Protein-protein interactions among ion channels regulate ion transport in the kidney.

E Boulpaep
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Abstract

Epithelial ion transport in various organs has long been known to be controlled by extracellular agonists acting via membrane receptors or by intracellular messengers. Evidence is mounting for regulation of transport by direct interaction among membrane proteins or between a membrane transport protein and membrane-attached proteins. The membrane protein CFTR (Cystic Fibrosis Transmembrane Regulator) is widely expressed along the length of the nephron, but its role as a chloride channel does not appear to be critical for renal handling of salt and water. It is well established that the inward rectifying K channels (ROMK = Kir 1.1) in the thick ascending limb of Henle and in principal cells of the collecting duct are inhibited by millimolar concentrations of cytosolic Mg-ATP. However, the mechanism of this inhibition has been an enigma. We propose that the ATP-Binding Cassette (ABC) protein CFTR is a cofactor for Kir 1.1 regulation. Indeed, Mg-ATP sensitivity of Kir 1.1 is completely absent in two different mouse models of cystic fibrosis. In addition, the open-closed state of CFTR appears to provide a molecular gating switch that prevents or facilitates the ATP sensing of Kir 1.1. Does Mg-ATP sensing by the CFTR- Kir 1.1 complex play a role in coupling metabolism to ion transport? Physiological intracellular ATP concentrations in tubule cells are in the millimolar range, a saturating concentration for the gating of Kir 1.1 by Mg-ATP. Therefore, Kir 1.1 channels would be closed and unable to contribute to regulation of potassium secretion unless some other process modulated the CFTR-dependent ATP-sensitivity of Kir 1.1. The third component of the metabolic sensor-effector complex for Kir 1.1 regulation is most likely the AMP-regulated serine-threonine kinase, AMP kinase (AMPK). Changing levels in AMP rather than in ATP constitute the metabolic signal "sensed" by tubule cells. Because AMPK inhibits CFTR by modulating CFTR channel gating, we propose that renal K secretion is physiologically regulated by tri-molecular interactions between Kir 1.1, CFTR and AMPK.

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离子通道之间的蛋白质-蛋白质相互作用调节肾脏中的离子运输。
上皮离子在各种器官中的转运是由细胞外激动剂通过膜受体或细胞内信使控制的。越来越多的证据表明,通过膜蛋白之间或膜转运蛋白与膜附着蛋白之间的直接相互作用来调节转运。膜蛋白CFTR(囊性纤维化跨膜调节因子)沿着肾单位的长度广泛表达,但其作为氯离子通道的作用似乎对肾脏处理盐和水并不重要。已经确定,在Henle的厚升翼和收集管的主要细胞中,向内整流的K通道(ROMK = Kir 1.1)受到毫摩尔浓度的细胞质Mg-ATP的抑制。然而,这种抑制的机制一直是一个谜。我们认为atp结合盒(ABC)蛋白CFTR是Kir 1.1调控的辅助因子。事实上,在两种不同的囊性纤维化小鼠模型中,Kir 1.1的Mg-ATP敏感性完全缺失。此外,CFTR的开闭状态似乎提供了一个分子门控开关,阻止或促进Kir 1.1的ATP感应。CFTR- Kir 1.1复合物对Mg-ATP的感应是否在离子转运的耦合代谢中起作用?小管细胞的生理细胞内ATP浓度在毫摩尔范围内,这是Mg-ATP门控Kir 1.1的饱和浓度。因此,Kir 1.1通道将被关闭,无法参与钾分泌的调节,除非有其他过程调节Kir 1.1依赖cftr的atp敏感性。调节Kir 1.1的代谢传感器效应复合物的第三个组成部分最有可能是AMP调节的丝氨酸-苏氨酸激酶,AMP激酶(AMPK)。AMP水平的变化而不是ATP水平的变化构成了小管细胞“感知”的代谢信号。由于AMPK通过调节CFTR通道门控来抑制CFTR,我们提出肾脏K的分泌受到Kir 1.1、CFTR和AMPK之间的三分子相互作用的生理调节。
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