Thiopurine Derivative-Induced Fpg/Nei DNA Glycosylase Inhibition: Structural, Dynamic and Functional Insights.

Charlotte Rieux,Stéphane Bourg,Artur Biela,Zahira Tber,Vincent Aucagne,Stéphane Goffinont,Virginie Gaudon,Vincent Roy,Bertrand Castaing,Franck Coste,Norbert Garnier,Martine Guérin,Luigi Agrofoglio,Julien Cros

doi:10.3390/ijms21062058

Abstract

DNA glycosylases are emerging as relevant pharmacological targets in inflammation, cancer and neurodegenerative diseases. Consequently, the search for inhibitors of these enzymes has become a very active research field. As a continuation of previous work that showed that 2-thioxanthine (2TX) is an irreversible inhibitor of zinc finger (ZnF)-containing Fpg/Nei DNA glycosylases, we designed and synthesized a mini-library of 2TX-derivatives (TXn) and evaluated their ability to inhibit Fpg/Nei enzymes. Among forty compounds, four TXn were better inhibitors than 2TX for Fpg. Unexpectedly, but very interestingly, two dithiolated derivatives more selectively and efficiently inhibit the zincless finger (ZnLF)-containing enzymes (human and mimivirus Neil1 DNA glycosylases hNeil1 and MvNei1, respectively). By combining chemistry, biochemistry, mass spectrometry, blind and flexible docking and X-ray structure analysis, we localized new TXn binding sites on Fpg/Nei enzymes. This endeavor allowed us to decipher at the atomic level the mode of action for the best TXn inhibitors on the ZnF-containing enzymes. We discovered an original inhibition mechanism for the ZnLF-containing Fpg/Nei DNA glycosylases by disulfide cyclic trimeric forms of dithiopurines. This work paves the way for the design and synthesis of a new structural class of inhibitors for selective pharmacological targeting of hNeil1 in cancer and neurodegenerative diseases.

Highlights

DNA constitutive elements are continually subjected to the deleterious effects of physical and chemical agents from endogenous and environmental sources
DNA glycosylases, which initiate base excision repair (BER), constitute the first line of defense against oxidative stress resulting in nucleobase oxidation
The very high level of oxidative stress in viral and bacterial infections, in cancer cells and in the cells of patients suffering from inflammatory diseases, such as Huntington’s disease, give reason to hope that the DNA glycosylases hOgg1 and hNeil1 are relevant pharmacological targets in precise pathologic situations [13,15,17,53,54,55,56]

Summary

Introduction

DNA constitutive elements are continually subjected to the deleterious effects of physical and chemical agents from endogenous and environmental sources. Oxidized bases can mislead or block replication and transcription machinery and result in mutations or cell death These structural DNA changes initiate inflammation, carcinogenesis and age-related neurodegenerative processes [5,6,7,8]. To counteract these adverse effects, organisms, bacteriophages and viruses have evolved numerous DNA repair strategies in which the basic principles have been conserved during evolution [9]. The resulting abasic (AP) site can be excised by the combined action of AP endonucleases, AP lyases and dRp lyases These reactions lead to one or more nucleotide gap. A DNA polymerase and a DNA ligase cooperate to fill in the gap and restore the DNA integrity

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