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Resection of DNA double strand breaks in the germline of Caenorhabditis elegansYin, Yizhi 01 August 2015 (has links)
Repair of double-strand DNA breaks (DSBs) by the homologous recombination (HR) pathway results in crossovers (COs) required for a successful first meiotic division. DSB resection is the nucleic degradation of DSB ends to expose 3’ single strand DNA (ssDNA), an intermediate required for HR. To investigate genes involved in meiosis, a forward genetic screen was performed to search for novel genes or informative new mutant alleles of known genes. Mre11 is one member of the MRX/N (Mre11-Rad50-Xrs2/Nbs1) complex required for meiotic DSB formation and for resection in budding yeast. In Caenorhabditis elegans, evidence for the MRX/N’s role in DSB resection is limited. We isolated the first separation of function allele in C. elegans , mre 11(iow1), isolated from our forward genetic screen. The mre-11(iow1) mutants are specifically defective in meiotic DSB resection but not in DSB formation. The mre 11(iow1) mutants display chromosomal fragmentation and aggregation in late prophase I. Recombination intermediates and crossover formation is greatly reduced in mre 11(iow1) mutants. Irradiation induced DSBs during meiosis fail to be repaired from the early to middle prophase I in mre 11(iow1) mutants. Our data suggest that some DSBs in mre 11(iow1) mutants are repaired by the non homologous end joining (NHEJ) pathway because removing NHEJ partially suppresses some meiotic defects conferred by mre 11(iow1). In the absence of NHEJ and a functional MRX/N, meiotic DSBs are channeled to an EXO 1 dependent form of recombination repair. Overall, our analysis supports a role for MRE-11 in the resection of DSBs in early to middle meiotic prophase I and in blocking NHEJ.
A reverse genetic screen and a yeast two hybrid screen were performed to search for genes with genetic and/or physical interactions with mre-11. The reverse genetic screen isolated a novel meiotic gene, nhr-2, as a partial suppressor of the meiotic defects conferred by mre-11(iow1). The yeast two hybrid screen identified kin-18 interacting with mre-11. KIN-18 is the C. elegans homolog of mammalian Thousand And One kinase (TAO) kinase. KIN-18/TAO is MAPK kinase kinase whose meiotic role was unknown. We have found that KIN-18 is essential for normal meiotic progression as kin-18 mutants exhibit accelerated meiotic recombination, ectopic germ cell differentiation, and enhanced levels of germline apoptosis. In C.elegans MPK-1 activation in late pachytene is required for physiological apoptosis (nuclei removed by apoptosis serve as nursing cells for oocytes) and oocyte differentiation. The kin-18 mutants also showed absence of MPK-1 activation and aberrant MPK-1 activation that includes ectopic activation in the wrong regions in the germline or more than one time of activation. The progression defects in kin-18 mutants are suppressed by inhibiting an upstream activator, KSR-2, of the canonical MPK-1 signaling. Our data suggest KIN-18 affects meiotic progression by modulating the timing of MPK-1 activation. This regulation ensures the proper timing of recombination and normal apoptosis, which is required for the formation of functional oocytes. Meiosis is a conserved process; revealing that KIN-18 is a novel regulator of meiotic progression in C. elegans will motivate hypothesis for TAO kinase’s role in the germline development in higher eukaryotes.
Meiosis is a crucial for sexually reproducing organisms to maintain ploidy level from one generation to the next. Accurate chromosome segregation in the meiosis requires meiotic recombination between homologous chromosomes. Failure in recombination can lead to abnormal segregation of chromosomes in meiosis, which leads to aneuploidy. Anueploidy is a leading cause of miscarriages and attributes to chromosomal related birth defects. Meiotic recombination starts with programmed DNA double strand breaks (DSBs), followed by repair of these DSBs by homologous recombination (HR) pathway. One key step in HR is resection, a process to covert DSB ends into single strand DNA (ssDNA). To broaden our understanding of meiotic DSB resection, we used a nematode, C. elegans, as a model to investigate genes in DSB resection. We have isolated a specific mutant allele of a meiotic gene, mre-11. Our data suggest meiotic DSB resection in C. elegans requires collaboration of mre-11 and another gene exo-1; efficient resection of DSB ends is important to safeguard repair of DSB by HR against other illegitimate repair pathway. In addition, we identified a gene kin-18 by looking for genes interacting with mre-11. Characterization of kin-18 show meiotic recombination is tightly coordinated with germ cell progression. Our analysis provides significant improvement in the understanding of meiotic recombination in C. elegans. Given the high conservation of the two genes, mre-11 and kin-18, our finding may be applied to other organisms.
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