Homeostats: The hidden rulers of ion homeostasis in plants.

Quantitative plant biology Pub Date : 2024-09-03 eCollection Date: 2024-01-01 DOI:10.1017/qpb.2024.8

Ingo Dreyer, Naomí Hernández-Rojas, Yasnaya Bolua-Hernández, Valentina de Los Angeles Tapia-Castillo, Sadith Z Astola-Mariscal, Erbio Díaz-Pico, Franko Mérida-Quesada, Fernando Vergara-Valladares, Oscar Arrey-Salas, María E Rubio-Meléndez, Janin Riedelsberger, Erwan Michard

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Abstract

Ion homeostasis is a crucial process in plants that is closely linked to the efficiency of nutrient uptake, stress tolerance and overall plant growth and development. Nevertheless, our understanding of the fundamental processes of ion homeostasis is still incomplete and highly fragmented. Especially at the mechanistic level, we are still in the process of dissecting physiological systems to analyse the different parts in isolation. However, modelling approaches have shown that it is not individual transporters but rather transporter networks (homeostats) that control membrane transport and associated homeostatic processes in plant cells. To facilitate access to such theoretical approaches, the modelling of the potassium homeostat is explained here in detail to serve as a blueprint for other homeostats. The unbiased approach provided strong arguments for the abundant existence of electroneutral H⁺/K⁺ antiporters in plants.

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平衡器：植物体内离子平衡的隐藏统治者。

离子稳态是植物体内一个至关重要的过程，与植物的营养吸收效率、抗逆性和整体生长发育密切相关。然而，我们对离子稳态的基本过程的理解仍然是不完整和高度分散的。特别是在机械层面上，我们仍然处于解剖生理系统的过程中，孤立地分析不同的部分。然而，建模方法表明，在植物细胞中，控制膜运输和相关的稳态过程的不是单个转运蛋白，而是转运蛋白网络（稳态因子）。为了方便这些理论方法的使用，这里详细解释了钾稳态器的建模，以作为其他稳态器的蓝图。无偏方法为植物中大量存在电中性的H+/K+反转运体提供了有力的论据。

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

Quantitative plant biology

CiteScore

2.50

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0.00%

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