Abstract
Programmed DNA double-strand breaks (DSBs) are required for meiotic recombination, but the number is strictly controlled because they are potentially harmful. Here we report a novel protein, Pars11, which is required for Spo11-dependent DSB formation in the protist Tetrahymena. Pars11 localizes to chromatin early in meiotic prophase in a Spo11-independent manner and is removed before the end of prophase. Pars11 removal depends on DSB formation and ATR-dependent phosphorylation. In the absence of the DNA damage sensor kinase ATR, Pars11 is retained on chromatin and excess DSBs are generated. Similar levels of Pars11 persistence and DSB overproduction occur in a non-phosphorylatable pars11 mutant. We conclude that Pars11 supports DSB formation by Spo11 until enough DSBs are formed; thereafter, DSB production stops in response to ATR-dependent degradation of Pars11 or its removal from chromatin. A similar DSB control mechanism involving a Rec114-Tel1/ATM-dependent negative feedback loop regulates DSB formation in budding yeast. However, there is no detectable sequence homology between Pars11 and Rec114, and DSB numbers are more tightly controlled by Pars11 than by Rec114. The discovery of this mechanism for DSB regulation in the evolutionarily distant protist and fungal lineages suggests that it is conserved across eukaryotes.
Highlights
During meiosis, numerous DNA double-strand breaks (DSBs) are generated to ensure proper homology searching and homologous pairing [see [1]]
Since Pars11 is required for DSB formation and DSB formation promotes ATR-dependent Pars11 phosphorylation and its removal from chromatin, we investigated whether ATR is involved in regulating DSB formation via Pars11
Pars11 regulates the number of DSBs In Tetrahymena, previous examples of genes required for meiotic initiation and DSBs included meiosis-specific cell cycle regulators such as cyclins and CDKs, which act upstream of the process [43,44], but co-factors that support DSB formation by Spo11 have not yet been found
Summary
Numerous DNA double-strand breaks (DSBs) are generated to ensure proper homology searching and homologous pairing [see [1]]. RMM (consisting of Rec114, Mer and Mei4), resides on chromatin and is required for Spo recruitment to the meiotic chromosome axis [12,13,14] After their formation, meiotic DSBs are occupied by the MRN/MRX-complex, which recruits and activates the DNA damage sensor kinase ATM, a phosphatidylinositol 3-kinase-related kinase (PIKK) [see [15,16]]. Chromosomes are arranged in a stretched bouquet-like manner, with centromeres and telomeres attached to opposing ends This arrangement promotes the juxtapositioning of homologous regions, thereby facilitating homologous pairing and CO without the help of a synaptonemal complex [26]. We characterize a novel gene, PARS11 (Partner of SPO11), which is required for both the DSB formation and ATR-dependent control of DSB number
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