Binding stoichiometry and structure of RecA-DNA complexes studied by flow linear dichroism and fluorescence spectroscopy. Evidence for multiple heterogeneous DNA co-ordination

Role of Water for Life

The behavior of benzoic acid in polyethylene inspired me to reflect on why water is a unique molecule that all living organisms depend upon. From properties of DNA in aqueous solution a seemingly counter-intuitive conjecture emerges: water is needed for the creation of certain dry low-dielectric nm-size environments where hydrogen bonding exerts strong recognition power. Such environments seem to be functionally crucial, and their interactions with other hydrophobic environments, or with hydrophobic agents that modulate the chemical potential of water, can cause structural transformations via ‘hydrophobic catalysis’. Possibly combined with an excluded volume osmosis effect (EVO), hydrophobic catalysis may have important biological roles, e.g., in genetic recombination. Hydrophobic agents are found to strongly accelerate spontaneous DNA strand exchange as well as certain other DNA rearrangement reactions. It is hypothesized that hydrophobic catalysis be involved in gene recognition and gene recombination mediated by bacterial RecA (one of the oldest proteins we know of) as well as in sexual recombination in higher organisms, by Rad51. Hydrophobically catalyzed unstacking fluctuations of DNA bases can favor elongated conformations, such as the recently proposed [Formula: see text]-DNA, with potential regulatory roles. That living cells can survive as dormant spores, with very low water content and in principle as such travel far in space is reflected upon: a random walk model with solar photon pressure as driving force indicates our life on earth could not have originated outside our galaxy but possibly from many solar systems within it — at some place, though, where there was plenty of liquid water.

Complementary strand relocation may play vital roles in RecA-based homology recognition

RecA-family proteins mediate homologous recombination and recombinational DNA repair through homology search and strand exchange. Initially, the protein forms a filament with the incoming single-stranded DNA (ssDNA) bound in site I. The RecA–ssDNA filament then binds double-stranded DNA (dsDNA) in site II. Non-homologous dsDNA rapidly unbinds, whereas homologous dsDNA undergoes strand exchange yielding heteroduplex dsDNA in site I and the leftover outgoing strand in site II. We show that applying force to the ends of the complementary strand significantly retards strand exchange, whereas applying the same force to the outgoing strand does not. We also show that crystallographically determined binding site locations require an intermediate structure in addition to the initial and final structures. Furthermore, we demonstrate that the characteristic dsDNA extension rates due to strand exchange and free RecA binding are the same, suggesting that relocation of the complementary strand from its position in the intermediate structure to its position in the final structure limits both rates. Finally, we propose that homology recognition is governed by transitions to and from the intermediate structure, where the transitions depend on differential extension in the dsDNA. This differential extension drives strand exchange forward for homologs and increases the free energy penalty for strand exchange of non-homologs.

RecA homology search is promoted by mechanical stress along the scanned duplex DNA

A RecA–single-stranded DNA (RecA–ssDNA) filament searches a genome for sequence homology by rapidly binding and unbinding double-stranded DNA (dsDNA) until homology is found. We demonstrate that pulling on the opposite termini (3′ and 5′) of one of the two DNA strands in a dsDNA molecule stabilizes the normally unstable binding of that dsDNA to non-homologous RecA–ssDNA filaments, whereas pulling on the two 3′, the two 5′, or all four termini does not. We propose that the ‘outgoing’ strand in the dsDNA is extended by strong DNA–protein contacts, whereas the ‘complementary’ strand is extended by the tension on the base pairs that connect the ‘complementary’ strand to the ‘outgoing’ strand. The stress resulting from different levels of tension on its constitutive strands causes rapid dsDNA unbinding unless sufficient homology is present.

Changes in the tension in dsDNA alter the conformation of RecA bound to dsDNA-RecA filaments

The RecA protein is an ATPase that mediates recombination via strand exchange. In strand exchange a single-stranded DNA (ssDNA) bound to RecA binding site I in a RecA/ssDNA filament pairs with one strand of a double-stranded DNA (dsDNA) and forms heteroduplex dsDNA in site I if homology is encountered. Long sequences are exchanged in a dynamic process in which initially unbound dsDNA binds to the leading end of a RecA/ssDNA filament, while heteroduplex dsDNA unbinds from the lagging end via ATP hydrolysis. ATP hydrolysis is required to convert the active RecA conformation, which cannot unbind, to the inactive conformation, which can unbind. If dsDNA extension due to RecA binding increases the dsDNA tension, then RecA unbinding must decrease tension. We show that in the presence of ATP hydrolysis decreases in tension induce decreases in length whereas in the absence of hydrolysis, changes in tension have no systematic effect. These results suggest that decreases in force enhance dissociation by promoting transitions from the active to the inactive RecA conformation. In contrast, increases in tension reduce dissociation. Thus, the changes in tension inherent to strand exchange may couple with ATP hydrolysis to increase the directionality and stringency of strand exchange.

Binding selectivity of RecA to a single stranded DNA, a computational approach

Homologous recombination (HR) is the major DNA double strand break repair pathway which maintains the genomic integrity. It is fundamental for the survivability and functionality of all organisms. One of the initial steps in HR is the formation of the nucleoprotein filament composed by a single stranded DNA chain surrounded by the recombinases protein. The filament orchestrates the search for an undamaged homologue, as a template for the repair process. Our theoretical study was aimed at elucidating the selectivity of the interaction between a monomer of the recombinases enzyme in the Escherichia coli, EcRecA, the bacterial homologue of human Rad51, with a series of oligonucleotides of nine bases length. The complex, equilibrated for 20 ns with Langevian dynamics, was inserted in a periodic box with a 8 Å buffer of water molecules explicitly described by the TIP3P model. The absolute binding free energies are calculated in an implicit solvent using the Poisson-Boltzmann (PB) and the generalized Born (GB) solvent accessible surface area, using the MM-PB(GB)SA model. The solute entropic contribution is also calculated by normal mode analysis. The results underline how a significant contribution of the binding free energy is due to the interaction with the Arg196, a critical amino acid for the activity of the enzyme. The study revealed how the binding affinity of EcRecA is significantly higher toward dT₉ rather than dA₉, as expected from the experimental results.

Direct observation of twisting steps during Rad51 polymerization on DNA

The human recombinase hRad51 is a key protein for the maintenance of genome integrity and for cancer development. Polymerization and depolymerization of hRad51 on duplex DNA were studied here using a new generation of magnetic tweezers, measuring DNA twist in real time with a resolution of 5 degrees . Our results combined with earlier structural information suggest that DNA is somewhat less extended by hRad51 than by RecA (4.5 vs. 5.1 A per base pair) and untwisted by 18.2 degrees per base pair. They also confirm a stoichiometry of 3-4 bp per protein in the hRad51-dsDNA nucleoprotein filament. At odds with earlier claims, we show that after initial deposition of a multimeric nucleus, nucleoprotein filament growth occurs by addition/release of single proteins, involving DNA twisting steps of 65 degrees +/- 5 degrees. Simple numeric simulations show that this mechanism is an efficient way to minimize nucleoprotein filament defects. Nucleoprotein filament growth from a preformed nucleus was observed at hRad51 concentrations down to 10 nM, whereas nucleation was never observed below 100 nM in the same buffer. This behavior can be associated with the different stoichiometries of nucleation and growth. It may be instrumental in vivo to permit efficient continuation of strand exchange by hRad51 alone while requiring additional proteins such as Rad52 for its initiation, thus keeping the latter under the strict control of regulatory pathways.

Tid1/Rdh54 promotes dissociation of Dmc1 from nonrecombinogenic sites on meiotic chromatin

The meiosis-specific recombinase Dmc1 plays a critical role in DNA strand exchange in budding yeast. Tid1/Rdh54, a member of the Swi2/Snf2 family of DNA translocases, has been shown to stimulate Dmc1-dependent recombination. Tid1and its budding yeast paralog Rad54 have a variety of biochemical activities that may contribute to their biological function. Here we demonstrate that Dmc1 can associate with chromatin in the absence of DNA double-strand breaks (DSBs), and Tid1 suppresses this association. Chromatin immunoprecipitation experiments indicate that an activity shared by Tid1 and Rad54 is required for normal assembly of Dmc1 at DSB sites in preparation for recombination. These results lead to a model in which the ATP hydrolysis-dependent DNA translocase activity of Tid1 acts to promote dissociation of Dmc1 from nonreombinogenic sites on chromatin, with Rad54 being able to substitute for this function in the absence of Tid1. The tendency of Dmc1 to form unproductive interactions with chromatin is proposed to be a consequence of the mechanism of strand exchange. The results raise the possibility that ATP hydrolysis-dependent disruption of nonproductive recombinase-DNA interactions is a feature shared with other homologous recombination systems.

Calorimetric analysis of binding of two consecutive DNA strands to RecA protein illuminates mechanism for recognition of homology

RecA protein recognises two complementary DNA strands for homologous recombination. To gain insight into the molecular mechanism, the thermodynamic parameters of the DNA binding have been characterised by isothermal calorimetry. Specifically, conformational changes of protein and DNA were searched for by measuring variations in enthalpy change (DeltaH) with temperature (heat capacity change, DeltaC(p)). In the presence of the ATP analogue ATPgammaS, the DeltaH for the binding of the first DNA strand depends upon temperature (large DeltaC(p)) and the type of buffer, in a way that is consistent with the organisation of disordered parts and the protonation of RecA upon complex formation. In contrast, the binding of the second DNA strand occurs without any pronounced DeltaC(p), indicating the absence of further reorganisation of the RecA-DNA filament. In agreement with these findings, a significant change in the CD spectrum of RecA was observed only upon the binding of the first DNA strand. In the absence of nucleotide cofactor, the DeltaH of DNA binding is almost independent of temperature, indicating a requirement for ATP in the reorganisation of RecA. When the second DNA strand is complementary to the first, the DeltaH is larger than that for non-complementary DNA strand, but less than the DeltaH of the annealing of the complementary DNA without RecA. This small DeltaH could reflect a weak binding that may facilitate the dissociation of only partly complementary DNA and thus speed the search for complementary DNA. The DeltaH of binding DNA sequences displaying strong base-base stacking is small for both the first and second binding DNA strand, suggesting that the second is also stretched upon interaction with RecA. These results support the proposal that the RecA protein restructures DNA, preparing it for the recognition of a complementary second DNA strand, and that the recognition is due mainly to direct base-base contacts between DNA strands.

Probing the DNA sequence specificity of Escherichia coli RECA protein

Escherichia coli RecA protein catalyzes the central DNA strand-exchange step of homologous recombination, which is essential for the repair of double-stranded DNA breaks. In this reaction, RecA first polymerizes on single-stranded DNA (ssDNA) to form a right-handed helical filament with one monomer per 3 nt of ssDNA. RecA generally binds to any sequence of ssDNA but has a preference for GT-rich sequences, as found in the recombination hot spot Chi (5′-GCTGGTGG-3′). When this sequence is located within an oligonucleotide, binding of RecA is phased relative to it, with a periodicity of three nucleotides. This implies that there are three separate nucleotide-binding sites within a RecA monomer that may exhibit preferences for the four different nucleotides. Here we have used a RecA coprotease assay to further probe the ssDNA sequence specificity of E.coli RecA protein. The extent of self-cleavage of a λ repressor fragment in the presence of RecA, ADP-AlF₄ and 64 different trinucleotide-repeating 15mer oligonucleotides was determined. The coprotease activity of RecA is strongly dependent on the ssDNA sequence, with TGG-repeating sequences giving by far the highest coprotease activity, and GC and AT-rich sequences the lowest. For selected trinucleotide-repeating sequences, the DNA-dependent ATPase and DNA-binding activities of RecA were also determined. The DNA-binding and coprotease activities of RecA have the same sequence dependence, which is essentially opposite to that of the ATPase activity of RecA. The implications with regard to the biological mechanism of RecA are discussed.

Construction and evaluation of a kinetic scheme for RecA-mediated DNA strand exchange

The Escherichia coli RecA protein is the prototype of a class of proteins playing a central role in genomic repair and recombination in all organisms. The unresolved mechanistic strategy by which RecA aligns a single strand of DNA with a duplex DNA and mediates a DNA strand switch is central to understanding its recombinational activities. Toward a molecular-level understanding of RecA-mediated DNA strand exchange, we explored its mechanism using oligonucleotide substrates and the intrinsic fluorescence of 6-methylisoxanthopterin (6MI). Steady- and presteady-state spectrofluorometric data demonstrate that the reaction proceeds via a sequential four-step mechanism comprising a rapid, bimolecular association step followed by three slower unimolecular steps. Previous authors have proposed multistep mechanisms involving two or three steps. Careful analysis of the differences among the experimental systems revealed a previously undiscovered intermediate (N1) whose formation may be crucial in the kinetic discrimination of homologous and heterologous sequences. This observation has important implications for probing the fastest events in DNA strand exchange using 6MI to further elucidate the molecular mechanisms of recombination and recombinational repair.

Direct evaluation of a mechanism for activation of the RecA nucleoprotein filament

The RecA protein of Escherichia coli controls the SOS response for DNA damage tolerance and plays a crucial role in recombinational DNA repair. The formation of a RecA.ATP.ssDNA complex initiates all RecA activities, and yet this process is not understood at the molecular level. An analysis of RecA.DNA interactions was performed using both a mutant RecA protein containing a tryptophan (Trp) reporter and oligodeoxyribonucleotides (ODNs) containing a fluorescent guanine analogue, 6-methylisoxanthopterin (6MI). Experiments using fluorescent ODNs allowed structurally distinct nucleoprotein filaments, formed in the absence and presence of ATPgammaS (a slowly hydrolyzed analogue of ATP), to be differentiated directly. Stopped-flow spectrofluorometry, combined with presteady-state kinetic analyses, revealed unexpected differences in the rates of RecA.ODN and RecA.ATPgammaS.ODN complex assembly. This is the first demonstration that such intrinsically fluorescent synthetic DNAs can be used to characterize definitively the real-time assembly and activation of RecA.ssDNA complexes. Surprisingly, the ssDNA binding event is almost 50-fold slower in the presence of the activating ATPgammaS cofactor. Furthermore, a combination of time-dependent emission changes from 6MI and Trp allowed the first direct chemical test of whether an inactive filament can isomerize to the active state. The results revealed that, unlike the hexameric motor proteins, the inactive RecA filament cannot directly convert to the active state upon ATPgammaS binding. These results have implications for understanding how a coincidence of functions--an ATP-communicated signal-like activity and an ATP-driven motorlike activity--are resolved within a single protein molecule.

Aggregation of RecA-derived peptides on single-stranded oligonucleotides triggered by schiff base-mediated crosslinking

We here show that single-stranded oligonucleotides containing 5-formyl-2'-deoxyuridine (fdU) can crosslink the peptides derived from the DNA binding site of RecA protein through a Schiff base formation. The ability of crosslinking of fdU-containing oligonucleotides was investigated using a series of peptides whose amino acid residues spanning the center of the RecA-derived peptide were sequentially replaced with lysine. Circular dichroism (CD) spectroscopy, gel mobility shift assay and sedimentation experiment demonstrated that crosslinking reaction proceeded efficiently only when the peptides bound to the oligonucleotides.

Hyper-recombinogenic RecA protein from Pseudomonas aeruginosa with enhanced activity of its primary DNA binding site

According to one prominent model, each protomer in the activated nucleoprotein filament of homologous recombinase RecA possesses two DNA-binding sites. The primary site binds (1) single-stranded DNA (ssDNA) to form presynaptic complex and (2) the newly formed double-stranded (ds) DNA whereas the secondary site binds (1) dsDNA of a partner to initiate strand exchange and (2) the displaced ssDNA following the strand exchange. RecA protein from Pseudomonas aeruginosa (RecAPa) promotes in Escherichia coli hyper-recombination in an SOS-independent manner. Earlier we revealed that RecAPa rapidly displaces E.coli SSB protein (SSB-Ec) from ssDNA to form presynaptic complex. Here we show that this property (1) is based on increased affinity of ssDNA for the RecAPa primary DNA binding site while the affinity for the secondary site remains similar to that for E.coli RecA, (2) is not specific for SSB-Ec but is also observed for SSB protein from P.aeruginosa that, in turn, predicts a possibility of enhanced recombination repair in this pathogenic bacterium.

The synaptic complex of RecA protein participates in hybridization and inverse strand exchange reactions

RecA protein catalyzes strand exchange between homologous single-stranded and double-stranded DNAs. In the presence of ATPgammaS, the post-strand exchange synaptic complex is a stable end product that can be studied. Here we ask whether such complexes can hybridize to or exchange with DNA, 2'-OMe RNA, PNA, or LNA oligonucleotides. Using a gel mobility shift assay, we show that the displaced strand of a 45 bp synaptic complex can hybridize to complementary oligonucleotides with different backbones to form a four-stranded (double D-loop) joint that survives removal of the RecA protein. This hybridization reaction, which confirms the single-stranded character of the displaced strand in a synaptic complex, might initiate recombination-dependent DNA replication if it occurs in vivo. We also show that either strand of the heteroduplex in a 30 bp synaptic complex can be replaced with a homologous DNA oligonucleotide in a strand exchange reaction that is mediated by the RecA filament. Consistent with the important role that deoxyribose plays in strand exchange, oligonucleotides with non-DNA backbones did not participate in this reaction. The hybridization and strand exchange reactions reported here demonstrate that short synaptic complexes are dynamic structures even in the presence of ATPgammaS.

Influence of DNA sequence on the positioning of RecA monomers in RecA-DNA cofilaments

We show that certain DNA sequences have the ability to influence the positioning of RecA monomers in RecA-DNA complexes. A tendency for RecA monomers to be phased was observed in RecA protein complexes with several oligonucleotides containing a recombinational hotspot sequence, the chi-site from Escherichia coli. This influence was observed in both the 5' to 3' and 3' to 5' directions with respect to chi. A 5'-end phosphate group and probably some other features in DNA also influence the phasing of RecA monomers. We conclude that natural DNAs contain a number of features that influence the positioning of RecA monomers. The ability of specific DNA sequences to influence the positioning of RecA monomers demonstrates some specificity in the binding of individual bases at different sites within a RecA monomer and, most likely, reflects the stereochemical non-equivalence of these sites. The possible biological implications of the phasing of RecA monomers in presynaptic DNA-protein cofilaments are discussed.

Effects of DNA sequence and structure on binding of RecA to single-stranded DNA

Fluorescence anisotropy is used to follow the binding of RecA to short single-stranded DNA (ssDNA) sequences (39 bases) at low DNA and RecA concentration where the initial phase of polymerization occurs. We observe that RecA condensation is extremely sensitive to minute changes in DNA sequences. RecA binds strongly to sequences that are rich in pyrimidines and that lack significant secondary structure and base stacking. We find a correlation between the DNA folding free energy and the onset concentration for RecA binding. These results suggest that the folding of ssDNA and base stacking represent a barrier for RecA binding. The link between secondary structure and binding affinity is further analyzed with two examples: discrimination between two naturally occurring polymorphisms differing by one base and RecA binding on a molecular beacon. A self-assembly model is introduced to explain these observations. We propose that RecA may be used to sense ssDNA sequence and structure.

Evidence for a four-strand exchange catalyzed by the RecA protein

Strand exchange between two duplexes is usually initiated as a three-strand event that requires the presence of a single-stranded overhang or gap in one of the two molecules. Here we show that the RecA protein can catalyze a four-strand exchange. Specifically, it can recombine short hairpin substrates with homologous stems provided that one of the hairpins possesses a chimeric DNA/RNA backbone. This four-strand exchange reaction goes to completion in the presence of ATPgammaS and releases a stable heteroduplex upon removal of the RecA protein. Under identical conditions, strand exchange between two DNA hairpins is incomplete and generates a nascent heteroduplex that rapidly dissociates when the RecA protein is denatured. Since presynaptic filament formation does not appear to melt either type of hairpin, we propose that exchange occurs between homologously aligned duplexes that are extended and unwound within a RecA filament. The first reaction provides a mechanism for gene targeting by chimeric double-hairpin oligonucleotides while the second reaction explains the ability of the RecA protein to transiently align double-stranded DNA molecules.

The L2 loop peptide of RecA stiffens and restricts base motions of single-stranded DNA similar to the intact protein

The L2 loop in the RecA protein is the catalytic center for DNA strand exchange. Here we investigate the DNA binding properties of the L2 loop peptide using optical spectroscopy with polarized light. Both fluorescence intensity and anisotropy of an etheno-modified poly(dA) increase upon peptide binding, indicate that the base motions of single-stranded DNA are restricted in the complex. In agreement with this conclusion, the peptide-poly(dT) complex exhibits a significant linear dichroism signal. The peptide is also found to modify the structure of double-stranded DNA, but does not denature it. It is inferred that strand separation may not be required for the formation of a joint molecule.

Nucleotide dependent structural and kinetic changes in Xenopus rad51.1-DNA complex stimulating the strand exchange reaction: destacking of DNA bases and restriction of their local motion

Rad51 is a eukaryotic homologue of RecA and it catalyzes the DNA strand exchange reaction in homologous recombination. This protein, like RecA, requires ATP as a cofactor for activity. We investigated the mechanism of activation of this protein by the nucleotide cofactor by studying the effect of various nucleotides, particularly ATP, ADP and the non-hydrolyzable analog of ATP, adenosine-5'-O-(3-thiotriphosphate) (ATPgammaS) on the DNA binding of a Xenopus Rad51 protein (XRad51.1). DNA binding was studied in solution by monitoring the fluorescence changes of etheno-modified fluorescent poly(dA) or fluorescein-labeled oligo(dT) and by filter binding assay. Active nucleotides (ATP, dATP) changed the DNA binding mode of XRad51.1. In the active complex, the DNA bases were destacked and their motion was highly restricted. Dissociation of XRad51.1 from DNA was accelerated by ATP and dATP, as was dissociation of RecA from DNA. In contrast to these similarities with RecA, the XRad51.1-DNA complex was dissociated by the non-hydrolyzable analog of ATP (ATPgammaS) and this dissociation was not significantly accelerated by ADP. The effect of ATP hydrolysis on the XRad51.1-DNA complex differs from that on the RecA-DNA complex. ATP hydrolysis may not be essential for the strand exchange reaction whereas the changes in the DNA structure by ATP are important.

No sliding during homology search by RecA protein

The RecA protein of Escherichia coli is a prototype of the RecA/Rad51 family of proteins that exist in virtually all the organisms. In a process called DNA synapsis, RecA first polymerizes onto a single-stranded DNA (ssDNA) molecule; the resulting RecA-ssDNA complex then searches for and binds to a double-stranded DNA (dsDNA) molecule containing the almost identical, or "homologous, " sequence. The RecA-ssDNA complex thus can be envisioned as a sequence-specific binding entity. How does the complex search for its target buried within nonspecific sequences? One possible mechanism is the sliding mechanism, in which the complex first binds to a dsDNA molecule nonspecifically and then linearly diffuses, or slides, along the dsDNA. To understand the mechanism of homology search by RecA, this sliding model was tested. A plasmid containing four homologous targets in tandem was constructed and used as the dsDNA substrate in the synapsis reaction. If the sliding is the predominant search mode, the two outermost targets should act as more efficient targets than the inner targets. No such positional preference was observed, indicating that a long range sliding of the RecA-ssDNA complex does not occur. These and other available data can be adequately explained by a simple three-dimensional random collision mechanism.

Probing of DNA-binding sites of Escherichia coli RecA protein utilizing 1-anilinonaphthalene-8-sulfonic acid

RecA protein of Escherichia coli plays an essential role in homologous recombination of DNA strands. To analyze the interaction of RecA with single-stranded DNA (ssDNA), we performed a fluorescence competition assay employing 1-anilinonaphthalene-8-sulfonic acid (ANS) as an extrinsic fluorescent probe. ANS bound to RecA at three sites, leading to enhancement of ANS fluorescence. Addition of synthetic polynucleotides to the RecA-ANS complex in the absence of a nucleotide quenched the ANS fluorescence, indicating displacement of ANS molecules by ssDNA. Less effective quenching by poly(dA) suggests that the nucleoprotein filament on poly(dA) may differ from those on poly(dT) and poly(dC). A titration experiment with poly(dT) and poly(dA) showed clear stoichiometric binding of 3.5 nucleotides per protein. The site size for poly(dC) was 7.0, which could be explained by the formation of a double helix of poly(dC). ATP and other nucleotides also displaced the ANS. To identify ANS-binding sites, ANS was incorporated into RecA by UV irradiation, and fluorescent peptides were isolated from the proteolytic digest. Sequence analysis suggested that ANS binds to or near the ATP-binding region. These results suggest that the fluorescence quenching and photoincorporation assay using ANS may be useful for the analysis of the interaction of a protein and its ligand.

Base orientation of second DNA in RecA.DNA filaments. Analysis by combination of linear dichroism and small angle neutron scattering in flow-oriented solution

To gain insight into the mechanism of pairing two complementary DNA strands by the RecA protein, we have determined the nucleobase orientation of the first and the second bound DNA strands in the RecA.DNA filament by combined measurements of linear dichroism and small angle neutron scattering on flow-oriented samples. An etheno-modified DNA, poly(depsilonA) was adapted as the first DNA and an oligo(dT) as the second DNA, making it possible to distinguish between the linear dichroism signals of the two DNA strands. The results indicate that binding of the second DNA does not alter the nucleobase orientation of the first bound strand and that the bases of the second DNA are almost coplanar to the bases of the first strand although somewhat more tilted (60 degrees relative to the fiber axis compared with 70 degrees for the first DNA strand). Similar results were obtained for the RecA.DNA complex formed with unmodified poly(dA) and oligo(dT). An almost coplanar orientation of nucleobases of two DNA strands in a RecA-DNA filament would facilitate scanning for, and recognition of, complementary base sequences. The slight deviation from co-planarity could increase the free energy of the duplex to facilitate dissociation in case of mismatching base sequences.

Site size of cooperative single-stranded RNA binding by poliovirus RNA-dependent RNA polymerase

The poliovirus RNA-dependent RNA polymerase binds cooperatively to single-stranded RNA. We have determined the minimal RNA-binding site size of the poliovirus polymerase using binding titration with oligonucleotides of increasing length. A dramatic increase in affinity was observed when the length of the oligo(U) increased from 8 to 10 nucleotides (nt), arguing that the minimal size of RNA for polymerase binding is 10 nt. Another increase in affinity seen as the oligo(U) reached 24 nt suggests that a 24-nucleotide RNA can be occupied by two polymerase molecules. Direct binding of wild-type polymerase to oligo(U)12 and oligo(U)24 RNAs showed differences in affinity and cooperativity consistent with this model. The increase in binding affinity seen for oligo(U)10 suggests either that the RNA-binding determinants are widely spaced on the polymerase structure or that a substantial conformational change in the polymerase occurs upon the filling of its RNA-binding site.

The function of the secondary DNA-binding site of RecA protein during DNA strand exchange

RecA protein features two distinct DNA-binding sites. During DNA strand exchange, the primary site binds to single-stranded DNA (ssDNA), forming the helical RecA nucleoprotein filament. The weaker secondary site binds double-stranded DNA (dsDNA) during the homology search process. Here we demonstrate that this site has a second important function. It binds the ssDNA strand that is displaced from homologous duplex DNA during DNA strand exchange, stabilizing the initial heteroduplex DNA product. Although the high affinity of the secondary site for ssDNA is essential for DNA strand exchange, it renders DNA strand exchange sensitive to an excess of ssDNA which competes with dsDNA for binding. We further demonstrate that single-stranded DNA-binding protein can sequester ssDNA, preventing its binding to the secondary site and thereby assisting at two levels: it averts the inhibition caused by an excess of ssDNA and prevents the reversal of DNA strand exchange by removing the displaced strand from the secondary site.

Characterization of strand exchange activity of yeast Rad51 protein

The Saccharomyces cerevisiae RAD51 gene product takes part in genetic recombination and repair of DNA double strand breaks. Rad51, like Escherichia coli RecA, catalyzes strand exchange between homologous circular single-stranded DNA (ssDNA) and linear double-stranded DNA (dsDNA) in the presence of ATP and ssDNA-binding protein. The formation of joint molecules between circular ssDNA and linear dsDNA is initiated at either the 5' or the 3' overhanging end of the complementary strand; joint molecules are formed only if the length of the overhanging end is more than 1 nucleotide. Linear dsDNAs with recessed complementary or blunt ends are not utilized. The polarity of strand exchange depends upon which end is used to initiate the formation of joint molecules. Joint molecules formed via the 5' end are processed by branch migration in the 3'-to-5' direction with respect to ssDNA, and joint molecules formed with a 3' end are processed in the opposite direction.

Thermochemical and kinetic evidence for nucleotide-sequence-dependent RecA-DNA interactions

RecA catalyses homologous recombination in Escherichia coli by promoting pairing of homologous DNA molecules after formation of a helical nucleoprotein filament with single-stranded DNA. The primary reaction of RecA with DNA is generally assumed to be unspecific. We show here, by direct measurement of the interaction enthalpy by means of isothermal titration calorimetry, that the polymerisation of RecA on single-stranded DNA depends on the DNA sequence, with a high exothermic preference for thymine bases. This enthalpic sequence preference of thymines by RecA correlates with faster binding kinetics of RecA to thymine DNA. Furthermore, the enthalpy of interaction between the RecA x DNA filament and a second DNA strand is large only when the added DNA is complementary to the bound DNA in RecA. This result suggests a possibility for a rapid search mechanism by RecA x DNA filaments for homologous DNA molecules.

DNA strand exchange mediated by the Escherichia coli RecA protein initiates in the minor groove of double-stranded DNA

The Escherichia coli RecA protein can recognize sequence homology between a single-stranded DNA (ssDNA) and homologous double-stranded DNA (dsDNA). One model for the homology recognition invokes a DNA triplex intermediate in which specific hydrogen bonds connect the ssDNA with groups in the major groove of dsDNA. Using photo-cross-linking methods, we have analyzed the arrangement of DNA strands after the local strand exchange. The results showed that the displaced strand sits in the major groove of the hybrid duplex product. This arrangement indicates that the ssDNA invades the minor groove of dsDNA and hence argues against the involvement of triplex intermediates. The results support an alternative model for the homology recognition that invokes melting of the dsDNA and annealing of the one strand to the invading ssDNA.

Effects of minor and major groove-binding drugs and intercalators on the DNA association of minor groove-binding proteins RecA and deoxyribonuclease I detected by flow linear dichroism

Linear and circular dichroic spectroscopies have been employed to investigate the effects of small DNA ligands on the interactions of two proteins which bind to the minor groove of DNA, viz. RecA protein from Escherichia coli and deoxyribonuclease I (bovine pancreas). Ligands representing three specific non-covalent binding modes were investigated: 4',6-diamidino-2-phenylindole and distamycin A (minor groove binders), methyl green (major groove binder), and methylene blue, ethidium bromide and ethidium dimer (intercalators). Linear dichroism was demonstrated to be an excellent detector, in real time, of DNA double-strand cleavage by deoxyribonuclease I. Ligands bound in all three modes interfered with the deoxyribonuclease I digestion of dsDNA, although the level of interference varied in a manner which could be related to the ligand binding site, the ligand charge appearing to be less important. In particular, the retardation of deoxyribonuclease I cleavage by the major groove binder methyl green demonstrates that accessibility to the minor groove can be affected by occupancy of the opposite groove. Binding of all three types of ligand also had marked effects on the interaction of RecA with dsDNA in the presence of non-hydrolyzable cofactor adenosine 5'-O-3-thiotriphosphate, decreasing the association rate to varying extents but with the strongest effects from ligands having some minor groove occupancy. Finally, each ligand was displaced from its DNA binding site upon completion of RecA association, again demonstrating that modification of either groove can affect the properties and behaviour of the other. The conclusions are discussed against the background of previous work on the use of small DNA ligands to probe DNA-protein interactions.

Locations of functional domains in the RecA protein. Overlap of domains and regulation of activities

We review the locations of various functional domains of the RecA protein of Escherichia coli, including how they have been assigned, and discuss the potential regulatory roles of spatial overlap between different domains. RecA is a multifunctional and ubiquitous protein involved both in general genetic recombination and in DNA repair: it regulates the synthesis and activity of DNA repair enzymes (SOS induction) and catalyses homologous recombination and mutagenesis. For these activities RecA interacts with a nucleotide cofactor, single-stranded and double-stranded DNAs, the LexA repressor, UmuD protein, the UmuD'2C complex as well as with RecA itself in forming the catalytically active nucleofilament. Attempts to locate the respective interaction sites have been advanced in order to understand the various functions of RecA. An intriguing question is how these numerous functional sites are contained within this rather small protein (38 kDa). To assess more clearly the roles of the respective sites and to what extent the sites may be interacting with each other, we review and compare the results obtained from various biological, biochemical and physico-chemical approaches. From a three-dimensional model it is concluded that all sites are concentrated to one part of the protein. As a consequence there are significant overlaps between the sites and it is speculated that corresponding interactions may play important roles in regulating RecA activities.

The specificity of the secondary DNA binding site of RecA protein defines its role in DNA strand exchange

The RecA protein-single-stranded DNA (ssDNA) filament can bind a second DNA molecule. Binding of ssDNA to this secondary site shows specificity, in that polypyrimidinic DNA binds to the RecA protein-ssDNA filament with higher affinity than polypurinic sequences. The affinity of ssDNA, which is identical in sequence to that bound in the primary site, is not always greater than that of nonhomologous DNA. Moreover, this specificity of DNA binding does not depend on the sequence of the DNA bound to the RecA protein primary site. We conclude that the specificity reflects an intrinsic property of the secondary site of RecA protein rather than an interaction between DNa molecules within nucleoprotein filament--i.e., self-recognition. The secondary DNA binding site displays a higher affinity for ssDNA than for double-stranded DNA, and the binding of ssDNA to the secondary site strongly inhibits DNA strand exchange. We suggest that the secondary binding site has a dual role in DNA strand exchange. During the homology search, it binds double-stranded DNA weakly; upon finding local homology, this site binds, with higher affinity, the ssDNA strand that is displaced during DNA strand exchange. These characteristics facilitate homologous pairing, promote stabilization of the newly formed heteroduplex DNA, and contribute to the directionality of DNA strand exchange.

Roles of Tyr103 and Tyr264 in the regulation of RecA-DNA interactions by nucleotide cofactors

The DNA-binding mode of the RecA protein, in particular its dependence on nucleotide cofactor, has been investigated by monitoring the fluorescence and linear-dichroism signals of a tryptophan residue inserted in the RecA to replace tyrosine at position 103 or 264. These residues are important for cofactor and DNA binding, as evidenced from their fluorescence changes upon binding of cofactor and DNA [Morimatsu, K., Horii, T. & Takahashi, M. (1995) Eur. J. Biochem. 228, 779-785]. The substitution of these residues with tryptophan does not affect the structure or biological function of the complex and can therefore be exploited to gain structural information in terms of the orientation and environment of the inserted reporter chromophore. The fluorescence change upon formation of the ternary cofactor.RecA. DNA complex was much smaller than the sum of the changes induced by cofactor or DNA alone. This difference indicates that the cofactor and DNA interact with RecA via common components. The fluorescence change caused by DNA in the presence of cofactor was almost independent of the base composition of DNA, in contrast to the interaction in the absence of cofactor. Hence, the contact mode between the selected residues and DNA in the complex may depend significantly on the cofactor. Linear-dichroism measurements indicate that the cofactor does not markedly alter the organization of RecA filament. Linear dichroism shows that neither the aromatic moiety of residue 103 nor that of residue 264 is intercalated between the DNA bases. The textural changes reported for the helical pitch and contour length of RecA fiber upon interaction with cofactor and DNA may derive from a subtle change in orientation of the RecA subunits in the filament.

Differential proximity probing of two DNA binding sites in the Escherichia coli recA protein using photo-cross-linking methods

The DNA strand-exchange reaction catalyzed by the Escherichia coli RecA protein occurs between the two DNA binding sites that are functionally distinct. Site I is the site to which a DNA molecule (normally single-stranded DNA) binds first; this first binding makes site II available for additional DNA-binding (normally double- stranded DNA). Photo-cross linking was employed to identify the amino acid residues located close to the bound DNA molecule(s). A ssDNA oligo containing multiple 5-iodouracil residues (IdU) was cross-linked to RecA by irradiation with a XeC1 pulse laser (308 nm), and the cross-linked peptides were purified and sequenced. To differentiate the two DNA binding sites, we used two protocols for making RecA-ssDNA complexes: (1) IdU-containing oligo was mixed with a stoichiometric excess of RecA, a condition which favors the binding of the oligo to site I, and (2) RecA was first allowed to bind to a nonphotoreactive oligo and then chased with the IdU-containing oligo, a condition which favors the binding of the IdU-oligo to site II. We observed that when RecA was in excess (site I probing), cross-linking occurred to Met-164 which is located in the disordered loop 1 of the RecA crystal structure [Story, R.M., Weber, I.T., & Steitz, T.A. (1992) Nature 355, 318-325]. When site II was probed, the majority of cross-linking occurred to Met-202 or Phe-203, located in loop 2. These results support the idea that, as predicted by Story and co-workers (1992), the disordered loops are involved in DNA binding. The results also suggest that the two sites are not only functionally but also physically distinct.

The central aromatic residue in loop L2 of RecA interacts with DNA. Quenching of the fluorescence of a tryptophan reporter inserted in L2 upon binding to DNA

To determine the role of the central aromatic residue in one of the DNA binding domains in Escherichia coli RecA protein, we have constructed a protein in which a tryptophan fluorescence reporter is inserted in the place of phenylalanine residue 203 in loop L2, a putative DNA binding site, and measured its fluorescence. The modified protein is active both in vivo and in vitro. The binding of nucleotide cofactor (ATP or its analog adenosine 5'-O-3-thiotriphosphate) does not modify the fluorescence. By contrast, the binding of DNA, both in the absence and presence of cofactor, strongly decreases the fluorescence in intensity (40-65%) and shifts the emission peak from 344 to 337 nm. The change occurs both with single- and double-stranded DNA and also upon the binding of a second single-stranded DNA. The results indicate that the residue 203 is in fact close to the first and second DNA binding sites. However, the quenching is not total and depends only slightly on the nature of DNA bases, thus suggesting an indirect interaction with DNA bases.

Binding of RecA to anti-parallel poly(dA).2poly(dT) triple helix DNA

Binding of RecA protein to conventional anti-parallel poly(dA).2poly(dT) triplex DNA has been studied using flow linear dichroism spectroscopy. The association requires the presence of cofactor analog adenosine 5'-O-3-thiotriphosphate (ATP gamma S) and occurs with a rate similar to that for the association of RecA to double-stranded poly(dA).poly(dT) DNA. The binding of RecA to DNA stiffens the nucleotide chain, as evidenced from high orientation already at low shear rates, and the complex with triplex DNA appears to be at least as stiff as that with the duplex DNA. Therefore, the observation of a lower magnitude of the LD spectrum at 260 nm, in the triplex-RecA compared to the duplex-RecA complex, but retained magnitude of protein LD at 280 nm, indicates a markedly impaired orientation of nucleo-bases, possibly reflecting a perturbation by RecA on the third strand making its bases deviate strongly from perpendicularity. The circular dichroism spectrum, appearing immediately after dissociation of RecA by SDS, suggests an intact triplex structure, meaning that complexation with RecA has not dissociated the third strand. In conclusion, binding of RecA to triplex DNA does not modify the main organisation of the strands, but could affect the base-base interactions between them. Tilted bases could reflect a conformational change that RecA imposes also on the biological intermediate triplex structure to relax the base-base hydrogen bonding between the DNA strands.

Evidence for elongation of the helical pitch of the RecA filament upon ATP and ADP binding using small-angle neutron scattering

Structural changes of the RecA filament upon binding of cofactors have been investigated by small-angle neutron scattering. Both ATP and ADP increased the helical pitch of the RecA homopolymer, which is observed to be 7 nm in the absence of any cofactor. The binding of ATP altered the pitch to 9 nm, whereas the binding of ADP only produced a pitch of 8.2 nm. The pitch determined for the RecA complex with the ATP analog adenosine 5'-[gamma-thio]triphosphate was similar to that found with ATP. Thus, at least three, somewhat different. RecA helical filamentous structures may form in solution. The binding of DNA to RecA did not alter the pitch significantly, indicating that the cofactor binding is the determining factor for the size of the helical pitch of the RecA filament. We also found that elongation of the helical pitch is a necessary, but not a sufficient condition, for the coprotease activity of RecA. The presence of acetate or glutamate ions is also required. The pitch of the ADP.RecA filament is in agreement with that found in the crystal structure. This correlation indicates that this structure corresponds to that of the ADP.RecA filament in solution, although this is not the species active in recombination.

Fluorescence-detected interactions of oligonucleotides in RecA complexes

A technique has been developed to probe directly RecA-DNA interactions by the use of the fluorescent chromophore, (+)anti-benzo(a)pyrene-7,8-dihydrodiol-9,10-epoxide (BPDE), covalently attached to DNA. The 24-mer oligonucleotide 5'-d(CTACTAAACATGTACAAATCATCC) was specifically modified on the exocyclic nitrogen of the central guanine, to yield a trans-adduct. Upon interaction of the modified oligonucleotide with RecA we find an increase in BPDE fluorescence and a rather high fluorescence anisotropy, suggesting a restricted motion of the BPDE-oligonucleotide in the protein filament. In the presence of the cofactor ATP gamma S, binding of two oligonucleotides, identical or complementary in sequence, in the RecA filament is possible. The RecA-DNA complex is, however, more stable when the sequences are complementary; in addition, a shift in the BPDE emission peaks is observed. In the presence of ATP (and an ATP regeneration system), the RecA-DNA interaction between two complementary oligonucleotides is changes, and we now find protein-mediated renaturation to occur.

Interaction of Tyr103 and Tyr264 of the RecA protein with DNA and nucleotide cofactors. Fluorescence study of engineered proteins

To obtain structural insight on the interaction of the RecA protein with nucleotide cofactors (ATP and ADP) and DNA, we have made two engineered RecA proteins, in which either Tyr103 or Tyr264 was replaced with tryptophan. The fluorescence of tryptophan residues (two/subunit) of wild-type RecA is not significantly altered upon the binding of cofactor or DNA. Therefore, any detectable fluorescence change of the engineered proteins could be directly related to interaction with the particular inserted tryptophan residue. The fluorescence of Trp103 is almost completely quenched upon ADP binding, supporting a stacking interaction of adenine base of ADP with Tyr103. By contrast, with ATP the quenching of fluorescence of Trp103 is not complete (75%), possibly indicating that there is no stacking interaction with ATP. Such a difference could explain the antagonistic effects of ATP and ADP. Both nucleotides partially quench the fluorescence of Trp264 (about 70%), confirming that this residue is in the vicinity of the cofactor-binding site. The binding of ssDNA also decreases the fluorescence of both Trp103 and Trp264, the degree of quenching depending upon base composition and decreasing in the following order: poly(dT) > poly(dI) > M13 ssDNA > poly(dA). This order coincides with that of the binding affinities of these polynucleotides to RecA reported by Cazenave et al. [Cazenave, C., Chabbert, M., Toulmé, J. J. & Hélène, C. (1984) Biochim. Biophys. Acta 781, 7-13]. This correlation supports the finding that a region very close to Tyr103 interacts with DNA.

Occurrence of three-stranded DNA within a RecA protein filament

A RecA protein-generated triple-stranded DNA species can be observed by electron microscopy, within narrowly defined conditions. Three-stranded DNA is detected only when initiation of normal DNA strand exchange is precluded by heterologous sequences within the duplex DNA substrate, when ATP is hydrolyzed, and when the DNA is cross-linked with a psoralen derivative prior to removal of RecA filaments. When adenosine 5'-O-(thiotriphosphate) is used, only the product hybrid duplex DNA can be cross-linked within the RecA filament. The third strand is either displaced or interwound in a conformation that does not permit cross-linking. When ATP is hydrolyzed by RecA, all three strands are cross-linked within the filament in a complex pattern that suggests a dynamic structure. This structure is altered when RecA protein is removed before cross-linking. Hsieh et al. (1990) and Rao et al. (1991, 1993) have proposed, on the basis of nuclease protection and chemical modification studies, that a stable triple-stranded DNA species can persist after removal of RecA protein. We have been unable to visualize these triple-stranded structures by the methods used in the present investigation. When RecA removal was followed immediately by interstrand cross-linking, only the two strands of the hybrid duplex DNA were cross-linked.

The cofactor ATP in DNA-RecA complexes is not intercalated between DNA bases

In an attempt to understand the role of ATP as a cofactor at the interaction of the RecA protein with DNA, we have studied the orientation geometries of the cofactor analogs adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S) and guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) in RecA-DNA complexes using flow linear dichroism spectroscopy. Both cofactors promote the formation of RecA-DNA complexes of similar structure as judged from similar orientations of DNA bases. The DNA orientation was probed through the dichroism of the long-wavelength absorption of a DNA analog, poly(d epsilon A). In this way differences between the dichroic spectra of the ATP gamma S-RecA-DNA and GTP gamma S-RecA-DNA complexes, observed in the shorter-wavelength region, are related to orientation at variations of the cofactor chromophores. The results show that the guanine plane of GTP gamma S is oriented parallel with the principal axis of the complex in contrast to the more perpendicular orientation of the DNA bases. This observation directly excludes the possibility that the cofactor could be intercalated between the DNA bases. The orientation of the adenine base of ATP gamma S, which may be similar to that of guanine of GTP gamma S albeit not exactly the same, is also inconsistent with intercalation. The possibility that the cofactor bound to the protein could be intercalated in DNA had been speculated from the observation that some DNA intercalators can induce RecA binding to DNA in the absence of cofactor.(ABSTRACT TRUNCATED AT 250 WORDS)

Properties of RecA-oligonucleotide complexes

The interaction of RecA protein with short single-stranded oligonucleotides is characterised by flow linear dichroism (LD), isoelectric focusing (IEF) and electron microscopy (EM). From LD and EM it is evident that RecA forms long filaments with at least some 50 oligonucleotides in a 'train formation'. The tendency to form trains is substantially lower when an amino group is attached to the 5' end of the oligonucleotide, suggesting that the modification impairs protein-protein interactions at the interface between two oligomers. From LD it is also evident that no bridging occurs between RecA-oligonucleotide complexes containing more than one oligomer strand per RecA filament. This property make them manageable in polyacrylamide gels, hence allowing characterisation by IEF. RecA was found acidic with a pI of 5.0. The pI was not dependent on the presence of bound cofactor (ATP gamma S) and oligonucleotides suggesting that protonation of the protein readily occurs to compensate for the negative charges provided by bound cofactor and DNA.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.

Spectroscopic observation of renaturation between polynucleotides with RecA in the presence of ATP hydrolysis

To obtain mechanistic insights about RecA-promoted base pairing between complementary polynucleotides, the complex formation of RecA with poly(dA) and poly(dT) in the presence of ATP (and ATP-regenerating system) has been studied. The reaction was followed using a fluorescent probe, benzopyrenediolepoxide (BPDE), covalently attached to less than 1% of the adenine bases of poly(dA). BPDE is sensitive to its environment and has been found useful for detection of interactions between DNA strands, in the three binding positions of the RecA filament, in the presence of adenosine 5'-O-3-thiotriphosphate (ATP[S]) [Wittung, P., Nordén, B. & Takahashi, M. (1994) J. Biol. Chem. 269, 5799-5803]. The emission spectrum of RecA:BPDE-poly(dA) formed in the presence of ATP is similar to that observed with ATP[S] supporting similar structures of the complexes. However, the fluorescence anisotropy is considerably reduced, suggesting a higher degree of freedom of DNA in the presence of ATP hydrolysis. Upon addition of a complementary strand, poly(dT), to a preformed filament of RecA:BPDE-poly(dA) in the presence of ATP, the fluorescence intensity slowly decreases and a change of emission profile consistent with Watson-Crick base pairing is observed. This contrasts with the case of ATP[S] in which normal base pairing is never observed. Hence, ATP hydrolysis appears necessary for the RecA filament to be able to promote true renaturation. The renaturation reaction is found more effective when one of the complementary DNA strands is bound in the primary RecA DNA-binding position and the other is added as the third strand, but the reaction can also occur between DNA strands in any combination of binding positions in the RecA filament. This observation suggests the importance of the third DNA-binding position of the RecA filament. Renaturation between DNA strands in the other two combinations of binding positions is speculated to have a role in aborting the strand-exchange reaction when the strands are insufficiently complementary.

Accessibility to modification of histidine residues of RecA protein upon DNA and cofactor binding

The potential role of histidine residues of RecA protein in binding DNA has been investigated by monitoring their accessibility to diethylpyrocarbonate. In the absence of both DNA and cofactor, only one of two histidine residues is modified by the reagent, indicating that the other residue is buried. However, both histidine residues become accessible after addition of cofactor analog adenosine 5'-O-(3-thiotriphosphate) (ATP[S]) indicating a change in the organization of the RecA filament and/or a change in the conformation of protein. The diethylpyrocarbonate-modified RecA is found to be able to polymerize just as the unmodified protein. The binding of double-stranded DNA, in the presence of ATP[S], reduces the reactivity of both histidine residues to diethylpyrocarbonate. The binding of single-stranded DNA (with ATP[S]) has a similar, though smaller, protective effect. However, no significant dissociation of either of the complexes as a result of the modification was observed and a RecA molecule which had been modified in the absence of DNA could still bind DNA. A protection of the histidine residues is also effected by high salt concentration which promotes, just as DNA binding, ATPase and coprotease activity in RecA. The protection of histidine residues to diethylpyrocarbonate upon DNA binding probably relates to a conformational change of RecA and may not be any direct effect of shielding by the DNA. Nonetheless, the domains including the histidine residues could be centers of allosteric effects and are concluded to be close to the DNA binding site.