Abstract
Genomic instability, a hallmark of almost all human cancers, drives both carcinogenesis and resistance to therapeutic interventions. Pivotal to the ability of a cell to maintain genome integrity are mechanisms that signal and repair deoxyribonucleic acid (DNA) double-strand breaks (DSBs), one of the most deleterious lesions induced by ionising radiation and various DNA-damaging chemicals. On the other hand, many current therapeutic regimens that effectively kill cancer cells are based on the induction of excessive DSBs. However, these drugs often lack selectivity for tumour cells, which results in severe side effects for the patients, thus compromising their therapeutic potential. Therefore, the development of novel tumour-specific treatment strategies is required. Unlike normal cells, however, cancer cells are often characterised by abnormalities in the DNA damage response including defects in cell cycle checkpoints and/or DNA repair, rendering them particularly sensitive to the induction of DSBs. Therefore, new anticancer agents designed to exploit these vulnerabilities are becoming promising drugs for enhancing the specificity and efficacy of future cancer therapies. Here, we summarise the latest preclinical and clinical developments in cancer therapy based on the current knowledge of DSB signalling and repair, with a special focus on the combination of small molecule inhibitors with synthetic lethality approaches.
Highlights
Cancer is the major cause of death in Switzerland among people aged 45–84 years [1]
In order to stratify cancer patients according to their deoxyribonucleic acid (DNA) repair status, tumour biopsies can be analysed with immunohistochemistry, fluorescence in-situ hybridisation (FISH), gene sequencing, expression profiling and other methods [86]
Relevant biomarker assays should ideally predict the functionality of DNA repair pathways, rather than just providing information about mutations or expression levels of proteins involved in the DNA damage response (DDR)
Summary
Cancer is the major cause of death in Switzerland among people aged 45–84 years [1]. The latest Swiss cancer statistics indicate that prostate cancer in men and breast cancer in women are the most common types, with 6,000 and 5,500 incidences per year, respectively. Inactivation of ATM or CHK1 resulted in reduced viability of FA-deficient cells, illustrating the concept that checkpoint signalling and FA are mutually compensatory pathways in the maintenance of genome integrity [79, 80] These observations highlight the usefulness of SMIs, as currently tested for CHK1, to treat tumours bearing a specific genetic background. Phase I trial in advanced solid tumours showing that MK-4827 is well tolerated, blocks [106] PARP and has promising antitumour activity in both BRCA-deficient and sporadic cancer
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