ATM controls meiotic double-strand break formation

In many organisms, developmentally programmed double-strand breaks (DSBs) formed by the SPO11 transesterase initiate meiotic recombination, which promotes pairing and segregation of homologous chromosomes(1). Because every chromosome must receive a minimum number of DSBs, attention has focused on factors that support DSB formation(2). However, improperly repaired DSBs can cause meiotic arrest or mutation(3,4), thus having too many DSBs is likely as deleterious as having too few. Only a small fraction of SPO11 protein ever makes a DSB in yeast or mouse(5), and SPO11 and its accessory factors remain abundant long after most DSB formation ceases(1), implying the existence of mechanisms that restrain SPO11 activity to limit DSB numbers. Here we report that the number of meiotic DSBs in mouse is controlled by ATM, a kinase activated by DNA damage to trigger checkpoint signaling and promote DSB repair. Levels of SPO11-oligonucleotide complexes, by-products of meiotic DSB formation, are elevated at least ten-fold in spermatocytes lacking ATM. Moreover, Atm mutation renders SPO11-oligonucleotide levels sensitive to genetic manipulations that modulate SPO11 protein levels. We propose that ATM restrains SPO11 via a negative feedback loop in which kinase activation by DSBs suppresses further DSB formation. Our findings explain previously puzzling phenotypes of Atm-null mice and provide a molecular basis for the gonadal dysgenesis observed in ataxia telangiectasia, the human syndrome caused by ATM deficiency.