Project description:Meiotic homologous recombination is a critical DNA-templated event for sexually-reproducing organisms. It is initiated by a programmed formation of DNA double strand breaks (DSBs), mainly formed at recombination hotspots, and is, like all other DNA-related processes, under great influence of chromatin structure. For example, local chromatin around hotspots directly impacts DSB formation. In addition, DSB is proposed to occur in a higher-order chromatin architecture termed “axis-loop”, in which many loops protrude from proteinaceous axis. Despite many recent insightful studies, still much remains unknown about how meiotic DSBs are generated in chromatin structure. Here, we show that the highly conserved histone H2A variant H2A.Z promotes meiotic DSB formation in fission yeast. Subsequent investigation revealed that H2A.Z is neither enriched around hotspots nor axis sites, and that transcript levels of DSB-promoting factors were maintained in the absence of H2A.Z. Instead, we found that H2A.Z facilitates chromatin binding of various proteins required for DSB formation. Strikingly, artificial tethering of one of such proteins, Rec10, to chromatin partially restored DSB reduction in H2A.Z-lacking cells. Based on these, we conclude that fission yeast H2A.Z promotes initiation of meiotic recombination partly through delivering DSB-related proteins onto chromatin.

Project description:Meiotic chromosome architecture called M-bM-^@M-^\axis-loop structuresM-bM-^@M-^] and histone modifications have been demonstrated to regulate the Spo11-dependent formation of DNA double-strand breaks (DSBs) that trigger meiotic recombination. Using genome-wide chromatin immunoprecipitation (ChIP) analyses followed by deep sequencing, we compared the genome-wide distribution of the axis protein Rec8 (the kleisin subunit of meiotic cohesin) with that of oligomeric DNA covalently bound to Spo11, indicative of DSB sites. The frequency of DSB sites is overall constant between Rec8 binding sites. However, DSB cold spots are observed in regions spanning M-BM-10.8 kb around Rec8 binding sites. The axis-associated cold spots are not due to exclusion of Spo11 localization from the axis, since ChIP experiments revealed that substantial Spo11 persists at Rec8 binding sites during DSB formation. Spo11 fused with Gal4 DNA binding domain (Gal4BD-Spo11) tethered in close proximity (M-bM-^IM-$0.8 kb) to Rec8 binding sites hardly forms meiotic DSBs, in contrast with other regions. In addition, H3K4 tri-methylation (H3K4me3) remarkably decreases at Rec8 binding sites. These results suggest that reduced histone H3K4me3 in combination with inactivation of Spo11 activity on the axis discourages DSB hot spot formation. ChIP-chip analysis of Rec8 on fission yeast meiotic chromosomes

Project description:During mouse meiosis, DNA double-strand breaks (DSBs) are initiated by SPO11 at recombination hotspots (HSs), activated by PRDM9. Although activated HSs are marked by H3K4me3 and H3K36me3 histone modifications at open chromatin, most of the DSB-initiating and repair proteins are associated with the chromosome axis. This study addresses the mechanistic importance of the axis-associated cohesin proteins in DSB formation. We demonstrate that interactions between PRDM9 and the meiotic axis proteins STAG3 and REC8 are essential for efficient DSB formation. The absence of STAG3 or REC8 leads to inefficient meiotic DSB formation at HSs. STAG3 is critical for DSB formation, even at PRDM9-independent DSB-sites. Also, STAG3 and REC8 facilitate recruitment of the DSB-promoting proteins HORMAD1, IHO1 and MEI4 required for SPO11 activity. Together, these results support an evolutionarily conserved model in which axis-associated cohesin complexes recruit recombination-initiating proteins to DSB sites to promote meiotic recombination initiation.

Project description:The DNA double strand breaks (DSBs) that initiate meiotic recombination are formed in the context of the meiotic chromosome axis, which in budding yeast contains a meiosis-specific cohesin isoform and the meiosis-specific proteins Hop1 and Red1. Hop1 and Red are important for DSB formation; DSB levels are reduced in their absence and their levels, which vary along the lengths of chromosomes, are positively correlated with DSB levels. How axis protein levels influence DSB formation and recombination remains unclear. To address this question, we developed a novel approach that uses a bacterial ParB-parS partition system to recruit axis proteins at high levels to inserts at recombination coldspots where Hop1 and Red1 levels are normally low. Recruiting Hop1 markedly increased DSBs and homologous recombination at target loci, to levels equivalent to those observed at endogenous recombination hotspots. This local increase in DSBs did not require Red1 or the meiosis-specific cohesin component Rec8, indicating that, of the axis proteins, Hop1 is sufficient to promote DSB formation. However, while most crossovers at endogenous recombination hotspots are formed by the meiosis-specific MutLγ resolvase, only a small fraction of crossovers that formed at an insert locus required MutLγ, regardless of whether or not Hop1 was recruited to that locus. Thus, while local Hop1 levels determine local DSB levels, the recombination pathways that repair these breaks can be determined by other factors, raising the intriguing possibility that different recombination pathways operate in different parts of the genome.

Project description:Histone modifications are associated with meiotic recombination hotspots, discrete sites with augmented recombination frequency. For example, trimethylation of histone H3 lysine4 (H3K4me3) marks most hotspots in budding yeast and mouse. Modified histones are known to regulate meiotic recombination partly by promoting DNA double strand break (DSB) formation, but the role and precise landscape of histone modifications at hotspots remain unclear. Here, we studied hotspot-associated modifications in fission yeast and found general features: acetylation of H3 lysine9 (H3K9ac) is strikingly elevated, and H3K4me3 is not significantly enriched. Remarkably, elimination of H3K9ac reduced binding of the DSB-inducing enzyme Rec12 and DSB at hotspots. We also found that the H3K4 metyltransferase Set1 promotes DSB formation at some loci, but it restricts Rec12 binding to hotspots. These results suggest that H3K9ac rather than H3K4me3 is a hotspot-associated mark involved in meiotic DSB formation in fission yeast.

Project description:Meiotic recombination is initiated by the Spo11-dependent programmed DNA double-strand breaks (DSBs) that are preferentially concentrated within genomic regions known as hotspots, but the factor(s) which specify the positions for meiotic DSB hotspots remain unclear. Here, we show that the frequency and distribution of R-loops, a type of functional chromatin structure comprising single-stranded DNA and a DNA:RNA hybrid, change dramatically throughout meiosis. We detected the formation of multiple de novo R-loops in the pachytene stage, and found they co-localize with meiotic DSB hotspots. We further show that transcription-replication head-on collisions could promote R-loop formation during meiosis, and apparently direct the initiation of meiotic DSB formation. Furthermore, the hotspots can be eliminated by reverse the direction of either transcription or replication, and reconstituted by reverse both of their direction. Our study reveals that R-loops may play dual roles in meiotic recombination. In addition to participation in meiotic DSB processing, some meiotic DSB hotspots may be originated from the transcription-replication head-on collisions during meiotic DNA replication.

Project description:DNA double-strand breaks (DSBs) are introduced in meiosis to initiate recombination and to generate crossovers, the reciprocal exchanges of genetic material between parental chromosomes. Here we present the first high-resolution map of meiotic DSBs in individual human genomes. Comparing DSB maps between individuals shows that along with DNA binding by PRDM9, additional factors dictate the efficiency of DSB formation. Furthermore, we find that in human males, the frequency of DSB formation is the primary determinant of crossover rate. Patterns of sequence polymorphisms around meiotic DSB hotspots provide evidence for both GC-biased gene conversion and for a mutagenic role of DSB repair and/or recombination. Finally, we provide compelling evidence that the aberrant repair of meiotic DSBs is a driver of human genomic disorders. Detection of meiotic double strand breaks in testis of several human male individuals.

Project description:Meiotic crossover (CO) recombination is a process in which programmed DNA double-strand breaks (DSBs) around hotspots are repaired by homologous chromosomes (homologs), and thus exchanges DNA molecules between two homologs. CO is critical for most sexually-reproducing organisms because it promotes accurate chromosome segregation and creates genetic diversity. Therefore, faithful accomplishment of CO formation must be ensured, but the bases of the regulation are not fully understood. Our previous study using fission yeast has revealed that mutants lacking the conserved histone H2A.Z are defective in DSB formation but maintain CO frequency at three loci tested. Here, we tested five additional sites to show that H2A.Z-lacking cells exhibit normal and increased CO frequency at two and three loci, respectively. Detailed interrogation on one of the intervals revealed that CO increase in the mutant would be genetically separable from DSB reduction, and regulated at least partly at the recombination intermediate level. In addition, through genetic analyses of model regions containing a hotspot flanked by two markers as well as genome-wide analyses, we propose that, in the absence of H2A.Z, CO arose from non-hotspot DSBs may compensate for DSB reduction at hotspots. These observations provide clues to further our understanding on CO control.

Project description:Meiotic recombination, crucial for proper chromosome segregation and genome evolution, is initiated by programmed DNA double-strand breaks (DSBs) in budding and fission yeasts and likely all sexually reproducing species. In fission yeast, DSBs occur up to several hundred times more frequently at special sites, called hotspots, than in other regions of the genome. What distinguishes hotspots from cold regions is a major unsolved problem, although transcription factors determine some hotspots. We report here the discovery that three coiled-coil proteins -- Rec25, Rec27, and Mug20 -- bind essentially all hotspots with unprecedented, high specificity even without DSB formation. These small proteins are components of linear elements, are related to synaptonemal complex proteins, and are essential for nearly all DSBs at most hotspots. Our results indicate that these hotspot determinants activate or stabilize the DSB-forming protein Rec12 (Spo11 homolog) rather than promote its binding to hotspots. We propose here a new paradigm for hotspot determination and crossover control by linear element proteins.

Project description:Meiotic recombination, crucial for proper chromosome segregation and genome evolution, is initiated by programmed DNA double-strand breaks (DSBs) in budding and fission yeasts and likely all sexually reproducing species. In fission yeast, DSBs occur up to several hundred times more frequently at special sites, called hotspots, than in other regions of the genome. What distinguishes hotspots from cold regions is a major unsolved problem, although transcription factors determine some hotspots. We report here the discovery that three coiled-coil proteins -- Rec25, Rec27, and Mug20 -- bind essentially all hotspots with unprecedented, high specificity even without DSB formation. These small proteins are components of linear elements, are related to synaptonemal complex proteins, and are essential for nearly all DSBs at most hotspots. Our results indicate that these hotspot determinants activate or stabilize the DSB-forming protein Rec12 (Spo11 homolog) rather than promote its binding to hotspots. We propose here a new paradigm for hotspot determination and crossover control by linear element proteins.