Biochemical events essential to the recombination activity of Escherichia coli RecA protein. II. Co-dominant effects of RecA142 protein on wild-type RecA protein function

In the accompanying paper, RecA142 protein was found to be completely defective in DNA heteroduplex formation. Here, we show that RecA142 protein not only is defective in this activity but also is inhibitory for certain activities of wild-type RecA protein. Under appropriate conditions, RecA142 protein substantially inhibits the DNA strand exchange reaction catalyzed by wild-type RecA protein; at equimolar concentrations of each protein, formation of full-length gapped duplex DNA product molecules is less than 7% of the amount produced by wild-type protein alone. Inhibition by RecA142 protein is also evident in S1 nuclease assays of DNA heteroduplex formation, although the extent of inhibition is less than is observed for the complete DNA strand exchange process; at equimolar concentrations of wild-type and mutant proteins, the extent of DNA heteroduplex formation is 36% of the wild-type protein level. This difference implies that RecA142 protein prevents, at minimum, the branch migration normally observed during DNA strand exchange. RecA142 protein does not inhibit either the single-strand (ss) DNA-dependent ATPase activity or the coaggregation activities of wild-type RecA protein. This suggests that these reactions are not responsible for the inhibition of wild-type protein DNA strand exchange activity by RecA142 protein. However, under conditions where RecA142 protein inhibits DNA strand exchange activity, RecA142 protein renders the M13 ssDNA-dependent ATPase activity of wild-type protein sensitive to inhibition by single-strand DNA-binding protein, and it inhibits the double-strand DNA-dependent ATPase activity of wild-type RecA protein. These results imply that these two activities are important components of the overall DNA strand exchange process. These experiments also demonstrate the applicability of using defective mutant RecA proteins as specific codominant inhibitors of wild-type protein activities in vitro and should be of general utility for mechanistic analysis of RecA protein function both in vitro and in vivo.     

Solution structure of DinI provides insight into its mode of RecA inactivation

The Escherichia coli RecA protein triggers both DNA repair and mutagenesis in a process known as the SOS response. The 81-residue E. coli protein DinI inhibits activity of RecA in vivo. The solution structure of DinI has been determined by multidimensional triple resonance NMR spectroscopy, using restraints derived from two sets of residual dipolar couplings, obtained in bicelle and phage media, supplemented with J couplings and a moderate number of NOE restraints. DinI has an alpha/beta fold comprised of a three-stranded beta-sheet and two alpha-helices. The beta-sheet topology is unusual: the central strand is flanked by a parallel and an antiparallel strand and the sheet is remarkably flat. The structure of DinI shows that six negatively charged Glu and Asp residues on DinI's kinked C-terminal alpha-helix form an extended, negatively charged ridge. We propose that this ridge mimics the electrostatic character of the DNA phospodiester backbone, thereby enabling DinI to compete with single-stranded DNA for RecA binding. Biochemical data confirm that DinI is able to displace ssDNA from RecA.     

Targeting of a functional Escherichia coli RecA protein to the nucleus of plant cells

We have characterised a RecA protein fused to the simian virus 40 large T nuclear-localisation signal. The fusion protein was targeted to the nucleus in transgenic tobacco plants with high efficiency. By contrast, authentic RecA was not enriched in the nuclei of plant cells expressing comparable amounts of protein. For detailed characterisation of the strand-exchange activity of the nuclear-targeted RecA protein, a nearly identical protein was expressed in Escherichia coli and purified to homogeneity. This protein was found to bind to single-stranded DNA with the same stoichiometry and to promote the exchange of homologous DNA strands with the same kinetics as authentic RecA. It was concluded that the amino-terminal modification did not alter any of the essential properties of RecA and that the fusion protein is a fully functional strand-exchange protein. However, the ATPase activity of this protein was 20 times greater than that of RecA in the absence of single-stranded DNA. As with RecA, this activity was further stimulated by the addition of single-stranded DNA. Since ATPase activity is correlated with the ability of RecA to assume its high affinity state for DNA, the nuclear-targeted RecA protein might be regarded as a constitutively stimulated RecA variant, fully functional in promoting homologous recombination.     

Effects of the Escherichia coli SSB protein on the binding of Escherichia coli RecA protein to single-stranded DNA. Demonstration of competitive binding and the lack of a specific protein-protein interaction

The effect of the Escherichia coli single-stranded DNA binding (SSB) protein on the stability of complexes of E. coli RecA protein with single-stranded DNA has been investigated through direct DNA binding experiments. The effect of each protein on the binding of the other to single-stranded DNA, and the effect of SSB protein on the transfer rate of RecA protein from one single-stranded DNA molecule to another, were studied. The binding of SSB protein and RecA protein to single-stranded phage M13 DNA is found to be competitive and, therefore, mutually exclusive. In the absence of a nucleotide cofactor, SSB protein binds more tightly to single-stranded DNA than does RecA protein, whereas in the presence of ATP-gamma-S, RecA protein binds more tightly than SSB protein. In the presence of ATP, an intermediate result is obtained that depends on the type of DNA used, the temperature, and the magnesium ion concentration. When complexes of RecA protein, SSB protein and single-stranded M13 DNA are formed under conditions of slight molar excess of single-stranded DNA, no effect of RecA protein on the equilibrium stability of the SSB protein-single-stranded DNA complex is observed. Under similar conditions, SSB protein has no observed effect on the stability of the RecA protein-etheno M13 DNA complex. Finally, measurements of the rate of RecA protein transfer from RecA protein-single-stranded DNA complexes to competing single-stranded DNA show that there is no kinetic stabilization of the RecA protein-etheno M13 DNA complex by SSB protein, but that a tenfold stabilization is observed when single-stranded M13 DNA is used to form the complex. However, this apparent stabilizing effect of SSB protein can be mimicked by pre-incubation of the RecA protein-single-stranded M13 DNA complex in low magnesium ion concentration, suggesting that this effect of SSB protein is indirect and is mediated through changes in the secondary structure of the DNA. Since no direct effect of SSB protein is observed on either the equilibrium or dissociation properties of the RecA protein-single-stranded DNA complex, it is concluded that the likely effect of SSB protein in the strand assimilation reaction is on a slow step in the association of RecA protein with single-stranded DNA. Direct evidence for this conclusion is presented in the accompanying paper.     

RecA Protein from the extremely radioresistant bacterium Deinococcus radiodurans: expression, purification, and characterization

The RecA protein of Deinococcus radiodurans (RecA(Dr)) is essential for the extreme radiation resistance of this organism. The RecA(Dr) protein has been cloned and expressed in Escherichia coli and purified from this host. In some respects, the RecA(Dr) protein and the E. coli RecA (RecA(Ec)) proteins are close functional homologues. RecA(Dr) forms filaments on single-stranded DNA (ssDNA) that are similar to those formed by the RecA(Ec). The RecA(Dr) protein hydrolyzes ATP and dATP and promotes DNA strand exchange reactions. DNA strand exchange is greatly facilitated by the E. coli SSB protein. As is the case with the E. coli RecA protein, the use of dATP as a cofactor permits more facile displacement of bound SSB protein from ssDNA. However, there are important differences as well. The RecA(Dr) protein promotes ATP- and dATP-dependent reactions with distinctly different pH profiles. Although dATP is hydrolyzed at approximately the same rate at pHs 7.5 and 8.1, dATP supports an efficient DNA strand exchange only at pH 8.1. At both pHs, ATP supports efficient DNA strand exchange through heterologous insertions but dATP does not. Thus, dATP enhances the binding of RecA(Dr) protein to ssDNA and the displacement of ssDNA binding protein, but the hydrolysis of dATP is poorly coupled to DNA strand exchange. The RecA(Dr) protein thus may offer new insights into the role of ATP hydrolysis in the DNA strand exchange reactions promoted by the bacterial RecA proteins. In addition, the RecA(Dr) protein binds much better to duplex DNA than the RecA(Ec) protein, binding preferentially to double-stranded DNA (dsDNA) even when ssDNA is present in the solutions. This may be of significance in the pathways for dsDNA break repair in Deinococcus.     

Complete inhibition of Streptococcus pneumoniae RecA protein-catalyzed ATP hydrolysis by single-stranded DNA-binding protein (SSB protein): implications for the mechanism of SSB protein-stimulated DNA strand exchange

The ATP-dependent three-strand exchange activity of the Streptococcus pneumoniae RecA protein (RecA(Sp)), like that of the Escherichia coli RecA protein (RecA(Ec)), is strongly stimulated by the single-stranded DNA-binding protein (SSB) from either E. coli (SSB(Ec)) or S. pneumoniae (SSB(Sp)). The RecA(Sp) protein differs from the RecA(Ec) protein, however, in that its ssDNA-dependent ATP hydrolysis activity is completely inhibited by SSB(Ec) or SSB(Sp) protein, apparently because these proteins displace RecA(Sp) protein from ssDNA. These results indicate that in contrast to the mechanism that has been established for the RecA(Ec) protein, SSB protein does not stimulate the RecA(Sp) protein-promoted strand exchange reaction by facilitating the formation of a presynaptic complex between the RecA(Sp) protein and the ssDNA substrate. In addition to acting presynaptically, however, it has been proposed that SSB(Ec) protein also stimulates the RecA(Ec) protein strand exchange reaction postsynaptically, by binding to the displaced single strand that is generated when the ssDNA substrate invades the homologous linear dsDNA. In the RecA(Sp) protein-promoted reaction, the stimulatory effect of SSB protein may be due entirely to this postsynaptic mechanism. The competing displacement of RecA(Sp) protein from the ssDNA substrate by SSB protein, however, appears to limit the efficiency of the strand exchange reaction (especially at high SSB protein concentrations or when SSB protein is added to the ssDNA before RecA(Sp) protein) relative to that observed under the same conditions with the RecA(Ec) protein.     

Regulation of bacterial RecA protein function

The RecA protein is a recombinase functioning in recombinational DNA repair in bacteria. RecA is regulated at many levels. The expression of the recA gene is regulated within the SOS response. The activity of the RecA protein itself is autoregulated by its own C-terminus. RecA is also regulated by the action of other proteins. To date, these include the RecF, RecO, RecR, DinI, RecX, RdgC, PsiB, and UvrD proteins. The SSB protein also indirectly affects RecA function by competing for ssDNA binding sites. The RecO and RecR, and possibly the RecF proteins, all facilitate RecA loading onto SSB-coated ssDNA. The RecX protein blocks RecA filament extension, and may have other effects on RecA activity. The DinI protein stabilizes RecA filaments. The RdgC protein binds to dsDNA and blocks RecA access to dsDNA. The PsiB protein, encoded by F plasmids, is uncharacterized, but may inhibit RecA in some manner. The UvrD helicase removes RecA filaments from RecA. All of these proteins function in a network that determines where and how RecA functions. Additional regulatory proteins may remain to be discovered. The elaborate regulatory pattern is likely to be reprised for RecA homologues in archaeans and eukaryotes.     

Targeting of a functional Escherichia coli RecA protein to the nucleus of plant cells

 We have characterised a RecA protein fused to the simian virus 40 large T nuclear-localisation signal. The fusion protein was targeted to the nucleus in transgenic tobacco plants with high efficiency. By contrast, authentic RecA was not enriched in the nuclei of plant cells expressing comparable amounts of protein. For detailed characterisation of the strand-exchange activity of the nuclear-targeted RecA protein, a nearly identical protein was expressed in Escherichia coli and purified to homogeneity. This protein was found to bind to single-stranded DNA with the same stoichiometry and to promote the exchange of homologous DNA strands with the same kinetics as authentic RecA. It was concluded that the amino-terminal modification did not alter any of the essential properties of RecA and that the fusion protein is a fully functional strand-exchange protein. However, the ATPase activity of this protein was 20 times greater than that of RecA in the absence of single-stranded DNA. As with RecA, this activity was further stimulated by the addition of single-stranded DNA. Since ATPase activity is correlated with the ability of RecA to assume its high affinity state for DNA, the nuclear-targeted RecA protein might be regarded as a constitutively stimulated RecA variant, fully functional in promoting homologous recombination. Received: 29 July 1996 / Accepted: 24 September 1996     

Removal of the RecA C-terminus results in a conformational change in the RecA-DNA filament

The Escherichia coli RecA protein catalyzes homologous recombination of DNA molecules, and the active form of the protein is a helical polymer that it forms around DNA. Previous image analysis of electron micrographs has revealed the RecA protein to be organized into two domains or lobes within the RecA-DNA filament. We have now been able to show that a small modification of the RecA protein by proteolysis results in a significant shift in the internal mass in the RecA filament. We have cleaved approximately 18 residues from the C-terminus of the RecA protein, producing a roughly 36K MW RecA core protein that binds DNA and polymerizes normally. A three-dimensional reconstruction of this complex has been computed, and has been compared with a previous reconstruction of the intact protein. The main difference is consistent with a 15 A outward movement of the lobe that was at an inner radius in the wild-type protein. These observations yield additional evidence about the conformational flexibility of the RecA filament, and will aid in understanding the structural mechanics and dynamics of the RecA filament.     

Effect of RecF protein on reactions catalyzed by RecA protein.

RecF protein is one of at least three single strand DNA (ssDNA) binding proteins which act in recombination and repair in Escherichia coli. In this paper we show that our RecF protein preparation complexes with ssDNA so as to retard its electrophoretic movement in an agarose gel. The apparent stoichiometry of RecF-ssDNA-binding measured in this way is one RecF molecule for every 15 nucleotides and the binding appears to be cooperative. Interaction of the other two ssDNA-binding proteins, RecA and Ssb proteins, has been studied extensively; so in this paper we begin the study of the interaction of RecF and RecA proteins. We found that the RecF protein preparation inhibits the activity of RecA protein in the formation of joint molecules whether added before or after addition of RecA protein to ssDNA. It, therefore, differs from Ssb protein which stimulates joint molecule formation when added to ssDNA after RecA protein. We found that our RecF protein preparation inhibits two steps prior to joint molecule formation: RecA protein binding to ssDNA and coaggregate formation between ssDNA-RecA complexes and dsDNA. We found that it required a much higher ratio of RecF to RecA protein than normally occurs in vivo to inhibit joint molecule formation. The insight that these data give to the normal functioning of RecF protein is discussed.     

Probing the activation stages of the RecA protein by monoclonal IgGs during the pairing of homologous DNA molecules

The biochemical properties of the RecA protein change in a stepwise manner with the binding of ATP and/or DNA during the course of the ATP-dependent formation of homologous joint molecules, which is assumed to be due to transition in the higher order structure. This transition was supposed to be detectable as changes in the affinity of the protein for monoclonal IgGs. In this study, we introduced an enzyme-linked immunosorbent assay, which enabled us to assay unbound IgG sensitively and quantitatively under the conditions for the RecA protein-mediated joint molecule formation. Through the use of this method, we studied the affinity of three anti-RecA protein monoclonal IgGs toward the RecA protein at the various stages of its activation during the formation of homologous joints. We found that the affinity of the RecA protein changed for each anti-RecA protein-IgG in a specific manner and the change in the cross-reactivity of the RecA protein correlated with its multiple activation stages. This result suggests that the RecA protein changes its higher order structure which is specific to each activation stage during the formation of homologous joint molecules.     

Affinity chromatography of RecA protein and RecA nucleoprotein complexes on RecA protein-agarose columns

We have analyzed the nature of RecA protein-RecA protein interactions using an affinity column prepared by coupling RecA protein to an agarose support. When radiolabeled soluble proteins from Escherichia coli are applied to this column, only the labeled RecA protein from the extract was selectively retained and bound tightly to the affinity column. Efficient binding of purified 35S-labeled RecA protein required Mg2+, and high salt did not interfere with the binding of RecA protein to the column. Complete removal of the bound enzyme from the affinity column required treatment with guanidine HCl (5 M) or urea (8 M). These and other properties suggest that hydrophobic interactions contribute significantly to RecA protein subunit recognition in solution. Using a series of truncated RecA proteins synthesized in vitro, we have obtained evidence that at least some of the sequences involved in protein recognition are localized within the first 90 amino-terminal residues of the protein. Based on the observation that RecA proteins from three heterologous bacteria are specifically retained on the E. coli RecA affinity column, it is likely that this binding domain is highly conserved and is required for interaction and association of RecA protein monomers. Stable ternary complexes of RecA protein and single-stranded DNA were formed in the presence of the nonhydrolyzable ATP analog adenosine 5'-O-(thiotriphosphate) and applied to the affinity columns. Most of the complexes formed with M13 DNA could be eluted in high salt, whereas a substantial fraction of those formed with the oligonucleotide (dT)25-30 remained bound in high salt and were quantitatively eluted with guanidine HCl (5 M). The different binding properties of these RecA protein-DNA complexes likely reflect differences in the availability of a hydrophobic surface on RecA protein when it is bound to long polynucleotides compared to short oligonucleotides.     

Biochemical basis of the constitutive coprotease activity of RecA P67W protein

The mutation of Pro67 to Trp (P67W) in the Escherichia coli RecA protein results in reduced recombination and constitutive coprotease phenotypes. We examined the biochemical properties of this mutant in an effort to understand these altered behaviors. We find that RecA P67W protein can access single-stranded DNA (ssDNA) binding sites within regions of secondary structure more effectively than wild-type protein, and binding to duplex DNA is both faster and more extensive as well. This mutant is also more effective than wild-type RecA protein in displacing SSB protein from ssDNA. An enhancement in SSB protein displacement has been shown previously for RecA441, RecA730, and RecA803 proteins, and similarly, this improved ability to displace SSB protein for RecA P67W protein correlates with an increased rate of association with ssDNA. As for the aforementioned mutant RecA proteins, we expect that this enhanced activity will allow RecA P67W protein to bind ssDNA naturally occurring in undamaged cells and to constitutively induce the SOS response. The DNA strand exchange activity of RecA P67W protein is also altered. Although the rate of duplex DNA uptake into joint molecules is increased compared to that of wild-type RecA protein, the resolution to the nicked circular dsDNA product is reduced. We suggest that either a limited amount of DNA strand reinvasion or a defect in DNA heteroduplex extension is responsible for the impaired recombination ability of this mutant protein.     

Regulation of Bacterial RecA Protein Function

ABSTRACT

The RecA protein is a recombinase functioning in recombinational DNA repair in bacteria. RecA is regulated at many levels. The expression of the recA gene is regulated within the SOS response. The activity of the RecA protein itself is autoregulated by its own C-terminus. RecA is also regulated by the action of other proteins. To date, these include the RecF, RecO, RecR, DinI, RecX, RdgC, PsiB, and UvrD proteins. The SSB protein also indirectly affects RecA function by competing for ssDNA binding sites. The RecO and RecR, and possibly the RecF proteins, all facilitate RecA loading onto SSB-coated ssDNA. The RecX protein blocks RecA filament extension, and may have other effects on RecA activity. The DinI protein stabilizes RecA filaments. The RdgC protein binds to dsDNA and blocks RecA access to dsDNA. The PsiB protein, encoded by F plasmids, is uncharacterized, but may inhibit RecA in some manner. The UvrD helicase removes RecA filaments from RecA. All of these proteins function in a network that determines where and how RecA functions. Additional regulatory proteins may remain to be discovered. The elaborate regulatory pattern is likely to be reprised for RecA homologues in archaeans and eukaryotes.     

A RecA filament capping mechanism for RecX protein

The RecX protein is a potent inhibitor of RecA protein activities. RecX functions by specifically blocking the extension of RecA filaments. In vitro, this leads to a net disassembly of RecA protein from circular single-stranded DNA. Based on multiple observations, we propose that RecX has a RecA filament capping activity. This activity has predictable effects on the formation and disassembly of RecA filaments. In vivo, the RecX protein may limit the length of RecA filaments formed during recombinational DNA repair and other activities. RecX protein interacts directly with RecA protein, but appears to interact in a functionally significant manner only with RecA filaments bound to DNA.     

Binding of double-stranded DNA by Escherichia coli RecA protein monitored by a fluorescent dye displacement assay.

We have developed a new assay to characterize the double-stranded DNA (dsDNA) binding properties of RecA protein. This assay is based on measurement of changes in the fluorescence of a 4',6-diamidino-2-phenylindole (DAPI)-dsDNA complex upon RecA protein binding. The binding of RecA protein to a complex of DAPI and dsDNA results in displacement of the bound DAPI, producing a decrease in the observed fluorescence. DAPI displacement is dependent on both RecA protein and ATP; dATP and, to a lesser extent, UTP and dCTP also support the DAPI displacement reaction, but dGTP, GTP, dITP and TTP do not. Binding stoichiometry for the RecA protein-dsDNA complex measured by DAPI displacement is 3 bp per RecA protein monomer in the presence of ATP. These results, taken together with data for mutant RecA proteins, suggest that this DAPI displacement assay monitors formation of the high affinity DNA binding state of RecA protein. Since this state of RecA protein defines the form of the nucleoprotein filament that is active in DNA strand exchange, these findings raise the possibility that the RecA protein-dsDNA filament may possess a homologous pairing capacity.     

Assembly of presynaptic filaments. Factors affecting the assembly of RecA protein onto single-stranded DNA

We have previously shown that the assembly of RecA protein onto single-stranded DNA (ssDNA) facilitated by SSB protein occurs in three steps: (1) rapid binding of SSB protein to the ssDNA; (2) nucleation of RecA protein onto this template; and (3) co-operative polymerization of additional RecA protein to yield presynaptic filaments. Here, electron microscopy has been used to further explore the parameters of this assembly process. The optimal extent of presynaptic filament formation required at least one RecA protein monomer per three nucleotides, high concentrations of ATP (greater than 3 mM in the presence of 12 mM-Mg2+), and relatively low concentrations of SSB protein (1 monomer per 18 nucleotides). Assembly was depressed threefold when SSB protein was added to one monomer per nine nucleotides. These effects appeared to be exerted at the nucleation step. Following nucleation, RecA protein assembled onto ssDNA at net rates that varied from 250 to 900 RecA protein monomers per minute, with the rate inversely related to the concentration of SSB protein. Combined sucrose sedimentation and electron microscope analysis established that SSB protein was displaced from the ssDNA during RecA protein assembly.     

Purification and characterization of the Thermus thermophilus HB8 RecX protein

The RecA protein plays a central role in homologous recombination by promoting strand exchange between ssDNA and homologous dsDNA. Since RecA alone can advance this reaction in vitro, it is widely used in gene manipulation techniques. The RecX protein downregulates the function of RecA, indicating that it could be used as an inhibitor to control the activities of RecA in vitro. In this study, the RecX protein of the hyper-thermophilic bacterium Thermus thermophilus (ttRecX) was over-expressed in Escherichia coli and purified by heat treatment and several column chromatography steps. Size-exclusion chromatography indicated that purified ttRecX exists as a monomer in solution. Circular dichroism measurements indicated that the alpha-helical content of ttRecX is 54% and that it is stable up to 80 degrees C at neutral pH. In addition, ttRecX inhibited the DNA-dependent ATPase activity of the T. thermophilus RecA protein (ttRecA). The stable ttRecX may be applicable for variety of techniques using the ttRecA reaction.     

Biochemical basis of the temperature-inducible constitutive protease activity of the RecA441 protein of Escherichia coli

We compared the biochemical properties of the RecA441 protein to those of the wild-type RecA protein in an effort to account for the constitutive protease activity observed in recA441 strains. The two RecA proteins have similar properties in the absence of single-stranded DNA binding protein (SSB protein), and the differences that do exist shed little light on the temperature-inducible phenotype observed in recA441 strains. In contrast, several biochemical differences are apparent when the two proteins are compared in the presence of SSB protein, and these are conducive to a hypothesis that explains the temperature-sensitive behavior observed in these strains. We find that both the single-stranded DNA (ssDNA)-dependent ATPase and LexA-protease activities of RecA441 protein are more resistant to inhibition by SSB protein than are the activities of the wild-type protein. Additionally, the RecA441 protein is more capable of using ssDNA that has been precoated with SSB protein as a substrate for ATPase and protease activities, implying that RecA441 protein is more proficient at displacing SSB protein from ssDNA. The enhanced SSB protein displacement ability of the RecA441 protein is dependent on elevated temperature. These observations are consistent with the hypothesis that the RecA441 protein competes more efficiently with SSB protein for limited ssDNA sites and can be activated to cleave repressors at elevated temperature by displacing SSB protein from the limited ssDNA that occurs naturally in Escherichia coli. Neither the ssDNA binding characteristics of the RecA441 protein nor the rate at which it transfers from one DNA molecule to another provides an explanation for its enhanced activities, leading us to conclude that kinetics of RecA441 protein association with DNA may be responsible for the properties of the RecA441 protein.     

Role of RecA in DNA damage repair in Deinococcus radiodurans

It has been shown previously that the RecA protein of Deinococcus radiodurans plays a unique role in the repair of DNA damage in this highly DNA damage-resistant organism. Despite the high level of amino-acid identity, previous work has shown that Escherichia coli RecA does not complement D. radiodurans RecA mutants, further suggesting the uniqueness of D. radiodurans RecA. The work presented here shows that E. coli RecA does in fact provide partial complementation to a D. radiodurans RecA null mutant, suggesting that the RecA protein from D. radiodurans may not be as unique as believed previously.