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

Single Molecule Study of the Polymerization of RecA on dsDNA: The Dynamics of Individual Domains

In the Escherichia coli, RecA plays a central role in the recombination and repair of the DNA. For homologous recombination, RecA binds to ssDNA forming a nucleoprotein filament. The RecA-ssDNA filament searches for a homologous sequence on a dsDNA and, subsequently, RecA mediates strand exchange between the ssDNA and the dsDNA. In vitro, RecA binds to both ssDNA and dsDNA. Despite a wide range of studies of the polymerization of RecA on dsDNA, both at the single molecule level and by means of biochemical methods, important aspects of this process are still awaiting a better understanding. Specifically, a detailed, quantitative description of the nucleation and growth dynamics of the RecA-dsDNA filaments is still lacking. Here, we use Optical Tweezers together with a single molecule analysis approach to measure the dynamics of the individual RecA domains on dsDNA and the corresponding growth rates for each of their fronts. We focus on the regime where the nucleation and growth rate constants, k_n and k_g, are comparable, leading to a coverage of the dsDNA molecule that consists of a small number of RecA domains. For the case of essentially irreversible binding (using ATPγS instead of ATP), we find that domain growth is highly asymmetric with a ratio of about 10:1 between the fast and slow fronts growth rates.

Direct visualization of the formation of RecA/dsDNA complexes at the single-molecule level

The assembly of RecA on linear dsDNA with ATPγS in the reaction was elucidated using atomic force microscopy (AFM) on a single-molecule level. It was found that assembly generally (∼95%) proceeded from a single nucleation site that started from one end of the DNA strand. About 5% of the complexes were formed starting either from both ends or from the middle of dsDNA strand. In all these cases, the RecA coating was contiguous for each region suggesting the binding of RecA to DNA is cooperative. The AFM observation provides direct experimental evidence to show how RecA binds to linear dsDNA in the presence of ATPγS.

Presynaptic filament dynamics in homologous recombination and DNA repair

Homologous recombination (HR) is an essential genome stability mechanism used for high-fidelity repair of DNA double-strand breaks and for the recovery of stalled or collapsed DNA replication forks. The crucial homology search and DNA strand exchange steps of HR are catalyzed by presynaptic filaments-helical filaments of a recombinase enzyme bound to single-stranded DNA (ssDNA). Presynaptic filaments are fundamentally dynamic structures, the assembly, catalytic turnover, and disassembly of which must be closely coordinated with other elements of the DNA recombination, repair, and replication machinery in order for genome maintenance functions to be effective. Here, we reviewed the major dynamic elements controlling the assembly, activity, and disassembly of presynaptic filaments; some intrinsic such as recombinase ATP-binding and hydrolytic activities, others extrinsic such as ssDNA-binding proteins, mediator proteins, and DNA motor proteins. We examined dynamic behavior on multiple levels, including atomic- and filament-level structural changes associated with ATP binding and hydrolysis as evidenced in crystal structures, as well as subunit binding and dissociation events driven by intrinsic and extrinsic factors. We examined the biochemical properties of recombination proteins from four model systems (T4 phage, Escherichia coli, Saccharomyces cerevisiae, and Homo sapiens), demonstrating how their properties are tailored for the context-specific requirements in these diverse species. We proposed that the presynaptic filament has evolved to rely on multiple external factors for increased multilevel regulation of HR processes in genomes with greater structural and sequence complexity.

Site-specific dynamics of strands in ss- and dsDNA as revealed by time-domain fluorescence of 2-aminopurine

It is well recognized that structure and dynamics of DNA strands guide proteins toward their cognate sites in DNA. While the dynamics is controlled primarily by the nucleotide sequence, the context of a particular sequence in relation to an open end could also play a significant role. In this work we have used the fluorescent analogue of adenine, 2-aminopurine (2-AP), to extract information on site-specific dynamics of DNA strands associated with 30-70 nucleotides length. Measurement of fluorescence lifetime and anisotropy decay kinetics in various types of DNA strands in which 2-AP was located in specific positions revealed novel insights into the dynamics of strands. We find that in single-stranded (ss) DNA, the extent of motional dynamics of the bases falls off sharply from the very end toward the middle of the strand. In contrast, the flexibility of the backbone decreases more gradually in the same direction. In double-stranded (ds) DNA, the level of base-pair fraying increases toward the ends in a graded manner. Surprisingly, the same is countered by the presence of ss-overhangs emanating from dsDNA ends. Moreover, the extent of concerted motion of bases in duplex DNA increased from the end to the middle of the duplex, a result which is both striking and counterintuitive. Most surprisingly, the two complementary strands of a duplex that were unequal in length exhibited differential dynamics: the longer one with overhangs showed a distinctly higher level of flexibility than the recessed shorter strand in the same duplex. All these results, taken together, provoke newer insights in our understanding of how different bases in DNA strands are endowed with specific dynamic properties as a function of their positions. These properties are likely to be used in facilitating specific recognitions of DNA bases by proteins during various DNA-protein interaction systems.

Visualization of RecA filaments and DNA by fluorescence microscopy

We have developed two experimental methods for observing Escherichia coli RecA-DNA filament under a fluorescence microscope. First, RecA-DNA filaments were visualized by immunofluorescence staining with anti-RecA monoclonal antibody. Although the detailed filament structures below submicron scale were unable to be measured accurately due to optical resolution limit, this method has an advantage to analyse a large number of RecA-DNA filaments in a single experiment. Thus, it provides a reliable statistical distribution of the filament morphology. Moreover, not only RecA filament, but also naked DNA region was visualized separately in combination with immunofluorescence staining using anti-DNA monoclonal antibody. Second, by using cysteine derivative RecA protein, RecA-DNA filament was directly labelled by fluorescent reagent, and was able to observe directly under a fluorescence microscope with its enzymatic activity maintained. We showed that the RecA-DNA filament disassembled in the direction from 5' to 3' of ssDNA as dATP hydrolysis proceeded.

Direct observation of individual RecA filaments assembling on single DNA molecules

Escherichia coli RecA is essential for the repair of DNA double-strand breaks by homologous recombination. Repair requires the formation of a RecA nucleoprotein filament. Previous studies have indicated a mechanism of filament assembly whereby slow nucleation of RecA protein on DNA is followed by rapid growth. However, many aspects of this process remain unclear, including the rates of nucleation and growth and the involvement of ATP hydrolysis, largely because visualization at the single-filament level is lacking. Here we report the direct observation of filament assembly on individual double-stranded DNA molecules using fluorescently modified RecA. The nucleoprotein filaments saturate the DNA and extend it approximately 1.6-fold. At early time points, discrete RecA clusters are seen, permitting analysis of single-filament growth from individual nuclei. Formation of nascent RecA filaments is independent of ATP hydrolysis but is dependent on the type of nucleotide cofactor and the RecA concentration, suggesting that nucleation involves binding of approximately 4-5 ATP-RecA monomers to DNA. Individual RecA filaments grow at rates of 3-10 nm s(-1). Growth is bidirectional and, in contrast to nucleation, independent of nucleotide cofactor, suggesting addition of approximately 2-7 monomers s(-1). These results are in accord with extensive genetic and biochemical studies, and indicate that assembly in vivo is controlled at the nucleation step. We anticipate that our approach and conclusions can be extended to the related eukaryotic counterpart, Rad51 (see ref.), and to regulation by assembly mediators.

Real-time observation of RecA filament dynamics with single monomer resolution

RecA and its homologs help maintain genomic integrity through recombination. Using single-molecule fluorescence assays and hidden Markov modeling, we show the most direct evidence that a RecA filament grows and shrinks primarily one monomer at a time and only at the extremities. Both ends grow and shrink, contrary to expectation, but a higher binding rate at one end is responsible for directional filament growth. Quantitative rate determination also provides insights into how RecA might control DNA accessibility in vivo. We find that about five monomers are sufficient for filament nucleation. Although ordinarily single-stranded DNA binding protein (SSB) prevents filament nucleation, single RecA monomers can easily be added to an existing filament and displace SSB from DNA at the rate of filament extension. This supports the proposal for a passive role of RecA-loading machineries in SSB removal.

Twisting and untwisting a single DNA molecule covered by RecA protein

We study dsDNA-RecA interactions by exerting forces in the pN range on single DNA molecules while the interstrand topological state is controlled owing to a magnetic tweezers setup. We show that unwinding a duplex DNA molecule induces RecA polymerization even at moderate force. Once initial polymerization has nucleated, the extent of RecA coverage still depends on the degree of supercoiling: exerting a positive or negative torsional constraint on the fiber forces partial depolymerization, with a strikingly greater stability when ATPgammaS is used as a cofactor instead of ATP. This nucleofilament's sensitivity to topology might be a way for the bacterial cell to limit consumption of precious RecA monomers when DNA damage is addressed through homologous recombination repair.

RecA protein filaments disassemble in the 5' to 3' direction on single-stranded DNA

RecA protein forms filaments on both single- and double-stranded DNA. Several studies confirm that filament extension occurs in the 5' to 3' direction on single-stranded DNA. These filaments also disassemble in an end-dependent fashion, and several indirect observations suggest that the disassembly occurs on the end opposite to that at which assembly occurs. By labeling the 5' end of single-stranded DNA with a segment of duplex DNA, we demonstrate unambiguously that RecA filaments disassemble uniquely in the 5' to 3' direction.

Lesion bypass by the Escherichia coli DNA polymerase V requires assembly of a RecA nucleoprotein filament

Translesion replication is carried out in Escherichia coli by the SOS-inducible DNA polymerase V (UmuC), an error-prone polymerase, which is specialized for replicating through lesions in DNA, leading to the formation of mutations. Lesion bypass by pol V requires the SOS-regulated proteins UmuD' and RecA and the single-strand DNA-binding protein (SSB). Using an in vitro assay system for translesion replication based on a gapped plasmid carrying a site-specific synthetic abasic site, we show that the assembly of a RecA nucleoprotein filament is required for lesion bypass by pol V. This is based on the reaction requirements for stoichiometric amounts of RecA and for single-stranded gaps longer than 100 nucleotides and on direct visualization of RecA-DNA filaments by electron microscopy. SSB is likely to facilitate the assembly of the RecA nucleoprotein filament; however, it has at least one additional role in lesion bypass. ATPgammaS, which is known to strongly increase binding of RecA to DNA, caused a drastic inhibition of pol V activity. Lesion bypass does not require stoichiometric binding of UmuD' along RecA filaments. In summary, the RecA nucleoprotein filament, previously known to be required for SOS induction and homologous recombination, is also a critical intermediate in translesion replication.

The efficiency of strand invasion by Escherichia coli RecA is dependent upon the length and polarity of ssDNA tails

RecA protein is essential for homologous recombination and the repair of DNA double-strand breaks in Escherichia coli. The protein binds DNA to form nucleoprotein filaments that promote joint molecule formation and strand exchange in vitro. RecA polymerises on ssDNA in the 5'-3' direction and catalyses strand exchange and branch migration with a 5'-3' polarity. It has been reported previously, using D-loop assays, in which ssDNA (containing a heterologous block at one end) invades supercoiled duplex DNA that 3'-homologous ends are reactive, whereas 5'-ends are inactive. This polarity bias was thought to be due to the polarity of RecA filament formation, which results in the 3'-ends being coated in RecA, whereas 5'-ends remain naked. Using a range of duplex substrates containing ssDNA tails of various lengths and polarities, we now demonstrate that when no heterologous block is imposed, 5'-ends are just as reactive as 3'-ends. Moreover, using short-tailed substrates, we find that 5'-ends form more stable D-loops than 3'-ends. This bias may be a consequence of the instability of short 3'-joints. With more physiological substrates containing long ssDNA tails, we find that RecA shows no intrinsic preference for 5' or 3'-ends and that both form D-loop complexes with high efficiency.

RecA protein-dependent R-loop formation in vitro

The RecA protein of Escherichia coli, which has crucial roles in homologous recombination, DNA damage repair, induction of the SOS response, and SOS mutagenesis, was found to catalyze assimilation of complementary RNA into a homologous region of a DNA duplex (R-loop). The reaction strictly requires a region of mismatch in the duplex, which may serve as a nucleation site for RecA protein polymerization. The optimum conditions for the assimilation reaction resemble those for the previously studied RecA protein-catalyzed homologous pairing and strand exchange reaction between two DNA molecules. Our finding lends strong support to the proposal that RecA protein-catalyzed assimilation of a transcript into duplex DNA results in formation of an R-loop at certain regions of the chromosome and that, when stabilized, the R-loop can serve as an origin of chromosome replication.

Recombinational repair of DNA damage in Escherichia coli and bacteriophage lambda

Although homologous recombination and DNA repair phenomena in bacteria were initially extensively studied without regard to any relationship between the two, it is now appreciated that DNA repair and homologous recombination are related through DNA replication. In Escherichia coli, two-strand DNA damage, generated mostly during replication on a template DNA containing one-strand damage, is repaired by recombination with a homologous intact duplex, usually the sister chromosome. The two major types of two-strand DNA lesions are channeled into two distinct pathways of recombinational repair: daughter-strand gaps are closed by the RecF pathway, while disintegrated replication forks are reestablished by the RecBCD pathway. The phage lambda recombination system is simpler in that its major reaction is to link two double-stranded DNA ends by using overlapping homologous sequences. The remarkable progress in understanding the mechanisms of recombinational repair in E. coli over the last decade is due to the in vitro characterization of the activities of individual recombination proteins. Putting our knowledge about recombinational repair in the broader context of DNA replication will guide future experimentation.

RecA protein filaments: end-dependent dissociation from ssDNA and stabilization by RecO and RecR proteins

RecA protein filaments formed on circular (ssDNA) in the presence of ssDNA binding protein (SSB) are generally stable as long as ATP is regenerated. On linear ssDNA, stable RecA filaments are believed to be formed by nucleation at random sites on the DNA followed by filament extension in the 5' to 3' direction. This view must now be enlarged as we demonstrate that RecA filaments formed on linear ssDNA are subject to a previously undetected end-dependent disassembly process. RecA protein slowly dissociates from one filament end and is replaced by SSB. The results are most consistent with disassembly from the filament end nearest the 5' end of the DNA. The bound SSB prevents re-formation of the RecA filaments, rendering the dissociation largely irreversible. The dissociation requires ATP hydrolysis. Disassembly is not observed when the pH is lowered to 6.3 or when dATP replaces ATP. Disassembly is not observed even with ATP when both the RecO and RecR proteins are present in the initial reaction mixture. When the RecO and RecR proteins are added after most of the RecA protein has already dissociated, RecA protein filaments re-form after a short lag. The newly formed filaments contain an amount of RecA protein and exhibit an ATP hydrolysis rate comparable to that observed when the RecO and RecR proteins are included in the initial reaction mixture. The RecO and RecR proteins thereby stabilize RecA filaments even at the 5' ends of ssDNA, a fact which should affect the recombination potential of 5' ends relative to 3' ends. The location and length of RecA filaments involved in recombinational DNA repair is dictated by both the assembly and disassembly processes, as well as by the presence or absence of a variety of other proteins that can modulate either process.

RuvA, RuvB and RuvC proteins: cleaning-up after recombinational repairs in E. coli

After the completion of RecA protein-mediated recombinational repair of daughter-strand gaps in E. coli, participating chromosomes are held together by Holliday junctions. Until recently, it was not known how the cell disengages the connected chromosomes. Accumulating genetic data suggested that the product of the ruv locus participates in recombinational repair and acts after the formation of Holliday junctions. Molecular characterization of the locus revealed that there are three genes--ruvA, ruvB and ruvC; mutations in any one of the genes confer the same phenotype. Recently, the RuvC protein was found to be a Holliday junction resolvase. At first glance, the resolving activity of RuvC alone would appear to be sufficient for the separation of recombining chromosomes. However, in vitro studies show that the filament of RecA protein is unable to dissociate from the products of the recombination reaction. Thus, in vivo, even if the Holliday junctions are resolved by RuvC, RecA filament must be holding two DNA duplexes together. New findings about enzymatic activities of RuvA and RuvB proteins foster the hope that the machinery for removing the RecA filament from DNA has been found.

Stable synapsis of homologous DNA molecules mediated by the Escherichia coli RecA protein involves local exchange of DNA strands

Escherichia coli RecA protein promotes stable synapsis between a single-stranded DNA and a homologous duplex DNA, resulting in the formation of a complex of RecA with three DNA strands. To gain insight into the molecular interactions responsible for DNA synapsis, the base-pairing status within the synaptic complex was analyzed by using dimethylsulfate and potassium permanganate as probes. The results indicate that the original base pairs in the parental duplex are disrupted; one strand is displaced and the other strand appears to be involved in Watson-Crick base-pairing with the incoming single-stranded DNA. The state of base-pairing thus resembles that of the end products of strand exchange and not a canonical DNA triple helix involving non-Watson-Crick base-pairing. The results also indicate that this local strand exchange can occur without homology at the ends of the DNA substrates (i.e., when axial rotation of the product heteroduplex with respect to the axis of the parental duplex is obstructed). Taken together, these results suggest that exchange of DNA strands mediated by RecA occur at or before the stage of stable DNA synapsis by a process that does not require DNA rotation.

RecA protein-promoted homologous pairing and strand exchange between intact and partially single-stranded duplex DNA

In the pairing reaction between circular gapped and fully duplex DNA, RecA protein first polymerizes on the gapped DNA to form a nucleoprotein filament. Conditions that removed the formation of secondary structure in the gapped DNA, such as addition of Escherichia coli single-stranded DNA binding protein or preincubation in 1 mM-MgCl2, optimized the binding of RecA protein and increased the formation of joint molecules. The gapped duplex formed stable joints with fully duplex DNA that had a 5' or 3' terminus complementary to the single-stranded region of the gapped molecule. However, the joints formed had distinct properties and structures depending on whether the complementary terminus was at the 5' or 3' end. Pairing between gapped DNA and fully duplex linear DNA with a 3' complementary terminus resulted in strand displacement, symmetric strand exchange and formation of complete strand exchange products. By contrast, pairing between gapped and fully duplex DNA with a 5' complementary terminus produced a joint that was restricted to the gapped region; there was no strand displacement or symmetric strand exchange. The joint formed in the latter reaction was likely a three-stranded intermediate rather than a heteroduplex with the classical Watson-Crick structure. We conclude that, as in the three-strand reaction, the process of strand exchange in the four-strand reaction is polar and progresses in a 5' to 3' direction with respect to the initiating strand. The present study provides further evidence that in both three-strand and four-strand systems the pairing and strand exchange reactions share a common mechanism.

RecA protein-promoted homologous pairing between duplex molecules: functional role of duplex regions of gapped duplex DNA

RecA protein promotes homologous pairing and symmetrical strand exchange between partially single-stranded duplex DNA and fully duplex molecules. We constructed circular gapped DNA with a defined gap length and studied the pairing reaction between the gapped substrate and fully duplex DNA. RecA protein polymerizes onto the single-stranded and duplex regions of the gapped DNA to form a nucleoprotein filament. The formation of such filaments requires a stoichiometric amount of RecA protein. Both the rate and yield of joint molecule formation were reduced when the pairing reaction was carried out in the presence of a sub-saturating amount of RecA protein. The amount of RecA protein required for optimal pairing corresponds to the binding site size of RecA protein at saturation on duplex DNA. The result suggests that in the 4-stranded system the single-stranded as well as the duplex regions are involved in pairing. By using fully duplex DNA that shares different lengths and regions of homology with the gapped molecule, we directly showed that the duplex region of the gapped DNA increased both the rate and yield of joint molecule formation. The present study indicates that even though strand exchange in the 4-stranded system must require the presence of a single-stranded region, the pairing that occurs in duplex regions between DNA molecules is functionally significant and contributes to the overall activity of the gapped DNA.

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.

Three-stranded paranemic joints: architecture, topological constraints and movement

The RecA and SSB proteins will catalyze the joining of two DNA molecules containing homologous sequences but lacking homologous ends in a reaction termed paranemic joining. The absence of homologous ends can be achieved by (1) pairing two circular DNAs or (2) using linear DNA(s) with ends lacking homology to the pairing partner. Here we have used electron microscopy (EM) to examine such pairings. Circular M13 single-stranded (ss) DNA enveloped by RecA protein into a presynaptic filament was paired with linear M13mp7 double-stranded (ds) DNA containing non-M13 sequences at its ends. Joint complexes were frequently seen in which the dsDNA was joined with the presynaptic filament over several kilobase (10(3) bases) lengths of the dsDNA. In this region, the presynaptic filament appeared disorganized as contrasted to the customary helical structure of the filament containing only a single strand of DNA. The same ultrastructure, but with greater detail, was observed when the samples were prepared for EM without fixation using a new method of fast-freezing and freeze-drying. EM immunogold staining demonstrated the presence of SSB protein in the disorganized region containing all three strands, but not in the regular helically arranged region. Psoralen photo-crosslinking of the DNA in the joint complexes revealed that the three DNA strands were in close proximity only over a single short (200 to 300 base-pairs) region. The joining of nicked circular M13 dsDNA and presynaptic filaments containing circular M13 ssDNA resulted in the intertwining of the dsDNA about the circular presynaptic filament. The joints produced in this case were short, as was the single region of psoralen photo-crosslinking of the three DNA strands. A model of how these long three-stranded joints form is presented involving the movement of a short "true" paranemic joint along the presynaptic filament.

Inhibition of recA protein promoted ATP hydrolysis. 1. ATP gamma S and ADP are antagonistic inhibitors

ADP and adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S) inhibit recA protein promoted ATP hydrolysis by fundamentally different mechanisms. In both cases, at least two modes of inhibition are observed. For ADP, the first mode is competitive inhibition. The second mode is manifested by dissociation of recA protein from DNA. These are readily distinguished in a comparison of ATP hydrolyses that are activated by (a) DNA and (b) high (approximately 2 M) salt concentrations. Competitive inhibition with a significant degree of cooperativity is observed under both sets of conditions, although the DNA-dependent activity is more sensitive to ADP than the high-salt reaction. The reaction in the presence of poly(deoxythymidylic acid) or duplex DNA ceases when about 60% of the available ATP is hydrolyzed, reflecting an ADP-mediated dissociation of recA protein from the DNA that is governed by the ADP/ATP ratio. In contrast, ATP hydrolysis proceeds nearly to completion at high salt concentrations. At high concentrations of ATP and ATP gamma S, ATP gamma S also acts as a competitive inhibitor. At low concentrations of ATP gamma S and ATP, however, ATP gamma S activates ATP hydrolysis. These patterns are observed for recA-mediated ATP hydrolysis with either high salt concentrations or a poly(deoxythymidylic acid) [poly(dT)] cofactor, although the activation is observed at much lower ATP and ATP gamma S concentrations when poly(dT) is used. ATP gamma S can also relieve the inhibitory effect of ADP under some conditions. ATP gamma S and ADP are antagonistic inhibitors, reinforcing the idea that they stabilize different conformations of the protein and suggesting that these conformations are mutually exclusive. The ATP gamma S (ATP) conformation is active in ATP hydrolysis. The ADP conformation is inactive.

RecA protein reinitiates strand exchange on isolated protein-free DNA intermediates. An ADP-resistant process

Efficient homologous pairing de novo of linear duplex DNA with a circular single strand (plus strand) coated with RecA protein requires saturation and extension of the single strand by the protein. However, strand exchange, the transfer of a strand from duplex DNA to the nucleoprotein filament, which follows homologous pairing, does not require the stable binding of RecA protein to single-stranded DNA. When RecA protein was added back to isolated protein-free DNA intermediates in the presence of sufficient ADP to inhibit strongly the binding of RecA protein to single-stranded DNA, strand exchange nonetheless resumed at the original rate and went to completion. Characterization of the protein-free DNA intermediate suggested that it has a special site or region to which RecA protein binds. Part of the nascent displaced plus strand of the deproteinized intermediate was unavailable as a cofactor for the ATPase activity of RecA protein, and about 30% resisted digestion by P1 endonuclease, which acts preferentially on single-stranded DNA. At the completion of strand exchange, when the distal 5' end of the linear minus strand had been fully incorporated into heteroduplex DNA, a nucleoprotein complex remained that contained all three strands of DNA from which the nascent displaced strand dissociated only over the next 50 to 60 minutes. Deproteinization of this intermediate yielded a complex that also contained three strands of DNA in which the nascent displaced strand was partially resistant to both Escherichia coli exonuclease I and P1 endonuclease. The deproteinized complex showed a broad melting transition between 37 degrees C and temperatures high enough to melt duplex DNA. These results show that strand exchange can be subdivided into two stages: (1) the exchange of base-pairs, which creates a new heteroduplex pair in place of a parental pair; and (2) strand separation, which is the physical displacement of the unpaired strand from the nucleoprotein filament. Between the creation of new heteroduplex DNA and the eventual separation of a third strand, there exists an unusual DNA intermediate that may contain three-stranded regions of natural DNA that are several thousand bases in length.

Enzymatic formation and resolution of Holliday junctions in vitro

E. coli RecA protein promotes homologous pairing and reciprocal strand exchange reactions between duplex DNA molecules in vitro. Reaction intermediates contain Holliday junctions that are driven along the DNA at a maximal rate approaching 1000 bases per minute. T4 endonuclease VII cleaves Holliday junctions in vitro, and its inclusion in RecA-mediated reactions leads to the rapid formation of heteroduplex products. Product analysis indicates patch and splice recombinant molecules similar to those expected from in vivo recombination events. The combined formation and resolution of Holliday junctions has led us to propose a model for resolution based on the structure of RecA-DNA helices. One feature of this model is that resolution, which gives rise to the two types of recombinant product, may occur without need for isomerization of the junction.

Homologous pairing and the formation of nascent synaptic intermediates between regions of duplex DNA by RecA protein

The RecA protein from E. coli gains access to duplex DNA, by nucleation from a short single-stranded gap, to form a spiral nucleoprotein filament that is capable of interaction with homologous duplex DNA. The observations described here demonstrate that any part of the nucleoprotein filament, whether it contains single- or double-stranded DNA, is capable of pairing with homologous duplex DNA. Homologous contacts between regions of duplex DNA lead to an increase in the initial rate and final extent of joint molecule formation. The experiments indicate that pairing is facilitated by the formation of nascent synaptic intermediates between duplex DNA sequences. Using chimeric form I DNA, which is incapable of forming an inter-wound or plectonemic joint with the gapped DNA due to the presence of flanking heterologous sequences, we show that these duplex-duplex pairing reactions involve extensive underwinding of the double helix.

Dissociation pathway for recA nucleoprotein filaments formed on linear duplex DNA

recA protein forms stable filaments on duplex DNA at low pH. When the pH is shifted above 6.8, recA protein remains stably bound to nicked circular DNA, but not to linear DNA. Dissociation of recA protein from linear duplex DNA proceeds to a non-zero endpoint. The kinetics and final extent of dissociation vary with several experimental parameters. The instability on linear DNA is most readily explained by a progressive unidirectional dissociation of recA protein from one end of the filament. Dissociation of recA protein from random points in the filament is eliminated as a possible mechanism by several observations: (1) the requirement for a free end; (2) the inverse and linear dependence of the rate of dissociation on DNA length (at constant DNA base-pair concentration); and (3) the kinetics of exposure of a restriction endonuclease site in the middle of the DNA. Evidence against another possible mechanism, ATP-mediated translocation of the filament along the DNA, is provided by a novel effect of the non-hydrolyzable ATP analog, ATP gamma S, which generally induces recA protein to bind any DNA tightly and completely inhibits ATP hydrolysis. We find that very low, sub-saturating levels of ATP gamma S completely stabilize the filament, while most of the ATP hydrolysis continues. If these levels of ATP gamma S are introduced after dissociation has commenced, further dissociation is blocked, but re-association does not occur. These observations are inconsistent with movement of recA protein along DNA that is tightly coupled to ATP hydrolysis. The recA nucleoprotein filament is polar and the protein binds the two strands asymmetrically, polymerizing mainly in the 5' to 3' direction on the initiating strand of a single-stranded DNA tailed duplex molecule. A model consistent with these results is presented.

Extent of duplex DNA underwinding induced by RecA protein binding in the presence of ATP

A method is described for the accurate determination of the superhelical density (omega) of highly underwound circular DNA molecules. Using this method, duplex DNA bound by RecA protein in the presence of ATP at pH 7.5 is found to be underwound by 39.6% (omega = -0.396), corresponding to a helical periodicity of 17.4 base-pairs per turn. The underwinding is increased to 41% (17.9 base-pairs per turn) in the presence of low levels of ATP gamma S, in good agreement with the 18.6 base-pairs per turn reported previously. In spite of the extensive underwinding, the distribution of DNA topoisomers produced by RecA protein binding is small. This indicates a high degree of structural uniformity among RecA-double-stranded DNA complexes in the presence of ATP.

General mechanism for RecA protein binding to duplex DNA

RecA protein binding to duplex DNA occurs by a multi-step process. The tau analysis, originally developed to examine the binding of RNA polymerase to promoter DNA, is adapted here to study two kinetically distinguishable reaction segments of RecA-double stranded (ds) DNA complex formation in greater detail. One, which is probably a rapid preequilibrium in which RecA protein binds weakly to native dsDNA, is found to have the following properties: (1) a sensitivity to pH, involving a net release of approximately one proton; (2) a sensitivity to salts; (3) little or no dependence on temperature; (4) little or no dependence on DNA length. The second reaction segment, the rate-limiting nucleation of nucleoprotein filament formation accompanied by partial DNA unwinding, is found to have the following properties: (1) a sensitivity to pH, involving a net uptake of approximately three protons; (2) a sensitivity to salts; (3) a relatively large dependence on temperature, with an Arrhenius activation energy of 39 kcal mol(-1); (4) a sensitivity to DNA topology; (5) a dependence on DNA length. These results contribute to a general mechanism for RecA protein binding to duplex DNA, which can provide a rationale for the apparent preferential binding to altered DNA structures such as pyrimidine dimers and Z-DNA.

The mechanics of winding and unwinding helices in recombination: torsional stress associated with strand transfer promoted by RecA protein

Homologous recombination usually involves the production of heteroduplex DNA, DNA containing strands contributed from two different duplexes. RecA protein of E. coli can promote the formation of heteroduplex DNA in vitro by the exchange of DNA strands between two helical structures, duplex DNA and a helical recA nucleoprotein filament containing a single strand of DNA. Complete unwinding of the parental duplex and the rewinding of one strand with a new complement requires rotation of the helical structures about one another, or about their respective longitudinal axes. The observations described here demonstrate an association of torsional stress with strand exchange, and suggest that exchange is accomplished principally by concomitant rotation of duplex DNA and the recA nucleoprotein filament, each about its longitudinal axis.