Project description:Homologous recombination (HR) is an ubiquitous DNA double-strand break (DSB) repair mechanism. It entails a homology search step, carried out along a conserved RecA/Rad51-ssDNA nucleoprotein filament (NPF) assembled on each DSB ends. In contrast to the extensive knowledge of DNA damage checkpoint (DDC)-induced changes in chromatin composition and mobility,  the questions of if, how, and to what extent a DSB impacts the spatial organization of chromatin, and whether this organization in turn influences the homology search process, remain ill-defined. Here we characterize two layers of spatial chromatin reorganization following DSB formation in S. cerevisiae. While cohesin folds chromosomes into cohesive arrays of ~20 kb-long chromatin loops as cells arrest in G2/M, the DSB-flanking regions interact locally in a resection- and 9-1-1 clamp-dependent manner, independently of cohesin, Mec1ATR, Rad52 and Rad51. This local structure blocks cohesin progression, constraining the DSB region at the base of a loop. Functionally, cohesin promotes DSB-dsDNA interactions and donor identification in cis, while inhibiting them in trans. This study identifies multiple direct and indirect ways by which cohesin regulates homology search during HR repair. 

Project description:Homologous recombination (HR) is an ubiquitous DNA double-strand break (DSB) repair mechanism. It entails a homology search step, carried out along a conserved RecA/Rad51-ssDNA nucleoprotein filament (NPF) assembled on each DSB ends. In contrast to the extensive knowledge of DNA damage checkpoint (DDC)-induced changes in chromatin composition and mobility,  the questions of if, how, and to what extent a DSB impacts the spatial organization of chromatin, and whether this organization in turn influences the homology search process, remain ill-defined. Here we characterize two layers of spatial chromatin reorganization following DSB formation in S. cerevisiae. While cohesin folds chromosomes into cohesive arrays of ~20 kb-long chromatin loops as cells arrest in G2/M, the DSB-flanking regions interact locally in a resection- and 9-1-1 clamp-dependent manner, independently of cohesin, Mec1ATR, Rad52 and Rad51. This local structure blocks cohesin progression, constraining the DSB region at the base of a loop. Functionally, cohesin promotes DSB-dsDNA interactions and donor identification in cis, while inhibiting them in trans. This study identifies multiple direct and indirect ways by which cohesin regulates homology search during HR repair. 

Project description:The formation of RAD51/DMC1 filaments on single-stranded (ss)DNAs, which is essential for homology search and strand exchange in DNA double-strand break (DSB) repair and for the protection of stalled DNA replication forks, is tightly regulated in time and space. FIGNL1 AAA+++ ATPase plays positive and negative roles in the RAD51-mediated recombination in human cells. However, the role of FIGNL1 in gametogenesis remains unsolved. Here, we characterized a germ-line-specific conditional knockout (cKO) mouse of FIGNL1. The Fignl1 cKO male mice showed defective chromosome synapsis and impaired meiotic DSB repair with the accumulation of RAD51/DMC1 on chromosomes in mid-meiotic prophase I, supporting a role of FIGNL1 in a post-assembly stage of RAD51/DMC1 filaments. Fignl1 cKO spermatocytes accumulate RAD51 and DMC1 ensembles on chromosomes not only in early meiotic prophase I but also in meiotic S-phase. These RAD51/DMC1 assemblies are independent of meiotic DSB formation. Finally, we showed that purified FIGNL1 dismantles RAD51 filament on double-stranded (ds)DNA as well as ssDNA. These results suggest a critical role of FIGNL1 to limit the uncontrolled assembly of RAD51 and DMC1 on native dsDNAs during the meiotic S-phase and meiotic prophase I.

Project description:Eukaryotic cells respond to DNA double-strand breaks (DSBs) by activating a checkpoint that depends on the protein kinases Tel1/ATM and Mec1/ATR. Mec1/ATR is activated by RPA-coated single-stranded DNA (ssDNA), which arises upon nucleolytic degradation (resection) of the DSB. Emerging evidences indicate that RNA processing factors play critical, yet poorly understood, roles in genomic stability. Here, we provide evidence that the Saccharomyces cerevisiae RNA decay factors Xrn1, Rrp6 and Trf4 regulate Mec1/ATR activation by promoting generation of RPA-coated ssDNA. The lack of Xrn1 inhibits ssDNA generation at the DSB by preventing the loading of the MRX complex. By contrast, DSB resection is not affected in the absence of Rrp6 or Trf4, but their lack impairs the recruitment of RPA, and therefore of Mec1, to the DSB. Rrp6 and Trf4 inactivation affects neither Rad51/Rad52 association nor DSB repair by HR, suggesting that full Mec1 activation requires higher amount of RPA-coated ssDNA than HR-mediated repair. Noteworthy, deep transcriptome analyses do not identify common misregulated gene expression that could explain the observed phenotypes. Our results provide a novel link between RNA processing and genome stability. Strand-specific transcriptome analysis of biological replicates of WT cells (JKM139 strain) at T0, or 60 and 240 minutes after HO induction, and of xrn1∆, rrp6∆ and trf4∆ cells at T0.

Project description:Eukaryotic cells respond to DNA double-strand breaks (DSBs) by activating a checkpoint that depends on the protein kinases Tel1/ATM and Mec1/ATR. Mec1/ATR is activated by RPA-coated single-stranded DNA (ssDNA), which arises upon nucleolytic degradation (resection) of the DSB. Emerging evidences indicate that RNA processing factors play critical, yet poorly understood, roles in genomic stability. Here, we provide evidence that the Saccharomyces cerevisiae RNA decay factors Xrn1, Rrp6 and Trf4 regulate Mec1/ATR activation by promoting generation of RPA-coated ssDNA. The lack of Xrn1 inhibits ssDNA generation at the DSB by preventing the loading of the MRX complex. By contrast, DSB resection is not affected in the absence of Rrp6 or Trf4, but their lack impairs the recruitment of RPA, and therefore of Mec1, to the DSB. Rrp6 and Trf4 inactivation affects neither Rad51/Rad52 association nor DSB repair by HR, suggesting that full Mec1 activation requires higher amount of RPA-coated ssDNA than HR-mediated repair. Noteworthy, deep transcriptome analyses do not identify common misregulated gene expression that could explain the observed phenotypes. Our results provide a novel link between RNA processing and genome stability.

Project description:DNA double-strand breaks (DSBs) initiate meiotic recombination. Past DSB-mapping studies have used rad50S or sae2? mutants, which are defective in break processing, to accumulate DSBs, and report large (= 50 kb) “DSB-hot” regions that are separated by “DSB-cold” domains of similar size. Substantial recombination occurs in some DSB-cold regions, suggesting that DSB patterns are not normal in rad50S or sae2? mutants. We therefore developed novel methods that detect DSBs using ssDNA enrichment and microarray hybridization, and that use background-based normalization to allow cross-comparison between array datasets, to map genome-wide the DSBs that accumulate in processing-capable, repair-defective dmc1î and dmc1î rad51î mutants. DSBs were observed at known hotspots, but also in most previously-identified “DSB-cold” regions, including near centromeres and telomeres. While about 40% of the genome is DSB-cold in rad50S mutants, analysis of meiotic ssDNA from dmc1? shows that most of these regions have significant DSB activity. Thus, DSBs are distributed much more uniformly than was previously believed. Southern-blot assays of DSBs in selected regions in dmc1?, rad50S and wild-type cells confirm these findings. Comparisons of DSB signals in dmc1, dmc1 rad51, and dmc1 spo11 mutant strains identify Dmc1 as the primary strand transfer activity genome-wide, and Spo11-induced lesions as initiating all meiotic recombination. Keywords: DSB mapping, ChIP-chip, single strand DNA , BND cellulose We use two different strategies to map the genome-wide distribution of meiotic DSBs in the yeast Saccharomyces cerevisiae. The first is a chromatin immunoprecipitation (ChIP) based approach that targets the Spo11p protein, which remains covalently attached to DSB ends in the rad50S mutant background. The second approach involves BND cellulose enrichment of the single strand DNA (ssDNA) recombination intermediate formed by end-resection at DSB sites following Spo11p removal. We use dmc1 and dmc1 rad51 mutants that accumulates meiotic single strand DNA intermediates

Project description:Homologous recombination (HR) is crucial for genetic exchange, accurate repair of DNA double-strand breaks and pivotal for genome integrity. HR uses homologous sequences for repair, but how homology search, the exploration of the genome for homologous DNA sequences, is conducted in the nucleus remains poorly understood. Here, we use time-resolved chromatin immunoprecipitations of repair proteins to monitor homology search in vivo. We found that homology search proceeds by a probing mechanism, which commences around the break and samples preferentially on the broken chromosome. However, elements thought to instruct chromosome loops mediate homology search shortcuts, and centromeres, which cluster within the nucleus, may facilitate homology search on other chromosomes. Our study thus revealed crucial parameters for homology search in vivo and emphasizes the importance of linear distance, chromosome architecture and proximity for recombination efficiency. 2 new custom ChIP-chip platforms used; both Nimblegen; differ in oligo density: (platform 1: 2006-07-18_Scerevisiae_ChIP_Stefan Jentsch MPI Biochemistry S.cerevisiae 385K Tiling Array Version 1) ( platform 2: 100304_Scer2_MS_Chip_Stefan Jentsch MPI Biochemistry S.cerevisiae 135K Tiling Array Version 2) ChIP-chip profiling of DSB repair factors (Rad51, Rad52, RPA, gamma-H2A) upon single inducible DSBs in S.cerevisiae

Project description:AID promotes chromosomal translocations by inducing DNA double-strand breaks (DSBs) at immunoglobulin (Ig) genes and oncogenes in G1. RPA is a ssDNA-binding protein that associates with resected DSBs in the S phase and facilitates the assembly of factors involved in homologous repair (HR) such as Rad51. Notably, RPA deposition also marks sites of AID-mediated damage, but its role in Ig gene recombination remains unclear. Here we demonstrate that RPA associates asymmetrically with resected ssDNA in response to lesions created by AID, RAG, or other nucleases. Small amounts of RPA are deposited at AID targets in G1 in an ATM-dependent manner. In contrast, recruitment in S-G2/M is extensive, ATM-independent, and associated with Rad51 accumulation. RPA in S-G2/M increases in NHEJ-deficient lymphocytes, where there is more extensive DNA-end resection. Thus, most RPA recruitment during CSR represents salvage of un-repaired breaks by homology-based pathways during the S-G2/M phases of the cell cycle. Chip-Seq of RPA from mouse activated B cells (n = 40), mouse thymocytes (n = 6), and MEFs (n = 1). Different genotypes and/or inhibitors were used.

Project description:AID promotes chromosomal translocations by inducing DNA double-strand breaks (DSBs) at immunoglobulin (Ig) genes and oncogenes in G1. RPA is a ssDNA-binding protein that associates with resected DSBs in the S phase and facilitates the assembly of factors involved in homologous repair (HR) such as Rad51. Notably, RPA deposition also marks sites of AID-mediated damage, but its role in Ig gene recombination remains unclear. Here we demonstrate that RPA associates asymmetrically with resected ssDNA in response to lesions created by AID, RAG, or other nucleases. Small amounts of RPA are deposited at AID targets in G1 in an ATM-dependent manner. In contrast, recruitment in S-G2/M is extensive, ATM-independent, and associated with Rad51 accumulation. RPA in S-G2/M increases in NHEJ-deficient lymphocytes, where there is more extensive DNA-end resection. Thus, most RPA recruitment during CSR represents salvage of un-repaired breaks by homology-based pathways during the S-G2/M phases of the cell cycle.

Project description:In a first step of DNA double-strand break (DSB) repair by homologous recombination, DNA ends are resected such that single-stranded DNA (ssDNA) overhangs are generated. ssDNA is specifically bound by RPA and other factors, which constitutes a ssDNA-compartment on damaged chromatin. The molecular organization of this ssDNA- as well as the adjacent dsDNA-compartment is crucial during DSB signaling and repair. However, data regarding the association of the most basic chromatin components – the nucleosomes – have been discrepant. Here, we use site-specific induction of DSBs and chromatin-immunoprecipitation followed by strand-specific sequencing to analyse in vivo binding of key DSB repair and signalling proteins to either the ssDNA- or dsDNA-compartment. In case of nucleosomes, we show that recently proposed ssDNA-nucleosomes are not a major, persistent species, but that nucleosomes eviction and DNA end resection are intrinsically coupled. These results support a model of separated dsDNA-nucleosome- and ssDNA-RPA-compartments during DSB signaling and repair.