Interdependence of the kinetics of NTP hydrolysis and the stability of the RecA-ssDNA complex.

The ssDNA-dependent NTP hydrolysis activity of the RecA protein was examined using a series of dTn oligomers ranging in size from dT10 to dT2000 as the ssDNA effector. There were three distinct manifestations of the dTn-dependent NTP hydrolysis reaction, depending on the length of the dTn effector that was used. With longer dTn oligomers, NTP hydrolysis occurred with a turnover number of 20-25 min(-1) and the observed S0.5 value for the NTP was independent of the concentration of the dTn oligomer (DNA concentration-independent hydrolysis). With dTn oligomers of intermediate length, NTP hydrolysis still occurred with a turnover number of 20-25 min(-1), but the observed S0.5 for the NTP decreased with increasing dTn concentration until reaching a value similar to that obtained with the longer dTn oligomers (DNA concentration-dependent hydrolysis). With shorter dTn oligomers, the NTP hydrolysis activity was effectively eliminated. Although this general progression of kinetic behavior was observed for the three structurally related NTPs (dATP, ATP, and GTP), the dTn oligomer length at which DNA concentration-independent, DNA concentration-dependent, and no NTP hydrolysis was observed depended on the NTP being considered. For example, dATP (S0.5 = 35 microM) was hydrolyzed in the presence of dT20, whereas ATP (S0.5 = 70 microM) and GTP (S0.5 = 1200 microM) required at least dT50 and dT200 for hydrolysis, respectively. These results are discussed in terms of a kinetic model in which the stability of the RecA-ssDNA-NTP complex is dependent on the intrinsic S0.5 value of the NTP being hydrolyzed.

Purification and characterization of the single-stranded DNA binding protein from Streptococcus pneumoniae.

The Escherichia coli single-stranded DNA binding (SSB) protein is a non-sequence-specific DNA binding protein that functions as an accessory factor for the RecA protein-promoted three-strand exchange reaction. An open reading frame encoding a protein similar in size and sequence to the E. coli SSB protein has been identified in the Streptococcus pneumoniae genome. The open reading frame has been cloned, an overexpression system has been developed, and the protein has been purified to greater than 99% homogeneity. The purified protein binds to ssDNA in a manner similar to that of the E. coli SSB protein. The protein also stimulates the S. pneumoniae RecA protein and E. coli RecA protein-promoted strand exchange reactions to an extent similar to that observed with the E. coli SSB protein. These results indicate that the protein is the S. pneumoniae analog of the E. coli SSB protein. The availability of highly-purified S. pneumoniae SSB protein will facilitate the study of the molecular mechanisms of RecA protein-mediated transformational recombination in S. pneumoniae.

ADP-dependent DNA strand exchange by the mutant [P67G/E68A] RecA protein.

We have prepared a mutant RecA protein in which proline 67 and glutamic acid 68 in the NTP binding site were replaced by a glycine and alanine residue, respectively. The [P67G/E68A]RecA protein catalyzes the single-stranded DNA-dependent hydrolysis of ATP and is able to promote the standard ATP-dependent three-strand exchange reaction between a circular bacteriophage phiX174 (phiX) single-stranded DNA molecule and a homologous linear phiX double-stranded (ds) DNA molecule (5.4 kilobase pairs). The strand exchange activity differs from that of the wild type RecA protein, however, in that it is (i) completely inhibited by an ATP regeneration system, and (ii) strongly stimulated by the addition of high concentrations of ADP to the reaction solution. These results indicate that the strand exchange activity of the [P67G/E68A]RecA protein is dependent on the presence of both ATP and ADP. The ADP dependence of the reaction is reduced or eliminated when (i) a shorter linear phiX dsDNA fragment (1.1 kilobase pairs) is substituted for the full-length linear phiX dsDNA substrate, or (ii) the Mg(2+) concentration is reduced to a level just sufficient to complex the ATP present in the reaction solution. These results indicate that it is the branch migration phase (and not the initial pairing step) of the [P67G/E68A]RecA protein-promoted strand exchange reaction that is dependent on ADP. It is likely that the [P67G/E68A]RecA mutation has revealed a requirement for ADP that also exists (but is not as readily apparent) in the strand exchange reaction of the wild type RecA protein.

Purification and characterization of the RecA protein from Streptococcus pneumoniae.

Streptococcus pneumoniae is a naturally transformable bacterium that is able to take up single-stranded DNA from its environment and incorporate the exogenous DNA into its genome. This process, known as transformational recombination, is dependent upon the presence of the recA gene, which encodes an ATP-dependent DNA recombinase whose sequence is 60% identical to that of the RecA protein from Escherichia coli. We have developed an overexpression system for the S. pneumoniae RecA protein and have purified the protein to greater than 99% homogeneity. The S. pneumoniae RecA protein has ssDNA-dependent NTP hydrolysis and NTP-dependent DNA strand exchange activities that are generally similar to those of the E. coli RecA protein. In addition to its role as a DNA recombinase, the E. coli RecA protein also acts as a coprotease, which facilitates the cleavage and inactivation of the E. coli LexA repressor during the SOS response to DNA damage. Interestingly, the S. pneumoniae RecA protein is also able to promote the cleavage of the E. coli LexA protein, even though a protein analogous to the LexA protein does not appear to be present in S. pneumoniae.

Differential rates of NTP hydrolysis by the mutant [S69G]RecA protein. Evidence for a coupling of NTP turnover to DNA strand exchange.

The x-ray crystal structure of the Escherichia coli RecA protein indicates that the phosphate groups of the nucleotide cofactor are bound by a loop whose amino acid sequence ((66)GPESSGKT(73)) corresponds to a consensus phosphate binding loop sequence (GXXXXGK[T/S]) found in many NTP-binding proteins. As part of an investigation of the role of the P-loop in ATP hydrolysis, we prepared a mutant RecA protein in which serine 69 was replaced by a glycine residue. We have found that the [S69G]RecA mutation has a differential effect on the hydrolysis of various nucleoside triphosphates. The [S69G]RecA protein catalyzes the single-stranded DNA-dependent hydrolysis of rATP, ddATP, and dATP with turnover numbers of 10, 20, and 36 min(-1), respectively. The wild type RecA protein, in contrast, hydrolyzes each of these nucleoside triphosphates with similar turnover numbers of 20-24 min(-1). Significantly, the [S69G]RecA protein promotes strand exchange with all three nucleoside triphosphates, and the rate of strand exchange is directly proportional to the rate of hydrolysis of each of the nucleotide cofactors. These findings with the [S69G]RecA protein provide support for the existence of a mechanistic coupling between NTP hydrolysis and DNA strand exchange.

Reevaluation of the nucleotide cofactor specificity of the RecA protein from Bacillus subtilis.

The RecA protein from the Gram-positive bacterium, Bacillus subtilis, has been reported to catalyze dATP hydrolysis and to promote strand exchange in the presence of dATP but to have no ATP hydrolysis or ATP-dependent strand exchange activity (Lovett, C. M., Jr., and Roberts, J. W. (1985) J. Biol. Chem. 260, 3305-3313). The well characterized RecA protein from Escherichia coli, in contrast, catalyzes the hydrolysis of ATP and dATP at similar rates and can use either ATP or dATP as a cofactor for the strand exchange reaction. To explore this reported difference in nucleotide cofactor specificity in detail, we developed an overexpression system for the B. subtilis RecA protein and purified the protein to greater than 95% homogeneity. Contrary to the previous report, we find that the B. subtilis RecA protein catalyzes the hydrolysis of both dATP and ATP and can perform strand exchange using either dATP or ATP as a cofactor. Our results suggest that the inability of previous investigators to detect the ATP hydrolysis and ATP-dependent strand exchange activities of the B. subtilis RecA protein may have been due to the particular assay conditions that were used in the earlier study.

Time-dependent inhibition of recA protein-catalyzed ATP hydrolysis by ATPgammaS: evidence for a rate-determining isomerization of the recA-ssDNA complex.

The ATP analog ATPgammaS is a competitive inhibitor of the recA protein-catalyzed ssDNA-dependent ATP hydrolysis reaction. The degree of inhibition by ATPgammaS, however, changes in a time-dependent manner and is consistent with a two step binding mechanism. In the first step, ATPgammaS binds to the recA-ssDNA complex in a rapid equilibrium step (KD = 50 microM). This initial binding step is followed by an isomerization of the recA-ssDNA-ATPgammaS complex to a new conformational state in which ATPgammaS is bound with a significantly higher affinity (overall K(D) = 0.3 microM). This isomerization is followed by the slow hydrolysis of ATPgammaS to ADP and thiophosphate (0.01 min(-1)). The first-order rate constant for the ATPgammaS-mediated isomerization step (20 min(-1)), although significantly greater than the rate of ATPgammaS hydrolysis, is identical to the steady-state rate constant for the recA protein-catalyzed ATP hydrolysis reaction. These results are consistent with a kinetic model in which an ATP-mediated isomerization of the recA-ssDNA complex represents the rate-determining step on the recA protein-catalyzed ssDNA-dependent ATP hydrolysis reaction pathway.

The rate-determining step on the recA protein-catalyzed ssDNA-dependent ATP hydrolysis reaction pathway.

We recently constructed a mutant recA protein in which His 163 was replaced by a tryptophan residue. The [H163W]recA protein is functionally identical to the wild-type protein, and the Trp163 side chain serves as a fluorescence reporter group for the ATP and ATPgammaS-mediated conformational transitions of the [H163W]recA-ssDNA complex. In this report, the pre-steady-state kinetics of the ATP and ATPgammaS-mediated transitions were examined by stopped-flow fluorescence. The kinetics of the ATP-mediated fluorescence change were consistent with a two-step mechanism in which an initial rapid equilibrium binding of ATP to the recA-ssDNA complex is followed by a first-order isomerization of the complex to a new conformational state; the rate constant for the isomerization step of 18 min is identical to the steady-state turnover number for ATP hydrolysis. The kinetics of the ATPgammaS-mediated fluorescence change were also consistent with a two-step binding mechanism with a unimolecular isomerization of 18 min(-1); since ATPgammaS is not hydrolyzed appreciably on the time scale of these experiments (0.017 min(-1)), this indicates that the isomerization step follows ATPgammaS (or ATP) binding but precedes ATPgammaS (or ATP) hydrolysis. These and other results are consistent with a kinetic model in which an ATP-mediated isomerization of the recA-ssDNA complex is the rate-determining step on the recA protein-catalyzed ssDNA-dependent ATP hydrolysis reaction pathway.

Reengineering the nucleotide cofactor specificity of the RecA protein by mutation of aspartic acid 100.

We have recently obtained evidence for a direct linkage between the S0.5 (S0.5 is the substrate concentration required for half-maximal velocity) value of a nucleoside triphosphate and the conformational state of the RecA-ssDNA complex, with an S0.5 value of 125 microM or less required for stabilization of the strand exchange-active conformation. For example, although ATP and ITP are hydrolyzed by the RecA protein with the same turnover number (18 min-1), ATP (S0.5 = 45 microM) functions as a cofactor for the strand exchange reaction, whereas ITP (S0.5 = 500 microM) is inactive as a strand exchange cofactor. The RecA protein crystal structure suggests that cofactor specificity is determined by Asp100, which likely forms a hydrogen bond with the exocyclic 6-amino group of ATP; the higher S0. 5 value for ITP is presumably due to unfavorable interactions between Asp100 and the 6-carbonyl group of the inosine ring. To test this hypothesis, we prepared a mutant RecA protein in which Asp100 was replaced by an asparagine residue. The S0.5(ITP) for the [D100N]RecA protein is 125 microM, indicating favorable interactions between the Asn100 side chain and the 6-carbonyl group of ITP. Correspondingly, ITP functions as a cofactor for the strand exchange activity of the [D100N]RecA protein. This result demonstrates the importance of the residue at position 100 in determining nucleotide cofactor specificity and underscores the importance of the S0.5 value in the RecA protein-promoted strand exchange reaction.

Spectroscopic demonstration of a linkage between the kinetics of NTP hydrolysis and the conformational state of the recA-single-stranded DNA complex.

We recently constructed a mutant recA protein in which His-163 was replaced by a tryptophan residue; the [H163W]recA protein is functionally identical to the wild-type protein, and the Trp-163 side chain serves as a reporter group for the conformational transitions of the [H163W]recA-single-stranded DNA (ssDNA) complex. We have now examined the fluorescence properties of the [H163W]recA-ssDNA complex in the presence of a series of alternate nucleoside triphosphate cofactors. Under standard conditions (pH 7.5), ATP (S0.5 = 70 microM) and purine riboside triphosphate (PTP) (S0.5 = 110 microM) effect a 44% decrease in Trp-163 fluorescence and are active as cofactors for the DNA strand exchange reaction. In contrast, ITP (S0.5 = 400 microM) elicits only a 20% decrease in Trp-163 fluorescence (a level identical to that observed with the nucleoside diphosphates ADP, PDP, and IDP) and is inactive as a strand exchange cofactor. If the S0.5 (PTP) is increased to 130 microM (by increasing the pH of the reaction solution), the PTP-mediated quenching of Trp-163 fluorescence decreases to 20%, and PTP becomes inactive as a strand exchange cofactor. These results provide direct evidence for a linkage between the S0.5 value of a nucleoside triphosphate and the conformational state of the recA-ssDNA complex, with an S0.5 of 100-120 microM or lower required for stabilization of the strand exchange-active conformation.

Introduction of a tryptophan reporter group into loop 1 of the recA protein. Examination of the conformational states of the recA-ssDNA complex by fluorescence spectroscopy.

Site-directed mutagenesis was used to replace His-163 in the Loop 1 region of the recA protein with a tryptophan residue. The [H163W]recA protein binds single-stranded DNA (ssDNA), catalyzes ssDNA-dependent ATP hydrolysis, and is fully active in the three-strand exchange reaction. In addition, the fluorescence properties of the Trp-163 reporter group are very sensitive to the binding of nucleotide cofactors to the H163W]recA-ssDNA complex. The fluorescence of Trp-163 is modestly quenched by the binding of ADP (21%) and strongly quenched by the nonhydrolyzable ATP analog, ATP gamma S (70%); since ADP and ATP gamma S stabilize the closed and open conformations of the recA-ssDNA complex, respectively, the quenched states observed with these nucleotides likely reflect differences in the fluorescence properties of tryptophan 163 in these two states. ATP has a more complex time-dependent effect on Trp-163 fluorescence. When ATP is added to [H163W]recA-ssDNA complexes, there is an immediate quenching of Trp-163 fluorescence (44%) which is intermediate in intensity between that observed with ADP and ATP gamma S. The ATP-induced quenching gradually decreases with time as the pool of ATP is converted to ADP by the ATP hydrolysis activity of the [H163W]recA protein. These results are discussed with regard to the nucleotide cofactor-dependent conformational transitions of the recA-ssDNA complex.

Activation of a recombinase-deficient mutant recA protein with alternate nucleoside triphosphate cofactors.

We recently described two mutant recA proteins, (G160N)recA and (H163A)recA, which have full single-stranded DNA-dependent ATP hydrolysis activity but which are unable to promote the ATP-dependent strand exchange reaction under standard reaction conditions (pH 7.5). These mutant proteins, however, are able to promote strand exchange at pH 6.0 to 6.8. Here we show that this activation correlates with a pH-dependent decrease in the S0.5 value for ATP, with the (H163A)recA protein becoming active in strand exchange at pH values where the S0.5(ATP) decreases below 100 microM. We also show that the (H163A)recA protein is active in strand exchange over the range of pH 6.0-8.2 if dATP (or ddATP) is used in place of ATP as a cofactor; dATP is hydrolyzed by (H163A)recA protein at the same rate as ATP but has an S0.5 value lower than 100 microM across this pH range. These results are discussed with regard to the general significance of the S0.5 value in determining whether a nucleoside triphosphate will be able to stabilize the recA-single-stranded DNA filament in the strand exchange active conformational state.

Two mutant RecA proteins possessing pH-dependent strand exchange activity exhibit pH-dependent presynaptic filament formation.

In previous studies it was shown that the mutant RecA proteins, [G160N]RecA and [H163A]RecA, are unable to catalyze ATP-dependent DNA strand exchanges at pH 7.5, but are active at pH 6.0 to 6.8. Here, we have used electron microscopy to follow the assembly of these mutant proteins onto single-stranded DNA at pH 7.5 and pH 6.2. In the absence of ATP, the filaments formed by the mutant proteins were similar to those formed by the wild-type protein, at both pH 7.5 and pH 6.2. In the presence of ATP, however, the filaments formed by the wild-type protein at pH 7.5 were extended and were stable in the presence of saturating SSB protein, whereas the filaments formed by the mutant proteins were shorter and unstable in the presence of SSB protein. At pH 6.2, in contrast, the filaments formed by the mutant proteins in the presence of ATP were of the same contour length as the wild-type RecA protein filaments and were stable in the presence of SSB protein. In the presence of the non-hydrolyzable ATP analog, ATP gamma S, and SSB protein, the mutant proteins formed full-length filaments at pH 7.5 that had a helical periodicity identical with that of the wild-type filaments (and characteristic of the strand exchange-active open conformational state); if SSB protein was omitted, the mutant protein filaments still exhibited the open helical periodicity, but were shorter and of highly variable length, presumably because of an improper threading of the ssDNA into the mutant filament. To account for these results, we propose that: (1) the mutant proteins are unable to isomerize efficiently to the open conformational state at pH 7.5 in the presence of ATP, but are able to do so in the presence of ATP gamma S; this indicates that the mechanistic defect is related to ATP hydrolysis rather than ATP binding; and (2) the mutant proteins are able to isomerize to the open conformational state in the presence of ATP at pH 6.2, indicating that protonation of the mutant filaments is sufficient to relieve the mechanistic deficiency.

Kinetics of ATP hydrolysis during the DNA helicase II-promoted unwinding of duplex DNA.

The ATP hydrolysis activity of DNA helicase II from Escherichia coli was examined in the presence of linear single-stranded DNA (ssDNA) and linear double-stranded DNA (dsDNA). In the presence of ssDNA, the ATP hydrolysis reaction followed a linear time course until the ATP was depleted. In the presence of dsDNA, in contrast, there was a kinetic lag before a linear phase of ATP hydrolysis was achieved. The nonlinear kinetics of the dsDNA-dependent ATP hydrolysis reaction could be modeled by a kinetic scheme in which helicase II undergoes a time-dependent transition from an ATPase-inactive to an ATPase-active form. Order of addition experiments indicated that this transition was not due to a rate-limiting association event between helicase II and any other component of the reaction. Instead, agarose gel assays showed that progressive unwinding of the dsDNA occurs during the same time period as the lag phase of the ATP hydrolysis reaction. No significant ATP hydrolysis was observed when the linear dsDNA was replaced with closed circular dsDNA, suggesting that the ATP hydrolysis reaction requires a dsDNA substrate that can be unwound to the complementary single strands. These results are consistent with a model in which the lag phase of the dsDNA-dependent ATP hydrolysis reaction corresponds to progressive unwinding of the dsDNA, with the ATP hydrolysis reaction arising from helicase II molecules that are bound to the separated single strands.

Inactivation of the recA protein by mutation of histidine 97 or lysine 248 at the subunit interface.

We have used site-directed mutagenesis to prepare two new mutant recA proteins, one in which histidine 97 has been replaced by alanine, and another in which lysine 248 has been replaced by alanine. Although these mutant proteins were originally designed from different considerations, they turned out to have remarkably similar properties. Both the [H97A]recA protein and the [K248A]recA protein bind poorly to single-stranded DNA, have no single-stranded DNA-dependent ATP hydrolysis activity, and do not promote renaturation of complementary single-stranded DNA molecules or the ATP-dependent three-strand exchange reaction. Furthermore, both mutant proteins are defective in Mg(2+)-induced helical filament formation. To account for these results, we propose that the mutation of either histidine 97 or lysine 248 alters subunit interactions between recA monomers and that this leads to the loss of cooperative single-stranded DNA binding and DNA pairing activities. This proposal is consistent with the recently determined x-ray structure of the recA protein, which shows that although histidine 97 and lysine 248 are distant from one another in the monomer structure, these two residues are on the opposing complementary faces of the recA subunit and pack against each other at the interface between adjacent recA monomers in the helical filament (Story, R. M., Weber, I. T., and Steitz, T. A. (1992) Nature 355, 318-325).

Effect of nucleotide cofactor structure on recA protein-promoted DNA pairing. 1. Three-strand exchange reaction.

The structurally related nucleoside triphosphates, adenosine triphosphate (ATP), purine riboside triphosphate (PTP), inosine triphosphate (ITP), and guanosine triphosphate (GTP), are all hydrolyzed by the recA protein with the same turnover number (17.5 min-1). The S0.5 values for these nucleotides increase progressively in the order ATP (45 microM), PTP (100 microM), ITP (300 microM), and GTP (750 microM). PTP, ITP, and GTP are each competitive inhibitors of recA protein-catalyzed ssDNA-dependent ATP hydrolysis, indicating that these nucleotides all compete for the same catalytic site on the recA protein. Despite these similarities, ATP and PTP function as cofactors for the recA protein-promoted three-strand exchange reaction, whereas ITP and GTP are inactive as cofactors. The strand exchange activity of the various nucleotides correlates directly with their ability to support the isomerization of the recA protein to a strand exchange-active conformational state. The mechanistic deficiency of ITP and GTP appears to arise as a consequence of the hydrolysis of these nucleotides to the corresponding nucleoside diphosphates, IDP and GDP. We speculate the nucleoside triphosphates with S0.5 values greater than 100 microM will be intrinsically unable to sustain the strand exchange-active conformational state of the recA protein during ongoing NTP hydrolysis and will therefore be inactive as cofactors for the strand exchange reaction.

Effect of nucleotide cofactor structure on recA protein-promoted DNA pairing. 2. DNA renaturation reaction.

We have examined the effects of the structurally related nucleoside triphosphates, adenosine triphosphate (ATP), purine riboside triphosphate (PTP), inosine triphosphate (ITP), and guanosine triphosphate (GTP), on the recA protein-promoted DNA renaturation reaction (phi X DNA). In the absence of nucleotide cofactor, the recA protein first converts the complementary single strands into unit-length duplex DNA and other relatively small paired DNA species; these initial products are then slowly converted into more complex multipaired network DNA products. ATP and PTP stimulate the conversion of initial product DNA into network DNA, whereas ITP and GTP completely suppress network DNA formation. The formation of network DNA is also inhibited by all four of the corresponding nucleoside diphosphates, ADP, PDP, IDP, and GDP. Those nucleotides which stimulate the formation of network DNA are found to enhance the formation of large recA-ssDNA aggregates, whereas those which inhibit network DNA formation cause the dissociation of these nucleoprotein aggregates. These results not only implicate the nucleoprotein aggregates as intermediates in the formation of network DNA, but also establish the functional equivalency of ITP and GTP with the nucleoside diphosphates. Additional experiments indicate that the net effect of ITP and GTP on the DNA renaturation reaction is dominated by the corresponding nucleoside diphosphates, IDP and GDP, that are generated by the NTP hydrolysis activity of the recA protein.

Disruption of an ATP-dependent isomerization of the recA protein by mutation of histidine 163.

We have used site-directed mutagenesis to replace histidine 163 of the recA polypeptide with an alanine residue. The new [Ala-163]recA protein catalyzes single-stranded (ss) DNA-dependent ATP hydrolysis with a turnover number that is similar to that of the wild-type recA protein. Despite being proficient in ssDNA-dependent ATP hydrolysis, the [Ala-163]recA protein is unable to promote the ATP-dependent three-strand exchange reaction under standard reaction conditions, pH 7.5. The [Ala-163]recA protein does exhibit three-strand exchange activity at pH 6.0-7.0, however, and the induction of strand exchange activity at low pH correlates directly with the activation of an ATP-dependent isomerization of the mutant protein. Thus, the [Ala-163]recA protein is functionally similar to our previously described mutant [Asn-160]recA protein (Bryant, F.R. (1988) J. Biol. Chem. 263, 8716-8723; Muench, K.A., and Bryant, F. R. (1990) J. Biol. Chem. 265, 11560-11566). Trypsin proteolysis studies indicate that the [Ala-163]recA and [Asn-160]recA proteins, like the wild-type recA protein, are organized into carboxyl-terminal and amino-terminal domains of nearly equal size. According to this structural model, the [Ala-163]recA and [Asn-160]recA mutations may lie in a linker region joining these two domains. We speculate that the [Ala-163]recA and [Asn-160]recA mutations interfere with an ATP-dependent conformational change of the recA protein that perhaps involves a change in the relative orientation of the carboxyl-terminal and amino-terminal domains.

An obligatory pH-mediated isomerization on the [Asn-160]recA protein-promoted DNA strand exchange reaction pathway.

We recently described a mutant recA protein in which glycine 160 of the recA polypeptide was replaced by an asparagine residue (Bryant, F. R. (1988) J. Biol. Chem. 263, 8716-8723). Although the [Asn-160]recA protein has a ssDNA-dependent ATPase activity that is similar to that of the wild-type recA protein, the mutant protein is unable to promote the ATP-dependent three-strand exchange reaction under standard reaction conditions (pH 7.5, 1 mM ATP). We have found that the [Asn-160]recA protein is able to carry out the three-strand exchange reaction at pH 6.0 to 6.7, but that the strand exchange activity is abolished at higher pH. The induction of strand exchange activity at low pH correlates directly with a pH-mediated activation of an ATP-dependent isomerization of the [Asn-160]recA protein. This ATP-dependent isomerization is characterized by the conversion of the [Asn-160]recA protein to a form that is not displaced from ssDNA by the Escherichia coli SSB protein. In contrast to the pronounced pH sensitivity of the [Asn-160]recA protein, the wild-type recA protein undergoes ATP-dependent isomerization, and is able to carry out the three-strand exchange reaction, over the range of pH 6.0 to 8.4. These results show that the [Asn-160] mutation disrupts the ATP-dependent isomerization of the recA protein and suggest that protonation of the [Asn-160]recA protein (or the [Asn-160]recA-ssDNA complex) relieves this mechanistic defect. Furthermore, the direct correlation between ATP-dependent isomerization and the strand exchange activity of the [Asn-160]recA protein strongly suggests that the ATP-dependent isomerization is an obligatory step in the recA protein-promoted strand exchange mechanism.

Kinetic modeling of the recA protein promoted renaturation of complementary DNA strands.

Quantitative agarose gel assays reveal that the recA protein promoted renaturation of complementary DNA strands (phi X DNA) proceeds in two stages. The first stage results in the formation of unit-length duplex DNA as well as a distribution of other products ("initial products"). In the second stage, the initial products are converted to complex multipaired DNA structures ("network DNA"). In the presence of ATP, the initial products are formed within 2 min and are then rapidly converted to network DNA. In the absence of ATP, the initial products are formed nearly as fast as with ATP present, but they are converted to network DNA at a much lower rate. The time-dependent formation of initial products and network DNA from complementary single strands for both the ATP-stimulated and ATP-independent reactions can be modeled by using a simple two-step sequential kinetic scheme. This model indicates that the primary effect of ATP in the recA protein promoted renaturation reaction is not on the initial pairing step (which leads to the formation of initial products) but rather is to increase the rate at which subsequent pairing events can occur.