Department of Medicine, Emory University School of Medicine , Atlanta, Georgia.
Department of Physiology, University of Maryland School of Medicine , Baltimore, Maryland.
Am J Physiol Renal Physiol. 2018 Jul 1;315(1):F7-F15. doi: 10.1152/ajprenal.00576.2017. Epub 2018 Feb 7.
α-Ketoglutarate (α-KG) is a citric acid cycle intermediate and a glutamine catabolism product. It is also the natural ligand of 2-oxoglutarate receptor 1 (OXGR1), a G protein-coupled receptor expressed on the apical membrane of intercalated cells. In the cortical collecting duct (CCD), Cl/[Formula: see text] exchange increases upon α-KG binding to the OXGR1. To determine the signaling pathway(s) by which α-KG stimulates Cl absorption, we examined α-KG-stimulated Cl absorption in isolated perfused mouse CCDs. α-KG increased electroneutral Cl absorption in CCDs from wild-type mice but had no effect on Cl absorption in pendrin knockout mice. Because G protein-coupled receptors activate PKC, we hypothesized that α-KG stimulates Cl absorption through PKC. If so, PKC agonists should mimic, whereas PKC inhibitors should abolish, α-KG-stimulated Cl absorption. Like α-KG, PKC agonist (phorbol-12,13-dibutyrate, 500 nM) application increased Cl absorption in wild-type but not in pendrin null CCDs. Moreover, PKC inhibitors (2.5 mM GF109203X and 20 nM calphostin C), Ca chelators (BAPTA, 10-20 μM), or PKC-α or -δ gene ablation eliminated α-KG-stimulated Cl absorption. We have shown that STE20/SPS-1-related proline-alanine-rich protein kinase (SPAK) gene ablation increases urinary α-KG excretion, renal pendrin abundance, and CCD Cl absorption. However, in SPAK null CCDs, Cl absorption was not activated further by luminal α-KG application nor was Cl absorption reduced with the PKC inhibitor GF109203 . Thus SPAK gene ablation likely acts through a PKC-independent pathway to produce a chronic adaptive increase in pendrin function. In conclusion, α-KG stimulates pendrin-dependent Cl/[Formula: see text] exchange through a mechanism dependent on PKC and Ca that involves PKC-α and PKC-δ.
α-酮戊二酸(α-KG)是柠檬酸循环的中间产物和谷氨酰胺分解产物。它也是 2-氧戊二酸受体 1(OXGR1)的天然配体,OXGR1 是一种表达在闰细胞顶膜上的 G 蛋白偶联受体。在皮质集合管(CCD)中,当α-KG 与 OXGR1 结合时,Cl/[Formula: see text]交换增加。为了确定 α-KG 刺激 Cl 吸收的信号通路,我们在分离灌注的小鼠 CCD 中检查了 α-KG 刺激的 Cl 吸收。α-KG 增加了野生型小鼠 CCD 中的电中性 Cl 吸收,但对 pendrin 敲除小鼠的 Cl 吸收没有影响。由于 G 蛋白偶联受体激活 PKC,我们假设 α-KG 通过 PKC 刺激 Cl 吸收。如果是这样,PKC 激动剂应该模拟,而 PKC 抑制剂应该消除,α-KG 刺激的 Cl 吸收。与 α-KG 一样,PKC 激动剂(佛波醇 12,13-二丁酸酯,500 nM)的应用增加了野生型但不增加 pendrin 缺失 CCD 中的 Cl 吸收。此外,PKC 抑制剂(2.5 mM GF109203X 和 20 nM 钙调蛋白 C)、Ca 螯合剂(BAPTA,10-20 μM)或 PKC-α 或 -δ 基因缺失消除了 α-KG 刺激的 Cl 吸收。我们已经表明,STE20/SPS-1 相关脯氨酸-丙氨酸丰富蛋白激酶(SPAK)基因缺失增加尿中 α-KG 排泄、肾脏 pendrin 丰度和 CCD Cl 吸收。然而,在 SPAK 缺失的 CCD 中,腔内 α-KG 应用并未进一步激活 Cl 吸收,PKC 抑制剂 GF109203X 也未降低 Cl 吸收。因此,SPAK 基因缺失可能通过一种独立于 PKC 的途径发挥作用,导致 pendrin 功能的慢性适应性增加。总之,α-KG 通过一种依赖于 PKC 和 Ca 的机制刺激 pendrin 依赖性 Cl/[Formula: see text]交换,该机制涉及 PKC-α 和 PKC-δ。
