DNA binding by the Rad9A subunit of the Rad9-Rad1-Hus1 complex

The Rad9-Rad1-Hus1 checkpoint clamp activates the DNA damage response and promotes DNA repair. DNA loading on the central channel of the Rad9-Rad1-Hus1 complex is required to execute its biological functions. Because Rad9A has the highest DNA affinity among the three subunits, we determined the domains and functional residues of human Rad9A that are critical for DNA interaction. The N-terminal globular domain (residues 1–133) had 3.7-fold better DNA binding affinity than the C-terminal globular domain (residues 134–266) of Rad9A(1-266). Rad9A(1-266) binds DNA 16-, 60-, and 30-fold better than Rad9A(1-133), Rad9A(134-266), and Rad9A(94-266), respectively, indicating that different regions cooperatively contribute to DNA binding. We show that basic residues including K11, K15, R22, K78, K220, and R223 are important for DNA binding. The reductions on DNA binding of Ala substituted mutants of these basic residues show synergistic effect and are dependent on their residential Rad9A deletion constructs. Interestingly, deletion of a loop (residues 160–163) of Rad9A(94-266) weakens DNA binding activity by 4.1-fold as compared to wild-type (WT) Rad9A(94-266). Cellular sensitivity to genotoxin of rad9A knockout cells is restored by expressing WT-Rad9A(full). However, rad9A knockout cells expressing Rad9A mutants defective in DNA binding are more sensitive to H(2)O(2) as compared to cells expressing WT-Rad9A(full). Only the rad9A knockout cells expressing loop-deleted Rad9A mutant are more sensitive to hydroxyurea than cells expressing WT-Rad9A. In addition, Rad9A-DNA interaction is required for DNA damage signaling activation. Our results indicate that DNA association by Rad9A is critical for maintaining cell viability and checkpoint activation under stress.