Abstract
DNA glycosylases initiate base excision repair by removing damaged or mismatched bases, producing apurinic/apyrimidinic (AP) DNA. For many glycosylases, the AP-DNA remains tightly bound, impeding enzymatic turnover. A prominent example is thymine DNA glycosylase (TDG), which removes T from G.T mispairs and recognizes other lesions, with specificity for damage at CpG dinucleotides. TDG turnover is very slow; its activity appears to reach a plateau as the [product]/[enzyme] ratio approaches unity. The follow-on base excision repair enzyme, AP endonuclease 1 (APE1), stimulates the turnover of TDG and other glycosylases, involving a mechanism that remains largely unknown. We examined the catalytic activity of human TDG (hTDG), alone and with human APE1 (hAPE1), using pre-steady-state kinetics and a coupled-enzyme (hTDG-hAPE1) fluorescence assay. hTDG turnover is exceedingly slow for G.T (k(cat)=0.00034 min(-1)) and G.U (k(cat)=0.005 min(-1)) substrates, much slower than k(max) from single turnover experiments, confirming that AP-DNA release is rate-limiting. We find unexpectedly large differences in k(cat) for G.T, G.U, and G.FU substrates, indicating the excised base remains trapped in the product complex by AP-DNA. hAPE1 increases hTDG turnover by 42- and 26-fold for G.T and G.U substrates, the first quantitative measure of the effect of hAPE1. hAPE1 stimulates hTDG by disrupting the product complex rather than merely depleting (endonucleolytically) the AP-DNA. The enhancement is greater for hTDG catalytic core (residues 111-308 of 410), indicating the N- and C-terminal domains are dispensable for stimulatory interactions with hAPE1. Potential mechanisms for hAPE1 disruption of the of hTDG product complex are discussed.
Highlights
The nucleobases in DNA are continuously modified by processes involving deamination, methylation, and oxidation, generating mutagenic and cytotoxic lesions that are implicated in aging and diseases including cancer and neurodegeneration [1, 2]
Kinetics of human thymine DNA glycosylase (hTDG) Alone—To advance our understanding of how human APE1 (hAPE1) stimulates the turnover of hTDG, it was necessary and G1⁄7FU20 substrates, reactions were rapidly brought to com- to first determine the kinetic parameters for hTDG in the pletion by adding 25 nM human uracil DNA glycosylase absence of hAPE1
Implications for the Kinetic Mechanism of hTDG—The presteady-state kinetics experiments collected here for hTDG provide important new insight into its catalytic mechanism. hTDG is widely regarded as a “single turnover” enzyme, because in many previous studies the reaction reaches a plateau as the [product]/[enzyme] ratio approaches unity for G1⁄7U and G1⁄7T substrates [13, 27]
Summary
APURINIC/APYRIMIDINIC ENDONUCLEASE 1 ACTIVELY STIMULATES THYMINE DNA GLYCOSYLASE BY DISRUPTING THE PRODUCT COMPLEX*. Previous studies of BER in organisms ranging from Escherichia coli to humans have shown that AP endonucleases stimulate the activity (turnover) of many DNA glycosylases (6 –10) These important findings suggest some degree of coordination in the initial steps of BER, yet the mechanism remains largely unknown. We address this question here for human thymine DNA glycosylase (hTDG), which removes T from G1⁄7T mispairs and excises many additional lesions, with specificity for damaged bases that are paired with guanine and located in a CpG sequence context [11,12,13,14,15]. The coupled-enzyme assay described here provides a new approach for studying the mechanism of hTDG using steady-state kinetics
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