The ERCC6L2-MRI-KU complex coordinates NHEJ at staggered DNA double-strand breaks

ERCC6L2 disease is a recessive bone marrow failure (BMF) syndrome caused by mutations in the SNF2-like putative DNA helicase ERCC6L2. While implicated in DNA replication, double strand break (DSB) repair via non-homologous end joining (NHEJ), and interstrand crosslink (ICL) repair, how ERCC6L2 supports haematopoietic longevity remains unclear. Investigating this in vivo , we find that an Ercc6l2- deficient haematopoietic stem and progenitor cell (HSPC) compartment in mice is unexpectedly resilient. Ercc6l2 loss was also tolerated in mice co-deficient for endogenous formaldehyde detoxification, which precipitates early-onset BMF in models of Fanconi anaemia. Instead, Ercc6l2 -deficient mice display a mild immunodeficiency, arising from defects in immunoglobulin class-switch recombination (CSR), that synergise with shieldin-deficiency, implicating ERCC6L2 and shieldin in distinct repair mechanisms. Furthermore, we demonstrate that ERRC6L2 stimulates chromosome fusions in the context of staggered, but not blunt dysfunctional telomeres. We reconcile ERCC6L2’s NHEJ function through proteomic elucidation of its endogenous interactome and AlphaFold structural modelling to reveal a complex formed of ERCC6L2 and KU that is bridged by the NHEJ accessory factor MRI/CYREN. Consequently, ERCC6L2-MRI inter-dependence characterises CSR. Together, our findings implicate the ERCC6L2-MRI complex as a KU-regulatory DNA translocase coordinating classical-NHEJ at staggered-end DSBs. We suggest that similar staggered-end breaks represent the pathological substrates driving haematopoietic failure in ERCC6L2 disease.