Tyrosyl-DNA phosphodiesterase I resolves both naturally and chemically induced DNA adducts and its potential as a therapeutic target

Abstract

DNA is subject to a wide range of insults, resulting from endogenous and exogenous sources that need to be metabolized/resolved to maintain genome integrity. Tyrosyl-DNA phosphodiesterase I (Tdp1) is a eukaryotic DNA repair enzyme that catalyzes the removal of covalent 3′-DNA adducts. As a phospholipase D superfamily member Tdp1 utilizes two catalytic histidines each within a His-Lys-Asn motif. Tdp1 was discovered for its ability to hydrolyze the 3′-phospho-tyrosyl that in the cell covalently links DNA Topoisomerase I (Topo1) and DNA. Tdp1’s list of substrates has since grown and can be divided into two groups: protein-DNA adducts, such as camptothecin stabilized Topo1-DNA adducts, and modified nucleotides, including oxidized nucleotides and chain terminating nucleoside analogs. Since many of Tdp1’s substrates are generated by clinically relevant chemotherapeutics, Tdp1 became a therapeutic target for molecularly targeted small molecules. Tdp1’s unique catalytic cycle allows for two different targeting strategies: (1) the intuitive inhibition of Tdp1 catalysis to prevent Tdp1-mediated repair of chemotherapeutically induced DNA adducts, thereby enhancing their toxicity and (2) stabilization of the Tdp1–DNA covalent reaction intermediate, prevents resolution of Tdp1–DNA adduct and increases the half-life of this potentially toxic DNA adduct. This concept is best illustrated by a catalytic Tdp1 mutant that forms the molecular basis of the autosomal recessive neurodegenerative disease spinocerebellar ataxia with axonal neuropathy, and results in an increased stability of its Tdp1–DNA reaction intermediate. Here, we will discuss Tdp1 catalysis from a structure–function perspective, Tdp1 substrates and Tdp1 potential as a therapeutic target.