Nucleic Acids Regulate Intracellular Ions and Membrane Potential

Paracelsus proceedings of experimental medicine Pub Date : 2022-03-15 DOI:10.33594/000000613

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Abstract

The positive charge on the major intracellular inorganic cations (K+, Na+, and Mg2+) significantly exceeds the combined negative charge on Cl- and HCO3-. This so-called anion gap must be balanced by organic anions. From the analysis of published data, we conclude that organic phosphorus-containing compounds (Po) are responsible for the neutralization of much of the anion gap. Importantly, many of them are large polymers, such as DNA, RNA, or polyphosphate, that undergo regular synthesis and degradation. That produces a variable average valency z associated with organic anions. It follows from theory that an increase in z should lead to membrane hyperpolarization and accumulation of cations: this result has been known before, and here we further confirm it by an analysis based on different cellular and computational models. Furthermore, we show that inhibition of potassium channels is expected to reduce the uptake of phosphorus through sodium-coupled transporters. This suggests a simple explanation to two long-established experimental facts about DNA synthesis: namely, that it is accompanied by cell hyperpolarization and that it requires functional potassium channels.

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核酸调节细胞内离子和膜电位

细胞内主要无机阳离子（K+、Na+和Mg2+）上的正电荷显著超过Cl-和HCO3-上的组合负电荷。这个所谓的阴离子间隙必须由有机阴离子平衡。通过对已发表数据的分析，我们得出结论，有机含磷化合物（Po）对大部分阴离子间隙的中和负有责任。重要的是，它们中的许多是大型聚合物，如DNA、RNA或聚磷酸盐，它们会定期合成和降解。这产生了与有机阴离子相关的可变平均化合价z。从理论上讲，z的增加应该导致膜超极化和阳离子的积累：这个结果以前已经知道了，在这里我们通过基于不同细胞和计算模型的分析进一步证实了这一点。此外，我们发现抑制钾通道有望减少通过钠偶联转运蛋白对磷的摄取。这为DNA合成的两个长期存在的实验事实提供了一个简单的解释：即它伴随着细胞超极化，并且需要功能性钾通道。

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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Paracelsus proceedings of experimental medicine

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