The context-dependent epigenetic and organogenesis programs determine 3D vs. 2D cellular fitness of MYC-driven murine liver cancer cells.

Research square Pub Date : 2024-09-13 DOI:10.21203/rs.3.rs-4390765/v1

Jun Yang, Jie Fang, Shivendra Singh, Brennan Wells, Qiong Wu, Hongjian Jin, Laura Janke, Shibiao Wan, Jacob Steele, Jon Connelly, Andrew Murphy, Ruoning Wang, Andrew Davidoff, Margaret Ashcroft, Shondra Pruett-Miller

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Abstract

3D cellular-specific epigenetic and transcriptomic reprogramming is critical to organogenesis and tumorigenesis. Here we dissect the distinct cell fitness in 2D (normoxia vs. chronic hypoxia) vs 3D (normoxia) culture conditions for a MYC-driven murine liver cancer model. We identify over 600 shared essential genes and additional context-specific fitness genes and pathways. Knockout of the VHL-HIF1 pathway results in incompatible fitness defects under normoxia vs. 1% oxygen or 3D culture conditions. Moreover, deletion of each of the mitochondrial respiratory electron transport chain complex has distinct fitness outcomes. Notably, multicellular organogenesis signaling pathways including TGFb-SMAD specifically constrict the uncontrolled cell proliferation in 3D while inactivation of epigenetic modifiers (Bcor, Kmt2d, Mettl3 and Mettl14) has opposite outcomes in 2D vs. 3D. We further identify a 3D-dependent synthetic lethality with partial loss of Prmt5 due to a reduction of Mtap expression resulting from 3D-specific epigenetic reprogramming. Our study highlights unique epigenetic, metabolic and organogenesis signaling dependencies under different cellular settings.

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环境依赖性表观遗传和器官发生程序决定了 MYC 驱动的癌症的三维与二维细胞适应性。

三维细胞特异性表观遗传和转录组重编程对器官生成和肿瘤发生至关重要。在这里，我们剖析了二维（常氧与慢性缺氧）与三维（常氧）培养条件下不同的细胞适应性。我们发现了 600 多个共享的重要基因以及其他特定环境下的适应性基因和通路。敲除 VHL-HIF1 通路会导致在常氧与 1% 氧或三维培养条件下出现不相容的适应性缺陷。此外，线粒体呼吸电子传递链复合物的每一个基因缺失都会导致不同的适应性结果。值得注意的是，多细胞器官发生信号通路（包括 TGFβ-SMAD）在三维条件下会特异性地限制细胞的失控增殖，而表观遗传修饰因子（Bcor、Kmt2d、Mettl3 和 Mettl14）的失活在二维与三维条件下会产生相反的结果。我们进一步发现，由于三维特异性表观遗传重编程导致Mtap表达减少，Prmt5部分缺失会导致三维依赖性合成致死。我们的研究强调了不同细胞环境下独特的表观遗传、新陈代谢和器官生成信号依赖性。

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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