Project description:Meiotic crossover recombination is triggered by the formation of programmed double strand breaks (DSBs) catalyzed by the conserved Spo11 protein. Only a subset of these DSBs are repaired as crossovers, promoted by a group of eight evolutionarily conserved proteins, named ZMM. The synaptonemal complex (SC) that assembles between homologous chromosomes is composed of two axial elements, from which chromatin loops emanate, held together by a central region, composed of the central element and a transverse filament protein. In budding yeast, crossover formation is functionally linked to the formation of the SC, but the underlying mechanism is unknown. Here we found that the SC central element protein, Ecm11, mainly localizes on both DSB sites and sites that attach chromatin loops to the chromosome axis, in a way that strictly requires the ZMM protein Zip4. We further show that Zip4 directly interacts with Ecm11 and that point mutants that specifically abolish the Zip4-Ecm11 interaction loose Ecm11 binding to chromosomes and exhibit defective SC assembly. Interestingly, SC assembly can be partially rescued by artificially tethering interaction-defective Ecm11 to Zip4. This direct connection that ensures SC assembly from CO sites could be a way for the meiotic cell to shut down further DSB formation once enough recombination sites have been selected for crossovers, thereby preventing excess crossovers. Finally, we found that the mammalian ortholog of Zip4, TEX11, interacts with the SC central element TEX12, raising the possibility that this may be a general mechanism.

Project description:Meiotic crossover formation requires the stabilization of early recombination intermediates by a set of proteins and occurs within the environment of the chromosome axis, a structure important for the regulation of meiotic recombination events. The molecular mechanisms underlying and connecting crossover recombination and axis localization are elusive. Here, we identified the ZZS (Zip2–Zip4–Spo16) complex, required for crossover formation, which carries two distinct activities: one provided by Zip4, which acts as hub through physical interactions with components of the chromosome axis and the crossover machinery, and the other carried by Zip2 and Spo16, which preferentially bind branched DNA molecules in vitro. We found that Zip2 and Spo16 share structural similarities to the structure-specific XPF–ERCC1 nuclease, although it lacks endonuclease activity. The XPF domain of Zip2 is required for crossover formation, suggesting that, together with Spo16, it has a noncatalytic DNA recognition function. Our results suggest that the ZZS complex shepherds recombination intermediates toward crossovers as a dynamic structural module that connects recombination events to the chromosome axis. The identification of the ZZS complex improves our understanding of the various activities required for crossover implementation and is likely applicable to other organisms, including mammals.

Project description:H3K4me3 is a fundamental and highly conserved chromatin mark across eukaryotes, playing a central role in many genome-related processes, including transcription, maintenance of cell identity, DNA damage repair, and meiotic recombination. However, identifying the causal function of H3K4me3 in these diverse pathways remains a challenge, and we lack the tools to manipulate it for agricultural benefit. Here we use the CRISPR-based SunTag system to direct H3K4me3 methyltransferases in the model plant, Arabidopsis thaliana. Targeting of SunTag-SDG2 activates the expression of the endogenous reporter gene, FWA. We show that SunTag-SDG2 can be employed to increase pathogen resistance by targeting the H3K4me3-dependent disease resistance gene, SNC1. Meiotic crossover recombination rates impose a limit on the speed with which new traits can be transferred to elite crop varieties. We demonstrate that targeting of SunTag-SDG2 to low recombining centromeric regions can significantly stimulate crossover formation. Finally, we reveal that the effect is not specific to SDG2 and is likely dependent on the H3K4me3 mark itself, as the orthogonal mammalian-derived H3K4me3 methyltransferase, PRDM9, produces a similar effect on gene expression with reduced off-target potential. Overall, our study supports an instructive role for H3K4me3 in transcription and meiotic recombination and opens the door to precise modulation of important agricultural traits.

Project description:Programmed DNA double-strand breaks (DSBs) initiate meiotic recombination and their subsequent repair culminates in crossover (CO) formation. COs result from the asymmetric cleavage of double-Holliday junction (dHJ) intermediates, that requires the MutLγ endonuclease and a non-catalytic function of Exo1, an activity essential for fertility but at risk of generating unwanted chromosome rearrangements. Here we show how crossover formation by MutLγ is activated at the right time and at the right place. MutLγ forms a constitutive complex with Exo1, and in meiotic cells transiently contacts the upstream MutSγ (Msh4-Msh5) heterodimer. MutLγ associates with DSB hotspots only once recombination intermediates have been stabilized and engaged in the crossover repair pathway. MutLγ-Exo1 is recruited to DSB hotspots independently of the polo-like Cdc5 kinase, but to activate dHJ resolution, Cdc5 is recruited to the recombination intermediates and interacts individually with both MutLγ and Exo1, suggesting their direct modification. in vivo, MutLγ occupancy is restrained on recombination intermediates, and MutLγ associates with the vast majority of DSB hotspots, but at a lower frequency in centromeres, consistent with a strategy to reduce at-risk crossover events in these regions, and in late replicating regions. Our data highlight the tight temporal and spatial control of the activity of this constitutive, potentially harmful, nuclease.

Project description:Programmed DNA double-strand breaks (DSBs) initiate meiotic recombination and their subsequent repair culminates in crossover (CO) formation. COs result from the asymmetric cleavage of double-Holliday junction (dHJ) intermediates, that requires the MutLγ complex together with a non-catalytic function of Exo1, an activity essential for fertility but at risk of generating unwanted chromosome rearrangements. Here we show how crossover formation by MutLγ is activated at the right time and at the right place. MutLγ forms a constitutive complex with Exo1, and in meiotic cells transiently contacts the upstream MutSγ (Msh4-Msh5) heterodimer. MutLγ associates with DSB hotspots at a late step in the recombinational repair, once recombination intermediates have been stabilized and engaged in the crossover repair pathway. MutLγ-Exo1 is recruited to DSB hotspots independently of the polo-like Cdc5 kinase, but to activate dHJ resolution, Cdc5 is recruited to the recombination intermediates and interacts individually with both MutLγ and Exo1, suggesting their direct modification. in vivo, MutLγ occupancy is restrained on recombination intermediates, and genome-wide, MutLγ associates with the vast majority of DSB hotspots, but at a lower frequency in centromeres, consistent with a strategy to reduce at-risk crossover events in these regions, and in late replicating regions. Our data highlight the highly temporally and spatially control of the activity of this constitutive, potentially harmful, nuclease

Project description:The Bloom syndrome helicase BLM interacts with topoisomerase IIIa (TOP3A), RMI1 and RMI2 to form the BTR complex, which dissolves double Holliday junctions to produce non-crossover products during homologous recombination (HR). BLM also promotes DNA-end resection and stalled replication fork restart. However, it is still unclear how the activities of the BTR complex are regulated in cells. Here, we identify multiple highly conserved short linear peptide motifs within the BTR complex that interact cooperatively with RPA. Furthermore, we demonstrate that RPA-binding is essential for stable recruitment of BLM to DNA damage sites and for stalled fork restart, but not for its roles in HR. Disruption of RPA-binding thus constitutes a novel separation-of-function mutation of the BTR complex, and suggest a model in which BTR contains the intrinsic ability to measure levels of RPA-ssDNA at replication forks, which controls its recruitment and activation in response to replication stress.

Project description:Meiotic recombination is initiated by programmed DNA double-strand breaks (DSBs) and proceeds via binding of RPA, RAD51 and DMC1 to single-stranded DNA (ssDNA) substrates created after the formation of DSBs. Here, we report high-resolution in vivo maps of RPA and RAD51 binding in meiosis, mapping their binding locations and lifespans in a B6 and a genetically modified B6xCAST F1 mouse. We ascribe signals separately to the individual homologous chromosomes in the hybrid mouse, thereby separating the signal of binding to the chromosome where DSBs occurred and the chromosome that was used as template for repair. Together with super-resolution microscopy and DMC1 binding maps, we show that DMC1 and RAD51 have distinct spatial localization on ssDNA: whereas DMC1 binds near the break-site, RAD51 binds away from it. We characterize the D-loop, a critical intermediate bound by RPA, in vivo. These data show that DMC1, not RAD51, performs strand exchange in mammalian meiosis. We find that the localisation of D-loop intermediates is similar in crossover and non-crossover pathways, with a longer lifespan for crossover-destined intermediates. These findings answer long-standing questions about the molecular intermediates of recombination.

Project description:During gamete formation, crossover recombination must occur on replicated DNA to ensure proper chromosome segregation in the first meiotic division. We identified a Mec1/ATR-dependent replication checkpoint in budding yeast that prevented the earliest stage of recombination, the programmed induction of DNA double-strand breaks (DSBs), when pre-meiotic DNA replication was delayed. The checkpoint suppressed DSBs through three complementary mechanisms: inhibition of Mer2 phosphorylation by Dbf4-dependent Cdc7 kinase, preclusion of chromosomal loading of Rec114 and Mre11, and lowered abundance of the Spo11 nuclease. Without this checkpoint, cells formed DSBs on partially replicated chromosomes. Importantly, such DSBs frequently failed to be repaired and impeded further DNA synthesis, leading to a rapid loss in cell viability. We conclude that a checkpoint-dependent constraint of DSB formation to duplicated DNA is critical not only for meiotic chromosome assortment, but also to protect genome integrity during gametogenesis. DSB factor association was measured in wild-type and checkpoint mutants strains under non-inducing or replication checkpoint inducing conditions. Additionally, DNA replication and helicase loading were measured in a replication and checkpoint deficient strain (cdc6-mn).

Project description:During meiosis, crossover recombination is essential to link homologous chromosomes and drive faithful chromosome segregation. Crossover recombination is non-random across the genome, and centromere-proximal crossovers are associated with an increased risk of aneuploidy, including Trisomy 21 in humans. Here, we identify the conserved Ctf19/CCAN kinetochore sub-complex as a major factor that minimizes potentially deleterious centromere-proximal crossovers in budding yeast. We uncover multi-layered suppression of pericentromeric recombination by the Ctf19 complex, operating across distinct chromosomal distances. The Ctf19 complex prevents meiotic DNA break formation, the initiating event of recombination, proximal to the centromere. The Ctf19 complex independently drives the enrichment of cohesin throughout the broader pericentromere to suppress crossovers, but not DNA breaks. This non-canonical role of the kinetochore in defining a chromosome domain that is refractory to crossovers adds a new layer of functionality by which the kinetochore prevents the incidence of chromosome segregation errors that generate aneuploid gametes.

Project description:During meiosis, crossover recombination is essential to link homologous chromosomes and drive faithful chromosome segregation. Crossover recombination is non-random across the genome, and centromere-proximal crossovers are associated with an increased risk of aneuploidy, including Trisomy 21 in humans. Here, we identify the conserved Ctf19/CCAN kinetochore sub-complex as a major factor that minimizes potentially deleterious centromere-proximal crossovers in budding yeast. We uncover multi-layered suppression of pericentromeric recombination by the Ctf19 complex, operating across distinct chromosomal distances. The Ctf19 complex prevents meiotic DNA break formation, the initiating event of recombination, proximal to the centromere. The Ctf19 complex independently drives the enrichment of cohesin throughout the broader pericentromere to suppress crossovers, but not DNA breaks. This non-canonical role of the kinetochore in defining a chromosome domain that is refractory to crossovers adds a new layer of functionality by which the kinetochore prevents the incidence of chromosome segregation errors that generate aneuploid gametes. Two samples total: two biological replicate Spo11-oligo maps of S. cerevisiae SK1 mcm21 null mutant