Since nitric oxide (NO) participates in the renal regulation of blood pressure, in part, by modulating transport of Na+ and Cl− in the kidney, we asked whether NO regulates net Cl− flux (JCl) in the cortical collecting duct (CCD) and determined the transporter(s) that mediate NO-sensitive Cl− absorption. Cl− absorption was measured in CCDs perfused in vitro that were taken from aldosterone-treated mice. Administration of an NO donor (10 μM MAHMA NONOate) reduced JCl and transepithelial voltage (VT) both in the presence or absence of angiotensin II. However, reducing endogenous NO production by inhibiting NO synthase (100 μM NG-nitro-l-arginine methyl ester) increased JCl only in the presence of angiotensin II, suggesting that angiotensin II stimulates NO synthase activity. To determine the transport process that mediates NO-sensitive changes in JCl, we examined the effect of NO on JCl following either genetic ablation or chemical inhibition of transporters in the CCD. Since the application of hydrochlorothiazide (100 μM) or bafilomycin (5 nM) to the perfusate or ablation of the gene encoding pendrin did not alter NO-sensitive JCl, NO modulates JCl independent of the Na+-dependent Cl−/HCO3− exchanger (NDCBE, Slc4a8), the A cell apical plasma membrane H+-ATPase and pendrin. In contrast, both total and NO-sensitive JCl and VT were abolished with application of an epithelial Na+ channel (ENaC) inhibitor (3 μM benzamil) to the perfusate. We conclude that NO reduces Cl− absorption in the CCD through a mechanism that is ENaC-dependent.
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P. Richard Grimm;
Yoskaly Lazo-Fernandez;
Eric Delpire;
Susan Wall;
Susan G. Dorsey;
Edward J. Weinman;
Richard Coleman;
James B. Wade;
Paul A. Welling
Thiazide diuretics are used to treat hypertension; however, compensatory processes in the kidney can limit antihypertensive responses to this class of drugs. Here, we evaluated compensatory pathways in SPAK kinase-deficient mice, which are unable to activate the thiazide-sensitive sodium chloride cotransporter NCC (encoded by Slc12a3). Global transcriptional profiling, combined with biochemical, cell biological, and physiological phenotyping, identified the gene expression signature of the response and revealed how it establishes an adaptive physiology. Salt reabsorption pathways were created by the coordinate induction of a multigene transport system, involving solute carriers (encoded by Slc26a4, Slc4a8, and Slc4a9), carbonic anhydrase isoforms, and V-type H⁺-ATPase subunits in pendrin-positive intercalated cells (PP-ICs) and ENaC subunits in principal cells (PCs). A distal nephron remodeling process and induction of jagged 1/NOTCH signaling, which expands the cortical connecting tubule with PCs and replaces acid-secreting α-ICs with PP-ICs, were partly responsible for the compensation. Salt reabsorption was also activated by induction of an α-ketoglutarate (α-KG) paracrine signaling system. Coordinate regulation of a multigene α-KG synthesis and transport pathway resulted in α-KG secretion into pro-urine, as the α-KG-activated GPCR (Oxgr1) increased on the PP-IC apical surface, allowing paracrine delivery of α-KG to stimulate salt transport. Identification of the integrated compensatory NaCl reabsorption mechanisms provides insight into thiazide diuretic efficacy.
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Jill W. Verlander;
Seongun Hong;
Vladimir Pech;
James L Bailey;
Diana Agazatian;
Sharon W. Matthews;
Thomas M. Coffman;
Thu Le;
Tadashi Inagami;
Florence M. Whitehill;
I. David Weiner;
Donna B. Farley;
Young Hee Kim;
Susan M Wall
Pendrin is an anion exchanger expressed in the apical regions of B and non-A, non-B intercalated cells. Since angiotensin II increases pendrin-mediated Cl− absorption in vitro, we asked whether angiotensin II increases pendrin expression in vivo and whether angiotensin-induced hypertension is pendrin dependent. While blood pressure was similar in pendrin null and wild-type mice under basal conditions, following 2 wk of angiotensin II administration blood pressure was 31 mmHg lower in pendrin null than in wild-type mice. Thus pendrin null mice have a blunted pressor response to angiotensin II. Further experiments explored the effect of angiotensin on pendrin expression. Angiotensin II administration shifted pendrin label from the subapical space to the apical plasma membrane, independent of aldosterone. To explore the role of the angiotensin receptors in this response, pendrin abundance and subcellular distribution were examined in wild-type, angiotensin type 1a (Agtr1a) and type 2 receptor (Agtr2) null mice given 7 days of a NaCl-restricted diet (< 0.02% NaCl). Some mice received an Agtr1 inhibitor (candesartan) or vehicle. Both Agtr1a gene ablation and Agtr1 inhibitors shifted pendrin label from the apical plasma membrane to the subapical space, independent of the Agtr2 or nitric oxide (NO). However, Agtr1 ablation reduced pendrin protein abundance through the Agtr2 and NO. Thus angiotensin II-induced hypertension is pendrin dependent. Angiotensin II acts through the Agtr1a to shift pendrin from the subapical space to the apical plasma membrane. This Agtr1 action may be blunted by the Agtr2, which acts through NO to reduce pendrin protein abundance.
The renal epithelial sodium channel (ENaC) provides regulated sodium transport in the distal nephron. The effects of intracellular calcium ([Ca2+]i) on this channel are only beginning to be elucidated. It appears from previous studies that the [Ca2+]i increases downstream of ATP administration may have a polarized effect on ENaC, where apical application of ATP and the subsequent [Ca2+]i increase have an inhibitory effect on the channel, whereas basolateral ATP and [Ca2+]i have a stimulatory effect. We asked whether this polarized effect of ATP is, in fact, reflective of a polarized effect of increased [Ca2+]i on ENaC and what underlying mechanism is responsible. We began by performing patch clamp experiments in which ENaC activity was measured during apical or basolateral application of ionomycin to increase [Ca2+]i near the apical or basolateral membrane, respectively. We found that ENaC does indeed respond to increased [Ca2+]i in a polarized fashion, with apical increases being inhibitory and basolateral increases stimulating channel activity. In other epithelial cell types, mitochondria sequester [Ca2+]i, creating [Ca2+]i signaling microdomains within the cell that are dependent on mitochondrial localization. We found that mitochondria localize in bands just beneath the apical and basolateral membranes in two different cortical collecting duct principal cell lines and in cortical collecting duct principal cells in mouse kidney tissue. We found that inhibiting mitochondrial [Ca2+]i uptake destroyed the polarized response of ENaC to [Ca2+]i. Overall, our data suggest that ENaC is regulated by [Ca2+]i in a polarized fashion and that this polarization is maintained by mitochondrial [Ca2+]i sequestration.
In normal rats, vasopressin and hyperosmolality enhance urea permeability (Purea) in the terminal, but not in the initial IMCD, a process thought to occur through the UT-A1 urea transporter. In the terminal IMCD, UT-A1 is detected as 97 and 117 kDa glycoproteins. However, in the initial IMCD, only the 97 kDa form is detected. During streptozotocin induced diabetes mellitus, UT-A1 protein abundance is increased and the 117 kDa UT-A1 glycoprotein appears in the initial IMCD. We hypothesize that the 117 kDa glycoprotein mediates the vasopressin- and osmolality-induced changes in Purea. Thus in the present study, we measured Purea in in vitro perfused initial IMCDs from diabetic rats by imposing a 5 mM bath-to-lumen urea gradient without any osmotic gradient. Basal Purea was similar in control vs. diabetic rats (3±1 vs. 5±1 x10−5 cm/sec, n=4, p=NS). Vasopressin (10 nM) significantly increased Purea to 16±5 x10−5 cm/sec, n=4, p<0.05 in diabetic, but not in control rats. Forskolin (10 μM, adenylyl cyclase activator) also significantly increased Purea in diabetic rats. In contrast, increasing osmolality to 690 mOsm/kg H2O did not change Purea in diabetic rats. We conclude that initial IMCDs from diabetic rats have vasopressin- and forskolin-, but not hyperosmolality-stimulated Purea. The appearance of vasopressin-stimulated Purea in initial IMCDs correlates with an increase in UT-A1 protein abundance and the appearance of the 117 kDa UT-A1 glycoprotein in this region during diabetes. This suggests that the 117 kDa UT-A1 glycoprotein is necessary for vasopressin-stimulated urea transport.
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.
We examined the interaction of a membrane-associated protein, MARCKS-like Protein-1 (MLP-1), and an ion channel, Epithelial Sodium Channel (ENaC), with the anionic lipid, phosphatidylinositol 4, 5-bisphosphate (PIP2). We found that PIP2 strongly activates ENaC in excised, inside-out patches with a half-activating concentration of 21 ± 1.17 µM. We have identified 2 PIP2 binding sites in the N-terminus of ENaC β and γ with a high concentration of basic residues. Normal channel activity requires MLP-1’s strongly positively charged effector domain to electrostatically sequester most of the membrane PIP2 and increase the local concentration of PIP2. Our previous data showed that ENaC covalently binds MLP-1 so PIP2 bound to MLP-1 would be near PIP2 binding sites on the cytosolic N terminal regions of ENaC. We have modified the charge structure of the PIP2 –binding domains of MLP-1 and ENaC and showed that the changes affect membrane localization and ENaC activity in a way consistent with electrostatic theory.
Aim: Protein kinase Cα (PKCα) is a critical regulator of multiple cell signaling pathways including gene transcription, posttranslation modifications and activation/inhibition of many signaling kinases. In regards to the control of blood pressure, PKCα causes increased vascular smooth muscle contractility, while reducing cardiac contractility. In addition, PKCα has been shown to modulate nephron ion transport. However, the role of PKCα in modulating mean arterial pressure (MAP) has not been investigated. In this study, we used a whole animal PKCα knock out (PKC KO) to test the hypothesis that global PKCα deficiency would reduce MAP, by a reduction in vascular contractility. Methods: Radiotelemetry measurements of ambulatory blood pressure (day/night) were obtained for 18 h/day during both normal chow and high-salt (4%) diet feedings. PKCα mice had a reduced MAP, as compared with control, which was not normalized with high-salt diet (14 days). Metabolic cage studies were performed to determine urinary sodium excretion. Results: PKC KO mice had a significantly lower diastolic, systolic and MAP as compared with control. No significant differences in urinary sodium excretion were observed between the PKC KO and control mice, whether fed normal chow or high-salt diet. Western blot analysis showed a compensatory increase in renal sodium chloride cotransporter expression. Both aorta and mesenteric vessels were removed for vascular reactivity studies. Aorta and mesenteric arteries from PKC KO mice had a reduced receptor-independent relaxation response, as compared with vessels from control. Vessels from PKC KO mice exhibited a decrease in maximal contraction, compared with controls. Conclusion: Together, these data suggest that global deletion of PKCα results in reduced MAP due to decreased vascular contractility.
Hyponatremia (hypo-osmolality) is a disorder of water homeostasis due to abnormal renal diluting capacity. The body limits the degree to which serum sodium concentration falls through a mechanism called "vasopressin escape". Vasopressin escape is a process that prevents the continuous decrease in serum sodium concentration even under conditions of sustained high plasma vasopressin levels. Previous reports suggest that aldosterone may be involved in the vasopressin escape mechanism. The abilities of aldosterone synthase (Cyp11b2) knockout and wild-type mice to escape from vasopressin were compared. Wild-type mice escaped while the aldosterone synthase knockout mice did not. Both the water channel aquaporin 2 (AQP2) and the urea transporter UT-A1 protein abundances were higher in aldosterone synthase knockout than in wild-type mice at the end of the escape period. Vasopressin escape was also blunted in rats given spironolactone, a mineralocorticoid receptor blocker. Next, the role of the phosphatase, calcineurin (protein phosphatase 2B, PP2B), in vasopressin escape was studied since aldosterone activates calcineurin in rat cortical collecting ducts. Tacrolimus, a calcineurin inhibitor, blunted vasopressin escape in rats compared with the control rats, increased UT-A1, AQP2, and pS256-AQP2, and decreased pS261-AQP2 protein abundances. Our results indicate that aldosterone regulates vasopressin escape through calcineurin-mediated protein changes in UT-A1 and AQP2.