WNT 信号通路和 AHCTF1 通过超级增强子介导的基因门控促进致癌 MYC 表达。

WNT signaling and AHCTF1 promote oncogenic MYC expression through super-enhancer-mediated gene gating.

机构信息

Department of Oncology-Pathology, Karolinska Institutet, Karolinska University Hospital, Bioclinicum, Solna, Sweden.

Bio Systems Design Department, Bio Analytical Systems Product Division, Analytical & Medical Solution Business Group, Hitachi High Technologies, Hitachinaka, Ibaraki, Japan.

出版信息

Nat Genet. 2019 Dec;51(12):1723-1731. doi: 10.1038/s41588-019-0535-3. Epub 2019 Nov 29.

DOI:10.1038/s41588-019-0535-3

PMID:31784729

Abstract

WNT signaling activates MYC expression in cancer cells. Here we report that this involves an oncogenic super-enhancer-mediated tethering of active MYC alleles to nuclear pores to increase transcript export rates. As the decay of MYC transcripts is more rapid in the nucleus than in the cytoplasm, the oncogenic super-enhancer-facilitated export of nuclear MYC transcripts expedites their escape from the nuclear degradation system in colon cancer cells. The net sum of this process, as supported by computer modeling, is greater cytoplasmic MYC messenger RNA levels in colon cancer cells than in wild type cells. The cancer-cell-specific gating of MYC is regulated by AHCTF1 (also known as ELYS), which connects nucleoporins to the oncogenic super-enhancer via β-catenin. We conclude that WNT signaling collaborates with chromatin architecture to post-transcriptionally dysregulate the expression of a canonical cancer driver.

摘要

WNT 信号通路在癌细胞中激活 MYC 表达。在这里，我们报告说，这涉及到一种致癌超级增强子介导的将活跃的 MYC 等位基因固定到核孔上，以增加转录物的输出率。由于 MYC 转录本在细胞核中的降解速度比在细胞质中更快，因此致癌超级增强子促进核 MYC 转录本的输出加速了它们从结肠癌细胞核降解系统中的逃逸。计算机建模支持的这一过程的净结果是，结肠癌细胞中的细胞质 MYC 信使 RNA 水平高于野生型细胞。MYC 的癌细胞特异性门控由 AHCTF1（也称为 ELYS）调节，该蛋白通过β-catenin 将核孔蛋白与致癌超级增强子连接起来。我们得出结论，WNT 信号通路与染色质结构合作，在后转录水平上失调典型的癌症驱动基因的表达。

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WNT 信号通路和 AHCTF1 通过超级增强子介导的基因门控促进致癌 MYC 表达。

WNT signaling and AHCTF1 promote oncogenic MYC expression through super-enhancer-mediated gene gating.

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