, M.
, Jacobs, A.
, Donley, N.
, Calkins, M.
, Jadhav, A.
, Dorjsuren, D.
, Maloney, D.
, Simeonov, A.
, Jaruga, P.
, Coskun, E.
, McCullough, A.
and Lloyd, R.
(2017),
Small molecule inhibitors of DNA glycosylases as potential drugs in cancer therapy, 2nd International Conference on Nucleic Acids, Molecular Biology & Biologics, Philadelphia, PA
(Accessed November 21, 2024)
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Small molecule inhibitors of DNA glycosylases as potential drugs in cancer therapy
Published
Author(s)
, Aaron C. Jacobs, Nathan Donley, Marcus J. Calkins, Ajit Jadhav, Dorjbal Dorjsuren, David Maloney, Anton Simeonov, , , Amanda K. McCullough, R. S. Lloyd
Abstract
Statement of the Problem: Most chemotherapeutic agents kill cancer cells by damaging DNA. Cancer cells overexpress DNA repair proteins and thus increase DNA repair capacity that can cause resistance to therapy by removing DNA lesions before they become toxic. DNA repair proteins constitute targets for inhibitors to overcome the therapy resistance. Inhibition of DNA repair proteins is a promising approach to enhance the efficacy of cancer therapy. Despite the successes with other proteins, the development of inhibitors has been lagging for DNA glycosylases involved in the base excision repair mechanism. The purpose of this study was to discover small molecule inhibitors of the major human DNA glycosylases NEIL1, NTH1 and OGG1. First, we developed a fluorescence-based assay using double-stranded oligodeoxynucleotides containing one substrate lesion to detect both glycosylase and apyrimidinic/apurinic lyase activities of DNA glycosylases. From a screen of ∼400,000 compunds, a number of inhibitors were identified. Subsequently, we applied gas chromatography/isotope-dilution tandem mass spectrometry to measure the glycosylase activities of NEIL1, NTH1 and OGG1 using damaged DNA containing multiple lesions. Findings: Four purine analogs were found to be potent inhibitors of excision of the main substrates of NEIL1. Three of NEIL1 inhibitors also inhibited the excision of NTH1 substrates, but did not affect OGG1 activity. From a screen of ∼50,000 molecules, five hydrazydes were identified as potent inhibitors of OGG1 (Figure 1). These compounds exhibited no inhibition of NEIL1 and NTH1 activities for all their substrates analyzed by two different methodologies used in this work. Conclusion & Significance: Overall, this work forms the foundation for future drug discovery for the entire family of DNA glycosylases. The inhibitors identified serve as a proof-of-concept for the initial phase of the drug discovery process. Future work will involve the screening of additional coConference Dates
August 31-September 1, 2017
Conference Location
Philadelphia, PA
Conference Title
2nd International Conference on Nucleic Acids, Molecular Biology & Biologics
Pub Type
Conferences
Keywords
cancer, DNA glycosylases, GC-MS/MS, DNA repair inhibitors
Citation
Issues
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Created August 31, 2017, Updated February 19, 2020