AI Article Synopsis
- ! Cancer cells can grow back after treatment and sometimes become resistant to drugs, which makes it really hard to get rid of them. *2! Some cancer cells have extra centrosomes, which help them divide and survive; researchers think that by targeting how these centrosomes group together, they might find a new way to treat cancer. *3! A protein called KIFC1 plays an important role in this centrosome grouping and can help cancer cells survive even after stressful treatments, so stopping KIFC1 might help doctors fight cancer better in the future.
Article Abstract
Drug resistance and tumor recurrence are major challenges in cancer treatment. Cancer cells often display centrosome amplification. To maintain survival, cancer cells achieve bipolar division by clustering supernumerary centrosomes. Targeting centrosome clustering is therefore considered a promising therapeutic strategy. However, the regulatory mechanisms of centrosome clustering remain unclear. Here we report that KIFC1, a centrosome clustering regulator, is positively associated with tumor recurrence. Under DNA damaging treatments, the ATM and ATR kinases phosphorylate KIFC1 at Ser26 to selectively maintain the survival of cancer cells with amplified centrosomes via centrosome clustering, leading to drug resistance and tumor recurrence. Inhibition of KIFC1 phosphorylation represses centrosome clustering and tumor recurrence. This study identified KIFC1 as a prognostic tumor recurrence marker, and revealed that tumors can acquire therapeutic resistance and recurrence via triggering centrosome clustering under DNA damage stresses, suggesting that blocking KIFC1 phosphorylation may open a new vista for cancer therapy.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7782532 | PMC |
| http://dx.doi.org/10.1038/s41467-020-20208-x | DOI Listing |
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