Interaction of recA protein with a photoaffinity analogue of ATP, 8-azido-ATP: determination of nucleotide cofactor binding parameters and of the relationship between ATP binding and ATP hydrolysis

The binding and cross-linking of the ATP photoaffinity analogue 8-azidoadenosine 5'-triphosphate (azido-ATP) with recA protein have been investigated, and through cross-linking inhibition studies, the binding of other nucleotide cofactors to recA protein has also been studied. The azido-ATP molecule was shown to be a good ATP analogue with regard to recA protein binding and enzymatic function by three criteria: first, the cross-linking follows a simple hyperbolic binding curve with a Kd of 4 microM and a cross-linking efficiency ranging from 10% to 70% depending on conditions; second, ATP, dATP, and adenosine 5'-O-(3-thiotriphosphate) (ATP-gamma-S) specifically inhibit the cross-linking of azido-ATP to recA protein; third, azido-ATP is a substrate for recA protein ATPase activity. Quantitative analysis of the cross-linking inhibition studies using a variety of nucleotide cofactors as competitors has shown that the binding affinity of adenine-containing nucleotides for recA protein decreases in the following order: ATP-gamma-S greater than dATP greater than ATP greater than adenylyl beta,gamma-imidodiphosphate (AMP-PNP) much greater than adenylyl beta,gamma-methylenediphosphate (AMP-PCP) approximately adenine. Similar competition studies also showed that nearly all of the other nucleotide triphosphates also bind to recA protein, with the affinity decreasing in the following order: UTP greater than GTP approximately equal to dCTP greater than dGTP greater than CTP. In addition, studies performed in the presence of single-stranded DNA demonstrated that the affinity of ATP, dATP, ATP-gamma-S, and AMP-PNP for recA protein is significantly increased. These results are discussed in terms of the reciprocal effects that nucleotide cofactors have on the modulation of recA protein--single-stranded DNA binding affinity and vice versa. In addition, it is demonstrated that nucleotide and DNA binding are necessary though not sufficient conditions for ATPase activity. The significance of this result in terms of the possible requirement of critically sized clusters of 15 or more recA protein molecules contiguously bound to DNA for ATPase activity is discussed.     

ATP-independent renaturation of complementary DNA strands by the mutant recA1 protein from Escherichia coli

In an effort to clarify the requirement for ATP in the recA protein-promoted renaturation of complementary DNA strands, we have analyzed the mutant recA1 protein which lacks single-stranded DNA-dependent ATPase activity at pH 7.5. Like the wild type, the recA1 protein binds to single-stranded DNA with a stoichiometry of one monomer per approximately four nucleotides. However, unlike the wild type, the mutant protein is dissociated from single-stranded DNA in the presence of ATP or ADP. The ATP analogue adenosine 5'-O-3' (thiotriphosphate) appears to stabilize the binding of recA1 protein to single-stranded DNA but does not elicit the stoichiometry of 1 monomer/8 nucleotides or the formation of highly condensed protein-DNA networks that are characteristic of the wild type recA protein in the presence of this analogue. The recA1 protein does not catalyze DNA renaturation in the presence of ATP, consistent with the dissociation of recA1 protein from single-stranded DNA under these conditions. However, it does promote a pattern of Mg2+-dependent renaturation identical to that found for wild type recA protein.     

Increase of the DNA strand assimilation activity of recA protein by removal of the C terminus and structure-function studies of the resulting protein fragment

A proteolytic fragment of recA protein, missing about 15% of the protein at the C terminus, was found to promote assimilation of homologous single-stranded DNA into duplex DNA more efficiently than intact recA protein. This difference was not found if Escherichia coli single-stranded DNA binding protein was present. The ATPase activity of both intact recA protein and the fragment was identical. The difference in strand assimilation activity cannot be due to differences in single-stranded DNA affinity, since both the fragment and intact proteins bind to single-stranded DNA with nearly identical affinities. However, the fragment was found to bind double-stranded DNA more tightly and to aggregate more extensively than recA protein; both of these properties may be important in strand assimilation. Aggregation of the fragment was extensive in the presence of duplex DNA under the same condition where recA protein did not aggregate. The double-stranded DNA binding of both recA protein and the fragment responds to nucleotide cofactors in the same manner as single-stranded DNA binding, i.e. ADP weakens and ATP gamma S strengthens the association. The missing C-terminal region of recA protein includes a very acidic region that is homologous to other single-stranded DNA binding proteins and which has been implicated in DNA binding modulation. This C-terminal region may serve a similar function in recA protein, possibly inhibiting double-stranded DNA invasion. The possible role of the enhanced double-stranded DNA affinity of the fragment protein in the mechanism of strand assimilation is discussed.     

Properties of the high-affinity single-stranded DNA binding state of the Escherichia coli recA protein

The properties of the high-affinity single-stranded DNA (ssDNA) binding state of Escherichia coli recA protein have been studied. We find that all of the nucleoside triphosphates that are hydrolyzed by recA protein induce a high-affinity ssDNA binding state. The effect of ATP binding to recA protein was partially separated from the ATP hydrolytic event by substituting calcium chloride for magnesium chloride in the binding buffer. Under these conditions, the rate of ATP hydrolysis is greatly inhibited. ATP increases the affinity of recA protein for ssDNA in a concentration-dependent manner in the presence of both calcium and magnesium chloride with apparent Kd values of 375 and 500 microM ATP, respectively. Under nonhydrolytic conditions, the molar ratio of ATP to ADP has an effect on the recA protein ssDNA binding affinity. Over an ATP/ADP molar ratio of 2-3, the affinity of recA protein for ssDNA shifts cooperatively from a low-to a high-affinity state.     

Interaction of the recA protein of Escherichia coli with single-stranded DNA

The interaction of recA protein with single-stranded (ss) phi X174 DNA has been examined by means of a nuclease protection assay. The stoichiometry of protection was found to be 1 recA monomer/approximately 4 nucleotides of ssDNA both in the absence of a nucleotide cofactor and in the presence of ATP. In contrast, in the presence of adenosine 5'-O-(thiotriphosphate) (ATP gamma S) the stoichiometry was 1 recA monomer/approximately 8 nucleotides. No protection was seen with ADP. In the absence of a nucleotide cofactor, the binding of recA protein to ssDNA was quite stable as judged by equilibration with a challenge DNA (t1/2 approximately 30 min). Addition of ATP stimulated this transfer (t1/2 approximately 3 min) as did ADP (t1/2 approximately 0.2 min). ATP gamma S greatly reduced the rate of equilibration (t1/2 greater than 12 h). Direct visualization of recA X ssDNA complexes at subsaturating recA protein concentrations using electron microscopy revealed individual ssDNA molecules partially covered with recA protein which were converted to highly condensed networks upon addition of ATP gamma S. These results have led to a general model for the interaction of recA protein with ssDNA.     

ADP-mediated dissociation of stable complexes of recA protein and single-stranded DNA

The complete exchange of strands between circular single-stranded and full length linear duplex DNAs promoted by the recA protein of Escherichia coli is dependent upon the hydrolysis of ATP and is strongly stimulated by the single-stranded DNA binding protein (SSB). In the presence of SSB, stable complexes of recA protein and single-stranded DNA are formed as an early step in the reaction. These complexes dissociate when the ADP/ATP ratio approaches a value of 0.6-1.5, depending upon reaction conditions. Thus, ATP hydrolysis never proceeds to completion but stops when 40-60% of the input ATP has undergone hydrolysis. recA protein can participate in a second round of strand exchange upon regeneration of the ATP. While 100-200 mol of ATP are hydrolyzed/mol of heteroduplex base pair formed under standard reaction conditions in the presence of SSB, this value is reduced to 16 at levels of ADP lower than that required to dissociate the complexes. ATP hydrolysis appears to be completely irreversible since efforts to detect exchange reactions using 18O probes have been unsuccessful.     

Salt-dependent changes in the DNA binding co-operativity of Escherichia coli single strand binding protein

The co-operative nature of the binding of the Escherichia coli single strand binding protein (SSB) to single-stranded nucleic acids has been examined over a range of salt concentrations (NaCl and MgCl2) to determine if different degrees of binding co-operativity are associated with the two SSB binding modes that have been identified recently. Quantitative estimates of the binding properties, including the co-operativity parameter, omega, of SSB to single-stranded DNA and RNA homopolynucleotides have been obtained from equilibrium binding isotherms, at high salt (greater than or equal to 0.2 M-NaCl), by monitoring the fluorescence quenching of the SSB upon binding. Under these high salt conditions, where only the high site size SSB binding mode exists (65 +/- 5 nucleotides per tetramer), we find only moderate co-operativity for SSB binding to both DNA and RNA, (omega = 50 +/- 10), independent of the concentration of salt. This value for omega is much lower than most previous estimates. At lower concentrations of NaCl, where the low site size SSB binding mode (33 +/- 3 nucleotides/tetramer) exists, but where SSB affinity for single-stranded DNA is too high to estimate co-operativity from classical binding isotherms, we have used an agarose gel electrophoresis technique to qualitatively examine SSB co-operativity with single-stranded (ss) M13 phage DNA. The apparent binding co-operativity increases dramatically below 0.20 M-NaCl, as judged by the extremely non-random distribution of SSB among the ssM13 DNA population at low SSB to DNA ratios. However, the highly co-operative complexes are not at equilibrium at low SSB/DNA binding densities, but are formed only transiently when SSB and ssDNA are directly mixed at low concentrations of NaCl. The conversions of these metastable, highly co-operative SSB-ssDNA complexes to their equilibrium, low co-operativity form is very slow at low concentrations of NaCl. At equilibrium, the SSB-ssDNA complexes seem to possess the same low degree of co-operativity (omega = 50 +/- 10) under all conditions tested. However, the highly co-operative mode of SSB binding, although metastable, may be important during non-equilibrium processes such as DNA replication. The possible relation between the two SSB binding modes, which differ in site size by a factor of two, and the high and low co-operativity complexes, which we report here, is discussed.     

recA protein-promoted ATP hydrolysis occurs throughout recA nucleoprotein filaments

When recA protein binds cooperatively to single-stranded DNA to form filamentous nucleoprotein complexes, it becomes competent to hydrolyze ATP. No correlation exists between the ends of such complexes and the rate of ATP hydrolysis. ATP hydrolysis is not, therefore, restricted to the terminal subunits on cooperatively bound recA oligomers, but occurs throughout the complex. Similarly, during recA protein-promoted branch migration (during DNA strand exchange), ATP hydrolysis is not restricted to recA protein monomers at the branch point. DNA cofactors of lengths varying from 16 bases to over 12,000 bases support ATP hydrolysis. The maximum value of kcat at infinite DNA concentration is about 29/min independent of the length of the DNA cofactor. The apparent dissociation constant, however, is a strong function of DNA length, providing evidence for a minimum site size of 30-50 bases for efficient binding of recA protein.     

Translocation of Escherichia coli recA protein from a single-stranded tail to contiguous duplex DNA

Duplex DNA with a contiguous single-stranded tail was nearly as effective as single-stranded DNA in acting as a cofactor for the ATPase activity of recA protein at neutral pH and concentrations of MgCl2 that support homologous pairing. The ATP hydrolysis reached a steady state rate that was proportional to the length of the duplex DNA attached to a short 5' single-stranded tail after a lag. Separation of the single-stranded tail from most of the duplex portion of the molecule by restriction enzyme cleavage led to a gradual decline in ATP hydrolysis. Measurement of the rate of hydrolysis as a function of DNA concentration for both tailed duplex DNA and single-stranded DNA cofactors indicated that the binding site size of recA protein on a duplex DNA lattice, about 4 base pairs, is similar to that on a single-stranded DNA lattice, about four nucleotides. The length of the lag phase preceding steady state hydrolysis depended on the DNA concentration, length of the duplex region, and the polarity of the single-stranded tail, but was comparatively independent of tail length for tails over 70 nucleotides in length. The lag was 5-10 times longer for 3' than for 5' single-stranded tailed duplex DNA molecules, whereas the steady state rates of hydrolysis were lower. These observations show that, after nucleation of a recA protein complex on the single-stranded tail, the protein samples the entire duplex region via an interaction that is labile and not strongly polarized.     

Asymmetry in the recA protein-DNA filament.

The apparent DNA site size obtained from an assay monitoring the ATPase activity of Escherichia coli recA protein (n = 3.5) differs from that determined from a direct DNA binding assay (n = 7) done under identical conditions. Investigation of this discrepancy indicates that at a DNA:protein ratio of 3.5:1, one-half of the recA protein population is less sensitive to ATPase activity inhibition by the nonhydrolyzable ATP analogue adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S), suggesting that the recA protein filament is asymmetric with respect to NTP affinity. This asymmetry does not depend on the presence of ATP gamma S since the apparent Km for ATP derived from single-stranded DNA-dependent ATP hydrolysis activity is dependent on the DNA:protein ratio. Three models are proposed to account for the observed site size discrepancy and the NTP binding affinity asymmetry. They differ mainly in the intrinsic site size for each recA protein monomer and in the number of DNA-binding sites/recA molecule. Gel filtration of recA-single-stranded DNA complexes at different DNA:protein ratios complements the enzymological data and provides an additional method of distinguishing among the proposed models. The phenomenon of subunit nonequivalence within the recA protein presynaptic filament may provide a molecular basis for understanding how recA protein can discriminate between different DNA molecules during homologous pairing.     

Interactions of nucleotide cofactors with the Escherichia coli replication factor DnaC protein

Quantitative analyses of the interactions of nucleotide cofactors with the Escherichia coli replicative factor DnaC protein have been performed using thermodynamically rigorous fluorescence titration techniques. This approach allowed us to obtain stoichiometries of the formed complexes and interaction parameters, without any assumptions about the relationship between the observed signal and the degree of binding. The stoichiometry of the DnaC-nucleotide complex has been determined in direct binding experiments with fluorescent nucleotide analogues, MANT-ATP and MANT-ADP. The stoichiometry of the DnaC complexes with unmodified ATP and ADP has been determined using the macromolecular competition titration method (MCT). The obtained results established that at saturation the DnaC protein binds a single nucleotide molecule per protein monomer. Analyses of the binding of fluorescent analogues and unmodified nucleotides to the DnaC protein show that ATP and ADP have the same affinities for the nucleotide-binding site, albeit the corresponding complexes have different structures, specifically affected by the presence of magnesium cations in solution. Although the presence of the gamma-phosphate does not affect the affinity, the structure of the triphosphate group is critical. While the affinity of ATP-gamma-S is the same as the affinity of ATP, the affinities of AMP-PNP and AMP-PCP are approximately 2 and approximately 4 orders lower than that of ATP, respectively. Moreover, the ribose plays a significant role in forming a stable complex. The binding constants of dATP and dADP are approximately 2 orders of magnitude lower than those for ribose nucleotides. The nucleotide-binding site of the DnaC protein is highly base specific. The intrinsic affinity of adenosine triphosphates and diphosphates is at least 3-4 orders of magnitude higher than for any of the other examined nucleotides. The obtained data indicate that the recognition mechanism of the nucleotide by the structural elements of the binding site is complex with the base providing the specificity and the ribose, as well as the second phosphate group contributing to the affinity. The significance of the results for the functioning of the DnaC protein is discussed.     

DNA-induced dimerization of the Escherichia coli Rep helicase.

The Escherichia coli Rep protein is a DNA helicase that is involved in DNA replication. We have examined the effects of DNA binding on the assembly state of the Rep protein using small-zone gel permeation chromatography and chemical crosslinking of the protein. Complexes of Rep protein were formed with short single-stranded and duplex hairpin oligodeoxynucleotides with lengths such that only a single Rep monomer could bind per oligodeoxynucleotide (i.e. 2 Rep monomers could not bind contiguously on the oligodeoxynucleotides). In the absence of DNA, Rep protein is monomeric (Mr 72,800) up to concentrations of at least 8 microM (monomer), even in the presence of its nucleotide cofactors (ATP, ADP, ATP-gamma-S). However, the binding of Rep monomers to single-stranded (ss) oligodeoxynucleotides, d(pN)n (12 less than or equal to n less than or equal to 20), induces the Rep monomers to oligomerize. Upon treatment of the Rep-ss oligodeoxynucleotide complexes with the protein crosslinking reagent dimethyl-suberimidate (DMS) and subsequent removal of the DNA, crosslinked Rep dimers are observed, independent of oligodeoxynucleotide length (n less than or equal to 20). Furthermore, short duplex oligodeoxynucleotides also induce the Rep monomers to dimerize. Formation of the Rep dimers results from an actual DNA-induced dimerization, rather than the adventitious crosslinking of Rep monomers bound contiguously to a single oligodeoxynucleotide. The purified DMS-crosslinked Rep dimer shows increased affinity for DNA and retains DNA-dependent ATPase and DNA helicase activities, as shown by its ability to unwind M13 RF DNA in the presence of the bacteriophage f1 gene II protein. On the basis of these observations and since the dimer is the major species when Rep is bound to DNA, we suggest that a DNA-induced Rep dimer is the functionally active form of the Rep helicase.     

recA protein promoted DNA strand exchange

recA protein and circular single-stranded DNA form a stable complex in the presence of single-stranded DNA binding protein (SSB), in which one recA protein monomer is bound per two nucleotides of DNA. These complexes are kinetically significant intermediates in the exchange of strands between the single-stranded DNA and an homologous linear duplex. After completion of strand exchange, the recA protein remains tightly associated with the circular duplex product of the reaction and the SSB is bound to the displaced linear single strand. Upon addition of ADP, the recA protein-duplex DNA complex dissociates. RecA protein also interacts with single-stranded DNA in the absence of SSB; however, the amount of recA protein bound is substantially reduced. These findings provide direct physical evidence for the participation of SSB in the formation of the recA protein-single-stranded DNA complexes inferred earlier from kinetic analysis. Moreover, they confirm the ability of recA protein to equilibrate between bound and free forms in the absence of SSB.     

Transfer of recA protein from one polynucleotide to another. Effect of ATP and determination of the processivity of ATP hydrolysis during transfer

The transfer of recA protein from a fluorescently modified single-stranded DNA, containing 1,N6-ethenoadenosine and 3,N4-ethenocytosine, to polydeoxythymidylic acid (poly(dT)) was shown to occur by a complex mechanism in both the absence and presence of ADP (Menetski, J. P., and Kowalczykowski, S. C. (1987) J. Biol. Chem. 262, 2085-2092). A part of the mechanism involves the formation of a kinetic ternary intermediate. Since the binding and hydrolysis of ATP by recA protein is involved in many of the recA protein in vitro activities, we have analyzed the effect of ATP on the transfer reaction. In the presence of ATP, the transfer reaction is dependent on the concentration of the competitor single-stranded DNA, poly(dT). This result suggests that transfer does not occur by a simple dissociation mechanism. The reaction occurs via two kinetically distinct species of protein X DNA complexes with properties that are similar to those characterized for the transfer reaction in the absence of ATP. There is a complicated effect of nucleotide concentration on the rate of transfer. At low concentrations of ATP (less than 50 microM), increasing nucleotide concentration increases the rate of transfer; this is similar to the effect of ADP. However, at high concentrations of ATP (greater than 50 microM), increasing ATP concentration decreases the rate of transfer. Finally, the processivity of ATP hydrolysis during transfer was found to increase with increases in ATP concentration. Less than one ATP molecule was hydrolyzed per transfer event at low ATP concentrations (less than 20 microM) while greater than 50 molecules were hydrolyzed at high ATP concentration (greater than 250 microM). These data suggest that the rate of transfer is not directly coupled to the rate of hydrolysis.     

Evidence for ATP binding and double-stranded DNA binding by Escherichia coli RecF protein.

RecF protein is one of the important proteins involved in DNA recombination and repair. RecF protein has been shown to bind single-stranded DNA (ssDNA) in the absence of ATP (T. J. Griffin IV and R. D. Kolodner, J. Bacteriol. 172:6291-6299, 1990; M. V. V. S. Madiraju and A. J. Clark, Nucleic Acids Res. 19:6295-6300, 1991). In the present study, using 8-azido-ATP, a photo-affinity analog of ATP, we show that RecF protein binds ATP and that the binding is specific in the presence of DNA. 8-Azido-ATP photo-cross-linking is stimulated in the presence of DNA (both ssDNA and double-stranded DNA [dsDNA]), suggesting that DNA enhances the affinity of RecF protein for ATP. These data suggest that RecF protein possesses independent ATP- and DNA-binding sites. Further, we find that stable RecF protein-dsDNA complexes are obtained in the presence of ATP or ATP-gamma-S [adenosine-5'-O-(3-thio-triphosphate)]. No other nucleoside triphosphates served as necessary cofactors for dsDNA binding, indicating that RecF is an ATP-dependent dsDNA-binding protein. Since a mutation in a putative phosphate-binding motif of RecF protein results in a recF mutant phenotype (S. J. Sandler, B. Chackerian, J. T. Li, and A. J. Clark, Nucleic Acids Res. 20:839-845, 1992), we suggest on the basis of our data that the interactions of RecF protein with ATP, with dsDNA, or with both are physiologically important for understanding RecF protein function in vivo.     

Separation of the presynaptic and synaptic phases of homologous pairing promoted by recA protein

Homologous pairing of single strands with duplex DNA promoted by recA protein occurred without a lag only when the protein was preincubated with ATP and single-stranded DNA. The rate-limiting presynaptic interaction of recA protein and single strands showed a high temperature coefficient: it proceeded 30 times more slowly at 30 degrees C than at 37 degrees C, whereas synapsis showed a normal temperature coefficient. Thus, the presynaptic phase could be separated experimentally from the rest of the reaction by preincubation of single strands with recA protein and ATP at 37 degrees C, followed by a shift to 30 degrees C before double-stranded DNA was added. The presynaptic phase was an order of magnitude more sensitive to inhibition by ADP than was subsequent strand exchange. Presynaptic complexes that were formed at 37 degrees C decayed only slowly at 30 degrees C, but Escherichia coli single strand binding protein caused complexes to form rapidly at 30 degrees C which indicates that single strand binding protein accelerated the rate of formation of complexes. Preincubation synchronized the initial pairing reaction, and further revealed the rapid formation of nascent heteroduplex DNA 250-300 base pairs in length.     

The distribution of Escherichia coli recA protein bound to duplex DNA with single-stranded ends

A short single-stranded tail on one end of an otherwise duplex DNA molecule enables recA protein, in the presence of ATP and MgCl2, to form a complex with the DNA which extends into the duplex portion of the molecule. Nuclease protection studies at a concentration of MgCl2 which permits homologous pairing showed that cleavage by restriction endonucleases at sites throughout the duplex region was inhibited, whereas digestion by DNase I was not affected. These results indicate that recA protein binds to the duplex portion of tailed DNA allowing access by DNase I to a random sample of the many sites at which it cleaves, but providing limited protection of the relatively rare restriction sites. Electron microscopy revealed that the recA nucleoprotein complex with duplex DNA is indeed a segmented or interrupted filament that, with time, extends further from the single-stranded tail into the duplex region. recA protein binding extended into the duplex region more rapidly for duplexes with 5' tails than for those with 3' tails. These observations show that recA protein translocates from a single-stranded region into duplex DNA in the form of a segmented filament by a mechanism that is not strongly polarized.     

Covalent modification of the recA protein from Escherichia coli with the photoaffinity label 8-azidoadenosine 5'-triphosphate

We have covalently modified the recA protein from Escherichia coli with the photoaffinity ATP analog 8-azido-[alpha-32P]ATP (N3-ATP). Covalent attachment of N3-ATP to recA protein is dependent on native protein conformation and is shown to be specific for the site of ATP hydrolysis by the following criteria. (i) Binding of the probe to recA protein is inhibited by ATP and competitive inhibitors of its ATP hydrolytic activity, e.g. adenosine 5'-O-(thiotriphosphate), ADP, and UTP, but not by adenosine; (ii) N3-ATP is efficiently hydrolyzed by recA protein in the presence of single-stranded DNA; (iii) labeling of recA protein occurs at a single site as judged by two-dimensional thin-layer peptide mapping and high-performance liquid chromatography peptide separation. We have purified and identified a tryptic fragment, spanning amino acid residues 257-280, which contains the primary site of attachment of N3-ATP. This peptide is likely to be contained within the ATP hydrolytic site of recA protein.     

Cobalt: an effector of E. coli recA protein activity.

Studies of cation requirements in the recA-catalyzed proteolysis of lambda repressor and strand assimilation reactions have demonstrated that Co2+ significantly enhances both activities. In the presence of 4mM MgCl2, the optimal concentration of CoCl2 for proteolysis was 1mM. 2mM Co2+ increased the rate and extent of D-loop formation as measured by membrane filtration. Cobalt did not replace Mg2+ for the ssDNA-dependent ATPase activity of recA, and did not affect the rate of hydrolysis of ATP, measured over a wide range of DNA concentrations. Cobalt did prevent the Mg-dependent ssDNA renaturation catalyzed by recA protein. Membrane filter binding assays established that Co2+ increases the affinity of recA protein for ssDNA with ATP, dATP, or ATP gamma S as cofactors. The dissociation of recA protein from ssDNA-nucleoside triphosphate complex was much slower with CoCl2. This metal provides an excellent tool for dissecting the various activities inherent in recA protein.