Kinetics of homologous pairing promoted by RecA protein: effects of ends and internal sites in DNA

Loop L1 governs the DNA-binding specificity and order for RecA-catalyzed reactions in homologous recombination and DNA repair

In all organisms, RecA-family recombinases catalyze homologous joint formation in homologous genetic recombination, which is essential for genome stability and diversification. In homologous joint formation, ATP-bound RecA/Rad51-recombinases first bind single-stranded DNA at its primary site and then interact with double-stranded DNA at another site. The underlying reason and the regulatory mechanism for this conserved binding order remain unknown. A comparison of the loop L1 structures in a DNA-free RecA crystal that we originally determined and in the reported DNA-bound active RecA crystals suggested that the aspartate at position 161 in loop L1 in DNA-free RecA prevented double-stranded, but not single-stranded, DNA-binding to the primary site. This was confirmed by the effects of the Ala-replacement of Asp-161 (D161A), analyzed directly by gel-mobility shift assays and indirectly by DNA-dependent ATPase activity and SOS repressor cleavage. When RecA/Rad51-recombinases interact with double-stranded DNA before single-stranded DNA, homologous joint-formation is suppressed, likely by forming a dead-end product. We found that the D161A-replacement reduced this suppression, probably by allowing double-stranded DNA to bind preferentially and reversibly to the primary site. Thus, Asp-161 in the flexible loop L1 of wild-type RecA determines the preference for single-stranded DNA-binding to the primary site and regulates the DNA-binding order in RecA-catalyzed recombinase reactions.

Structural aspects of DNA repair: the role of restricted diffusion

DNA repair and protection processes impose arduous demands upon cellular systems. The high-fidelity recombinational repair pathway entails a rapid genome-wide search for sequence homology. The efficiency of this transaction is intriguing in light of the uniquely adverse diffusion traits of the involved species. DNA protection in cells exposed to continuous stress or prolonged starvation is equally enigmatic, because the ability of such cells to deploy energy-dependent enzymatic repair processes is hampered as a result of progressive perturbation of the intracellular energy balance. DNA repair in radio-resistant bacteria, which involves accurate chromosome reconstruction from multiple fragments, is similarly associated with apparently insurmountable logistical obstacles. The studies reviewed here imply that the mechanisms deployed to overcome these intrinsic hurdles have a basic common denominator. In all these cases, condensed and ordered chromatin assemblies are formed, within which molecular diffusion is restricted and confined. Restricted diffusion thus appears as a general strategy that is exploited by nature to facilitate homologous search, to promote energy-independent DNA protection through physical DNA sequestration and attenuated accessibility to damaging agents, and to enable error-free repair of multiple double-strand DNA breaks.

Homologous genetic recombination as an intrinsic dynamic property of a DNA structure induced by RecA/Rad51-family proteins: a possible advantage of DNA over RNA as genomic material

Heteroduplex joints are general intermediates of homologous genetic recombination in DNA genomes. A heteroduplex joint is formed between a single-stranded region (or tail), derived from a cleaved parental double-stranded DNA, and homologous regions in another parental double-stranded DNA, in a reaction mediated by the RecA/Rad51-family of proteins. In this reaction, a RecA/Rad51-family protein first forms a filamentous complex with the single-stranded DNA, and then interacts with the double-stranded DNA in a search for homology. Studies of the three-dimensional structures of single-stranded DNA bound either to Escherichia coli RecA or Saccharomyces cerevisiae Rad51 have revealed a novel extended DNA structure. This structure contains a hydrophobic interaction between the 2' methylene moiety of each deoxyribose and the aromatic ring of the following base, which allows bases to rotate horizontally through the interconversion of sugar puckers. This base rotation explains the mechanism of the homology search and base-pair switch between double-stranded and single-stranded DNA during the formation of heteroduplex joints. The pivotal role of the 2' methylene-base interaction in the heteroduplex joint formation is supported by comparing the recombination of RNA genomes with that of DNA genomes. Some simple organisms with DNA genomes induce homologous recombination when they encounter conditions that are unfavorable for their survival. The extended DNA structure confers a dynamic property on the otherwise chemically and genetically stable double-stranded DNA, enabling gene segment rearrangements without disturbing the coding frame (i.e., protein-segment shuffling). These properties may give an extensive evolutionary advantage to DNA.

Ordered intracellular RecA-DNA assemblies: a potential site of in vivo RecA-mediated activities

The inducible SOS response increases the ability of bacteria to cope with DNA damage through various DNA repair processes in which the RecA protein plays a central role. Here we present the first study of the morphological aspects that accompany the SOS response in Escherichia coli. We find that induction of the SOS system in wild-type bacteria results in a fast and massive intracellular coaggregation of RecA and DNA into a lateral macroscopic assembly. The coaggregates comprise substantial portions of both the cellular RecA and the DNA complement. The structural features of the coaggregates and their relation to in vitro RecA-DNA networks, as well as morphological studies of strains carrying RecA mutants, are all consistent with the possibility that the intracellular assemblies represent a functional entity in which RecA-mediated DNA repair and protection activities occur.

Base pair switching by interconversion of sugar puckers in DNA extended by proteins of RecA-family: a model for homology search in homologous genetic recombination

Escherichia coli RecA is a representative of proteins from the RecA family, which promote homologous pairing and strand exchange between double-stranded DNA and single-stranded DNA. These reactions are essential for homologous genetic recombination in various organisms. From NMR studies, we previously reported a novel deoxyribose-base stacking interaction between adjacent residues on the extended single-stranded DNA bound to RecA protein. In this study, we found that the same DNA structure was induced by the binding to Saccharomyces cerevisiae Rad51 protein, indicating that the unique DNA structure induced by the binding to RecA-homologs was conserved from prokaryotes to eukaryotes. On the basis of this structure, we have formulated the structure of duplex DNA within filaments formed by RecA protein and its homologs. Two types of molecular structures are presented. One is the duplex structure that has the N-type sugar pucker. Its helical pitch is approximately 95 A (18.6 bp/turn), corresponding to that of an active, or ATP-form of the RecA filament. The other is one that has the S-type sugar pucker. Its helical pitch is approximately 64 A (12.5 bp/turn), corresponding to that of an inactive, or ADP-form of the RecA filament. During this modeling, we found that the interconversion of sugar puckers between the N-type and the S-type rotates bases horizontally, while maintaining the deoxyribose-base stacking interaction. We propose that this base rotation enables base pair switching between double-stranded DNA and single-stranded DNA to take place, facilitating homologous pairing and strand exchange. A possible mechanism for strand exchange involving DNA rotation also is discussed.

The role of negative superhelicity and length of homology in the formation of paranemic joints promoted by RecA protein

Escherichia coli RecA protein pairs homologous DNA molecules to form paranemic joints when there is an absence of a free end in the region of homologous contact. Paranemic joints are a key intermediate in homologous recombination and are important in understanding the mechanism for a search of homology. The efficiency of paranemic joint formation depended on the length of homology and the topological forms of the duplex DNA. The presence of negative superhelicity increased the pairing efficiency and reduced the minimal length of homology required for paranemic joint formation. Negative superhelicity stimulated joint formation by favoring the initial unwinding of duplex DNA that occurred during the homology search and was not essential in the maintenance of the paired structure. Regardless of length of homology, formation of paranemic joints using circular duplex DNA required the presence of more than six negative supercoils. Above six negative turns, an increasing degree of negative superhelicity resulted in a linear increase in the pairing efficiency. These results support a model of two distinct kinds of DNA unwinding occurring in paranemic joint formation: an initial unwinding caused by heterologous contacts during synapsis and a later one during pairing of the homologous molecules.

Sequence-specific targeting and covalent modification of human genomic DNA

We compare two techniques which enable selective, nucleotide-specific covalent modification of human genomic DNA, as assayed by quantitative ligation- mediated PCR. In the first, a purine motif triplex-forming oligonucleotide with a terminally appended chlorambucil was shown to label a target guanine residue adjacent to its binding site in 80% efficiency at 0.5 microM. Efficiency was higher in the presence of the triplex-stabilizing intercalator coralyne. In the second method, an oligonucleotide targeting a site containing all four bases and bearing chlorambucil on an interior base was shown to efficiently react with a specific nucleotide in the target sequence. The targeted sequence in these cases was in the DQbeta1*0302 allele of the MHC II locus.

Kinetic analysis of pairing and strand exchange catalyzed by RecA. Detection by fluorescence energy transfer

RecA is a 38-kDa protein from Escherichia coli that polymerizes on single-stranded DNA, forming a nucleoprotein filament that pairs with homologous duplex DNA and carries out strand exchange in vitro. In this study, we measured RecA-catalyzed pairing and strand exchange in solution by energy transfer between fluorescent dyes on the ends of deoxyribo-oligonucleotides. By varying the position of the dyes in separate assays, we were able to detect the pairing of single-stranded RecA filament with duplex DNA as an increase in energy transfer, and strand displacement as a decrease in energy transfer. With these assays, the kinetics of pairing and strand displacement were studied by stopped-flow spectrofluorometry. The data revealed a rapid, second order, reversible pairing step that was followed by a slower, reversible, first order strand exchange step. These data indicate that an initial unstable intermediate exists which can readily return to reactants, and that a further, rate-limiting step (or steps) is required to effect or complete strand exchange.

The search for DNA homology does not limit stable homologous pairing promoted by RecA protein

BACKGROUND

The basic molecular mechanisms that govern the search for DNA homology and subsequent homologous pairing during genetic recombination are not understood. RecA is the central homologous recombination protein of Escherichia coli; because several RecA homologues have been identified in eukaryotic cells, it is likely that the mechanisms employed by RecA are conserved throughout evolution. Analysis of the kinetics of the homologous search and pairing reactions catalyzed by RecA should therefore provide insights of general relevance into the mechanisms by which macromolecules locate, and interact with, specific DNA targets.

RESULTS

RecA forms three-stranded synaptic complexes with a single-stranded oligonucleotide and a homologous region in duplex DNA. The kinetics of this initial pairing reaction were characterized using duplex DNA molecules of various concentrations and complexities containing a single target site, as well as various concentrations of homologous single-stranded oligonucleotides. The formation of the synaptic complex follows apparent second-order reaction kinetics with a rate proportional to the concentrations of both the homologous single-stranded oligonucleotide and the target sites within the duplex DNA. The reaction rate is independent of the complexity of duplex DNA in the reaction. We propose a kinetic scheme in which the RecA-single-stranded DNA filament interacts with duplex DNA and locates its target in a relatively fast reaction. We also suggest that complex conformational changes occur during the subsequent rate-limiting step.

CONCLUSIONS

We conclude that, during the formation of synaptic complexes by RecA, the search for homology is not rate-limiting, and that the iteration frequency of the search is around 10(2)-10(3) s-1. This value agrees well with what has been calculated as the minimum number for such a frequency in genome-wide searches, and limits the possible structures involved in the search for homology to those involving very soft (low energy) interactions. Furthermore, from the order of the reaction at the DNA concentrations found in eukaryotic nuclei, and the rate constant of the overall reaction, we predict that the search for homology is also not the rate-limiting step in the genome-wide searches implicated in meiosis and in gene targeting.

ATP-dependent DNA renaturation and DNA-dependent ATPase reactions catalyzed by the Ustilago maydis homologous pairing protein

Purification of the ATP-dependent homologous pairing activity from Ustilago maydis yields a protein preparation that is enriched for a 70-kDa polypeptide as determined by SDS-gel electrophoresis. The protein responsible for the ATP-dependent pairing activity, using renaturation of complementary single strands of DNA as an assay, has a Stokes radius of 3.6 nm and a sedimentation coefficient of 4.3 S consistent with the interpretation that the activity arises from a monomeric globular protein of 70 kDa. Including heparin-agarose and FPLC gel filtration chromatography steps in the previously published protocol improves the purification of the protein. ATP and Mg2+ are necessary cofactors for optimal DNA renaturation activity. ADP inhibits the reaction. Analysis of the ATP-dependent renaturation kinetics indicates the reaction proceeds through a first-order mechanism. The protein has an associated DNA-dependent ATPase as indicated by co-chromatography with the purified ATP-dependent renaturation activity through an FPLC gel-filtration column. Single-stranded DNA and Mg2+ are required for optimal ATP hydrolytic activity, although a number of other polynucleotides and divalent cations can substitute to varying degrees. Hydrolysis of ATP is activated in a sigmoidal manner with increasing amounts of the protein. At ATP concentrations below 0.1 mM the ATPase activity exhibits positive cooperativity as indicated from the Hill coefficient of 1.8 determined by steady-state kinetic analysis of the reaction. ADP and adenosine 5'-[beta,gamma-imido]triphosphate are inhibitors of the ATPase activity although they appear to exert their inhibitory effects through different modes. These results are interpreted as evidence for protein-protein interactions.

DNA homology requirements for mitotic gap repair in Drosophila

We used P transposable-element mobilization to study the repair of double-strand DNA breaks in Drosophila melanogaster premeiotic germ cells. Distribution of conversion tracts was found to be largely unaffected by changes in the length of sequence homology between the broken ends and the template, suggesting that only a short match is required. However, the frequency of repair was highly sensitive to single-base mismatches within the homologous region, ranging from 19% reversion when there were no mismatches to 5% when 15 mismatches were present over a 3455-bp span.

Unwinding of heterologous DNA by RecA protein during the search for homologous sequences

The search for homologous sequences promoted by RecA protein in vitro involves a presynaptic filament and naked duplex DNA, the multiple contacts of which produce nucleoprotein networks or coaggregates. The single-stranded DNA within the presynaptic filaments, however, is extended to an axial spacing 1.5 times that of B-form DNA. To investigate this paradoxical difference between the spacing of bases in the RecA presynaptic filament versus the target duplex DNA, we explored the effect of heterologous contacts on the conformation of DNA, and vice versa. In the presence of wheat germ topoisomerase I, RecA presynaptic filaments induced a rapid, limited reduction in the linking number of heterologous circular duplex DNA. This limited unwinding of heterologous duplex DNA, termed heterologous unwinding, was detected within 30 seconds and reached a steady state within a few minutes. Presynaptic filaments that were formed in the presence of ATP gamma S and separated from free RecA protein by gel filtration also generated a ladder of topoisomers upon incubation with relaxed duplex DNA and topoisomerase. The inhibition of heterologous contacts by 60 mM-NaCl or 5 mM-ADP resulted in a corresponding decrease in heterologous unwinding. In reciprocal fashion, the stability or number of heterologous contacts with presynaptic filaments was inversely related to the linking number of circular duplex DNA. These observations show that heterologous contacts with the presynaptic filament cause a limited unwinding of the duplex DNA, and conversely that the ability of the DNA to unwind stabilizes transient heterologous contacts.

Dynamic light scattering investigations of RecA self-assembly and interactions with single strand DNA

Dynamic light scattering (DLS) measurements were performed on self-assembled solutions of RecA as a function of assembly time under strand exchange ionic strength conditions (10 mM MgCl2, 65 mM NaCl, 10 mM Tris-HCl, pH = 7.5, 1 mM DTT, 3-4 microM RecA) in the absence of ATP. These measurements yield distributions of the translational diffusion coefficients of the changing populations of assembling protein species. Interpretations of results of DLS measurements are made in terms of model hydrodynamic calculations that indicate, under the solution conditions employed, the smallest fundamental quaternary subunit of RecA is a hexamer in a toroidal or lock-washer configuration. Interactions of M13mp19 circular single strand DNA (ssDNA) with RecA assembled to different stages were also investigated. Additions of ssDNA to self-assembled solutions of RecA acts to dissociate the associated structures into hexamer subunits. However, the effect of ssDNA on assembled RecA is highly dependent on the RecA self-assembly state. The longer the assembly time, the less reversible the self-assembled structures of RecA become. Binding isotherms of titrated mixtures of ssDNA with RecA self-assembled to various stages were also determined. Evaluated dissociation constants of RecA/ssDNA complexes were found to increase with increases of the associated state of RecA. These results strongly suggest that, under the solvent conditions employed, the active ssDNA binding form of RecA is a hexamer.

Monoclonal antibodies and mechanistic studies on recA protein

A protein has various epitopes, and a monoclonal antibody specifically binds to the protein by recognizing 1 of the epitopes. This characteristic of the monoclonal antibody has opened various new approaches in a wide variety of research works. In studies about recA protein and its promoted various reactions relating to genetic recombination, anti-recA protein-monoclonal antibodies are very useful to analyse reaction mechanisms and to detect transition in the higher order-structure of the protein, as well as to measure the amounts of recA protein in vitro or in vivo and to identify the related proteins. In this article, we will review studies on recA protein in which monoclonal antibodies were used as major tools. By using anti-recA protein-monoclonal IgGs as specific inhibitors, the partial reactions of the homologous pairing and strand exchange promoted by recA protein were separated, and by use of a set of anti-recA protein IgGs the stages of activation of recA protein in the above reactions were discriminated.

Properties of the duplex DNA-dependent ATPase activity of Escherichia coli RecA protein and its role in branch migration

We have investigated the double-stranded DNA (dsDNA)-dependent ATPase activity of recA protein. This activity is distinguished from the single-stranded DNA (ssDNA)-dependent ATPase activity by the presence of a pronounced lag time before the onset of steady-state ATP hydrolysis. During the lag phase there is little ATP hydrolysis. The duration of the lag phase, referred to as the lag time, is found to increase with the thermal stability of the dsDNA substrate. Increasing either the MgCl2 or NaCl concentration increases the lag time, whereas increasing the temperature decreases the lag time. The lag time shows little dependence on recA protein concentration but is strongly dependent on ATP concentration. After the lag phase, a steady-state ATP hydrolysis rate is achieved that approaches the rate observed with ssDNA. The steady-state phase of the reaction is proportional to the concentration of recA protein-DNA complex and shows saturation behavior at approximately equal to 5 +/- 1 base pairs per recA protein monomer. These results suggest that the lag phase represents a rate-limiting step in the dsDNA-dependent ATP hydrolysis reaction that requires a structural transition in the dsDNA and that involves a ternary complex of ATP, recA protein, and DNA. We propose that this transition involves the transient denaturation of the dsDNA to form regions of ssDNA. Elsewhere we demonstrate that the dsDNA-dependent ATPase activity is proportional to the rate of recA protein-catalyzed branch migration. We suggest that this activity is responsible for a polar polymerization that drives the branch migration reaction.

Ability of RecA protein to promote a search for rare sequences in duplex DNA

RecA nucleoprotein filaments found homologous targets even when the latter was mixed with 200,000 times as much heterologous duplex DNA. By contrast, mixing of the single-stranded probe with only 100 times as much heterologous single strands markedly reduced the rate of finding homologous duplex molecules. Titration of the reaction with different proportions of homologous single-stranded DNA distinguished a condition under which the search for homology itself was rate limiting from a condition under which some later step was limiting. Less than 1 min was required to scan 6.4 kilobase pairs of duplex DNA for homology to a RecA-coated single strand of the same size, but these experiments revealed that rapid searching by RecA nucleoprotein filaments was largely confined to neighboring duplex molecules. These observations provide guidelines for the use of RecA protein in locating rare sequences in complex mixtures of duplex DNA, and we describe a simple protocol by which rare sequences can be rapidly enriched at least a thousandfold.

Homologous pairing of DNA molecules by Ustilago rec1 protein is promoted by sequences of Z-DNA

Plasmids containing Z-DNA stretches can be paired and linked by combined action of Ustilago rec1 protein and topoisomerase. The product formed is a hemicatenated dimer in which two DNA rings are topologically intertwined at a region of homology. Superhelicity governs the reaction. Formation of linked product is coupled with formation of Z-DNA in the plasmid, a process dependent on the superhelix density. Pairing appears to initiate within the Z-DNA sequence, not at the unwound B-Z junction. The reaction can be blocked by a Z-DNA-specific binding protein, namely Z-DNA antibody. Plasmids with alternating Z-DNA dG-dC sequences at different sites on otherwise homologous molecules can be linked at the dG-dC sequences. However, a plasmid with a (dG-dC)n.(dG-dC)n Z-DNA stretch cannot be linked with a plasmid containing a (dG-dT)n.(dC-dA)n Z-DNA stretch.

Intermediates in homologous pairing promoted by recA protein. Isolation and characterization of active presynaptic complexes

recA protein promotes homologous pairing and strand exchange by an ordered reaction in which the protein first polymerizes on single-stranded DNA. This presynaptic intermediate, which can be formed either in the presence or absence of Escherichia coli single-stranded binding protein (SSB), has been isolated by gel filtration and characterized. At saturation, purified complexes contained one molecule of recA protein per 3.6 nucleotide residues of single-stranded DNA. Complexes that had been formed in the presence of SSB contained up to one molecule of SSB per 15 nucleotide residues, but the content of SSB in different preparations of isolated complexes appeared to be inversely related to the content of recA protein. Even when they have lost as much as a third of their recA protein, presynaptic complexes can retain activity, because the formation of stable joint molecules depends principally on the binding of recA protein to the single-stranded DNA in the localized region that corresponds to the end of the duplex substrate.

Ionic inhibition of formation of RecA nucleoprotein networks blocks homologous pairing

Conditions that favor the complete coating of single-stranded DNA by RecA protein promote the association of these presynaptic filaments with naked double-stranded DNA to form large nucleoprotein networks before homologous pairing occurs. These RecA nucleoprotein networks sequester virtually all of the DNA in the reaction mixture. Conditions that are suboptimal for the formation of the RecA presynaptic filament rendered both the formation of RecA-DNA networks and the subsequent formation of joint molecules sensitive to inhibition by excess ATP or by pyrophosphate when these were added during synapsis. The rate of homologous pairing was directly related to the degree of inhibition of network formation. Various multivalent cations added during synapsis restored both the formation of networks and the pairing of homologous molecules. These observations support the view that the nucleoprotein network is a synaptic intermediate by means of which RecA protein facilitates the conjunction of DNA molecules and the subsequent processive search for homology. Inhibition by multivalent anions and restoration by multivalent cations suggests in addition, that negative charge repulsion inhibits the binding of naked duplex DNA to presynaptic filaments.