Department of Biological Chemistry, University of Michigan, Ann Arbor, Michigan 48109, USA.
Biochemistry. 2010 Sep 14;49(36):7879-91. doi: 10.1021/bi100889r.
The base excision repair (BER) pathway repairs a wide variety of damaged nucleobases in DNA. This pathway is initiated by a DNA repair glycosylase, which locates the site of damage and catalyzes the excision of the damaged nucleobase. The resulting abasic site is further processed by apurinic/apyrimidinic site endonuclease 1 (APE1) to create a single-strand nick with the 3'-hydroxyl that serves as a primer for DNA repair synthesis. Because an abasic site is highly mutagenic, it is critical that the steps of the BER pathway be coordinated. Most human glycosylases bind tightly to their abasic product. APE1 displaces the bound glycosylase, thereby stimulating multiple-turnover base excision. It has been proposed that direct protein-protein interactions are involved in the stimulation by APE1, but no common interaction motifs have been identified among the glycosylases that are stimulated by APE1. We characterized the APE1 stimulation of alkyladenine DNA glycosylase (AAG) using a variety of symmetric and asymmetric lesion-containing oligonucleotides. Efficient stimulation of a wide variety of substrates favors a model in which both AAG and APE1 can simultaneously bind to DNA but may not interact directly. Rather, nonspecific DNA binding by both AAG and APE1 enables APE1 to replace AAG at the abasic site. AAG is not displaced into solution but remains bound to an adjacent undamaged site. We propose that nonspecific DNA binding interactions allow transient exposure of the abasic site so that it can be captured by APE1.
碱基切除修复 (BER) 途径修复 DNA 中多种受损的碱基。该途径由 DNA 修复糖苷酶启动,糖苷酶定位损伤部位并催化损伤碱基的切除。产生的无碱基位点进一步由脱嘌呤/脱嘧啶核酸内切酶 1 (APE1) 处理,在无碱基位点产生单链切口,其中 3'-羟基可作为 DNA 修复合成的引物。因为无碱基位点具有高度诱变作用,所以 BER 途径的步骤必须协调一致。大多数人类糖苷酶与它们的无碱基产物紧密结合。APE1 取代结合的糖苷酶,从而刺激多次碱基切除。据推测,APE1 的刺激涉及直接的蛋白质-蛋白质相互作用,但尚未确定 APE1 刺激的糖苷酶之间存在共同的相互作用基序。我们使用各种对称和不对称含损伤的寡核苷酸来表征 APE1 对烷基腺嘌呤 DNA 糖苷酶 (AAG) 的刺激作用。对各种底物的有效刺激有利于这样一种模型,即 AAG 和 APE1 都可以同时与 DNA 结合,但可能不会直接相互作用。相反,AAG 和 APE1 的非特异性 DNA 结合使 APE1 能够在无碱基位点取代 AAG。AAG 不会被置换到溶液中,而是仍然结合到相邻的未受损部位。我们提出,非特异性 DNA 结合相互作用允许无碱基位点短暂暴露,从而可以被 APE1 捕获。