The transmission of a stable genome is critical for the maintenance of genome stability throughout sexual reproduction in all eukaryotes. However, our current understanding of the mechanisms that guide how eukaryotic cells safeguard their genome during the meiotic division is limited. The main goal of this project is to investigate how unstable repetitive DNA elements are protected from instability during sexual reproduction. For this, we use the unicellular organism Saccharomyces cerevisiae (i.e. budding yeast) as a model system. We are focusing on a particular repetitive DNA elements, namely the ribosomal DNA element (rDNA), and we are trying to understand how a recently defined "anti-DSB" system, composed of the enzymes Pch2 and Orc1 is acting to protect these sequences agains meiotic DNA break formation and recombination. We have investigated, using cell biology, genome-wide analyses, and biochemical reconstitution to study this complex. In addition, we have developed systems to manipulate the behaviour of the repetitive DNA elements, in order to one able to elucidate how and why these regions are so at-risk during meiotic cell divisions. In general, the aim of this proposal is thus to illuminate our understanding of the maintenance of genome stability during sexual reproduction. Many human genetic disorders are caused by genome destabilisation during sexual reproduction. Therefore, deepening our understanding of the factors that safeguard sexual reproduction is expected to help us understand the aetiology of human disease.