Transcriptional Regulation of Math1 by Aryl Hydrocarbon Receptor: Effect on Math1+ Progenitor Cells in Mouse Small Intestine.

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
ACS Applied Electronic Materials Pub Date : 2023-01-01 Epub Date: 2023-01-26 DOI:10.1080/10985549.2022.2160610
Yoko Yagishita, Tanvi Joshi, Thomas W Kensler, Nobunao Wakabayashi
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Abstract

The physiological roles of aryl hydrocarbon receptor (AhR) in the small intestine have been revealed as immunomodulatory and barrier functions. However, its contributions to cell fate regulation are incompletely understood. The Notch-activated signaling cascade is a central component of intestinal cell fate determinations. The lateral inhibitory mechanism governed by Notch directs cell fates toward distinct cell lineages (i.e., absorptive and secretory cell lineages) through its downstream effector, mouse atonal homolog 1 (MATH1). An investigation employing cell lines and intestinal crypt cells revealed that AhR regulates Math1 expression in a xenobiotic response element (XRE)-dependent manner. The AhR-Math1 axis was further addressed using intestinal organoids, where AhR-Math1 and HES1-Math1 axes appeared to coexist within the underlying Math1 transcriptional machinery. When the HES1-Math1 axis was pharmacologically suppressed, β-naphthoflavone-mediated AhR activation increased the number of goblet and Math1+ progenitor cells in the organoids. The same pharmacological dissection of the AhR-Math1 axis was applied in vivo, demonstrating an enhanced number of Math1+ progenitor cells in the small intestine following AhR activation. We report here that AhR-Math1 is a direct transcriptional axis with effects on Math1+ progenitor cells in the small intestine, highlighting a novel molecular basis for fine-tuning Notch-mediated cell fate regulation.

芳香烃受体对 Math1 的转录调控:对小鼠小肠中 Math1+祖细胞的影响
芳基烃受体(AhR)在小肠中的生理作用已被揭示为免疫调节和屏障功能。然而,人们对其在细胞命运调控中的作用还不完全了解。Notch激活的信号级联是肠细胞命运决定的核心组成部分。由Notch支配的横向抑制机制通过其下游效应物小鼠节律同源物1(MATH1)将细胞命运导向不同的细胞系(即吸收细胞系和分泌细胞系)。一项利用细胞系和肠隐窝细胞进行的研究发现,AhR 以一种依赖于异生物反应元件(XRE)的方式调控 Math1 的表达。利用肠器官进一步研究了AhR-Math1轴,发现AhR-Math1轴和HES1-Math1轴似乎共存于潜在的Math1转录机制中。当 HES1-Math1 轴被药理学抑制时,β-萘甲黄酮介导的 AhR 激活增加了器官组织中小腺和 Math1+ 祖细胞的数量。对 AhR-Math1 轴的药理分析同样应用于体内,结果表明 AhR 激活后小肠中 Math1+ 祖细胞的数量增加。我们在此报告说,AhR-Math1 是一个直接转录轴,对小肠中的 Math1+ 祖细胞有影响,突出了微调 Notch 介导的细胞命运调控的新分子基础。
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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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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