Cell-active small molecule inhibitors validate the SNM1A DNA repair nuclease as a cancer target.
Marcin BielinskiLucy R HendersonYuliana YosaatmadjaLonnie P SwiftHannah T BaddockMatthew J BowenJürgen BremPhilip S JonesStuart P McElroyAngus MorrisonMichael SpeakeStan van BoeckelEls van DoornmalenJan van GroningenHelma van den HurkOpher GileadiJoseph A NewmanPeter J McHughChristopher J SchofieldPublished in: Chemical science (2024)
The three human SNM1 metallo-β-lactamase fold nucleases (SNM1A-C) play key roles in DNA damage repair and in maintaining telomere integrity. Genetic studies indicate that they are attractive targets for cancer treatment and to potentiate chemo- and radiation-therapy. A high-throughput screen for SNM1A inhibitors identified diverse pharmacophores, some of which were shown by crystallography to coordinate to the di-metal ion centre at the SNM1A active site. Structure and turnover assay-guided optimization enabled the identification of potent quinazoline-hydroxamic acid containing inhibitors, which bind in a manner where the hydroxamic acid displaces the hydrolytic water and the quinazoline ring occupies a substrate nucleobase binding site. Cellular assays reveal that SNM1A inhibitors cause sensitisation to, and defects in the resolution of, cisplatin-induced DNA damage, validating the tractability of MBL fold nucleases as cancer drug targets.
Keyphrases
- dna damage
- dna repair
- high throughput
- small molecule
- single cell
- radiation therapy
- papillary thyroid
- oxidative stress
- escherichia coli
- endothelial cells
- genome wide
- squamous cell
- photodynamic therapy
- dna damage response
- genome editing
- multidrug resistant
- cell therapy
- emergency department
- drug delivery
- gene expression
- amino acid
- cancer therapy
- biofilm formation
- case control
- childhood cancer
- histone deacetylase