Effect of length and location of heterologous sequences on RecA-mediated strand exchange

Uncovering the role of Rad51 in homologous recombination-mediated antigenic diversification in the human malaria parasite Plasmodium falciparum

The human malaria parasite Plasmodium falciparum maintains the chronicity of infections through antigenic variation, a well-coordinated immune evasion mechanism. The most prominent molecular determinant of antigenic variation in this parasite includes the members of the var multigene family. Homologous recombination (HR)-mediated genomic rearrangements have been implicated to play a major role in var gene diversification. However, the key molecular factors involved in the generation of diversity at var loci are less known. Here, we tested the hypothesis that PfRad51 could carry out recombination between var genes that are not homologous but homeologous in nature. We employed the whole-genome sequencing (WGS) approach to investigate recombination events among var sequences over 100 generations and compared the rate of sequence rearrangement at the var loci in both PfRad51-proficient and -deficient parasite lines. This brief report provides evidence that the loss of the key recombinase function renders the parasite with inefficient HR and results in fewer recombination events among the var sequences, thereby impacting the diversification of the var gene repertoire.

Highly mismatch-tolerant homology testing by RecA could explain how homology length affects recombination

In E. coli, double strand breaks (DSBs) are resected and loaded with RecA protein. The genome is then rapidly searched for a sequence that is homologous to the DNA flanking the DSB. Mismatches in homologous partners are rare, suggesting that RecA should rapidly reject mismatched recombination products; however, this is not the case. Decades of work have shown that long lasting recombination products can include many mismatches. In this work, we show that in vitro RecA forms readily observable recombination products when 16% of the bases in the product are mismatched. We also consider various theoretical models of mismatch-tolerant homology testing. The models test homology by comparing the sequences of Ltest bases in two single-stranded DNAs (ssDNA) from the same genome. If the two sequences pass the homology test, the pairing between the two ssDNA becomes permanent. Stringency is the fraction of permanent pairings that join ssDNA from the same positions in the genome. We applied the models to both randomly generated genomes and bacterial genomes. For both randomly generated genomes and bacterial genomes, the models show that if no mismatches are accepted stringency is ∼ 99% when Ltest = 14 bp. For randomly generated genomes, stringency decreases with increasing mismatch tolerance, and stringency improves with increasing Ltest. In contrast, in bacterial genomes when Ltest ∼ 75 bp, stringency is ∼ 99% for both mismatch-intolerant and mismatch-tolerant homology testing. Furthermore, increasing Ltest does not improve stringency because most incorrect pairings join different copies of repeats. In sum, for bacterial genomes highly mismatch tolerant homology testing of 75 bp provides the same stringency as homology testing that rejects all mismatches and testing more than ∼75 base pairs is not useful. Interestingly, in vivo commitment to recombination typically requires homology testing of ∼ 75 bp, consistent with highly mismatch intolerant testing.

Iterative homology checking and non-uniform stepping during RecA-mediated strand exchange

Recombinase-mediated homologous recombination (HR) in which strands are exchanged between two similar or identical DNA molecules is essential for maintaining genome fidelity and generating genetic diversity. It is believed that HR comprises two distinct stages: an initial alignment with stringent homology checking followed by stepwise heteroduplex expansion. If and how homology checking takes place during heteroduplex expansion, however, remains unknown. In addition, the number of base pairs (bp) involved in each step is still under debate. By using single-molecule approaches to catch transient intermediates in RecA-mediated HR with different degrees of homology, we show that (i) the expansion proceeds with step sizes of multiples of 3 bp, (ii) the step sizes follow wide distributions that are similar to that of initial alignment lengths, and (iii) each distribution can be divided into a short-scale and a long-scale part irrespective of the degree of homology. Our results suggest an iterative mechanism of strand exchange in which ssDNA-RecA filament interrogates double-stranded DNA using a short tract (6-15 bp) for quick checking and a long tract (>18 bp) for stringent sequence comparison. The present work provides novel insights into the physical and structural bases of DNA recombination.

Chromosomal transformation in Bacillus subtilis is a non-polar recombination reaction

Natural chromosomal transformation is one of the primary driving forces of bacterial evolution. This reaction involves the recombination of the internalized linear single-stranded (ss) DNA with the homologous resident duplex via RecA-mediated integration in concert with SsbA and DprA or RecO. We show that sequence divergence prevents Bacillus subtilis chromosomal transformation in a log-linear fashion, but it exerts a minor effect when the divergence is localized at a discrete end. In the nucleotide bound form, RecA shows no apparent preference to initiate recombination at the 3′- or 5′-complementary end of the linear duplex with circular ssDNA, but nucleotide hydrolysis is required when heterology is present at both ends. RecA·dATP initiates pairing of the linear 5′ and 3′ complementary ends, but only initiation at the 5′-end remains stably paired in the absence of SsbA. Our results suggest that during gene transfer RecA·ATP, in concert with SsbA and DprA or RecO, shows a moderate preference for the 3′-end of the duplex. We show that RecA-mediated recombination initiated at the 3′- or 5′-complementary end might have significant implication on the ecological diversification of bacterial species with natural transformation.

Influence of sequence mismatches on the specificity of recombinase polymerase amplification technology

Recombinase polymerase amplification (RPA) technology relies on three major proteins, recombinase proteins, single-strand binding proteins, and polymerases, to specifically amplify nucleic acid sequences in an isothermal format. The performance of RPA with respect to sequence mismatches of closely-related non-target molecules is not well documented and the influence of the number and distribution of mismatches in DNA sequences on RPA amplification reaction is not well understood. We investigated the specificity of RPA by testing closely-related species bearing naturally occurring mismatches for the tuf gene sequence of Pseudomonas aeruginosa and/or Mycobacterium tuberculosis and for the cfb gene sequence of Streptococcus agalactiae. In addition, the impact of the number and distribution of mismatches on RPA efficiency was assessed by synthetically generating 14 types of mismatched forward primers for detecting five bacterial species of high diagnostic relevance such as Clostridium difficile, Staphylococcus aureus, S. agalactiae, P. aeruginosa, and M. tuberculosis as well as Bacillus atropheus subsp. globigii for which we use the spores as internal control in diagnostic assays. A total of 87 mismatched primers were tested in this study. We observed that target specific RPA primers with mismatches (n > 1) at their 3'extrimity hampered RPA reaction. In addition, 3 mismatches covering both extremities and the center of the primer sequence negatively affected RPA yield. We demonstrated that the specificity of RPA was multifactorial. Therefore its application in clinical settings must be selected and validated a priori. We recommend that the selection of a target gene must consider the presence of closely-related non-target genes. It is advisable to choose target regions with a high number of mismatches (≥36%, relative to the size of amplicon) with respect to closely-related species and the best case scenario would be by choosing a unique target gene.

Dominant negative mutant of Plasmodium Rad51 causes reduced parasite burden in host by abrogating DNA double-strand break repair

Malaria parasites survive through repairing a plethora of DNA double-stranded breaks (DSBs) experienced during their asexual growth. In Plasmodium Rad51 mediated homologous recombination (HR) mechanism and homology-independent alternative end-joining mechanism have been identified. Here we address whether loss of HR activity can be compensated by other DSB repair mechanisms. Creating a transgenic Plasmodium line defective in HR function, we demonstrate that HR is the most important DSB repair pathway in malarial parasite. Using mouse malaria model we have characterized the dominant negative effect of PfRad51(K143R) mutant on Plasmodium DSB repair and host-parasite interaction. Our work illustrates that Plasmodium berghei harbouring the mutant protein (PfRad51(K143R)) failed to repair DSBs as evidenced by hypersensitivity to DNA-damaging agent. Mice infected with mutant parasites lived significantly longer with markedly reduced parasite burden. To better understand the effect of mutant PfRad51(K143R) on HR, we used yeast as a surrogate model and established that the presence of PfRad51(K143R) completely inhibited DNA repair, gene conversion and gene targeting. Biochemical experiment confirmed that very low level of mutant protein was sufficient for complete disruption of wild-type PfRad51 activity. Hence our work provides evidence that HR pathway of Plasmodium could be efficiently targeted to curb malaria.

Optimizing the design of oligonucleotides for homology directed gene targeting

Background

Gene targeting depends on the ability of cells to use homologous recombination to integrate exogenous DNA into their own genome. A robust mechanistic model of homologous recombination is necessary to fully exploit gene targeting for therapeutic benefit.

Methodology/Principal Findings

In this work, our recently developed numerical simulation model for homology search is employed to develop rules for the design of oligonucleotides used in gene targeting. A Metropolis Monte-Carlo algorithm is used to predict the pairing dynamics of an oligonucleotide with the target double-stranded DNA. The model calculates the base-alignment between a long, target double-stranded DNA and a probe nucleoprotein filament comprised of homologous recombination proteins (Rad51 or RecA) polymerized on a single strand DNA. In this study, we considered different sizes of oligonucleotides containing 1 or 3 base heterologies with the target; different positions on the probe were tested to investigate the effect of the mismatch position on the pairing dynamics and stability. We show that the optimal design is a compromise between the mean time to reach a perfect alignment between the two molecules and the stability of the complex.

Conclusion and Significance

A single heterology can be placed anywhere without significantly affecting the stability of the triplex. In the case of three consecutive heterologies, our modeling recommends using long oligonucleotides (at least 35 bases) in which the heterologous sequences are positioned at an intermediate position. Oligonucleotides should not contain more than 10% consecutive heterologies to guarantee a stable pairing with the target dsDNA. Theoretical modeling cannot replace experiments, but we believe that our model can considerably accelerate optimization of oligonucleotides for gene therapy by predicting their pairing dynamics with the target dsDNA.

Heterology tolerance and recognition of mismatched base pairs by human Rad51 protein

Human Rad51 (hRad51) promoted homology recognition and subsequent strand exchange are the key steps in human homologous recombination mediated repair of DNA double-strand breaks. However, it is still not clear how hRad51 deals with sequence heterology between the two homologous chromosomes in eukaryotic cells, which would lead to mismatched base pairs after strand exchange. Excessive tolerance of sequence heterology may compromise the fidelity of repair of DNA double-strand breaks. In this study, fluorescence resonance energy transfer (FRET) was used to monitor the heterology tolerance of human Rad51 mediated strand exchange reactions, in real time, by introducing either G-T or I-C mismatched base pairs between the two homologous DNA strands. The strand exchange reactions were much more sensitive to G-T than to I-C base pairs. These results imply that the recognition of homology and the tolerance of heterology by hRad51 may depend on the local structural motif adopted by the base pairs participating in strand exchange. AnhRad51 mutant protein (hRad51K133R), deficient in ATP hydrolysis, showed greater heterology tolerance to both types of mismatch base pairing, suggesting that ATPase activity may be important for maintenance of high fidelity homologous recombination DNA repair.

Caught in the act: the lifetime of synaptic intermediates during the search for homology on DNA

Homologous recombination plays pivotal roles in DNA repair and in the generation of genetic diversity. To locate homologous target sequences at which strand exchange can occur within a timescale that a cell’s biology demands, a single-stranded DNA-recombinase complex must search among a large number of sequences on a genome by forming synapses with chromosomal segments of DNA. A key element in the search is the time it takes for the two sequences of DNA to be compared, i.e. the synapse lifetime. Here, we visualize for the first time fluorescently tagged individual synapses formed by RecA, a prokaryotic recombinase, and measure their lifetime as a function of synapse length and differences in sequence between the participating DNAs. Surprisingly, lifetimes can be ∼10 s long when the DNAs are fully heterologous, and much longer for partial homology, consistently with ensemble FRET measurements. Synapse lifetime increases rapidly as the length of a region of full homology at either the 3′- or 5′-ends of the invading single-stranded DNA increases above 30 bases. A few mismatches can reduce dramatically the lifetime of synapses formed with nearly homologous DNAs. These results suggest the need for facilitated homology search mechanisms to locate homology successfully within the timescales observed in vivo.

Nuclear gene targeting in Chlamydomonas as exemplified by disruption of the PHOT gene

Chlamydomonas reinhardtii is the most powerful photosynthetic eukaryotic unicellular model organism. However, its potential is not fully exploitable since as in most green plants specific targeting of nuclear genes is not routinely possible. Recently, we have shown by repair of an introduced truncated model gene that transformation of Chlamydomonas with single stranded DNA greatly suppresses random integration of the DNA in the genome whereas homologous recombination (HR) is left unchanged. However, endogenous genes still could not be targeted. Here we present optimized transformation conditions that further improved HR and suppressed non-homologous DNA integration (NHI). The improved transformation strategy allowed us now to specifically inactivate in two different Chlamydomonas strains the nuclear PHOT gene, which encodes for the blue light photoreceptor phototropin (PHOT). The option to target moderately expressed Chlamydomonas nuclear genes with high efficiency now further improves the utility of this this alga for basic science and biotechnology.

Single molecule studies of homologous recombination

Single molecule methods offer an unprecedented opportunity to examine complex macromolecular reactions that are obfuscated by ensemble averaging. The application of single molecule techniques to study DNA processing enzymes has revealed new mechanistic details that are unobtainable from bulk biochemical studies. Homologous DNA recombination is a multi-step pathway that is facilitated by numerous enzymes that must precisely and rapidly manipulate diverse DNA substrates to repair potentially lethal breaks in the DNA duplex. In this review, we present an overview of single molecule assays that have been developed to study key aspects of homologous recombination and discuss the unique information gleaned from these experiments.

High fidelity of RecA-catalyzed recombination: a watchdog of genetic diversity

Homologous recombination plays a key role in generating genetic diversity, while maintaining protein functionality. The mechanisms by which RecA enables a single-stranded segment of DNA to recognize a homologous tract within a whole genome are poorly understood. The scale by which homology recognition takes place is of a few tens of base pairs, after which the quest for homology is over. To study the mechanism of homology recognition, RecA-promoted homologous recombination between short DNA oligomers with different degrees of heterology was studied in vitro, using fluorescence resonant energy transfer. RecA can detect single mismatches at the initial stages of recombination, and the efficiency of recombination is strongly dependent on the location and distribution of mismatches. Mismatches near the 5′ end of the incoming strand have a minute effect, whereas mismatches near the 3′ end hinder strand exchange dramatically. There is a characteristic DNA length above which the sensitivity to heterology decreases sharply. Experiments with competitor sequences with varying degrees of homology yield information about the process of homology search and synapse lifetime. The exquisite sensitivity to mismatches and the directionality in the exchange process support a mechanism for homology recognition that can be modeled as a kinetic proofreading cascade.

Mechanism of RecA-mediated homologous recombination revisited by single molecule nanomanipulation

The mechanisms of RecA-mediated three-strand homologous recombination are investigated at the single-molecule level, using magnetic tweezers. Probing the mechanical response of DNA molecules and nucleoprotein filaments in tension and in torsion allows a monitoring of the progression of the exchange in real time, both from the point of view of the RecA-bound single-stranded DNA and from that of the naked double-stranded DNA (dsDNA). We show that strand exchange is able to generate torsion even along a molecule with freely rotating ends. RecA readily depolymerizes during the reaction, a process presenting numerous advantages for the cell's 'protein economy' and for the management of topological constraints. Invasion of an untwisted dsDNA by a nucleoprotein filament leads to an exchanged duplex that remains topologically linked to the exchanged single strand, suggesting multiple initiations of strand exchange on the same molecule. Overall, our results seem to support several important assumptions of the monomer redistribution model.

A tolerance of DNA heterology in the mammalian targeted gene repair reaction

Targeted gene repair consists of at least two major steps, the pairing of an oligonucleotide to a site bearing DNA sequence complementarity followed by a nucleotide exchange reaction directed by the oligonucleotide. In this study, oligonucleotides with different structures were designed to target a stably integrated (mutant) enhanced green fluorescent protein (EGFP) gene and used to direct the repair of a single base mutation. We show that the efficiency of correction is influenced by the degree of DNA sequence homology existing between the oligonucleotide and target gene. Correction is reduced when a heterologous stretch of DNA sequence is placed in the center of the oligonucleotide and the mismatched base pair is then formed near the terminus. The negative impact of heterology is dependent on the type of DNA sequence inserted and on the size of the heterologous region. If the heterologous sequence is palindromic and adopts a secondary structure, the negative impact on the correction frequency is removed, and wild-type levels of repair are restored. Although differences in the efficiency of correction are observed in various cell types, the effect of structural changes on gene repair is consistent. These results reveal the existence of a directional-specific repair pathway that relies on the pairing stability of a bilateral complex and emphasize the importance of sequence homology between pairing partners for efficient catalysis of gene repair.

Organized unidirectional waves of ATP hydrolysis within a RecA filament

The RecA protein forms nucleoprotein filaments on DNA, and individual monomers within the filaments hydrolyze ATP. Assembly and disassembly of filaments are both unidirectional, occurring on opposite filament ends, with disassembly requiring ATP hydrolysis. When filaments form on duplex DNA, RecA protein exhibits a functional state comparable to the state observed during active DNA strand exchange. RecA filament state was monitored with a coupled spectrophotometric assay for ATP hydrolysis, with changes fit to a mathematical model for filament disassembly. At 37 degrees C, monomers within the RecA-double-stranded DNA (dsDNA) filaments hydrolyze ATP with an observed k(cat) of 20.8 +/- 1.5 min(-1). Under the same conditions, the rate of end-dependent filament disassembly (k(off)) is 123 +/- 16 monomers per minute per filament end. This rate of disassembly requires a tight coupling of the ATP hydrolytic cycles of adjacent RecA monomers. The relationship of k(cat) to k(off) infers a filament state in which waves of ATP hydrolysis move unidirectionally through RecA filaments on dsDNA, with successive waves occurring at intervals of approximately six monomers. The waves move nearly synchronously, each one transiting from one monomer to the next every 0.5 s. The results reflect an organization of the ATPase activity that is unique in filamentous systems, and could be linked to a RecA motor function.

Characterization of kinetics of DNA strand-exchange and ATP hydrolysis activities of recombinant PfRad51, a Plasmodium falciparum recombinase

Although homologous recombination-mediated DNA rearrangements are quite widespread in Plasmodium falciparum, the molecular mechanisms involved are essentially unknown. Recent identification of PfRad51 in P. falciparum has suggested that it may play central role during homologous recombination and DNA rearrangements. Full-length recombinant PfRad51 was over expressed in Escherichia coli and purified to near homogeneity. Using optimized enzymatic activity conditions recombinant PfRad51 protein was shown to catalyze DNA strand-exchange reaction, a central step during homologous recombination. Unlike bacterial RecA protein, PfRad51 promoted strand-exchange reaction does not require ATP hydrolysis. The PfRad51 protein also catalyzed ssDNA-dependent ATP hydrolysis and the k(cat) values were similar to those reported for human Rad51. The demonstration of strand-exchange activity of PfRad51 protein, first such report in any protozoan parasite, suggests importance of similar recombination mechanism during DNA rearrangements associated with antigenic variation in P. falciparum.

Fluorescent detection and isolation of DNA variants using stabilized RecA-coated oligonucleotides

Several genome resequencing strategies have been developed to detect genetic variation in populations and correlate diversity with phenotypic consequences. Commonly used methods of detecting single nucleotide polymorphisms (SNPs) use PCR amplification and indirect analysis, which can create template biases and enable user contamination. Here we present a novel assay to detect and isolate DNA variants using stabile nanostructures formed directly on duplex DNA. The assay incorporates the well-established RecA-catalyzed strand invasion process with a novel stabilizing hybridization step. First, short RecA-coated oligonucleotide filaments invade duplex DNA to form a synaptic intermediate or "D-loop." Sequentially, chemically modified oligonucleotide probes anneal to the displaced DNA strand of the complex to form a stable "double D-loop." These joint molecules resist dissociation when both oligonucleotides are completely complementary to the target duplex; however, if the probes are mismatched, the complex is inherently instable and rapidly dissociates. SNPs are identified by detecting the fluorophore assimilated into stable complexes produced by homologous probes compared to unstable differentially labeled mismatched probes. Furthermore, this strategy can be used to isolate specific allelic variants by affinity purification from complex populations. Stabilized double D-Loop intermediates accordingly offer the promise of haplotyping and pharmacogenomic analysis directly in double-stranded DNA samples.

The Bacterial RecA Protein as a Motor Protein

The bacterial RecA protein plays a central role in the repair of stalled replication forks, double-strand break repair, general recombination, induction of the SOS response, and SOS mutagenesis. The major activity of RecA in DNA metabolism is the promotion of DNA strand exchange reactions. RecA is the prototype for a ubiquitous family of proteins but exhibits a few activities that some of its eukaryotic, archaeal, and viral homologs appear to lack. In particular, the bacterial RecA protein possesses an apparent motor function that is not evident in the reactions promoted by the eukaryotic Rad51 protein. This motor may be needed only in a subset of the DNA metabolism contexts in which RecA protein functions. Models for the coupling of DNA strand exchange to ATP hydrolysis are examined.

The bacterial RecA protein and the recombinational DNA repair of stalled replication forks

The primary function of bacterial recombination systems is the nonmutagenic repair of stalled or collapsed replication forks. The RecA protein plays a central role in these repair pathways, and its biochemistry must be considered in this context. RecA protein promotes DNA strand exchange, a reaction that contributes to fork regression and DNA end invasion steps. RecA protein activities, especially formation and disassembly of its filaments, affect many additional steps. So far, Escherichia coli RecA appears to be unique among its nearly ubiquitous family of homologous proteins in that it possesses a motorlike activity that can couple the branch movement in DNA strand exchange to ATP hydrolysis. RecA is also a multifunctional protein, serving in different biochemical roles for recombinational processes, SOS induction, and mutagenic lesion bypass. New biochemical and structural information highlights both the similarities and distinctions between RecA and its homologs. Increasingly, those differences can be rationalized in terms of biological function.

Incorporation of large heterologies into heteroduplex DNA during double-strand-break repair in mouse cells

In this study, the formation and repair of large (>1 kb) insertion/deletion (I/D) heterologies during double-strand-break repair (DSBR) was investigated using a gene-targeting assay that permits efficient recovery of sequence insertion events at the haploid chromosomal immunoglobulin (Ig) mu-locus in mouse hybridoma cells. The results revealed that (i) large I/D heterologies were generated on one or both sides of the DSB and, in some cases, formed symmetrically in both homology regions; (ii) large I/D heterologies did not negatively affect the gene targeting frequency; and (iii) prior to DNA replication, the large I/D heterologies were rectified.

Meiotic recombination involving heterozygous large insertions in Saccharomyces cerevisiae: formation and repair of large, unpaired DNA loops

Meiotic recombination in Saccharomyces cerevisiae involves the formation of heteroduplexes, duplexes containing DNA strands derived from two different homologues. If the two strands of DNA differ by an insertion or deletion, the heteroduplex will contain an unpaired DNA loop. We found that unpaired loops as large as 5.6 kb can be accommodated within a heteroduplex. Repair of these loops involved the nucleotide excision repair (NER) enzymes Rad1p and Rad10p and the mismatch repair (MMR) proteins Msh2p and Msh3p, but not several other NER (Rad2p and Rad14p) and MMR (Msh4p, Msh6p, Mlh1p, Pms1p, Mlh2p, Mlh3p) proteins. Heteroduplexes were also formed with DNA strands derived from alleles containing two different large insertions, creating a large "bubble"; repair of this substrate was dependent on Rad1p. Although meiotic recombination events in yeast are initiated by double-strand DNA breaks (DSBs), we showed that DSBs occurring within heterozygous insertions do not stimulate interhomologue recombination.

Appropriate initiation of the strand exchange reaction promoted by RecA protein requires ATP hydrolysis

The DNA-dependent ATPase activity of the Escherichia coli RecA protein has been recognized for more than two decades. Yet, the role of ATP hydrolysis in the RecA-promoted strand exchange reaction remains unclear. Here, we demonstrate that ATP hydrolysis is required as part of a proofreading process during homology recognition. It enables the RecA-ssDNA complex, after determining that the strand-exchanged duplex is mismatched, to dissociate from the synaptic complex, which allows it to re-initiate the search for a "true" homologous region. Furthermore, the results suggest that when non-homologous sequences are present at the proximal end, ATP hydrolysis is required to allow ssDNA-RecA to reinitiate the strand exchange from an internal homologous region.

RecA force generation by hydrolysis waves

We present a simple theory of the dynamics of force generation by RecA during homologous strand exchange and a continuous, deterministic mathematical model of the proposed process. Calculations show that force generation is possible in this model for certain reasonable values of the parameters. We predict the shape of the force-velocity curve for the Holliday junction, which exhibits a distinctive kink at large retarding force, and suggest experiments which should distinguish between the proposed model and other models in the literature.

Recombinational DNA repair in bacteria and the RecA protein

In bacteria, the major function of homologous genetic recombination is recombinational DNA repair. This is not a process reserved only for rare double-strand breaks caused by ionizing radiation, nor is it limited to situations in which the SOS response has been induced. Recombinational DNA repair in bacteria is closely tied to the cellular replication systems, and it functions to repair damage at stalled replication forks, Studies with a variety of rec mutants, carried out under normal aerobic growth conditions, consistently suggest that at least 10-30% of all replication forks originating at the bacterial origin of replication are halted by DNA damage and must undergo recombinational DNA repair. The actual frequency may be much higher. Recombinational DNA repair is both the most complex and the least understood of bacterial DNA repair processes. When replication forks encounter a DNA lesion or strand break, repair is mediated by an adaptable set of pathways encompassing most of the enzymes involved in DNA metabolism. There are five separate enzymatic processes involved in these repair events: (1) The replication fork assembled at OriC stalls and/or collapses when encountering DNA damage. (2) Recombination enzymes provide a complementary strand for a lesion isolated in a single-strand gap, or reconstruct a branched DNA at the site of a double-strand break. (3) The phi X174-type primosome (or repair primosome) functions in the origin-independent reassembly of the replication fork. (4) The XerCD site-specific recombination system resolves the dimeric chromosomes that are the inevitable by-product of frequent recombination associated with recombinational DNA repair. (5) DNA excision repair and other repair systems eliminate lesions left behind in double-stranded DNA. The RecA protein plays a central role in the recombination phase of the process. Among its many activities, RecA protein is a motor protein, coupling the hydrolysis of ATP to the movement of DNA branches.

Homeologous plastid DNA transformation in tobacco is mediated by multiple recombination events

Efficient plastid transformation has been achieved in Nicotiana tabacum using cloned plastid DNA of Solanum nigrum carrying mutations conferring spectinomycin and streptomycin resistance. The use of the incompletely homologous (homeologous) Solanum plastid DNA as donor resulted in a Nicotiana plastid transformation frequency comparable with that of other experiments where completely homologous plastid DNA was introduced. Physical mapping and nucleotide sequence analysis of the targeted plastid DNA region in the transformants demonstrated efficient site-specific integration of the 7.8-kb Solanum plastid DNA and the exclusion of the vector DNA. The integration of the cloned Solanum plastid DNA into the Nicotiana plastid genome involved multiple recombination events as revealed by the presence of discontinuous tracts of Solanum-specific sequences that were interspersed between Nicotiana-specific markers. Marked position effects resulted in very frequent cointegration of the nonselected peripheral donor markers located adjacent to the vector DNA. Data presented here on the efficiency and features of homeologous plastid DNA recombination are consistent with the existence of an active RecA-mediated, but a diminished mismatch, recombination/repair system in higher-plant plastids.

Polarity of DNA strand exchange promoted by recombination proteins of the RecA family

Homologs of Escherichia coli RecA recombination protein, which have been found throughout the living kingdom, promote homologous pairing and strand exchange. The nucleoprotein filament, within which strand exchange occurs, has been conserved through evolution, but conservation of the polarity of exchange and the significance of that directionality has not been settled. Using oligonucleotides as substrates, and assays based on fluorescence resonance energy transfer (FRET), we distinguished the biased formation of homologous joints at either end of duplex DNA from the subsequent directionality of strand exchange. As with E. coli RecA protein, the homologous Rad51 proteins from both Homo sapiens (HsRad51) and Saccharomyces cerevisiae (ScRad51) propagated DNA strand exchange preferentially in the 5' to 3' direction. The data suggest that 5' to 3' polarity is a conserved intrinsic property of recombination filaments.

Branch migration through DNA sequence heterology

Branch migration of a DNA Holliday junction is a key step in genetic recombination. Previously, it was shown that a single base-pair heterology between two otherwise identical DNA sequences is a substantial barrier to passage of a Holliday junction during spontaneous branch migration. Here, we exploit this inhibitory effect of sequence heterology to estimate the step size of branch migration. We also devise a simulation of branch migration through mismatched base-pairs to arrive at the underlying molecular basis for the block to branch migration imposed by sequence heterology. Based on the observation that two adjacent sequence heterologies exert their effects on branch migration more or less independently, we conclude that the step size of branch migration is quite small, of the order of one or two base-pairs per migratory step. Comparison of branch migration experiments through a single base-pair heterology with simulations of a random walk through sequence heterology suggests that the inhibition of branch migration is largely attributable to a thermodynamic barrier arising from the formation of unpaired or mispaired bases in heteroduplex DNAs.

Processing of recombination intermediates by the RuvABC proteins

The RuvA, RuvB, and RuvC proteins in Escherichia coli play important roles in the late stages of homologous genetic recombination and the recombinational repair of damaged DNA. Two proteins, RuvA and RuvB, form a complex that promotes ATP-dependent branch migration of Holliday junctions, a process that is important for the formation of heteroduplex DNA. Individual roles for each protein have been defined, with RuvA acting as a specificity factor that targets RuvB, the branch migration motor to the junction. Structural studies indicate that two RuvA tetramers sandwich the junction and hold it in an unfolded square-planar configuration. Hexameric rings of RuvB face each other across the junction and promote a novel dual helicase action that "pumps" DNA through the RuvAB complex, using the free energy provided by ATP hydrolysis. The third protein, RuvC endonuclease, resolves the Holliday junction by introducing nicks into two DNA strands. Genetic and biochemical studies indicate that branch migration and resolution are coupled by direct interactions between the three proteins, possibly by the formation of a RuvABC complex.

On the mechanism of RecA-mediated repair of double-strand breaks: no role for four-strand DNA pairing intermediates

RecA protein will bind to a gapped duplex DNA molecule and promote a DNA strand exchange with a second homologous linear duplex. A double-strand break in the second duplex is efficiently bypassed in the course of these reactions. We demonstrate that the bypass of double-strand breaks is not explained by a mechanism involving homologous interactions between two duplex DNA molecules, but instead requires the ATP-mediated generation of DNA torsional stress brought about by the action of RecA. The results suggest new pathways for the repair of double-strand breaks and underline the need for new paradigms to explain the alignment of homologous DNAs during genetic recombination.

(GT)n repetitive tracts affect several stages of RecA-promoted recombination

The effect of GT/CA dinucleotide repeat tracts on RecA-dependent homologous recombination was examined in vitro. By measuring the binding of RecA protein to oligonucleotides containing GT or CA repeats using the surface plasmon resonance (BIAcore), we show that the efficiency of RecA protein binding is sequence dependent: the protein binds to non-repetitive, poly(CA) or poly(GT) sequences with an increasing affinity. This preferential binding to repetitive sequences is specific for RecA protein and is not observed with the single-strand DNA binding (SSB) protein. Despite the fact that RecA filaments formed on GT tracts efficiently bind duplex DNAs, they are unable to promote stable joint formation. Moreover, strand exchange between a duplex DNA and a fully homologous single-stranded DNA (ssDNA) containing dinucleotide repeats, is inhibited as a function of the length of the repetitive tract. The number of molecules which underwent a complete strand exchange decreased from 100% to 80% and 30% for DNA containing seven, 16 and 39 GT repeats, respectively. The inhibition is less pronounced when the ssDNA contains CA instead of GT dinucleotide repeats. We propose that the high affinity of RecA protein for (CA)n or (GT)n tracts prevents strand exchange from progressing across such sequences. Thus, our results suggest that repetitive tracts of dinucleotides CA/GT could influence recombinational activity potentially leading to an increase in genomic rearrangements.

RecA as a motor protein. Testing models for the role of ATP hydrolysis in DNA strand exchange

ATP hydrolysis (by RecA protein) fundamentally alters the properties of RecA protein-mediated DNA strand exchange reactions. ATP hydrolysis renders DNA strand exchange unidirectional, greatly increases the lengths of hybrid DNA created, permits the bypass of heterologous DNA insertions in one or both DNA substrates, and is absolutely required for exchange reactions involving four DNA strands. There are at least two viable models to explain how ATP hydrolysis is coupled to DNA strand exchange so as to bring about these effects. The first couples ATP hydrolysis to a redistribution of RecA monomers within a RecA filament. The second couples ATP hydrolysis to a facilitated rotation of the DNA substrates. The RecA monomer redistribution model makes the prediction that heterology bypass should not occur if the single-stranded DNA substrate is linear. The facilitated DNA rotation model predicts that RecA protein should promote the separation of paired DNA strands within a RecA filament if one of them is contiguous with a length of DNA being rotated about the filament exterior. Here, a facile bypass of heterologous insertions with linear DNA substrates is demonstrated, providing evidence against a role for RecA monomer redistribution in heterology bypass. In addition, we demonstrate that following a four-strand DNA exchange reaction, a distal segment of DNA hundreds of base pairs in length can be unwound in a nonreciprocal phase of the reaction, consistent with the direct coupling of an ATP hydrolytic motor to the proposed DNA rotation.

In vitro reconstitution of the late steps of genetic recombination in E. coli

Purified proteins have been used to reconstitute an in vitro system for the medial-to-late stages of recombination in E. coli. In this system, RecA protein formed recombination intermediates that were processed by the actions of the RuvA, RuvB, and RuvC proteins. RuvAB was found to promote branch migration, to dissociate the RecA filament, and to modulate the orientation of cleavage of Holliday junction resolution by RuvC. Monoclonal antibodies directed against RuvA, RuvB, or RuvC inhibited resolution in the reconstituted system. Specific protein-protein interactions between the branch migration motor (RuvB) and the resolvase (RuvC) were also observed. These results provide evidence for coordinated action during the late stages of recombination, possibly involving the assembly of a RuvABC branch migration/resolution complex.

RecA-catalyzed, sequence-specific alkylation of DNA by cross-linking oligonucleotides. Effects of length and nonhomologous base substitutions

Oligodeoxyribonucleotides (ODNs) bearing the reactive nitrogen mustard chlorambucil have been used as sequence-directed affinity labeling reagents to investigate the length and homology requirements for RecA-catalyzed alkylation of double-stranded DNA. The cross-linkage reaction, which takes place at the N-7 position of a targeted complementary strand guanine following strand exchange, was highly sequence specific with both a 272 bp DNA fragment and a linearized plasmid. Alkylation required the ODN to be at least 26 nucleotides long and to possess homology to the target in the vicinity of the modification site. The extent of alkylation was improved by using longer ODNs, with a 50-mer giving over 50% reaction. Mismatches inhibited alkylation when they perturbed the structure of the strand exchange product near the targeted guanine. Longer heterology also inhibited alkylation when it prevented strand exchange. Our inability to detect cross-linkage in stable synaptic complexes unable to undergo complete strand exchange is best explained by a model for homologous alignment in which the presynaptic filament approaches from the minor groove of the duplex. Since the N-7 position of guanine is in the major groove, it is inaccessible to the tethered chlorambucil group of the ODN during the search for homology. The reaction specificity of chlorambucil-bearing ODNs suggests that they may have general use as recombinase-mediated DNA targeting agents.

Isolation, characterization, and magnesium-induced self-association kinetics of discrete aggregates of RecA protein from Escherichia coli

Dynamic and static intensity light scattering techniques were employed to identify conditions allowing preparation of homogeneous solutions of distinct oligomeric states of RecA protein. These hydrodynamically distinguishable oligomer populations of RecA protein were obtained in homogeneous pure quantities sufficient for physical studies. Results indicate two fairly narrow distributions of RecA oligomers comprised on average of 42 +/- 3 and 18 +/- 1 RecA monomers. These structures, denoted RecA42 and RecA18, respectively, could be obtained reproducibly in milligram quantities and were stable for at least one week. This enabled reliable characterizations of their hydrodynamic properties by dynamic and total intensity light scattering. These measurements revealed RecA42 had an average translational diffusion coefficient, D20(L) = 8 +/- 2 x 10(-8) cm2/s, molecular weight, M(r) = 1.6 +/- 0.1 x 10(6), and radius of gyration, RG = 465 +/- 29 A. The smaller aggregate, RecA18, had D20(S) = 20.5 +/- 2.5 x 10(-8) cm2/s, M(r) = 7.0 +/- 0.4 x 10(5), and RG = 300 +/- 20 A. Heating RecA18 at 37 degrees C overnight resulted in conversion to a species with hydrodynamic properties indistinguishable from RecA42, called RecA18/42. Conversion of RecA42 to RecA18 occurred almost instantaneously by 50% dilution at 38 degrees C or very slowly with incubation at 4 degrees C for at least 39 days. Self-association reactions of the three starting oligomeric states (RecA18, RecA42, and RecA18/42) induced by MgCl2 were monitored at several temperatures by dynamic light scattering. Results of these experiments provided evaluations of kinetic activation parameters of the self-association reactions. The activation parameters found for each starting oligomeric state of the protein were significantly different, revealing the variable influence of MgCl2 on the activation barriers to RecA self-association. Highly aggregated equilibrium solutions that ultimately form in solutions of each starting oligomeric species, incubated in MgCl2 at 38 degrees C for four days, were characterized by total intensity light scattering. Interpretations of these data in terms of characteristic behavior of random polymers suggests the surface morphologies of these highly associated equilibrium states formed from RecA42 and RecA18/42 are similar but contrast with that of RecA18. Calculated values of the translational diffusion coefficient D0 were obtained for oligomeric structures modeled as helical arrays of connected monomer spheres. Best agreement with experimentally determined diffusion coefficients required that constituent monomer spheres of RecA42 have radii 33-40% larger than the monomer spheres of RecA18. Results suggest the hydrodynamically distinct oligomeric forms of RecA may reside in conformational states with different surface exposure of hydrophobic residues, which results in substantial differences in local solvation/hydration.

Structure and function of RecA-DNA complexes

While the E. coli RecA protein has been the most intensively studied enzyme of homologous recombination, the unusual RecA-DNA filament has stood alone until very recently. It now appears that this protein is part of a universal family that spans all of biology, and the filament that is formed by the protein on DNA is a universal structure. With RecA's role in recombination given new and greatly increased significance, we focus in this review on the energetics of the RecA-mediated strand exchange and the relation between the energetics and recombination spanning heterologous inserts.