Probing conformational changes in Ape1 during the progression of base excision repair

Abstract

Abasic (AP) sites are the most common lesions arising in genomic DNA. Repair of this potentially mutagenic DNA damage is initiated by the major apurinic/apyrimidinic endonuclease Ape1, which specifically recognizes and cleaves the DNA backbone 5' to the AP site. Ape1 is one of the major proteins in the base excision repair pathway (BER), and deletions in any of the BER proteins result in embryonic lethality. In this study, we employed fluorescence spectroscopy and in vitro mass spectrometric protein footprinting to investigate Ape1 conformational changes during various nucleoprotein interactions along its reaction pathway. Differences in intrinsic fluorescence emission spectra were observed during Ape1 protein's processing of the substrate, indicating possible conformational changes of the nucleoprotein complexes. To determine the protein domains that are involved in the putative conformational change, full-length Ape1 protein was probed with a lysine-reactive reagent (NHS-biotin) in the context of free protein and DNA-bound complexes. Protection patterns between pre- and postincision complexes revealed an increased susceptibility of lysine residues localized on the Ape1 surface that contacts the 3' end of the incised duplex (downstream of the incision site). We propose that the decreased protection results from Ape1 having a more relaxed grip on this section of the incised duplex to facilitate the handoff to the downstream BER enzyme. Protection of lysines (residues 24-35) in the N-terminal region was also observed in the intact AP-DNA-bound complex. These residues are part of the Ref1 domain which functions to regulate the activity of several transcription factors but to date has not been ascribed a DNA binding function. The reactivity of these Ref1 lysines was restored in the postincision complex. The differential protection patterns of lysines in the flexible N-terminal domain suggest a novel Ref1 conformational change concomitant with DNA binding and catalysis. It is likely that Ape1 employs this structural switch to mediate redox and nuclease activities. The ability of the Ape1-AP-DNA complex to recruit other BER proteins was also investigated by probing ternary complexes comprised of Ape1, DNA polymerase beta (Polbeta), and different BER DNA intermediates (abasic or gapped DNA). Our results suggest that Polbeta approaches the Ape1-DNA complex downstream of the incision site, displaces Ape1 DNA binding contacts (K227, K228, and K276), and in the process makes minimal interactions with lysine residues in the Ref1 domain.