Balancing sodium and potassium: Implication of mTORC2-mediated ENaC activation in DCT2 and early CNT for potassium balance in high dietary potassium

Abstract

Background: The activity of the epithelial sodium ion channel, ENaC, and ENaC-dependent potassium (K+) secretion through ROMK are influenced by both aldosterone-dependent and independent mechanisms in response to dietary potassium (K+). While ENaC activity in the late connecting tubule (CNT) and cortical collecting duct (CCD) depends on aldosterone, it is aldosterone-independent in the late distal convoluted tubule (DCT2) and early CNT (eCNT). Aldosterone-stimulated ENaC activity relies on SGK1, transcriptionally upregulated by aldosterone and subsequently phosphorylated and activated by mTOR complex-2 (mTORC2). Recent evidence suggests that high potassium can rapidly activate mTORC2/SGK1 signaling to stimulate ENaC. In this study, we explore mTORC2’s role in K+ secretion and aldosterone-independent ENaC regulation. Methods: Rictor, a core component of mTORC2, was selectively knocked out (KO'd) in DCT2, CNT and CD by utilizing Calbindin as Cre-driver (CRKO mice) or late CNT and CD, by employing AQP2 as the Cre-driver (ARKO mice). Both wild-type (WT) and KO mice were subjected to a high potassium (HK) diet for short-term (4 hours) or medium-term (48 hours) periods, enabling the monitoring of both the early response and prolonged adaptation to the HK diet. Parameters assessed include urinary and blood electrolyte levels, renal transporter expression, activity and localization, and mTORC2 target phosphorylation. Results: On a normal K+ diet, both KO mice maintained Na+ and K+ balance but CRKO mice had elevated aldosterone levels. After short-term (4-hour) HK intake, CRKO mice had disrupted Na+ and K+ balance, reduced K+ excretion and hyperkalemia. In contrast, ARKO mice maintained Na+ and K+ balance with elevated aldosterone. On a prolonged HK diet (48 hours), CRKO mice had severe hyperkalemia, reduced GFR and significantly elevated aldosterone level. Immunofluorescence studies indicated markedly reduced apical localization of active ENaC in DCT2/eCNT of CRKO mice. Conversely, ENaC apical localization in the late CNT and CCD was mostly unaffected. Phosphorylation of mTORC2 targets involved in ENaC regulation, such as SGK1, and SGK1’s target, Nedd4-2, was also reduced in CRKO mice. ARKO mice maintained ion balance with normal K+ levels but significantly increased aldosterone levels and maintained ENaC apical localization in the late CNT and CCD. Conclusions: The data suggest that high aldosterone can compensate mTORC2 deficiency and maintain ENaC activity in the late CNT and CCD. However, mTORC2 activity is crucial for maintaining ENaC activity in the late DCT and early CNT (aldosterone-independent) and preserving potassium balance during high dietary potassium intake. National Institutes of Health (R01- DK56695), James Hilton Manning and Emma Austin Manning Foundation. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.