Unbiased functional genetic screens reveal essential RNA modifications in human cancer and drug resistance

bioRxiv Pub Date : 2024-07-16 DOI:10.1101/2024.07.13.603368
C. Pauli, M. Kienhöfer, M. Blank, Oguzhan Begik, Christian Rohde, D. Heid, Fu Xu, Sarah Miriam Naomi Zimmermann, Katharina Weidenauer, Sylvain Delaunay, Nadja Krall, Katrin Trunk, Duoduo Zhao, Fengbiao Zhou, Anke Heit-Mondrzyk, U. Platzbecker, Claudia Baldus, H. Serve, M. Bornhäuser, Cathrine Broberg Vågbø, Salvador Aznar Benitah, Jeroen Krijgsveld, E. Novoa, Carsten Müller-Tidow, Michaela Frye
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Abstract

RNA modification pathways are mis-regulated in multiple types of human cancer. To comprehensively identify cancer-relevant RNA modifications and their regulators, we screened all 150 annotated human RNA modifying proteins across 18 different normal and cancer cell lines using a CRISPR-based genetic knockout system. Fifty RNA modifying proteins were essential for survival of at least one cell type. A third of these essential genes were amplified in 38 different human primary cancer types and potentially drive cancer growth. Unexpectedly, the number of essential genes per cell line varied considerably, and this variation was not due to tissue of origin. Instead, we found that cancer cell-specific mitochondrial metabolic plasticity was responsible for the unique requirement of certain RNA modifications. For example, leukemia cells with high intrinsic drug tolerance required mitochondrial flexibility to survive treatment with the anti-leukemic drugs cytarabine and venetoclax. Synthetic lethality screens revealed that drug-resistance is abolished by deleting the mitochondrial methyltransferase TRMT5, which is responsible for the formation of N1-methylguanosine (m1G) in the tRNA anticodon loop. In summary, our study identifies cancer-relevant RNA modifying enzymes, and reveals a novel promising drug target for therapy-resistant acute myeloid leukemia.
无偏见的功能基因筛选揭示了人类癌症和耐药性中至关重要的 RNA 修饰
在多种类型的人类癌症中,RNA修饰通路被错误调控。为了全面鉴定与癌症相关的 RNA 修饰及其调控因子,我们使用基于 CRISPR 的基因敲除系统筛选了 18 种不同正常细胞系和癌细胞系中所有 150 个注释的人类 RNA 修饰蛋白。有 50 种 RNA 修饰蛋白对至少一种细胞类型的存活至关重要。其中三分之一的重要基因在 38 种不同的人类原发性癌症类型中被扩增,并可能驱动癌症生长。意想不到的是,每个细胞系的必需基因数量差异很大,而这种差异并不是由于原发组织造成的。相反,我们发现癌细胞特定的线粒体代谢可塑性是某些 RNA 修饰的独特需求的原因。例如,具有高度内在耐药性的白血病细胞需要线粒体的灵活性,才能在抗白血病药物阿糖胞苷和 Venetoclax 的治疗中存活下来。合成致死筛选显示,删除线粒体甲基转移酶 TRMT5 就能消除耐药性,TRMT5 负责在 tRNA 反密码子环中形成 N1-甲基鸟苷(m1G)。总之,我们的研究发现了与癌症相关的 RNA 修饰酶,并揭示了治疗耐药急性髓性白血病的新药靶点。
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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