AI Article Synopsis
- Radiation and genotoxic drugs are essential in cancer treatment but often encounter resistance due to DNA repair mechanisms.
- DNA damage responses (DDR) involve key kinases like ATM, ATR, and DNA-PK, which regulate the body's response to DNA damage and can be targeted to enhance treatment effectiveness.
- The review discusses the potential of ATM inhibitors and other related inhibitors to improve cancer therapy through selective killing of cancer cells via a concept called synthetic lethality, although few effective inhibitors have been identified so far.
Article Abstract
Radiation and genotoxic drugs are two of the cornerstones of current cancer treatment strategy. However, this type of therapy often suffers from radio- or chemo-resistance caused by DNA repair mechanisms. With the aim of increasing the efficacy of these treatments, there has been great interest in studying DNA damage responses (DDR). Among the plethora of signal and effector proteins involved in DDR, three related kinases ATM (ataxia telangiectasia mutated), ATR (ATM and Rad3-related) and DNA-PK (DNA-dependent protein kinase) play the main roles in initiation and regulation of signaling pathways in response to DNA double and single strand breaks (DSB and SSB). ATM inhibitors, as well as those of ATR and DNA-PK, provide an opportunity to sensitize cancer cells to therapy. Moreover, they can lead to selective killing of cancer cells, exploiting a concept known as synthetic lethality. However, only a very few selective inhibitors have been identified to this date. This mini-review is focused both on the development of selective inhibitors of ATM and other inhibitors which have ATM as one of their targets.
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