Distinguishing mechanisms underlying EMT tristability.

Cancer convergence Pub Date : 2017-01-01 Epub Date: 2017-11-01 DOI:10.1186/s41236-017-0005-8

Dongya Jia, Mohit Kumar Jolly, Satyendra C Tripathi, Petra Den Hollander, Bin Huang, Mingyang Lu, Muge Celiktas, Esmeralda Ramirez-Peña, Eshel Ben-Jacob, José N Onuchic, Samir M Hanash, Sendurai A Mani, Herbert Levine

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引用次数: 74

Abstract

Background: The Epithelial-Mesenchymal Transition (EMT) endows epithelial-looking cells with enhanced migratory ability during embryonic development and tissue repair. EMT can also be co-opted by cancer cells to acquire metastatic potential and drug-resistance. Recent research has argued that epithelial (E) cells can undergo either a partial EMT to attain a hybrid epithelial/mesenchymal (E/M) phenotype that typically displays collective migration, or a complete EMT to adopt a mesenchymal (M) phenotype that shows individual migration. The core EMT regulatory network - miR-34/SNAIL/miR-200/ZEB1 - has been identified by various studies, but how this network regulates the transitions among the E, E/M, and M phenotypes remains controversial. Two major mathematical models - ternary chimera switch (TCS) and cascading bistable switches (CBS) - that both focus on the miR-34/SNAIL/miR-200/ZEB1 network, have been proposed to elucidate the EMT dynamics, but a detailed analysis of how well either or both of these two models can capture recent experimental observations about EMT dynamics remains to be done.

Results: Here, via an integrated experimental and theoretical approach, we first show that both these two models can be used to understand the two-step transition of EMT - E→E/M→M, the different responses of SNAIL and ZEB1 to exogenous TGF-β and the irreversibility of complete EMT. Next, we present new experimental results that tend to discriminate between these two models. We show that ZEB1 is present at intermediate levels in the hybrid E/M H1975 cells, and that in HMLE cells, overexpression of SNAIL is not sufficient to initiate EMT in the absence of ZEB1 and FOXC2.

Conclusions: These experimental results argue in favor of the TCS model proposing that miR-200/ZEB1 behaves as a three-way decision-making switch enabling transitions among the E, hybrid E/M and M phenotypes.

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区分EMT可信赖性的机制。

背景:上皮-间质转化(Epithelial-Mesenchymal Transition, EMT)使上皮细胞在胚胎发育和组织修复过程中具有增强的迁移能力。EMT也可以被癌细胞吸收，以获得转移潜力和耐药性。最近的研究表明，上皮细胞(E)可以经历部分EMT以获得典型的集体迁移的上皮/间充质(E/M)杂交表型，或者完全EMT以采用显示个体迁移的间充质(M)表型。核心EMT调控网络- miR-34/SNAIL/miR-200/ZEB1 -已被各种研究确定，但该网络如何调节E、E/M和M表型之间的转换仍存在争议。已经提出了两个主要的数学模型-三联嵌合体开关(TCS)和级联双稳态开关(CBS) -它们都关注miR-34/SNAIL/miR-200/ZEB1网络，以阐明EMT动力学，但是对这两个模型中的一个或两个模型如何很好地捕获最近关于EMT动力学的实验观察的详细分析仍有待完成。结果:本文通过实验与理论相结合的方法，首先证明了这两个模型都可以用来理解EMT - E→E/M→M的两步转变，SNAIL和ZEB1对外源性TGF-β的不同反应，以及完全EMT的不可逆性。接下来，我们提出了新的实验结果，倾向于区分这两种模型。我们发现ZEB1在E/M H1975杂交细胞中以中等水平存在，而在HMLE细胞中，在缺乏ZEB1和FOXC2的情况下，SNAIL的过表达不足以启动EMT。结论:这些实验结果支持TCS模型，提出miR-200/ZEB1作为三向决策开关，使E、杂交E/M和M表型之间实现转换。

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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Cancer convergence

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