RecA Homolog Research Articles

New insights into the biological function of BRCA2 from its structural interactions.

Around 50% of all familial breast and ovarian cancers are due to mutations in BRCA1 and BRCA2. Germline mutations in the BRCA2 gene are associated with an increased susceptibility to breast cancer (in both males and females) and they also confer an increased risk of early onset ovarian, prostate, and pancreatic cancer. The biological function of BRCA2 in the cell is still uncertain, although there is increasing evidence for a role in the repair of DNA by homologous recombination. BRCA2 and RAD51 (a homolog of the baterial recombination protein RecA) both co-localise to nuclear foci thought to be sites of DNA damage and repair and these nuclear foci fail to form in BRCA2 deficient cells. Loss of BRCA2 leads to error prone repair of double strand DNA breaks and in dividing cells can lead to chromosomal abberations and loss of genetic information. Compelling evidence of a more direct role for BRCA2 in DNA repair is provided by two recent studies investigating some of the protein's structural interactions.

Ionizing radiation-induced Rad51 nuclear focus formation is cell cycle-regulated and defective in both ATM −/− and c-Abl −/− cells

In eukaryotes, DNA double-strand breaks (DSBs) can be repaired by either non-homologous end-joining (NHEJ) or homologous recombination (HR) pathways. Rad50 protein is a component of the Rad50/NBS1/Mre11 nuclease complex that functions in both the NHEJ and recombinational repair of DNA DSBs. On the other hand, Rad51 protein, a homolog of bacterial RecA and a member of the Rad52 epistasis group, plays a crucial role exclusively in the recombinational repair pathway. We analyzed the effects of cell cycle progression and genetic background on the ionizing radiation (IR)-induced Rad51 and Rad50 repair focus formation. Herein, we demonstrated that IR-induced Rad51, but not Rad50, nuclear focus formation was cell cycle-dependent. Furthermore, IR-induced Rad51 focus formation was defective in AT and c-Abl −/− cells, but not wild type or NBS cells. A decreased and delayed formation of Rad51 foci-containing nuclei was observed in AT cells upon IR, whereas in c-Abl −/− cells a decreased but not delayed formation of Rad51 foci-containing nuclei was observed. In conclusion, effective and prompt IR-induced Rad51 focus formation is cell cycle-regulated and requires both ATM and c-Abl.

Hallmarks of homology recognition by RecA-like recombinases are exhibited by the unrelated Escherichia coli RecT protein.

Homologous recombination is a fundamental process for genome maintenance and evolution. Various proteins capable of performing homology recognition and pairing of DNA strands have been isolated from many organisms. The RecA family of proteins exhibits a number of biochemical properties that are considered hallmarks of homology recognition. Here, we investigated whether the unrelated Escherichia coli RecT protein, which mediates homologous pairing and strand exchange, also exhibits such properties. We found that, like RecA and known RecA homologs: (i) RecT promotes the co-aggregation of ssDNA with duplex DNA, which is known to facilitate homologous contacts; (ii) RecT binding to ssDNA mediates unstacking of the bases, a key step in homology recognition; (iii) RecT mediates the formation of a three-strand synaptic intermediate where pairing is facilitated by local helix destabilization, and the preferential switching of A:T base pairs mediates recognition of homology; and (iv) RecT-mediated pairing occurs from both 3'- and 5'-single-stranded ends. Taken together, our results show that RecT shares fundamental homology-recognition properties with the RecA homologs, and provide new insights on an underlying universal mechanism of homologous recognition.

Physical and Functional Interactions among Basic Chromosome Organizational Features Govern Early Steps of Meiotic Chiasma Formation

Analysis of meiotic recombination by functional genomic approaches reveals prominent spatial and functional interactions among diverse organizational determinants. Recombination occurs between chromatin loop sequences; however, these sequences are spatially tethered to underlying chromosome axes via their recombinosomes. Meiotic chromosomal protein, Red1, localizes to chromosome axes; however, Red1 loading is modulated by R/G-bands isochores and thus by bulk chromatin state. Recombination is also modulated by isochore determinants: R-bands differentially favor double-strand break (DSB) formation but disfavor subsequent loading of meiotic RecA homolog, Dmc1. Red1 promotes DSB formation in both R- and G-bands and then promotes Dmc1 loading, specifically counteracting disfavoring R-band effects. These complexities are discussed in the context of chiasma formation as a series of coordinated local changes at the DNA and chromosome-axis levels.

Mechanisms underlying targeted gene correction using chimeric RNA/DNA and single-stranded DNA oligonucleotides.

Chimeric RNA/DNA oligonucleotides and modified single-stranded oligonucleotides have been developed for site-specific correction of episomal and chromosomal target genes. The gene repair approach relies on specific hybridization of the oligonucleotides to the target gene generating a mismatch with the targeted point mutation. Restored gene function is anticipated to occur through activation of endogenous repair systems that recognize the created mismatch. We present an overview of the gene correction results obtained in several target genes by employing various oligonucleotide designs and a discussion of the possible mechanisms underlying the gene correction techniques. Experimental data suggest that modified single-stranded oligonucleotides form intermediate three-stranded heteroduplexes involving the human RecA homologue, hRad51, whereas chimeric RNA/DNA oligonucleotides may participate in three or four-stranded intermediate structures. Protein factors such as hRad52, hRad54, hRPA, and p53 may modulate the heteroduplex formation and participate in the activation of the endogenous mismatch repair and/or nucleotide excision repair pathway(s). The efficiency of the gene correction process may furthermore be influenced by the differential recognition of mismatches by repair enzymes and possible sequence context effects.

Role of ATP-binding motifs on DNA-binding activity and biological function of Rhp51, a Rad51 homologue in fission yeast.

Rhp51, a RecA and Rad51 homologue of Schizosaccharomyces pombe, plays a pivotal role in homologous recombination and recombinational repair. It has a set of the well-conserved type A and type B ATP-binding motifs, which are highly conserved in all RecA homologues. In a previous study [Kim, Lee, Park, Park and Park (2001) Nucleic Acids Res. 29, 1724-1732], we reported that a single mutation of the conserved lysine in A motif [Lys(155)-->Ala (K155A)] destroyed the DNA repair ability of Rhp51 and that overexpression of this mutant protein conferred dominant negativity. In the present paper, we investigated DNA-binding properties of recombinant Rhp51 and its mutant proteins. Purified Rhp51 protein showed ATP-dependent double- and single-strand DNA-binding activities. To characterize the role of ATP-binding motifs, we generated Rhp51 K155A and Rhp51 Asp(244)-->Gln (D244Q), which have a single amino acid substitution in A and B motifs respectively. Interestingly, K155A and D244Q mutations impaired ATP-dependent DNA binding in a different manner. K155A lost the DNA binding itself, whereas D244Q maintained the binding ability but lost the ATP dependency. However, despite the difference in DNA-binding ability, both mutations failed to rescue the methylmethane sulphonate and UV sensitivity of the rhp51Delta mutant. Together, these results suggested that not only the DNA binding but also the ATP dependence in DNA binding is required for proper in vivo functioning of Rhp51.

Optimising gene repair strategies in cell culture

Gene repair, the precise modification of the genome, offers a number of advantages over replacement gene therapy. In practice, gene targeting strategies are limited by the inefficiency of homologous recombination in mammalian cells. A number of strategies, including RNA-DNA oligonucleotides (RDOs) and short DNA fragments (SDFs), show promise in improving the efficiency of gene correction. We are using GFP as a reporter for gene repair in living cells. A single base substitution was introduced into GFP to create a nonsense mutation (STOP codon, W399X). RDOs and SDFs are used to repair this mutation episomally in transient transfections and restore green fluorescence. The correction efficiency is determined by FACS analysis. SDFs appear to correct GFP W399X in a number of different cell lines (COS7, A549, HT1080, HuH-7), although all at a similar low frequency ( approximately 0.6% of transfected cells). RDOs correct only one of our cell lines significantly (HT1080-RAD51), these cells overexpress the human RAD51 gene; the bacterial RecA homologue. The GFP W399X reporter is a fusion gene with hygromycin (at the 5' end), this has allowed us to make stable cell lines (A549, HT1080) to study genomic correction. Initial studies using our correction molecules show only low efficiencies of genomic repair ( approximately 10(-4)). Polyethylenimine (PEI) is used to deliver RDOs and SDFs into mammalian cells in culture for our study. We have used fluorescently labelled RDOs and SDFs to study the effectiveness of this process. FACS analysis of transfected nuclei implied efficient delivery (>90%) both with SDFs and RDOs. However, confocal fluorescence microscopy suggests that a large proportion of the complexed RDO/SDF appears to remain outside the nucleus (or attached to the nuclear membrane). On the basis of these data we are assessing new delivery methods and factors that may alter recombination status to optimise gene repair.

Biochemical Characterization of the Human RAD51 Protein: III. MODULATION OF DNA BINDING BY ADENOSINE NUCLEOTIDES

Adenosine nucleotides affect the ability of RecA small middle dotsingle-stranded DNA (ssDNA) nucleoprotein filaments to cooperatively assume and maintain an extended structure that facilitates DNA pairing during recombination. Here we have determined that ADP and ATP/ATPgammaS affect the DNA binding and aggregation properties of the human RecA homolog human RAD51 protein (hRAD51). These studies have revealed significant differences between hRAD51 and RecA. In the presence of ATPgammaS, RecA forms a stable complex with ssDNA, while the hRAD51 ssDNA complex is destabilized. Conversely, in the presence of ADP and ATP, the RecA ssDNA complex is unstable, while the hRAD51 ssDNA complex is stabilized. We identified two hRAD51 small middle dotssDNA binding forms by gel shift analysis, which were distinct from a well defined RecA small middle dotssDNA binding form. The available evidence suggests that a low molecular weight hRAD51 small middle dotssDNA binding form (hRAD51 small middle dotssDNA(low)) correlates with active ADP and ATP processing. A high molecular weight hRAD51 small middle dotssDNA aggregate (hRAD51 small middle dotssDNA(high)) appears to correlate with a form that fails to process ADP and ATP. Our data are consistent with the notion that hRAD51 is unable to appropriately coordinate ssDNA binding with adenosine nucleotide processing. These observations suggest that other factors may assist hRAD51 in order to mirror RecA recombinational function.

Biochemical Characterization of the Human RAD51 Protein: I. ATP HYDROLYSIS

The prototypical bacterial RecA protein promotes recombination/repair by catalyzing strand exchange between homologous DNAs. While the mechanism of strand exchange remains enigmatic, ATP-induced cooperativity between RecA protomers is critical for its function. A human RecA homolog, human RAD51 protein (hRAD51), facilitates eukaryotic recombination/repair, although its ability to hydrolyze ATP and/or promote strand exchange appears distinct from the bacterial RecA. We have quantitatively examined the hRAD51 ATPase. The catalytic efficiency (k(cat)/K(m)) of the hRAD51 ATPase was approximately 50-fold lower than the RecA ATPase. Altering the ratio of DNA/hRAD51 and including salts that stimulate DNA strand exchange (ammonium sulfate and spermidine) were found to affect the catalytic efficiency of hRAD51. The average site size of hRAD51 was determined to be approximately 3 nt (bp) for both single-stranded and double-stranded DNA. Importantly, hRAD51 lacks the magnitude of ATP-induced cooperativity that is a hallmark of RecA. Together, these results suggest that hRAD51 may be unable to coordinate ATP hydrolysis between neighboring protomers.

3 Homologous chromosome associations and nuclear order in meiotic and mitotically dividing cells of budding yeast

This chapter discusses the relationship between nuclear order and the association of homologous DNA sequences in the budding yeast, Saccharomyces cerevisiae. Homologous chromosomes functionally interact with one another to repair DNA double-strand breaks (DSBs) introduced either environmentally (e.g., by gamma-irradiation) or deliberately by the cell (e. g., during meiosis). DNA homology recognition in these instances often involves the (RecA) homolog RAD51 and/or the related gene, DMC1. Evidence for interactions between homologous chromosomes occurring independent of DSB formation and (RecA) homolog function has also been described in meiotic, premeiotic, and mitotically dividing cells of yeast. These interactions presumably depend upon DNA homology but the molecular details of such associations are poorly understood. Both DSB-dependent and -independent homolog associations may be facilitated by the nonrandom organization of chromosomes in the nucleus, including centromere and telomere clustering, which are also discussed.

Archaeal RadA protein binds DNA as both helical filaments and octameric rings

The Escherichia coli RecA protein has been a model for understanding homologous eukaryotic recombination proteins such as Rad51. The active form of both RecA and Rad51 appear to be helical filaments polymerized on DNA, in which an unusual helical structure is induced in the DNA. Surprisingly, the human meiosis-specific homolog of RecA, Dmc1, has thus far only been observed to bind DNA as an octameric ring. Sequence analysis and biochemical studies have shown that archaeal RadA proteins are more closely related to Rad51 and Dmc1 than the bacterial RecA proteins. We find that the Sulfolobus solfataricus RadA protein binds DNA in the absence of nucleotide cofactor as an octameric ring and in the presence of ATP as a helical filament. Since it is likely that RadA is closely related to a common ancestral protein of both Rad51 and Dmc1, the two DNA-binding forms of RadA may provide insight into the divergence that has taken place between Rad51 and Dmc1.

BCR/ABL Regulates Mammalian RecA Homologs, Resulting in Drug Resistance

RAD51 is one of six mitotic human homologs of the E. coli RecA protein (RAD51-Paralogs) that play a central role in homologous recombination and repair of DNA double-strand breaks (DSBs). Here we demonstrate that RAD51 is important for resistance to cisplatin and mitomycin C in cells expressing the BCR/ABL oncogenic tyrosine kinase. BCR/ABL significantly enhances the expression of RAD51 and several RAD51-Paralogs. RAD51 overexpression is mediated by a STAT5-dependent transcription as well as by inhibition of caspase-3-dependent cleavage. Phosphorylation of the RAD51 Tyr-315 residue by BCR/ABL appears essential for enhanced DSB repair and drug resistance. Induction of the mammalian RecA homologs establishes a unique mechanism for DNA damage resistance in mammalian cells transformed by an oncogenic tyrosine kinase.

Saccharomyces cerevisiae Dmc1 protein promotes renaturation of single-strand DNA (ssDNA) and assimilation of ssDNA into homologous super-coiled duplex DNA.

Dmc1 and Rad51 are eukaryotic RecA homologues that are involved in meiotic recombination. The expression of Dmc1 is limited to meiosis, whereas Rad51 is expressed in mitosis and meiosis. Dmc1 and Rad51 have unique and overlapping functions during meiotic recombination. Here we report the purification of the Dmc1 protein from the budding yeast Saccharomyces cerevisiae and present basic characterization of its biochemical activity. The protein has a weak DNA-dependent ATPase activity and binds both single-strand DNA (ssDNA) and double-strand DNA. Electrophoretic mobility shift assays suggest that DNA binding by Dmc1 is cooperative. Dmc1 renatures linearized plasmid DNA with first order reaction kinetics and without requiring added nucleotide cofactor. In addition, Dmc1 catalyzes strand assimilation of ssDNA oligonucleotides into homologous supercoiled duplex DNA in a reaction promoted by ATP or the non-hydrolyzable ATP analogue AMP-PNP.

Archaeal RecA homologues: different response to DNA-damaging agents in mesophilic and thermophilic Archaea.

Two archaeal proteins, RadA and RadB, share similarity with the RecA/Rad51 family of recombinases, with RadA being the functional homologue. We have studied and compared the RadA and RadB proteins of mesophilic and thermophilic Archaea. In growing cells, RadA levels are similar in mesophilic Methanococcus species and the hyperthermophile Methanococcus jannaschii. Treatment of cells with mutagenic agents (methylmethane sulfonate or UV light) increased the expression of RadA (as evidenced by higher levels of both mRNA and protein) in all organisms tested, but the increase was greater in the mesophiles than in the thermophiles M. jannaschii and Sulfolobus solfataricus. Recombinantly expressed RadA proteins from the mesophile M. voltae and the thermophile M. jannaschii were similar in their ATPase- and DNA-binding activities. All the data are consistent with proposals that RadA plays the same role as eukaryotic Rad51. Surprisingly, the data also suggested that the thermophiles do not need more RadA protein or activity than the mesophiles. On the other hand, RadB is not coregulated with RadA, and its role remains unclear. Neither RadA nor RadB from a mesophile or from a thermophile rescued the UV-sensitive phenotype of an Escherichia coli recA- host.

Isolation, Characterization, and Expression Patterns of a DMC1 Homolog from the Basidiomycete Pleurotus ostreatus

Here we describe the isolation of a Pleurotus ostreatus gene PoDMC1. The predicted amino acid sequence of the oyster mushroom gene is 62% identical to the yeast DMC1 and 60% identical to human DMC1. The highest degree of amino acid identity (88%), however, was shown with Coprinus CoLIM15, a DMC1 homolog recently found in Coprinus cinereus. The exact matching of sizes and positions of most introns in both basidiomycete genes underlines the close relationship between these DMC1 orthologs. The RecA homolog DMC1 from yeast and its orthologs from other species have been reported to be meiosis specific and essential for sporulation. Here we show that PoDMC1 is exclusively expressed in the lamellae/basidiospore fraction of fruit bodies and not in somatic cells of fruiting bodies or in vegetative mycelium. Furthermore, the gene is not expressed in the lamellae/basidiospore fraction of a nonsporulating mutant of P. ostreatus. Since one of the major problems in cultivating the oyster mushroom is the abundant sporulation that causes allergic reactions in man, PoDMC1 could be an important target gene in constructing sporeless Pleurotus strains.

Chromosomal instability and cancer predisposition: insights from studies on the breast cancer susceptibility gene BRCA2

Inherited mutations in the breast cancer susceptibility gene BRCA2 predispose to breast, ovarian and other cancers. BRCA2 encodes a 3418-amino-acid protein that localizes to the nucleus of dividing cells. The biological functions of the protein and its role in tumour suppression remain uncertain. We have identified an essential function for BRCA2 in DNA repair by homologous recombination. In BRCA2-deficient cells, DNA breaks introduced into chromosomal substrates are inefficiently repaired by homology-directed mechanisms, although repair by nonhomologous end-joining is unaffected. BRCA2 interacts with the RAD51 recombination protein, a functional homolog of bacterial RecA. The correct intracellular localization and function of RAD51 are dependent upon BRCA2, suggesting a mechanistic basis for its role in repair. Loss of BRCA2 induces chromosomal instability characterized by spontaneous breakage, in appropriate mitotic exchanges and chromosomal fusions. Evidence will be presented that the repair of DNA breaks that arise spontaneously during DNA replication require BRCA2 for their error-free resolution. Loss of this function may foster carcinogenesis by increasing the rate of spontaneous mutation. Paradoxically, BRCA2-deficient cells undergo cell cycle arrest rather than the unrestrained proliferation that is typical of neoplastic transformation. We find that mutations inactivating cell cycle checkpoints that regulate assembly of the mitotic spindle reverse proliferative arrest, and foster transformation, in BRCA2-deficient cells. These findings have implications not only for the evolution of tumours following BRCA2 loss, but also for the mechanisms by which cells perceive and respond to chromosome breakage.

Role of Interaction between Two Silkworm RecA Homologs in Homologous DNA Pairing

Recombinant BmRad51 and BmDmc1, silkworm homologs of the Escherichia coli RecA proteins catalyzing the homologous DNA pairing, were purified from E. coli cells carrying expression vectors. These possessed different enzymatic properties in the joint molecule formation between single-stranded circular DNA and homologous linear double-stranded DNA. The requirement of single-stranded circular DNA for the efficient reaction was twofold higher in BmRad51 than in BmDmc1. Although able to mediate the joint molecule formation independently, a complex of the two enzymes formed prior to single-stranded DNA binding was found to have augmented efficiency of the pairing reaction.

A RecA homologue in Ustilago maydis that is distinct and evolutionarily distant from Rad51 actively promotes DNA pairing reactions in the absence of auxiliary factors.

Two RecA homologues have been identified to date in Ustilago maydis. One is orthologous to Rad51 while the other, Rec2, is structurally quite divergent and evolutionarily distant. DNA repair and recombination proficiency in U. maydis requires both Rec2 and Rad51. Here we have examined biochemical activities of Rec2 protein purified after overexpression of the cloned gene. Rec2 requires DNA as a cofactor to hydrolyze ATP and depends on ATP to promote homologous pairing and DNA strand exchange. ATPgammaS was found to substitute for ATP in all pairing reactions examined. With superhelical DNA and a homologous single-stranded oligonucleotide as substrates, Rec2 actively promoted formation and dissociation of D-loops. When an RNA oligonucleotide was substituted it was found that R-loops could also be formed and utilized as primer/template for limited DNA synthesis. In DNA strand exchange reactions using oligonucleotides, we found that Rec2 exhibited a pairing bias that is opposite that of RecA. Single-stranded oligonucleotides were activated for DNA strand exchange when attached as tails protruding from a duplex sequence due to enhanced binding of Rec2. The results indicate that Rec2 is competent, and in certain ways even better than Rad51, in the ability to provide the fundamental DNA pairing activity necessary for recombinational repair. We propose that the emerging paradigm for homologous recombination featuring Rad51 as the essential catalytic component for strand exchange may not be universal in eukaryotes.

An Aspergillus nidulans uvsC null mutant is deficient in homologous DNA integration.

The Aspergillus nidulans uvsC gene was identified as a homolog of RAD51 and recA of Saccharomyces cerevisiae and Escherichia coli, respectively, whose role in genetic recombination and recombinational repair has been extensively studied. Like many other filamentous fungi, A. nidulans shows no bias towards either homologous or ectopic integration of exogenous DNA. Therefore it is a unique and useful organism for the study of the mechanisms of DNA integration. Homologous integration of a 1.7-kb argB gene was not detected in 50 transformants obtained from a uvsC null mutant. In contrast, the frequency of homologous integration in uvsC+ control strains varied from 41 to 86%. Another feature observed with the uvsC null mutant was that an increased number of transformants had undergone ectopic integrations at multiple sites in the genome. These results are consistent with the established function of Rad51/RecA, and further indicate the involvement of redundant pathways in integration of exogenous DNA. This study provides direct evidence for the involvement of uvsC in exogenous DNA integration and should contribute to the improvement of genetic manipulations in general, but particularly in fungi.

Tid1/Rdh54 promotes colocalization of rad51 and dmc1 during meiotic recombination.

Two RecA homologs, Rad51 and Dmc1, assemble as cytologically visible complexes (foci) at the same sites on meiotic chromosomes. Time course analysis confirms that co-foci appear and disappear as the single predominant form. A large fraction of co-foci are eliminated in a red1 mutant, which is expected as a characteristic of the interhomolog-specific recombination pathway. Previous studies suggested that normal Dmc1 loading depends on Rad51. We show here that a mutation in TID1/RDH54, encoding a RAD54 homolog, reduces Rad51-Dmc1 colocalization relative to WT. A rad54 mutation, in contrast, has relatively little effect on RecA homolog foci except when strains also contain a tid1/rdh54 mutation. The role of Tid1/Rdh54 in coordinating RecA homolog assembly may be very direct, because Tid1/Rdh54 is known to physically bind both Dmc1 and Rad51. Also, Dmc1 foci appear early in a tid1/rdh54 mutant. Thus, Tid1 may normally act with Rad51 to promote ordered RecA homolog assembly by blocking Dmc1 until Rad51 is present. Finally, whereas double-staining foci predominate in WT nuclei, a subset of nuclei with expanded chromatin exhibit individual Rad51 and Dmc1 foci side-by-side, suggesting that a Rad51 homo-oligomer and a Dmc1 homo-oligomer assemble next to one another at the site of a single double-strand break (DSB) recombination intermediate.