Abstract

DNA polymerase theta (Pol{theta}) is a DNA repair enzyme critical for microhomology mediated end joining (MMEJ). Pol{theta} has limited expression in normal tissues but is frequently overexpressed in cancer cells and, therefore, represents an ideal target for tumor-specific radiosensitization. Here, we show that ART558 and ART899, two novel and specific allosteric inhibitors of the Pol{theta} DNA polymerase domain, potently radiosensitize tumor cells, particularly when combined with fractionated radiation. Importantly, normal fibroblasts are not radiosensitized by Pol{theta} inhibition. Mechanistically, we show that the radiosensitization caused by Pol{theta} inhibition is most effective in replicating cells and is due to impaired DNA damage repair. We also show that radiosensitization is still effective under hypoxia, suggesting that these inhibitors may help overcome hypoxia-induced radioresistance. In addition, we describe for the first time ART899 and characterize it as a potent and specific Pol{theta} inhibitor with improved metabolic stability. In vivo, the combination of Pol{theta} inhibition using ART899 with fractionated radiation is well tolerated and results in a significant reduction in tumor growth compared to radiation alone. These results pave the way for future clinical trials of Pol{theta} inhibitors in combination with radiotherapy.