Regulations of myo-inositol homeostasis: Mechanisms, implications, and perspectives

Q1 Biochemistry, Genetics and Molecular Biology
Xue Bessie Su, An-Li Andrea Ko, Adolfo Saiardi
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引用次数: 5

Abstract

Phosphorylation is the most common module of cellular signalling pathways. The dynamic nature of phosphorylation, which is conferred by the balancing acts of kinases and phosphatases, allows this modification to finely control crucial cellular events such as growth, differentiation, and cell cycle progression. Although most research to date has focussed on protein phosphorylation, non-protein phosphorylation substrates also play vital roles in signal transduction. The most well-established substrate of non-protein phosphorylation is inositol, whose phosphorylation generates many important signalling molecules such as the second messenger IP3, a key factor in calcium signalling.

A fundamental question to our understanding of inositol phosphorylation is how the levels of cellular inositol are controlled. While the availability of protein phosphorylation substrates is known to be readily controlled at the levels of transcription, translation, and/or protein degradation, the regulatory mechanisms that control the uptake, synthesis, and removal of inositol are underexplored. Potentially, such mechanisms serve as an important layer of regulation of cellular signal transduction pathways.

There are two ways in which mammalian cells acquire inositol. The historic use of radioactive 3H-myo-inositol revealed that inositol is promptly imported from the extracellular environment by three specific symporters SMIT1/2, and HMIT, coupling sodium or proton entry, respectively. Inositol can also be synthesized de novo from glucose-6P, thanks to the enzymatic activity of ISYNA1. Intriguingly, emerging evidence suggests that in mammalian cells, de novo myo-inositol synthesis occurs irrespective of inositol availability in the environment, prompting the question of whether the two sources of inositol go through independent metabolic pathways, thus serving distinct functions. Furthermore, the metabolic stability of myo-inositol, coupled with the uptake and endogenous synthesis, determines that there must be exit pathways to remove this extraordinary sugar from the cells to maintain its homeostasis. This essay aims to review our current knowledge of myo-inositol homeostatic metabolism, since they are critical to the signalling events played by its phosphorylated forms.

肌醇动态平衡的调节:机制、意义和观点
磷酸化是细胞信号通路中最常见的模块。激酶和磷酸酶的平衡作用赋予磷酸化的动态性质,使这种修饰能够精细地控制关键的细胞事件,如生长、分化和细胞周期进展。尽管迄今为止大多数研究都集中在蛋白质磷酸化上,但非蛋白质磷酸化底物在信号转导中也起着至关重要的作用。最成熟的非蛋白质磷酸化底物是肌醇,其磷酸化产生许多重要的信号分子,如第二信使IP3,这是钙信号传导的关键因素。我们理解肌醇磷酸化的一个基本问题是如何控制细胞肌醇的水平。虽然已知蛋白质磷酸化底物的可用性很容易在转录、翻译和/或蛋白质降解水平上得到控制,但控制肌醇摄取、合成和去除的调节机制尚未得到充分探索。这些机制可能成为细胞信号转导途径的重要调控层。哺乳动物细胞获得肌醇有两种途径。放射性3H-肌醇的历史使用表明,肌醇通过三个特异性转运体SMIT1/2和HMIT分别偶联钠或质子进入而迅速从细胞外环境输入。由于ISYNA1的酶活性,肌醇也可以从葡萄糖-6P从头合成。有趣的是,新出现的证据表明,在哺乳动物细胞中,无论肌醇在环境中的可用性如何,都会发生从头开始的肌醇合成,这引发了一个问题,即肌醇的两种来源是否通过独立的代谢途径,从而发挥不同的功能。此外,肌醇的代谢稳定性,加上摄取和内源性合成,决定了必须有出口途径从细胞中去除这种特殊的糖,以维持其稳态。本文旨在回顾我们目前对肌醇稳态代谢的了解,因为它们对其磷酸化形式所起的信号事件至关重要。
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
Advances in biological regulation
Advances in biological regulation Biochemistry, Genetics and Molecular Biology-Molecular Medicine
CiteScore
8.90
自引率
0.00%
发文量
41
审稿时长
17 days
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