Regulation of trophectoderm morphogenesis by small GTPase RHOA through HIPPO signaling-dependent and -independent mechanisms in mouse preimplantation development

IF 2.2 3区生物学 Q4 CELL BIOLOGY

Differentiation Pub Date : 2025-01-01 DOI:10.1016/j.diff.2025.100835

Yusuke Marikawa, Vernadeth B. Alarcon

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Abstract

The trophectoderm (TE) is the first tissue to differentiate during the preimplantation development of the mammalian embryo. It forms the outer layer of the blastocyst and is responsible for generating the blastocoel, a fluid-filled cavity whose expansion is essential for successful hatching and implantation. Here, we investigated the role of the small GTPase RHOA in the morphogenesis of the TE, particularly its relationship with HIPPO signaling, using mouse embryos as a model. Inhibition of RHOA resulted in the failure to form a blastocoel and significantly altered the expression of numerous genes. Transcriptomic analysis revealed that 330 genes were down-regulated and 168 genes were up-regulated by more than two-fold. Notably, 98.4% of these transcriptional changes were reversed by simultaneous inhibition of LATS kinases, indicating that the transcriptional influence of RHOA is primarily mediated through HIPPO signaling. Many of the down-regulated genes are involved in critical processes of TE morphogenesis, such as apical-basal cell polarization, tight junction formation, and sodium and water transport, suggesting that RHOA supports TE development by enhancing the expression of morphogenesis-related genes through HIPPO signaling, specifically via TEAD transcription factors. However, RHOA inhibition also disrupted apical-basal polarity and tight junctions, effects that were not restored by LATS inhibition, pointing to additional HIPPO signaling-independent mechanisms by which RHOA controls TE morphogenesis. Furthermore, RHOA inhibition impaired cell viability at the late blastocyst stage, with partial rescue observed upon LATS inhibition, suggesting that RHOA maintains cell survival through both HIPPO signaling-dependent and -independent pathways. A deeper knowledge of the molecular mechanisms governing TE morphogenesis, including blastocoel expansion and cell viability, could significantly advance assisted reproductive technologies aimed at producing healthy blastocysts.

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小GTPase RHOA通过HIPPO信号依赖性和非依赖性机制调控小鼠着床前发育的滋养外胚层形态发生。

营养外胚层（TE）是哺乳动物胚胎着床前发育过程中最先分化的组织。它形成囊胚的外层，负责产生囊胚腔，囊胚腔是一个充满液体的腔，其扩张对成功孵化和着床至关重要。在这里，我们以小鼠胚胎为模型，研究了小GTPase RHOA在TE形态发生中的作用，特别是它与HIPPO信号传导的关系。RHOA的抑制导致囊胚不能形成，并显著改变了许多基因的表达。转录组学分析显示，330个基因下调，168个基因上调2倍以上。值得注意的是，98.4%的这些转录变化通过同时抑制LATS激酶而逆转，这表明RHOA的转录影响主要是通过HIPPO信号传导介导的。许多下调的基因参与TE形态发生的关键过程，如尖-基底细胞极化、紧密连接的形成以及钠和水的运输，这表明RHOA通过HIPPO信号，特别是通过TEAD转录因子，通过增强形态发生相关基因的表达来支持TE的发展。然而，RHOA抑制也破坏了根尖极性和紧密连接，而LATS抑制无法恢复这种影响，这表明RHOA控制TE形态发生的另外一种与HIPPO信号无关的机制。此外，RHOA抑制会损害囊胚后期的细胞活力，在LATS抑制下观察到部分恢复，这表明RHOA通过HIPPO信号依赖性和非依赖性途径维持细胞存活。更深入地了解TE形态发生的分子机制，包括囊胚膨胀和细胞活力，可以显著推进旨在产生健康囊胚的辅助生殖技术。

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来源期刊

Differentiation 生物-发育生物学

CiteScore

4.10

自引率

3.40%

发文量

审稿时长

51 days

期刊介绍： Differentiation is a multidisciplinary journal dealing with topics relating to cell differentiation, development, cellular structure and function, and cancer. Differentiation of eukaryotes at the molecular level and the use of transgenic and targeted mutagenesis approaches to problems of differentiation are of particular interest to the journal. The journal will publish full-length articles containing original work in any of these areas. We will also publish reviews and commentaries on topics of current interest. The principal subject areas the journal covers are: • embryonic patterning and organogenesis • human development and congenital malformation • mechanisms of cell lineage commitment • tissue homeostasis and oncogenic transformation • establishment of cellular polarity • stem cell differentiation • cell reprogramming mechanisms • stability of the differentiated state • cell and tissue interactions in vivo and in vitro • signal transduction pathways in development and differentiation • carcinogenesis and cancer • mechanisms involved in cell growth and division especially relating to cancer • differentiation in regeneration and ageing • therapeutic applications of differentiation processes.