线粒体代谢是决定大肠癌化疗敏感性的关键因素

Deborah Y Moss, Connor Brown, Andrew Shaw, Christopher McCann, Nikita Lewis, Aaron Phillips, Sarah Gallagher, William J McDaid, Andrew Roe, Aisling Y Coughlan, Brenton Cavanagh, Callum Ormsby, Fiammetta Falcone, Rachel McCole, Scott Monteith, Emily Rogan, Matilda Downs, Sudhir B Malla, Alexandra J Emerson, Letitia Mohammed-Smith, Shaun Sharkey, Peter F Gallagher, Arindam Banerjee, Sufyan Pandor, Brett Greer, Christopher Elliott, Aideen Ryan, Philip D Dunne, Vicky Coyle, Ian G Mills, Simon S McDade, Owen Sansom, Triona Ni Chonghaile, Daniel B Longley, Melissa J LaBonte, Emma M Kerr
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引用次数: 0

摘要

每年有超过 80% 的癌症患者因耐药性而死亡,因此迫切需要克服这一挑战,以改善患者的治疗效果。尽管5-氟尿嘧啶(5FU)在结直肠癌(CRC)治疗中被广泛使用,但人们对它的耐药性仍然知之甚少。在这里,我们研究了 CRC 细胞对 5FU 治疗的转录反应,揭示了线粒体活性显著增强的代谢重编程。利用 CRC 模型,我们证明了 5FU 治疗后线粒体生物生成和功能的持续增强,从而在体外和体内环境中产生抗药性。此外,我们还表明,以线粒体代谢为靶点,特别是通过抑制复合体 I (CI),可使 CRC 细胞对 5FU 敏感,从而在临床前模型中延缓肿瘤生长并延长存活时间。此外,我们对患者数据的分析表明,氧化代谢特征可预测对基于 5FU 的化疗的反应。这些发现揭示了 5FU 耐药的机制,并提出了治疗 CRC 联合疗法的合理策略,强调了以线粒体代谢为靶点克服耐药和改善患者预后的潜在临床益处。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mitochondrial metabolism is a key determinant of chemotherapy sensitivity in Colorectal Cancer
Therapy resistance is attributed to over 80% of cancer deaths per year emphasizing the urgent need to overcome this challenge for improved patient outcomes. Despite its widespread use in colorectal cancer (CRC) treatment, resistance to 5-fluorouracil (5FU) remains poorly understood. Here, we investigate the transcriptional responses of CRC cells to 5FU treatment, revealing significant metabolic reprogramming towards heightened mitochondrial activity. Utilizing CRC models, we demonstrate sustained enhancement of mitochondrial biogenesis and function following 5FU treatment, leading to resistance in both in vitro and in vivo settings. Furthermore, we show that targeting mitochondrial metabolism, specifically by inhibiting Complex I (CI), sensitizes CRC cells to 5FU, resulting in delayed tumour growth and prolonged survival in preclinical models. Additionally, our analysis of patient data suggests that oxidative metabolism signatures may predict responses to 5FU-based chemotherapy. These findings shed light on mechanisms underlying 5FU resistance and propose a rational strategy for combination therapy in CRC, emphasizing the potential clinical benefit of targeting mitochondrial metabolism to overcome resistance and enhance patient outcomes.
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