Jan Benada, Daria Bulanova, Violette Azzoni, Valdemaras Petrosius, Saba Ghazanfar, Krister Wennerberg, Claus Storgaard Sørensen
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引用次数: 0
摘要
卵巢癌是由基因改变驱动的,这种改变需要通过细胞周期控制和基因组维护来做出保护性 DNA 损伤和复制应激反应。这就造成了一些可被治疗利用的特殊弱点。WEE1 激酶是一种关键的细胞周期控制激酶,已成为一种很有前景的癌症治疗靶点。然而,不良反应限制了其临床进展,尤其是在与化疗药物联合使用时。WEE1和PKMYT1之间存在很强的遗传相互作用,这使我们假设,利用联合抑制WEE1和PKMYT1的多重低剂量方法可以利用合成致死性。我们发现,WEE1 和 PKMYT1 联合抑制在低剂量根除卵巢癌细胞和类器官模型方面表现出协同效应。WEE1和PKMYT1抑制剂协同促进CDK活化。此外,联合治疗会加剧 DNA 复制应激和复制灾难,导致基因组不稳定性增加和 STAT1 信号激活。这些研究结果表明,通过与PKMYT1的合成致死相互作用,一种新的多重低剂量方法可利用WEE1的抑制作用,这可能有助于开发治疗卵巢癌的新疗法。
Synthetic lethal interaction between WEE1 and PKMYT1 is a target for multiple low-dose treatment of high-grade serous ovarian carcinoma.
Ovarian cancer is driven by genetic alterations that necessitate protective DNA damage and replication stress responses through cell cycle control and genome maintenance. This creates specific vulnerabilities that may be exploited therapeutically. WEE1 kinase is a key cell cycle control kinase, and it has emerged as a promising cancer therapy target. However, adverse effects have limited its clinical progress, especially when tested in combination with chemotherapies. A strong genetic interaction between WEE1 and PKMYT1 led us to hypothesize that a multiple low-dose approach utilizing joint WEE1 and PKMYT1 inhibition would allow exploitation of the synthetic lethality. We found that the combination of WEE1 and PKMYT1 inhibition exhibited synergistic effects in eradicating ovarian cancer cells and organoid models at a low dose. The WEE1 and PKMYT1 inhibition synergistically promoted CDK activation. Furthermore, the combined treatment exacerbated DNA replication stress and replication catastrophe, leading to increase of the genomic instability and inflammatory STAT1 signalling activation. These findings suggest a new multiple low-dose approach to harness the potency of WEE1 inhibition through the synthetic lethal interaction with PKMYT1 that may contribute to the development of new treatments for ovarian cancer.