NEK9 ablation rewires docetaxel resistance through induction of ERK-mediated cancer cell pyroptosis

bioRxiv - Cancer Biology Pub Date : 2024-09-14 DOI:10.1101/2024.09.10.612209

Shamima Azma Ansari, Sibasish Mohanty, Pallavi Mohapatra, Rachna Rath, Dillip Muduli, Saroj Kumar Das Majumdar, Rajeeb K. Swain, Rupesh Dash

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Abstract

Docetaxel alone or in combination with other drugs is the most common chemotherapy regimen for several neoplasms including advanced OSCC. Unfortunately, chemoresistance leads to relapse and continued tumor growth. It is therefore important to explore the causative factors for docetaxel resistance. In this study, we performed a CRISPR-based kinome screening that identified Never In Mitosis Gene-A Related Kinase-9 (NEK9) as a major player of docetaxel resistance in OSCC, prostate, and pancreatic cancer lines. NEK9 expression was upregulated in tumor samples of chemotherapy non-responders compared to responder OSCC patients. Our validation data suggests selectively knocking out NEK9 sensitizes cancer cells to docetaxel. Mechanistically, we found that ablation of NEK9 induces DNA damage, activating ERK(p-T202/Y204) that leads to Gasdermin-E mediated Cancer Cell pyroptosis. The in-vitro kinase activity assay identified fostamatinib as a potent inhibitor of NEK9. The xenograft data suggest that fostamatinib restores docetaxel sensitivity and facilitates a significant reduction of tumor burden. Overall, our data suggests a novel combination of fostamatinib and docetaxel needs further clinical investigation in advanced OSCC.

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NEK9 消融可通过诱导 ERK 介导的癌细胞热休克重塑多西他赛耐药性

多西他赛单独使用或与其他药物联合使用是包括晚期OSCC在内的多种肿瘤最常用的化疗方案。不幸的是，化疗耐药会导致复发和肿瘤继续生长。因此，探索多西他赛耐药的致病因素非常重要。在本研究中，我们进行了基于CRISPR的激酶组筛选，发现Never In Mitosis Gene-A Related Kinase-9（NEK9）是OSCC、前列腺癌和胰腺癌株中多西他赛耐药的主要参与者。与有耐药性的 OSCC 患者相比，NEK9 在化疗无应答者的肿瘤样本中表达上调。我们的验证数据表明，选择性敲除 NEK9 可使癌细胞对多西他赛敏感。从机理上讲，我们发现消减 NEK9 会诱导 DNA 损伤，激活 ERK(p-T202/Y204)，从而导致 Gasdermin-E 介导的癌细胞热休克。体外激酶活性测定发现，福斯塔替尼是NEK9的强效抑制剂。异种移植数据表明，福斯塔替尼能恢复多西他赛的敏感性，并能显著减轻肿瘤负荷。总之，我们的数据表明，在晚期OSCC中，需要进一步临床研究福斯塔替尼与多西他赛的新型组合。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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bioRxiv - Cancer Biology

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