Abstract
MDC1 is a key factor of DNA damage response in mammalian cells. It possesses two phospho-binding domains. In its C terminus, a tandem BRCA1 C-terminal domain binds phosphorylated histone H2AX, and in its N terminus, a forkhead-associated (FHA) domain mediates a phosphorylation-enhanced homodimerization. The FHA domain of the Drosophila homolog of MDC1, MU2, also forms a homodimer but utilizes a different dimer interface. The functional importance of the dimerization of MDC1 family proteins is uncertain. In the fission yeast Schizosaccharomyces pombe, a protein sharing homology with MDC1 in the tandem BRCA1 C-terminal domain, Mdb1, regulates DNA damage response and mitotic spindle functions. Here, we report the crystal structure of the N-terminal 91 amino acids of Mdb1. Despite a lack of obvious sequence conservation to the FHA domain of MDC1, this region of Mdb1 adopts an FHA-like fold and is therefore termed Mdb1-FHA. Unlike canonical FHA domains, Mdb1-FHA lacks all the conserved phospho-binding residues. It forms a stable homodimer through an interface distinct from those of MDC1 and MU2. Mdb1-FHA is important for the localization of Mdb1 to DNA damage sites and the spindle midzone, contributes to the roles of Mdb1 in cellular responses to genotoxins and an antimicrotubule drug, and promotes in vitro binding of Mdb1 to a phospho-H2A peptide. The defects caused by the loss of Mdb1-FHA can be rescued by fusion with either of two heterologous dimerization domains, suggesting that the main function of Mdb1-FHA is mediating dimerization. Our data support that FHA-mediated dimerization is conserved for MDC1 family proteins.
Highlights
Fission yeast Mdb[1] is homologous to mammalian MDC1, but the extent of conservation is unclear
Dimerization Is the Main Function of Mdb1-FHA—In this study, we present multiple lines of evidence including crystal structure, gel filtration, analytical ultracentrifugation, and co-immunoprecipitation to show that Mdb1-FHA forms a homodimer
The defect of FHA-truncated Mdb[1] in DNA damage response can be attributed to its inability to bind ␥H2A. This is not due to a direct role of Mdb1-FHA in ␥H2A binding because, first, Mdb1-FHA lacks phospho-binding residues; second, ␥H2A-binding requires the phosphobinding residues in the tBRCT domain (19); third, recombinant Mdb1-FHA failed to bind ␥H2A in vitro; and fusing a heterologous dimerization domain rescues the ␥H2A binding defect caused by FHA truncation
Summary
Fission yeast Mdb[1] is homologous to mammalian MDC1, but the extent of conservation is unclear. MDC1 is a key factor of DNA damage response in mammalian cells In the fission yeast Schizosaccharomyces pombe, a protein sharing homology with MDC1 in the tandem BRCA1 C-terminal domain, Mdb[1], regulates DNA damage response and mitotic spindle functions. Unlike canonical FHA domains, Mdb1-FHA lacks all the conserved phospho-binding residues It forms a stable homodimer through an interface distinct from those of MDC1 and MU2. The FHA domain in the Drosophila ortholog of MDC1, MU2, was found to forms a homodimer (12), raising the possibility that dimerization is an ancient and conserved function of the FHA domains in MDC1 family proteins. The dimerization function of this domain is important for the roles of Mdb[1] in DNA damage response and mitotic spindle regulation. Our findings suggest that FHA-mediated dimerization is a universal and conserved property of MDC1 family proteins
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