Abstract
Eliciting DNA damage in tumor cells continues to be one of the most successful strategies against cancer. This is the case for classical chemotherapy drugs and radiotherapy. In the modern era of personalized medicine, this strategy tries to identify specific vulnerabilities found in each patient's tumor, to inflict DNA damage in certain cell contexts that end up in massive cancer cell death. Cells rely on multiple DNA repair pathways to fix DNA damage, but cancer cells frequently exhibit defects in these pathways, many times being tolerant to the damage. Key vulnerabilities, such as BRCA1/BRCA2 mutations, have been exploited with PARP inhibitors, leveraging synthetic lethality to selectively kill tumor cells and improving patients' survival. In the DNA damage response (DDR) network, kinases ATM, ATR, Chk1, and Chk2 coordinate DNA repair, cell cycle arrest, and apoptosis. Inhibiting these proteins enhances tumor sensitivity to DNA-damaging therapies, especially in DDR-deficient cancers. Several small-molecule inhibitors targeting ATM/Chk2 or ATR/Chk1 are currently being tested in preclinical and/or clinical settings, showing promise in cancer models and patients. Additionally, pharmacological blockade of ATM/Chk2 and ATR/Chk1 axes enhances the effects of immunotherapy by increasing tumor immunogenicity, promoting T-cell infiltration and activating immune responses. Combining ATM/Chk2- or ATR/Chk1-targeting drugs with conventional chemotherapy, radiotherapy or immune checkpoint inhibitors offers a compelling strategy to improve treatment efficacy, overcome resistance, and enhance patients' survival in modern oncology.