A conserved HOTAIRM1-HOXA1 regulatory axis contributes early to neuronal differentiation.

IF 3.6 3区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

RNA Biology Pub Date : 2023-01-01 Epub Date: 2023-09-24 DOI:10.1080/15476286.2023.2258028

Dana Segal, Samy Coulombe, Jasper Sim, Josée Dostie

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Abstract

HOTAIRM1 is unlike most long non-coding RNAs in that its sequence is highly conserved across mammals. Such evolutionary conservation points to it having a role in key cellular processes. We previously reported that HOTAIRM1 is required to curb premature activation of downstream HOXA genes in a cell model recapitulating their sequential induction during development. We found that it regulates 3' HOXA gene expression by a mechanism involving epigenetic and three-dimensional chromatin changes. Here we show that HOTAIRM1 participates in proper progression through the early stages of neuronal differentiation. We found that it can associate with the HOXA1 transcription factor and contributes to its downstream transcriptional program. Particularly, HOTAIRM1 affects the NANOG/POU5F1/SOX2 core pluripotency network maintaining an undifferentiated cell state. HOXA1 depletion similarly perturbed expression of these pluripotent factors, suggesting that HOTAIRM1 is a modulator of this transcription factor pathway. Also, given that binding of HOTAIRM1 to HOXA1 was observed in different cell types and species, our results point to this ribonucleoprotein complex as an integral part of a conserved HOTAIRM1-HOXA1 regulatory axis modulating the transition from a pluripotent to a differentiated neuronal state.

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一个保守的HOTAIRM1-HOXA1调节轴有助于神经元分化的早期。

HOAIRM1与大多数长的非编码RNA不同，其序列在哺乳动物中高度保守。这种进化保守性表明它在关键的细胞过程中发挥着作用。我们之前报道，HOAIRM1需要在细胞模型中抑制下游HOXA基因的过早激活，该模型概括了它们在发育过程中的顺序诱导。我们发现它通过一种涉及表观遗传学和三维染色质变化的机制来调节3'HOXA基因的表达。在这里，我们发现HOAIRM1在神经元分化的早期阶段参与了适当的进展。我们发现它可以与HOXA1转录因子结合，并参与其下游转录程序。特别地，HOAIRM1影响维持未分化细胞状态的NANOG/POU5F1/SOX2核心多能性网络。HOXA1缺失同样干扰了这些多能因子的表达，表明HOAIRM1是这种转录因子途径的调节剂。此外，鉴于在不同的细胞类型和物种中观察到HOAIRM1与HOXA1的结合，我们的结果表明，这种核糖核蛋白复合物是保守的HOAIRM1-HOXA1调节轴的组成部分，该调节轴调节从多能神经元状态向分化神经元状态的转变。

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

RNA Biology 生物-生化与分子生物学

CiteScore

8.60

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： RNA has played a central role in all cellular processes since the beginning of life: decoding the genome, regulating gene expression, mediating molecular interactions, catalyzing chemical reactions. RNA Biology, as a leading journal in the field, provides a platform for presenting and discussing cutting-edge RNA research. RNA Biology brings together a multidisciplinary community of scientists working in the areas of: Transcription and splicing Post-transcriptional regulation of gene expression Non-coding RNAs RNA localization Translation and catalysis by RNA Structural biology Bioinformatics RNA in disease and therapy

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