The intercalated cell Cl−/HCO3− exchanger, pendrin, modulates ENaC subunit abundance and function. Whether ENaC modulates pendrin abundance and function is however unknown. Because αENaC mRNA has been detected in pendrin-positive intercalated cells, we hypothesized that ENaC, or more specifically the αENaC subunit, modulates intercalated cell function. The purpose of this study was therefore to determine if αENaC is expressed at the protein level in pendrin-positive intercalated cells and to determine if αENaC gene ablation or constitutively upregulating ENaC activity changes pendrin abundance, subcellular distribution, and/or function. We observed diffuse, cytoplasmic αENaC label in pendrin-positive intercalated cells from both mice and rats, with much lower label intensity in pendrin-negative, type A intercalated cells. However, while αENaC gene ablation within principal and intercalated cells of the CCD reduced Cl− absorption, it did not change pendrin abundance or subcellular distribution in aldosterone-treated mice. Further experiments used a mouse model of Liddle’s syndrome to explore the effect of increasing ENaC channel activity on pendrin abundance and function. The Liddle’s variant did not increase either total or apical plasma membrane pendrin abundance in aldosterone-treated or in NaCl-restricted mice. Similarly, while the Liddle’s mutation increased total Cl− absorption in CCDs from aldosterone-treated mice, it did not significantly affect the change in Cl− absorption seen with pendrin gene ablation. We conclude that in rats and mice, αENaC localizes to pendrin-positive ICs where its physiological role remains to be determined. While pendrin modulates ENaC abundance, subcellular distribution, and function, ENaC does not have a similar effect on pendrin.
New Findings: What is the central question of this study? Pregnancy requires a robust plasma volume expansion driven by renal sodium retention. In the late-pregnant kidney, the aldosterone-responsive epithelial Na+ channel is increased, whereas the sodium-chloride cotransporter is decreased. Pendrin has been shown to support sodium reabsorption in the distal nephron and compensate for loss of the sodium-chloride cotransporter. We investigated the expression and abundance of pendrin in the pregnant kidney. What is the main finding and its importance? Pendrin protein, apical localization and thiazide sensitivity are increased in pregnancy. This implicates a possible role for pendrin in supporting the renal sodium chloride reabsorption and plasma volume expansion of pregnancy. Pregnancy is characterized by cumulative plasma volume expansion as a result of renal sodium retention, driven by activation of aldosterone. We previously reported that the abundance and activity of the aldosterone-responsive epithelial Na+ channel is increased, whereas the sodium-chloride cotransporter (NCC) is decreased in the kidney of the late-pregnant rat. The chloride-bicarbonate exchanger pendrin is also aldosterone responsive and has been shown to support activity of the aldosterone-responsive epithelial Na+ channel and compensate for the loss of NCC. Additionally, pendrin coupled to the sodium-dependent chloride-bicarbonate exchanger (NDCBE) mediates thiazide-sensitive sodium reabsorption in the cortical collecting duct. In this study, we investigated pendrin and NDCBE transcript expression, pendrin protein abundance, pendrin cellular localization and thiazide sensitivity in virgin, mid-pregnant and late-pregnant rats to test the hypothesis that increased pendrin activity might occur in pregnancy. By RT-PCR, NDCBE and pendrin mRNA expression was unchanged from virgins, whereas pendrin protein abundance determined by Western blotting was increased in both mid- and late-pregnant rats. The apical localization of pendrin was also increased in late-pregnant rats compared with virgins by immunohistochemistry. Pregnant rats displayed an increased natriuretic response to hydrochlorothiazide compared with virgins. Given that NCC expression is decreased in late pregnancy, an increased thiazide sensitivity may be due to inhibition of upregulated pendrin-NDCBE-coupled sodium reabsorption. Thus, increased pendrin in pregnant rats may compensate for the decreased NCC and aid in the renal sodium chloride reabsorption of pregnancy.