AI Article Synopsis
- Interfering with mitosis has been a successful cancer treatment for over 20 years, using microtubule poisons, but the exact mechanisms of how these drugs work remain unclear.
- Arresting cancer cells during mitosis can lead to cell death in lab studies; however, cancer cells often develop escape strategies, creating complications in understanding cell death processes.
- The text explores mechanisms and signaling pathways that govern cell death during mitosis and after escape, while also considering how to enhance the clinical effectiveness of anti-mitotic drugs.
Article Abstract
Interfering with mitosis for cancer treatment is an old concept that has proven highly successful in the clinics. Microtubule poisons are used to treat patients with different types of blood or solid cancer since more than 20 years, but how these drugs achieve clinical response is still unclear. Arresting cells in mitosis can promote their demise, at least in a petri dish. Yet, at the molecular level, this type of cell death is poorly defined and cancer cells often find ways to escape. The signaling pathways activated can lead to mitotic slippage, cell death, or senescence. Therefore, any attempt to unravel the mechanistic action of microtubule poisons will have to investigate aspects of cell cycle control, cell death initiation in mitosis and after slippage, at single-cell resolution. Here, we discuss possible mechanisms and signaling pathways controlling cell death in mitosis or after escape from mitotic arrest, as well as secondary consequences of mitotic errors, particularly sterile inflammation, and finally address the question how clinical efficacy of anti-mitotic drugs may come about and could be improved.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC5836099 | PMC |
| http://dx.doi.org/10.15252/embr.201745440 | DOI Listing |
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