Abstract
Mediator of DNA damage checkpoint protein 1 (MDC1) serves as a docking platform to promote the localization of various DNA damage response (DDR) components to DNA double-strand break (DSB) sites. MDC1 is vital in controlling proper DDR and maintaining genomic stability. In cancers, genomic instability results from mutations in DNA repair genes and drives cancer development. The mutations of MDC1 in human cancers have not been systematically examined and little is known about the molecular phenotypes caused by these genetic changes. Here, we summarized cancer-associated mutations of MDC1 including insertion/deletion mutations as well as missense mutations in key functional domains of MDC1 from ICGC, TCGA and COSMIC databases. We analyzed 711 somatic mutations of MDC1 across 26 types of human cancers and examined the functional defects of these cancer-associated mutations of MDC1 in the context of DNA damage repair. 6 truncation mutations and 7 missense mutations of MDC1 were chosen for further study. 6 truncation mutations which abolish MDC1-γH2AX interaction abrogate its biological functions in DNA damage repair. 2 missense mutations in FHA domain impaired ATM (ataxia telangiectasia mutated) phosphorylation. 5 missense mutations in BRCT domain also abolished its interaction with γH2AX, resulting in defects in foci formation of MDC1, 53BP1 and BRCA1 as well as defects in G2/M checkpoints. We further used structural modeling to analyze the potential molecular mechanism by which the 7 missense mutations cause the DNA damage repair defects. Taken together, our results reveal these cancer-associated MDC1 mutations can result in functional defects in DNA damage response and may serve as biomarkers for cancer diagnostics in future.