Structural data suggest that the active and inactive forms of the RecA filament are not simply interconvertible.

We have used electron microscopy to examine the two major conformational states of the helical filament formed by the RecA protein of Escherichia coli. The compressed filament, formed in the absence of a nucleotide cofactor either as a self-polymer or on a single-stranded DNA molecule, is characterized in solution by about 6.1 subunits per turn of a 76 A pitch helix, and appears to be inactive with respect to all RecA activity. The active state of the filament, formed with ATP or an ATP analog on either a single or double-stranded DNA substrate, has about 6.2 subunits per turn of a 94 A pitch helix. Measurements of the contour length of RecA-covered single-stranded DNA circles in ice, formed in the absence of nucleotide cofactor, indicate that each RecA subunit binds five bases, in contrast to the three bases or base-pairs per subunit in the active state. The different stoichiometries of DNA binding suggests that the two polymeric forms are not interconvertible, as has been suggested on biochemical grounds. A three-dimensional reconstruction of the inactive state shows the same general features as the 83 A pitch filament present in the RecA crystal. This structural similarity and the fact that the crystal does not contain ATP or DNA suggests that the crystal structure is more similar to the compressed filament than the active, extended filament.     

Structural studies on MtRecA-nucleotide complexes: insights into DNA and nucleotide binding and the structural signature of NTP recognition

RecA protein plays a crucial role in homologous recombination and repair of DNA. Central to all activities of RecA is its binding to Mg(+2)-ATP. The active form of the protein is a helical nucleoprotein filament containing the nucleotide cofactor and single-stranded DNA. The stability and structure of the helical nucleoprotein filament formed by RecA are modulated by nucleotide cofactors. Here we report crystal structures of a MtRecA-ADP complex, complexes with ATPgammaS in the presence and absence of magnesium as well as a complex with dATP and Mg+2. Comparison with the recently solved crystal structures of the apo form as well as a complex with ADP-AlF4 confirms an expansion of the P-loop region in MtRecA, compared to its homologue in Escherichia coli, correlating with the reduced affinity of MtRecA for ATP. The ligand bound structures reveal subtle variations in nucleotide conformations among different nucleotides that serve in maintaining the network of interactions crucial for nucleotide binding. The nucleotide binding site itself, however, remains relatively unchanged. The analysis also reveals that ATPgammaS rather than ADP-AlF4 is structurally a better mimic of ATP. From among the complexed structures, a definition for the two DNA-binding loops L1 and L2 has clearly emerged for the first time and provides a basis to understand DNA binding by RecA. The structural information obtained from these complexes correlates well with the extensive biochemical data on mutants available in the literature, contributing to an understanding of the role of individual residues in the nucleotide binding pocket, at the molecular level. Modeling studies on the mutants again point to the relative rigidity of the nucleotide binding site. Comparison with other NTP binding proteins reveals many commonalties in modes of binding by diverse members in the structural family, contributing to our understanding of the structural signature of NTP recognition.     

The recA gene from the thermophile Thermus aquaticus YT-1: cloning, expression, and characterization.

We have cloned, expressed, and purified the RecA analog from the thermophilic eubacterium Thermus aquaticus YT-1. Analysis of the deduced amino acid sequence indicates that the T. aquaticus RecA is structurally similar to the Escherichia coli RecA and suggests that RecA-like function has been conserved in thermophilic organisms. Preliminary biochemical analysis indicates that the protein has an ATP-dependent single-stranded DNA binding activity and can pair and carry out strand exchange to form a heteroduplex DNA under reaction conditions previously described for E. coli RecA, but at 55 to 65 degrees C. Further characterization of a thermophilically derived RecA protein should yield important information concerning DNA-protein interactions at high temperatures. In addition, a thermostable RecA protein may have some general applicability in stabilizing DNA-protein interactions in reactions which occur at high temperatures by increasing the specificity (stringency) of annealing reactions.     

Purification and characterization of the human Rad51 protein, an analogue of E. coli RecA.

In bacteria, genetic recombination is catalysed by RecA protein, the product of the recA gene. A human gene that shares homology with Escherichia coli recA (and its yeast homologue RAD51) has been cloned from a testis cDNA library, and its 37 kDa product (hRad51) purified to homogeneity. The human Rad51 protein binds to single- and double-stranded DNA and exhibits DNA-dependent ATPase activity. Using a topological assay, we demonstrate that hRad51 underwinds duplex DNA, in a reaction dependent upon the presence of ATP or its non-hydrolysable analogue ATP gamma S. Complexes formed with single- and double-stranded DNA have been observed by electron microscopy following negative staining. With nicked duplex DNA, hRad51 forms helical nucleoprotein filaments which exhibit the striated appearance characteristic of RecA or yeast Rad51 filaments. Contour length measurements indicate that the DNA is underwound and extended within the nucleoprotein complex. In contrast to yeast Rad51 protein, human Rad51 forms filaments with single-stranded DNA in the presence of ATP/ATP gamma S. These resemble the inactive form of the RecA filament which is observed in the absence of a nucleotide cofactor.     

Crystal structure of RecA from Deinococcus radiodurans: insights into the structural basis of extreme radioresistance

The resistance of Deinococcus radiodurans (Dr) to extreme doses of ionizing radiation depends on its highly efficient capacity to repair dsDNA breaks. Dr RecA, the key protein in the repair of dsDNA breaks by homologous recombination, promotes DNA strand-exchange by an unprecedented inverse pathway, in which the presynaptic filament is formed on dsDNA instead of ssDNA. In order to gain insight into the remarkable repair capacity of Dr and the novel mechanistic features of its RecA protein, we have determined its X-ray crystal structure in complex with ATPgammaS at 2.5A resolution. Like RecA from Escherichia coli, Dr RecA crystallizes as a helical filament that is closely related to its biologically relevant form, but with a more compressed pitch of 67 A. Although the overall fold of Dr RecA is similar to E.coli RecA, there is a large reorientation of the C-terminal domain, which in E.coli RecA has a site for binding dsDNA. Compared to E.coli RecA, the inner surface along the central axis of the Dr RecA filament has an increased positive electrostatic potential. Unique amino acid residues in Dr RecA cluster around a flexible beta-hairpin that has also been implicated in DNA binding.     

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

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

Complexes of RecA with LexA and RecX differentiate between active and inactive RecA nucleoprotein filaments

The bacterial RecA protein has been the dominant model system for understanding homologous genetic recombination. Although a crystal structure of RecA was solved ten years ago, we still do not have a detailed understanding of how the helical filament formed by RecA on DNA catalyzes the recognition of homology and the exchange of strands between two DNA molecules. Recent structural and spectroscopic studies have suggested that subunits in the helical filament formed in the RecA crystal are rotated when compared to the active RecA-ATP-DNA filament. We examine RecA-DNA-ATP filaments complexed with LexA and RecX to shed more light on the active RecA filament. The LexA repressor and RecX, an inhibitor of RecA, both bind within the deep helical groove of the RecA filament. Residues on RecA that interact with LexA cannot be explained by the crystal filament, but can be properly positioned in an existing model for the active filament. We show that the strand exchange activity of RecA, which can be inhibited when RecX is present at very low stoichiometry, is due to RecX forming a block across the deep helical groove of the RecA filament, where strand exchange occurs. It has previously been shown that changes in the nucleotide bound to RecA are associated with large motions of RecA's C-terminal domain. Since RecX binds from the C-terminal domain of one subunit to the nucleotide-binding core of another subunit, a stabilization of RecA's C-terminal domain by RecX can likely explain the inhibition of RecA's ATPase activity by RecX.     

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

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

Head to head dimer model; an alternative model for the strand exchange reaction by RecA protein of Escherichia coli

The RecA protein of E coli promotes a strand exchange reaction in vitro which appears to be similar to homologous genetic recombination in vivo. A model for the mechanism of strand transfer reaction by RecA protein has been proposed by Howard-Flanders et al based on the assumption that the RecA monomer has two distinctive DNA binding sites both of which can bind to ssDNA as well as dsDNA. Here, I propose an alternative model based on the assumption that RecA monomer has a single domain for binding to a polynucleotide chain with a unique polarity. In addition, the model is based on a few mechanical assumptions that, in the presence of ATP, two RecA molecules form a head to head dimer as the basic binding unit to DNA, and that the binding of RecA protein to a polynucleotide chain induces a structural change of RecA protein that causes a higher state of affinity for another RecA molecule that is expressed as cooperativy. The model explains many of the biochemical capabilities of RecA protein including the polar polymerization of RecA protein on single stranded DNA and polar strand transfer of DNA by the protein as well as the formation of a joint DNA molecule in a paranemic configuration. The model also presents the energetics in the strand transfer reaction.     

RecA-mediated SOS induction requires an extended filament conformation but no ATP hydrolysis

The Escherichia coli SOS response to DNA damage is modulated by the RecA protein, a recombinase that forms an extended filament on single-stranded DNA and hydrolyzes ATP. The RecA K72R ( recA2201 ) mutation eliminates the ATPase activity of RecA protein. The mutation also limits the capacity of RecA to form long filaments in the presence of ATP. Strains with this mutation do not undergo SOS induction in vivo . We have combined the K72R variant of RecA with another mutation, RecA E38K ( recA730 ). In vitro , the double mutant RecA E38K/K72R ( recA730,2201 ) mimics the K72R mutant protein in that it has no ATPase activity. The double mutant protein will form long extended filaments on ssDNA and facilitate LexA cleavage almost as well as wild-type, and do so in the presence of ATP. Unlike recA K72R, the recA E38K/K72R double mutant promotes SOS induction in vivo after UV treatment. Thus, SOS induction does not require ATP hydrolysis by the RecA protein, but does require formation of extended RecA filaments. The RecA E38K/K72R protein represents an improved reagent for studies of the function of ATP hydrolysis by RecA in vivo and in vitro .     

Three-strand exchange by the Escherichia coli RecA protein using ITP as a nucleotide cofactor: mechanistic parallels with the ATP-dependent reaction of the RecA protein from Streptococcus pneumoniae

The RecA protein from Escherichia coli promotes an ATP-dependent three-strand exchange reaction between a circular single-stranded DNA (ssDNA) and a homologous linear double-stranded (dsDNA). We have now found that under certain conditions, the RecA protein is also able to promote the three-strand exchange reaction using the structurally related nucleoside triphosphate, ITP, as the nucleotide cofactor. However, although both reactions are stimulated by single-stranded DNA-binding (SSB) protein, the ITP-dependent reaction differs from the ATP-dependent reaction in that it is observed only at low SSB protein concentrations, whereas the ATP-dependent reaction proceeds efficiently even at high SSB protein concentrations. Moreover, the circular ssDNA-dependent ITP hydrolysis activity of the RecA protein is strongly inhibited by SSB protein (suggesting that SSB protein displaces RecA protein from ssDNA when ITP is present), whereas the ATP hydrolysis activity is uninhibited even at high SSB protein concentrations (because RecA protein is resistant to displacement by SSB protein when ATP is present). These results suggest that SSB protein does not stimulate the ITP-dependent strand exchange reaction presynaptically (by facilitating the binding of RecA protein to the circular ssDNA substrate) but may act postsynaptically (by binding to the displaced strand that is generated when the circular ssDNA invades the linear dsDNA substrate). Interestingly, the mechanistic characteristics of the ITP-dependent strand exchange reaction of the E. coli RecA protein are similar to those of the ATP-dependent strand exchange reaction of the RecA protein from Streptococcus pneumoniae. These findings are discussed in terms of the relationship between the dynamic state of the RecA-ssDNA filament and the mechanism of the SSB protein-stimulated three-strand exchange reaction.     

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

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

Simple and efficient purification of Escherichia coli DNA polymerase V: cofactor requirements for optimal activity and processivity in vitro

Most damage induced mutagenesis in Escherichia coli is dependent upon the UmuD'(2)C protein complex, which comprises DNA polymerase V (pol V). Biochemical characterization of pol V has been hindered by the fact that the enzyme is notoriously difficult to purify, largely because overproduced UmuC is insoluble. Here, we report a simple and efficient protocol for the rapid purification of milligram quantities of pol V from just 4 L of bacterial culture. Rather than over producing the UmuC protein, it was expressed at low basal levels, while UmuD'(2)C was expressed in trans from a high copy-number plasmid with an inducible promoter. We have also developed strategies to purify the β-clamp and γ-clamp loader free from contaminating polymerases. Using these highly purified proteins, we determined the cofactor requirements for optimal activity of pol V in vitro and found that pol V shows robust activity on an SSB-coated circular DNA template in the presence of the β/γ-complex and a RecA nucleoprotein filament (RecA*) formed in trans. This strong activity was attributed to the unexpectedly high processivity of pol V Mut (UmuD'(2)C · RecA · ATP), which was efficiently recruited to a primer terminus by SSB.     

Interaction of RecA protein with acidic phospholipids inhibits DNA-binding activity of RecA.

The RecA protein of Escherichia coli binds specifically to acidic phospholipids such as cardiolipin and phosphatidylglycerol. This binding appears to be affected by the presence of divalent cations such as Ca2+ and Mg2+. The interaction leads to the inhibition of RecA binding to at least two different conformations of DNA, single-stranded DNA and left-handed Z-DNA, thus suggesting that the phospholipids interact at the DNA-binding site of the RecA protein. Inclusion of a nucleotide cofactor [adenosine 5'-O-(gamma-thiotriphosphate)] in the reactions did not prevent the inhibition of DNA-binding activities of RecA protein by the phospholipids. The interaction of RecA protein with cardiolipin and phosphatidylglycerol, which represent two of the three major phospholipids of the E. coli membrane, may be physiologically important, as it provides a possible mechanism for the RecA-membrane association during the SOS response. These observations raise the possibility that the Z-DNA-binding activity of RecA protein is merely a manifestation of its phospholipid-binding property.     

The RecA protein as a recombinational repair system

The Escherichia coli RecA protein plays a central role in homologous genetic recombination, recombinational repair, and several other processes in bacteria. In vitro, an extended filament involving thousands of RecA monomers promotes a reaction in which individual DNA strands switch pairing partners (DNA strand exchange). This reaction has been extensively studied as a paradigm for the central steps in recombination. Because the strand-exchange reaction is relatively simple and isoenergetic, the complexity of the RecA system that carries it out has led to controversy about the functional significance of many fundamental properties of RecA. Filamentous protein structures involving thousands of RecA monomers, which hydrolyse 100 ATPs per base pair of heteroduplex DNA formed, are hard to rationalize in the context of recombination between two homologous DNAs. The thermodynamic barriers to strand exchange are much too small. These molecular features of the system can be easily rationalized, however, by shifting the focus to DNA repair.     

Kinetic mechanism for the formation of the presynaptic complex of the bacterial recombinase RecA

RecA protein from Escherichia coli catalyzes DNA strand exchange during homologous recombination in a reaction that requires nucleoside triphosphate cofactor. In the first step of this reaction RecA protein polymerizes on single-stranded DNA to form a filament with a stoichiometry of three nucleotides/RecA monomer called the presynaptic complex. We have used fluorescence anisotropy of a fluorescein-labeled oligonucleotide to investigate presynaptic complex formation. RecA-ATPgammaS bound to oligonucleotide by a two-step process. Kinetic studies revealed an intermediate in the polymerization reaction that had greater mobility than the final product filament. The intermediate was transformed into the final product by a process that was independent of filament concentration and temperature, k = 0.3 +/- 0.1 min(-1). This process had the same rate as that reported for a step in the isomerization of presynaptic complex by ATPgammaS (Paulus, B. F., and Bryant, F. R. (1997) Biochemistry 36, 7832-7838). Judging from anisotropy measurements, the intermediate had hydrodynamic properties similar to a mixed filament containing RecA monomers with and without ATPgammaS. These results show that the presynaptic complex can assume conformations with different segmental mobilities that could play a role in homologous recombination.     

Equilibrium binding of single-stranded DNA to the secondary DNA binding site of the bacterial recombinase RecA

The bacterial recombinase RecA forms a nucleoprotein filament in vitro with single-stranded DNA (ssDNA) at its primary DNA binding site, site I. This filament has a second site, site II, which binds ssDNA and double-stranded DNA. We have investigated the binding of ssDNA to the RecA protein in the presence of adenosine 5'-O-(thiotriphosphate) cofactor using fluorescence anisotropy. The RecA protein carried out DNA strand exchange with a 5'-fluorescein-labeled 32-mer oligonucleotide. The anisotropy signal was shown to measure oligonucleotide binding to RecA, and the relationship between signal and binding density was determined. Binding of ssDNA to site I of RecA was stable at high NaCl concentrations. Binding to site II could be described by a simple two-state equilibrium, K = 4.5 +/- 1.5 x 10(5) m(-1) (37 degrees C, 150 mm NaCl, pH 7.4). The reaction was enthalpy-driven and entropy-opposed. It depended on salt concentration and was sensitive to the type of monovalent anion, suggesting that anion-dependent protein conformations contribute to ssDNA binding at site II.     

RNA-DNA hybridization promoted by E. coli RecA protein.

RecA protein of E. coli plays a central regulatory role that is induced by damage to DNA and results in the inactivation of LexA repressor. In vitro, RecA protein binds preferentially to single-stranded DNA to form a nucleoprotein filament that can recognize homology in naked duplex DNA and promote extensive strand exchange. Although RecA protein shows little tendency at neutral pH to bind to RNA, we found that it nonetheless catalyzed at 37 degrees C the hybridization of complementary RNA and single-stranded DNA sequences. Hybrids made by RecA protein at 37 degrees C appeared indistinguishable from ones prepared by thermal annealing. RNA-DNA hybridization by RecA protein at neutral pH required, as does RecA-promoted homologous pairing, optimal conditions for the formation of RecA nucleoprotein filaments. The cosedimentation of RNA with those filaments further paralleled observations made on the formation of networks of nucleoprotein filaments with double-stranded DNA, an instrumental intermediate in homologous pairing in vitro. These similarities with the pairing reaction support the view that RecA protein acts specifically in the hybridization reaction.     

Structure of helical RecA-DNA complexes. III. The structural polarity of RecA filaments and functional polarity in the RecA-mediated strand exchange reaction

The RecA protein of Escherichia coli has been used in vitro to mediate a strand-exchange reaction between homologous DNA molecules. A three-dimensional reconstruction of a RecA filament on double-stranded DNA has been previously determined from electron micrographs, and the reconstruction displays a clear axial polarity. The RecA-mediated strand-exchange reaction between a double-stranded DNA and a homologous single-stranded DNA that is complexed with a RecA helical polymer proceeds with a known polarity. Using image analysis of electron micrographs, we have determined the relation between the structural polarity of RecA filaments and the 3' and 5' polarity of single-stranded DNA. Thus, the structural polarity of RecA filaments can now be related to the direction in which the RecA-mediated strand-exchange reaction advances along the complexed single-stranded DNA.