Abstract
Apurinic/Apyrimidinic (AP)-sites are common and highly mutagenic DNA lesions that can arise spontaneously or as intermediates during Base Excision Repair (BER). The enzyme apurinic/apyrimidinic endonuclease 1 (APE1) initiates repair of AP-sites by cleaving the DNA backbone at the AP-site via its endonuclease activity. Here, we investigated the functional role of the APE1 active site residue N174 that contacts the AP-site during catalysis. We analyzed the effects of three rationally designed APE1 mutations that alter the hydrogen bonding potential, size, and charge of N174: N174A, N174D, and N174Q. We found impaired catalysis of the APE1 (N174A) and APE1 (N174D) mutants due to disruption of hydrogen bonding and electrostatic interactions between residue 174 and the AP-site. In comparison, the APE1 (N174Q) mutant was less impaired due to retaining similar hydrogen bonding and electrostatic characteristics as N174 in wild-type APE1. Structures and computational simulations further revealed that the AP-site was destabilized within the active sites of the APE1 (N174A) and APE1 (N174D) mutants due to loss of hydrogen bonding between residue 174 and the AP-site. Cumulatively, we show that N174 stabilizes the AP-site within the APE1 active site through hydrogen bonding and electrostatic interactions to enable effective catalysis. These findings highlight the importance of N174 in APE1's function and provide new insights into the molecular mechanism by which APE1 processes AP-sites during DNA repair.