moving dnaB protein acts as a "mobile promoter" signal for dnaG protein (primase) to produce many RNA primers. Schemes are proposed for participation of dnaB protein both in the initiation of replication at the origin of the Escherichia coli chromosome and in the initiation of primers for nascent (Okazaki) fragments at a replication fork.     

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

When a mixture of superhelical DNA (RFI) of phage phiX174 am3 and fragments of single-stranded DNA from wild-type phiX174 was added to spheroplasts of E. coli carrying an amber suppressor, several percent of the progeny phage were recombinant. The yield of wild-type progeny was 10(3) to 10(4) times lower when the fragments came from phiX174 am3 or phage G4 am+, or when fragments were absent. Fewer recombinants were produced in proportion to the decrease in the fraction of RFI in samples treated with S1 nuclease, whereas the total yield of phage did not decrease. Transfection by fragments and superhelical DNA produced 20 to 100 times more recombinants than transfection by fragments and either nicked circular DNA or relaxed closed circular DNA. Transfection of a recA- strain by RFI DNA and fragments yielded 5-10% as many recombinants as transfection of a rec+ strain. This partial requirement for recA was bypassed by transfection with complexes of RFI AM3 DNA and am+ fragments made in vitro.     

Escherichia coli RecQ protein is a DNA helicase.

The Escherichia coli recQ gene, a member of the RecF recombination gene family, was set in an overexpression plasmid, and its product was purified to near-homogeneity. The purified RecQ protein exhibited a DNA-dependent ATPase and a helicase activity. Without DNA, no ATPase activity was detected. The capacity as ATPase cofactor varied with the type of DNA in the following order: circular single strand greater than linear single strand much greater than circular or linear duplex. As a helicase, RecQ protein displaced an annealed 71-base or 143-base single-stranded fragment from circular or linear phage M13 DNA, and the direction of unwinding seemed to be 3'----5' with respect to the DNA single strand to which the enzyme supposedly bound. Furthermore, the protein could unwind 143-base-pair blunt-ended duplex DNA at a higher enzyme concentration. It is concluded that RecQ protein is a previously unreported helicase, which might possibly serve to generate single-stranded tails for a strand transfer reaction in the process of recombination.     

The RecA proteins of Deinococcus radiodurans and Escherichia coli promote DNA strand exchange via inverse pathways

The RecA protein of Escherichia coli, and all filament-forming homologues identified to date, promote DNA strand exchange by a common, ordered pathway. A filament is first formed on single-stranded DNA, followed by uptake of the duplex substrate. These proteins are thereby targeted to single-strand gaps and tails where recombinational DNA repair is required. The observed course of DNA strand exchange promoted by the RecA protein from the extremely radioresistant bacterium Deinococcus radiodurans is the exact inverse of this established pathway. This reaction lies at the heart of a remarkably efficient system for the repair of DNA damage.     

Identification and radiochemical purification of the recA protein of Escherichia coli K-12.

The product of the recA gene of E. coli has been identified by labeling proteins synthesized in UV-treated cells after infection with specialized transducing phages carrying the recA gene. Following infection of UV-treated cells by lambda precA, which carries the recA+ gene, a major protein with a molecular weight of 43,000 is detected on polyacrylamide gels containing sodium dodecyl sulfate. This protein is also made after infection of suppressing hosts by lambda precA99, which carries an amber recA- mutation, but is not synthesized after infection of nonsuppressing hosts by this transducing phage. A spontaneous recatrevertant of lambda preca99 induces synthesis of this protein after infection of a nonsuppressing host. The product of the recA gene is a soluble protein found in a complex with a molecular weight of approximately 150,000 after mild detergent lysis of cells.     

Recombinational bypass of pyrimidine dimers promoted by the recA protein of Escherichia coli.

recA protein, in the presence of single-stranded DNA binding protein and ATP, promotes the complete exchange of strands between circular single-stranded DNA containing pyrimidine dimers and a homologous linear duplex, converting the pyrimidine dimer-containing single-stranded DNA to a circular duplex. Bypass of a pyrimidine dimer during the branch-migration phase of the reaction requires approximately 20 seconds, a rate 1/50th of that in the absence of the dimer. The circular duplex product is specifically incised by the pyrimidine dimer-specific T4 endonuclease V, and the resulting 3' hydroxyl termini can serve as primers for deoxynucleotide polymerization by DNA polymerase I. These findings indicate that recA protein serves a direct role in recombinational repair and demonstrate that the pyrimidine dimers that have been bypassed can be processed by enzymes of the excision-repair pathway.     

tif-1 mutation alters polynucleotide recognition by the recA protein of Escherichia coli.

The requirements for polynucleotide-dependent hydrolysis of ATP and for proteolytic cleavage of phage lambda repressor have been examined for both the wild-type (recA+ protein) and the tif-1 mutant form [tif(recA) protein] of the recA gene product. The recA+ and tif(recA) proteins catalyze both reactions in the presence of long single-stranded DNAs or certain deoxyhomopolymers. However, short oligonucleotides [(dT)12, (dA)14] stimulate neither the protease nor the ATPase activities of the recA+ protein. In contrast, these short oligonucleotides activate tif(recA) protein to cleave lambda repressor without stimulating its ATPase activity. Moreover, both the ATPase and protease activities of the tif(recA) protein are stimulated by poly(rU) and poly(rC) whereas the recA+ protein does not respond to these ribopolymers. We have purified the recA protein from a strain in which the tif mutation is intragenically suppressed. This mutant protein (recA629) is inactive in the presence of (dT)12, (dA)14, poly(rU), and poly(rC) for lambda repressor cleavage and ATP hydrolysis. These results argue that the tif-1 mutation (or mutations) alters the DNA binding site of the recA protein. We suggest that in vivo the tif(recA) protein is activated for cleaving repressors of SOS genes by complex formation with short single-stranded regions or gaps that normally occur near the growing fork of replicating chromosomes and are too short for activating the recA+ enzyme. This mechanism can account for the expression of SOS functions in the absence of DNA damage in tif mutant strains.     

Heteroduplex formation by recA protein: polarity of strand exchanges.

Purified recA protein promotes strand exchanges between linear duplex DNA and homologous circular single-stranded phage phi X174 DNA that carries a short hybridized fragment [West, S. C., Cassuto, E. & Howard-Flanders, P. (1981) Proc. Natl. Acad. Sci. USA 78, 2100-2104]. In this paper we investigate the mechanism of this strand exchange reaction. We show that recA protein initiates strand exchanges by pairing the free end of the duplex fragment with the single-stranded DNA. In addition, we find that strand exchanges are polar, stable heteroduplex molecules being formed by the directional transfer transfer of the (-) strands starting at 3' termini.