Bloom's syndrome (BS) is[Keywords: Bloom's syndrome; BLM helicase; homologous recombination; Rad51; RecQ; Rad54] Supplemental material is available at http://www.genesdev.org.
Human Rad51 (hRad51) protein plays a key role in homologous recombination and DNA repair. hRad51 protein forms a helical filament on single-stranded DNA (ssDNA), which performs the basic steps of homologous recombination: a search for homologous double-stranded DNA (dsDNA) and DNA strand exchange. hRad51 protein possesses DNA-dependent ATPase activity; however, the role of this activity has not been understood. Our current results show that Ca 2؉ greatly stimulates DNA strand exchange activity of hRad51 protein. We found that Ca 2؉ exerts its stimulatory effect by modulating the ATPase activity of hRad51 protein.Our data demonstrate that, in the presence of Mg 2؉ , the hRad51-ATP-ssDNA filament is quickly converted to an inactive hRad51-ADP-ssDNA form, due to relatively rapid ATP hydrolysis and slow dissociation of ADP. Ca 2؉ maintains the active hRad51-ATP-ssDNA filament by reducing the ATP hydrolysis rate. These findings demonstrate a crucial role of the ATPase activity in regulation of DNA strand exchange activity of hRad51 protein. This mechanism of Rad51 protein regulation by modulating its ATPase activity is evolutionarily recent; we found no such mechanism for yeast Rad51 (yRad51) protein.
Homologous recombination (HR) is a molecular process that plays multiple important roles in DNA metabolism, both for DNA repair and genetic variation in all forms of life1. Generally, HR involves exchange of genetic information between two identical or nearly identical DNA molecules1; however, HR can also occur between RNA molecules, as shown for RNA viruses2. Previous research showed that synthetic RNA oligonucleotides (oligos) can template DNA double-strand break (DSB) repair in yeast and human cells3,4, and artificial long RNA templates injected in ciliate cells can guide genomic rearrangements5. Here we report that endogenous transcript RNA mediates HR with chromosomal DNA in yeast Saccharomyces cerevisiae. We developed a system to detect events of HR initiated by transcript RNA following repair of a chromosomal DSB occurring either in a homologous but remote locus (in trans), or in the same transcript-generating locus (in cis) in reverse transcription defective yeast strains. We found that RNA-DNA recombination is blocked by ribonucleases (RNases) H1 and H2. In the presence of RNases H, DSB repair proceeds through a cDNA intermediate, whereas in their absence, it proceeds directly through RNA. The proximity of the transcript to its chromosomal DNA partner in cis facilitates Rad52-driven HR during DSB repair. In accord, we demonstrate that yeast and human Rad52 proteins efficiently catalyze annealing of RNA to a DSB-like DNA end in vitro. Our results reveal a novel mechanism of HR and DNA repair templated by transcript RNA. Thus, considering the abundance of RNA transcripts in cells, the impact of RNA on genomic stability and plasticity could be vast.
Rad51 and Rad54 proteins are important for the repair of double-stranded DNA (dsDNA) breaks by homologous recombination in eukaryotes. Rad51 assembles on single-stranded DNA (ssDNA) to form a helical nucleoprotein filament that performs homologous pairing with dsDNA; Rad54 stimulates this pairing substantially. Here, we demonstrate that Rad54 acts in concert with the mature Rad51-ssDNA filament. Enhancement of DNA pairing by Rad54 is greatest at an equimolar ratio relative to Rad51 within the filament. Reciprocally, the Rad51-ssDNA filament enhances both the dsDNA-dependent ATPase and the dsDNA unwinding activities of Rad54. We conclude that Rad54 participates in the DNA homology search as a component of the Rad51-nucleoprotein filament and that the filament delivers Rad54 to the dsDNA pairing locus, thereby linking the unwinding of potential target DNA with the homology search process.
Homologous recombination has a crucial function in the repair of DNA double-strand breaks and in faithful chromosome segregation. The mechanism of homologous recombination involves the search for homology and invasion of the ends of a broken DNA molecule into homologous duplex DNA to form a cross-stranded structure, a Holliday junction (HJ). A HJ is able to undergo branch migration along DNA, generating increasing or decreasing lengths of heteroduplex. In both prokaryotes and eukaryotes, the physical evidence for HJs, the key intermediate in homologous recombination, was provided by electron microscopy. In bacteria there are specialized enzymes that promote branch migration of HJs. However, in eukaryotes the identity of homologous recombination branch-migration protein(s) has remained elusive. Here we show that Rad54, a Swi2/Snf2 protein, binds HJ-like structures with high specificity and promotes their bidirectional branch migration in an ATPase-dependent manner. The activity seemed to be conserved in human and yeast Rad54 orthologues. In vitro, Rad54 has been shown to stimulate DNA pairing of Rad51, a key homologous recombination protein. However, genetic data indicate that Rad54 protein might also act at later stages of homologous recombination, after Rad51 (ref. 13). Novel DNA branch-migration activity is fully consistent with this late homologous recombination function of Rad54 protein.
SWI2/SNF2 chromatin-remodeling proteins mediate the mobilization of nucleosomes and other DNA-associated proteins. SWI2/SNF2 proteins contain sequence motifs characteristic of SF2 helicases but do not have helicase activity. Instead, they couple ATP hydrolysis with the generation of superhelical torsion in DNA. The structure of the nucleosome-remodeling domain of zebrafish Rad54, a protein involved in Rad51-mediated homologous recombination, reveals that the core of the SWI2/SNF2 enzymes consist of two alpha/beta-lobes similar to SF2 helicases. The Rad54 helicase lobes contain insertions that form two helical domains, one within each lobe. These insertions contain SWI2/SNF2-specific sequence motifs likely to be central to SWI2/SNF2 function. A broad cleft formed by the two lobes and flanked by the helical insertions contains residues conserved in SWI2/SNF2 proteins and motifs implicated in DNA-binding by SF2 helicases. The Rad54 structure suggests that SWI2/SNF2 proteins use a mechanism analogous to helicases to translocate on dsDNA.
RAD51 is a key protein of homologous recombination that plays a critical role in the repair of DNA double-strand breaks (DSB) and interstrand cross links (ICL). To better understand the cellular function(s) of human RAD51, we propose to develop specific RAD51 inhibitors. RAD51 inhibitors may also help to increase the potency of anticancer drugs that act by inducing DSBs or ICLs, e.g., cisplatin or ionizing radiation. In vitro, RAD51 promotes DNA strand exchange between homologous ss- and dsDNA. Here, we developed a DNA strand exchange assay based on fluorescence resonance energy transfer and used this assay to identify RAD51 inhibitors by high throughput screening of the NIH Small Molecule Repository (>200,000 compounds). Seventeen RAD51 inhibitors were identified and analyzed for selectivity using additional non-fluorescent DNA-based assays. As a result, we identified a compound (B02) that specifically inhibited human RAD51 (IC50 = 27.4 μM), but not its E. coli homologue RecA (IC50 > 250 μM). Two other compounds (A03 and A10) were identified that inhibited both RAD51 and RecA, but not the structurally unrelated RAD54 protein. The structure-activity relationship (SAR) analysis allowed us to identify the structural components of B02 that are critical for RAD51 inhibition. The described approach can be used for identification of specific inhibitors of other human proteins that play an important role in DNA repair, e.g., RAD54 or Bloom’s syndrome helicase.
Rad52 promotes the annealing of complementary strands of DNA bound by replication protein A (RPA) during discrete repair pathways. Here, we used a fluorescence resonance energy transfer (FRET) between two fluorescent dyes incorporated into DNA substrates to probe the mechanism by which human Rad52 (hRad52) interacts with and mediates annealing of ssDNA–hRPA complexes. Human Rad52 bound ssDNA or ssDNA–hRPA complex in two, concentration-dependent modes. At low hRad52 concentrations, ssDNA was wrapped around the circumference of the protein ring, while at higher protein concentrations, ssDNA was stretched between multiple hRad52 rings. Annealing by hRad52 occurred most efficiently when each complementary DNA strand or each ssDNA–hRPA complex was bound by hRad52 in a wrapped configuration, suggesting homology search and annealing occur via two hRad52–ssDNA complexes. In contrast to the wild type protein, hRad52RQK/AAA and hRad521–212 mutants with impaired ability to bind hRPA protein competed with hRPA for binding to ssDNA and failed to counteract hRPA-mediated duplex destabilization highlighting the importance of hRad52-hRPA interactions in promoting efficient DNA annealing.
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