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棘皮动物基因 - 调控系统的结构与演化。

Architecture and evolution of the -regulatory system of the echinoderm gene.

机构信息

Department of Biological Sciences, Carnegie Mellon University, Pittsburgh, United States.

出版信息

Elife. 2022 Feb 25;11:e72834. doi: 10.7554/eLife.72834.

DOI:10.7554/eLife.72834
PMID:35212624
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8903837/
Abstract

The gene regulatory network (GRN) that underlies echinoderm skeletogenesis is a prominent model of GRN architecture and evolution. is an essential downstream effector gene in this network and encodes an Ig-superfamily protein required for the fusion of skeletogenic cells and the formation of the skeleton. In this study, we dissected the transcriptional control region of the gene of the purple sea urchin, . Using plasmid- and bacterial artificial chromosome-based transgenic reporter assays, we identified key -regulatory elements (CREs) and transcription factor inputs that regulate , including direct, positive inputs from two key transcription factors in the skeletogenic GRN, Alx1 and Ets1. We next identified -regulatory regions from seven other echinoderm species that together represent all classes within the phylum. By introducing these heterologous regulatory regions into developing sea urchin embryos we provide evidence of their remarkable conservation across ~500 million years of evolution. We dissected in detail the regulatory region of the sea star, , and demonstrated that it also receives direct inputs from Alx1 and Ets1. Our findings identify as a component of the ancestral echinoderm skeletogenic GRN. They support the view that GRN subcircuits, including specific transcription factor-CRE interactions, can remain stable over vast periods of evolutionary history. Lastly, our analysis of establishes direct linkages between a developmental GRN and an effector gene that controls a key morphogenetic cell behavior, cell-cell fusion, providing a paradigm for extending the explanatory power of GRNs.

摘要

基因调控网络(GRN)是棘皮动物骨骼发生的基础,它是 GRN 结构和进化的突出模型。是该网络中的一个重要下游效应基因,编码一种 Ig 超家族蛋白,该蛋白对于骨骼生成细胞的融合和骨骼的形成是必需的。在这项研究中,我们剖析了紫色海胆 基因的转录调控区。通过质粒和细菌人工染色体(BAC)为基础的转基因报告基因检测,我们鉴定了关键的 - 调控元件(CREs)和转录因子输入,这些输入调节 ,包括骨骼发生 GRN 中的两个关键转录因子 Alx1 和 Ets1 的直接、正调控输入。接下来,我们从其他 7 种棘皮动物物种中鉴定了 - 调控区,它们共同代表了该门的所有类群。通过将这些异源调控区引入正在发育的海胆胚胎中,我们提供了它们在大约 5 亿年的进化过程中显著保守的证据。我们详细剖析了海星 基因的 调控区,并证明它也接收来自 Alx1 和 Ets1 的直接输入。我们的研究结果将 确定为祖先棘皮动物骨骼发生 GRN 的一个组成部分。它们支持这样的观点,即 GRN 亚回路,包括特定的转录因子-CRE 相互作用,可以在漫长的进化历史中保持稳定。最后,我们对 基因的分析建立了发育 GRN 与控制关键形态发生细胞行为(细胞融合)的效应基因之间的直接联系,为扩展 GRN 的解释能力提供了范例。

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