Systematic analysis of the molecular and biophysical properties of key DNA damage response factors

Abstract

ABSTRACTRepair of DNA double strand breaks (DSBs) is integral to preserving genomic integrity. Therefore, defining the mechanisms underlying DSB repair will enhance our understanding of how defects in these pathways contribute to human disease and could lead to the discovery of new approaches for therapeutic intervention. Here, we established a panel of HaloTagged DNA damage response factors in U2OS cells which enables concentration-dependent protein labeling. Genomic insertion of the HaloTag at the endogenous loci of the repair factors preserves expression levels and proteins retain proper subcellular localization, foci-forming ability, and functionally support DSB repair. We systematically analyzed total cellular protein abundance, measured recruitment kinetics to DSBs, and defined the diffusion dynamics and chromatin binding by live-cell single-molecule imaging. Our work demonstrates that the Shieldin complex, a critical factor in end joining, does not exist in a preassembled state and Shieldin components are recruited to DSBs with different kinetics. Additionally, live-cell single-molecule imaging revealed the constitutive interaction between MDC1 and chromatin mediated by the PST repeat domain of MDC1. Altogether, our studies demonstrate the utility of single-molecule imaging to provide mechanistic insights into DNA repair, which will serve as a powerful resource for characterizing the biophysical properties of DNA repair factors in living cells.