Meiotic DNA breaks drive multifaceted mutagenesis in the human germ line.

Journal article

Meiotic recombination commences with hundreds of programmed DNA breaks; however, the degree to which they are accurately repaired remains poorly understood. We report that meiotic break repair is eightfold more mutagenic for single-base substitutions than was previously understood, leading to de novo mutation in one in four sperm and one in 12 eggs. Its impact on indels and structural variants is even higher, with 100- to 1300-fold increases in rates per break. We uncovered new mutational signatures and footprints relative to break sites, which implicate unexpected biochemical processes and error-prone DNA repair mechanisms, including translesion synthesis and end joining in meiotic break repair. We provide evidence that these mechanisms drive mutagenesis in human germ lines and lead to disruption of hundreds of genes genome wide.

Authors: Hinch, R; Donnelly, P; Hinch, AG

• Publication status: Published
• Peer review status: Peer reviewed
• Publisher: American Association for the Advancement of Science
• Journal: Science
• Volume: 382
• Issue: 6674
• Article number: eadh2531
• Place of publication: United States
• Publication date: 2023-12-01
• DOI: 10.1126/science.adh2531
• EISSN: 1095-9203
• ISSN: 0036-8075
• Pmid: 38033082
• Language: English
• Keywords: double-stranded; recombination; dna breaks; genetic; meiosis; mutation; FFR; semen; mutagenesis; ovum; genome; human; translesion dna synthesis; DNA repair