The interaction of pendrin and the epithelial sodium channel in blood pressure regulation

PURPOSE OF REVIEW: This review summarizes the contribution of the Cl-/HCO3- exchanger pendrin in the renal regulation of blood pressure. RECENT FINDINGS: Intercalated cells are found in the distal convoluted tubule, the connecting tubule and the collecting duct. These cells regulate acid-base balance by secreting or absorbing OH-/H- equivalents and regulate vascular volume and blood pressure by absorbing chloride ions. In type B and non-A, non-B intercalated cells chloride absorption and HCO3- secretion are accomplished through the apical sodium-independent Cl-/HCO3- exchanger pendrin. With increased circulating aldosterone, pendrin abundance and transport are upregulated. In the absence of functional pendrin (Slc26a4 (-/-) mice), aldosterone-stimulated chloride absorption is reduced, which attenuates the blood pressure response to this steroid hormone. Pendrin also regulates aldosterone-induced changes in epithelial sodium channel abundance and function through a kidney-specific mechanism that does not involve changes in concentration of a circulating hormone. In vitro, angiotensin II increases sodium chloride absorption in the collecting duct by increasing the driving force for pendrin-mediated chloride absorption and the epithelial sodium channel-mediated sodium absorption through greater electrogenic hydrogen secretion. SUMMARY: Aldosterone and angiotensin II modulate the renal regulation of blood pressure, in part, by regulating pendrin-mediated chloride absorption and the epithelial sodium channel-mediated sodium absorption. Pendrin also modulates stimulation of the epithelial sodium channel by aldosterone.     

Pendrin modulates ENaC function by changing luminal HCO3-

The epithelial Na(+) channel, ENaC, and the Cl(-)/HCO(3)(-) exchanger, pendrin, mediate NaCl absorption within the cortical collecting duct and the connecting tubule. Although pendrin and ENaC localize to different cell types, ENaC subunit abundance and activity are lower in aldosterone-treated pendrin-null mice relative to wild-type mice. Because pendrin mediates HCO(3)(-) secretion, we asked if increasing distal delivery of HCO(3)(-) through a pendrin-independent mechanism "rescues" ENaC function in pendrin-null mice. We gave aldosterone and NaHCO(3) to increase pendrin-dependent HCO(3)(-) secretion within the connecting tubule and cortical collecting duct, or gave aldosterone and NaHCO(3) plus acetazolamide to increase luminal HCO(3)(-) concentration, [HCO(3)(-)], independent of pendrin. Following treatment with aldosterone and NaHCO(3), pendrin-null mice had lower urinary pH and [HCO(3)(-)] as well as lower renal ENaC abundance and function than wild-type mice. With the addition of acetazolamide, however, acid-base balance as well as ENaC subunit abundance and function was similar in pendrin-null and wild-type mice. We explored whether [HCO(3)(-)] directly alters ENaC abundance and function in cultured mouse principal cells (mpkCCD). Amiloride-sensitive current and ENaC abundance rose with increased [HCO(3)(-)] on the apical or the basolateral side, independent of the substituting anion. However, ENaC was more sensitive to changes in [HCO(3)(-)] on the basolateral side of the monolayer. Moreover, increasing [HCO(3)(-)] on the apical and basolateral side of Xenopus kidney cells increased both ENaC channel density and channel activity. We conclude that pendrin modulates ENaC abundance and function, at least in part by increasing luminal [HCO(3)(-)] and/or pH.     

Regulation of the expression of the Cl-/anion exchanger pendrin in mouse kidney by acid-base status

BACKGROUND: Pendrin belongs to a superfamily of Cl-/anion exchangers and is expressed in the inner ear, the thyroid gland, and the kidney. In humans, mutations in pendrin cause Pendred syndrome characterized by sensorineural deafness and goiter. Recently pendrin has been localized to the apical side of non-type A intercalated cells of the cortical collecting duct, and reduced bicarbonate secretion was demonstrated in a pendrin knockout mouse model. To investigate a possible role of pendrin in modulating acid-base transport in the cortical collecting duct, we examined the regulation of expression of pendrin by acid-base status in mouse kidney. METHODS: Mice were treated orally either with an acid or bicarbonate load (0.28 mol/L NH4Cl or NaHCO3) or received a K+-deficient diet for one week. Immunohistochemistry and Western blotting was performed. RESULTS: Acid-loading caused a reduction in pendrin protein expression levels within one day and decreased expression to 23% of control levels after one week. Concomitantly, pendrin protein was shifted from the apical membrane to the cytosol, and the relative abundance of pendrin positive cells declined. Similarly, in chronic K+-depletion, known to elicit a metabolic alkalosis, pendrin protein levels decreased and pendrin expression was shifted to an intracellular pool with the relative number of pendrin positive cells reduced. In contrast, following oral bicarbonate loading pendrin was found exclusively in the apical membrane and the relative number of pendrin positive cells increased. CONCLUSIONS: These results are in agreement with a potential role of pendrin in bicarbonate secretion and regulation of acid-base transport in the cortical collecting duct.     

Expression of the ammonia transporter, rh C glycoprotein, in normal and neoplastic human kidney

Recent studies have identified the presence of a novel Mep/Amt/Rh glycoprotein family of proteins that may play an important role in transmembrane ammonia transport. One of the mammalian members of this family, Rh C glycoprotein (RhCG), transports ammonia, is expressed in distal nephron sites that are critically important for ammonia secretion, exhibits increased expression in response to chronic metabolic acidosis, and originally was cloned as a tumor-related protein. The purpose of our studies was to determine the localization of RhCG in the normal and neoplastic human kidney. Immunoblot analysis of human renal cortical protein lysates demonstrated RhCG protein expression with a molecular weight of approximately 52 kD. Immunohistochemistry revealed both apical and basolateral Rhcg expression in the distal convoluted tubule, connecting segment, and initial collecting tubule and throughout the collecting duct. Co-localization with calbindin-D28k, H(+)-ATPase, aquaporin-2, and pendrin showed that distal convoluted tubule and connecting segment cells, A-type intercalated cells, and non-A, non-B cells express RhCG and that B-type intercalated cells, principal cells, and inner medullary collecting duct cells do not. In renal neoplasms, RhCG was expressed by chromophobe renal cell carcinoma and renal oncocytoma but not by clear cell renal cell carcinoma or by papillary renal cell carcinomas. These studies suggest that RhCG contributes to both apical and basolateral membrane ammonia transport in the human kidney. Furthermore, renal chromophobe renal cell carcinoma and renal oncocytoma seem to originate from the A-type intercalated cell.     

Molecular physiology of the renal chloride-formate exchanger

Renal apical chloride-base exchangers are essential to electrolyte and acid-base homeostasis. Different functional isoforms of apical anion exchangers have been identified in kidney proximal tubule and cortical collecting duct. Included amongst these are the following: chloride-formate, chloride-oxalate, and chloride-hydroxyl exchangers in proximal tubule; and chloride-bicarbonate exchanger in cortical collecting duct. Chloride-formate exchange, which was first identified in kidney proximal tubule, works in parallel with the apical sodium-hydrogen exchanger, and is thought to reabsorb the bulk of luminal chloride. Despite numerous studies, the molecular identities of apical chloride-base exchangers have remained unknown. Recent studies have identified a new class of anion exchangers, including pendrin (encoded by the PDS gene) and downregulated in adenoma (DRA, encoded by the DRA gene). Pendrin is expressed in the kidney, whereas DRA is not. Functional studies indicate that pendrin can function in chloride-formate and chloride-base exchange modes. It is unlikely that pendrin is the apical chloride-formate exchanger in the kidney proximal tubule. However, it is the only molecule that has been shown to mediate chloride-formate exchange. In the present review, recent studies regarding the renal distribution and membrane localization of pendrin, and its functional properties, including its roles in chloride reabsorption and base excretion, are addressed.     

Increased apical targeting of renal epithelial sodium channel subunits and decreased expression of type 2 11beta-hydroxysteroid dehydrogenase in rats with CCl4-induced decompensated liver cirrhosis

It was hypothesized that dysregulation of renal epithelial sodium channel (ENaC) subunits and/or 11beta-hydroxysteroid dehydrogenase (11betaHSD2) may play a role in the increased sodium retention in liver cirrhosis (LC). Experimental LC was induced in rats by CCl(4) (1 ml/kg, intraperitoneally, twice a week) for 12 wk (protocol 1) or for 11 wk (protocol 2). In both protocols, one group of rats with cirrhosis showed significantly decreased urinary sodium excretion and urinary Na/K ratio (group A), whereas a second group exhibited normal urinary sodium excretion (group B) compared with controls, even though extensive ascites was seen in both groups of rats with cirrhosis. In group A, protein abundance of alpha-ENaC was unchanged, whereas beta-ENaC abundance was decreased in the cortex/outer stripe of outer medulla compared with controls. The gamma-ENaC underwent a complex change associated with increased abundance of the 70-kD band with a concomitant decrease in the main 85-kD band, corresponding to an aldosterone effect. In contrast, no changes in the abundance of ENaC subunit were observed in group B. Immunoperoxidase microscopy revealed an increased apical targeting of alpha-, beta-, and gamma-ENaC subunits in distal convoluted tubule (DCT2), connecting tubule (CNT), and cortical and medullary collecting duct segments in group A but not in group B. Immunolabeling intensity of 11betaHSD2 in the DCT2, CNT, and cortical collecting duct was significantly reduced in group A but not in group B, and this was confirmed by immunoblotting. In conclusion, increased apical targeting of ENaC subunits combined with diminished abundance of 11betaHSD2 in the DCT2, CNT, and cortical collecting duct is likely to play a role in the sodium retaining stage of liver cirrhosis.     

Sodium retention in cirrhotic rats is associated with increased renal abundance of sodium transporter proteins

BACKGROUND: Liver cirrhosis with ascites is associated with a decrease in renal sodium excretion and therefore sodium retention. METHODS: In this paper, we utilize transporter-specific antibodies to address the hypothesis that dysregulation of one or more sodium transporters or channels is associated with sodium chloride (NaCl) retention in a rat model of cirrhosis induced by repeated exposure to carbon tetrachloride. Age-matched controls and cirrhotic rats were pair fed to ensure identical NaCl and water intake for 4 days prior to euthanasia for quantitative immunoblotting studies. RESULTS AND CONCLUSION: The rats manifested marked extracellular fluid volume expansion with massive ascites. Plasma aldosterone levels were markedly elevated. Analysis of immunoblots revealed marked increases in the abundances of both of the major aldosterone-sensitive apical transport proteins of the renal tubule, namely the thiazide-sensitive NaCl cotransporter NCC and the epithelial sodium channel alpha subunit (alpha-ENaC). These results are consistent with an important role for hyperaldosteronism in the pathogenesis of sodium retention and ascites formation in cirrhosis. In addition, we observed a large decrease in cortical NHE3 abundance (proximal tubule) and a large increase in NKCC2 abundance (thick ascending limb), potentially shifting premacula densa sodium absorption from proximal tubule to loop of Henle (which powers urinary concentration and dilution).     

Respective roles of H-ATPase and H-K-ATPase in ion transport in the kidney.

Two types of proton-translocating ATPases, H-ATPase and H-K-ATPase, are found in the renal tubular cells. H-ATPase is present in both endocytic vesicles and apical membranes in almost all nephron segments. On the other hand, H-K-ATPase is present only in the connecting tubule and collecting duct. There is evidence to suggest that H-ATPase may be involved in H secretion in almost all nephron segments. H-K-ATPase is involved not only in H secretion but also in K absorption in the collecting duct segments. Aldosterone administration and metabolic acidosis stimulate the activity of H-ATPase in all collecting duct segments, whereas hypokalemia has only a limited effect on H-ATPase activity. On the other hand, hypokalemia, as well as metabolic acidosis, stimulates H-K-ATPase activity in the collecting duct segments, whereas aldosterone administration alone plays a minor role in the regulation of this enzyme. The physiological role and regulation of H-ATPase in the proximal tubule has not been established.     

BK channels in the kidney

PURPOSE OF REVIEW: Large, BK (calcium-activated potassium) channels are now regarded as relevant players in many aspects of renal physiology, including potassium secretion. This review will highlight recent discoveries regarding the function and localization of BK in the kidney. RECENT FINDINGS: Patch clamp electrophysiology has revealed BK in cultured podocytes, glomerular mesangial cells, and in several tubule segments including principal cells (connecting tubules/principal cells), and intercalated cells of connecting tubules and cortical collecting ducts. Flow-induced potassium secretion is mediated by BK in the distal nephron and may be partly the result of shear stress-induced increases in cell calcium concentrations. ROMK-/- and wild-type mice on a high potassium diet exhibit BK-mediated potassium secretion, and studies of BK-alpha-/- and BK-beta1-/- mice suggest that flow-induced potassium secretion is mediated by BK-alpha/beta1, which is specifically localized in the apical membrane of the connecting tubule of the mouse and connecting tubule plus initial cortical collecting duct of the rabbit. SUMMARY: BK channels, located in glomerular cells and in many nephron segments, especially mediate potassium secretion in the combined condition of potassium adaptation and high flow. Understanding the molecular makeup of BK in specific renal cells and the dietary and physiological conditions for their expression can yield improved potassium-sparing compounds.     

Thiazide diuretic effect on medullary collecting duct function in the rat

The distal convoluted tubule is thought to be the principal site of action of thiazide diuretics, but, to our knowledge, there are no studies of their possible effects on collecting duct transport. Microcatheterization of the inner medullary collecting duct (IMCD) was carried out in rats undergoing a modest diuresis, natriuresis, and chloriuresis from hydro-chlorothiazide (2 mg/kg/hr) and in normal controls. Delivery of fluid, sodium, and chloride to the beginning of the IMCD was increased, but not significantly, while the load remaining at the papillary tip (end) of the duct was increased markedly by hydrochlorothiazide. Chloride reabsorption in the IMCD was affected most markedly; the chloride reabsorption between the beginning and end of the duct, as a fraction of the delivered load, was reduced from 70.4 +/- 5.4% in controls to insignificant amounts with hydrochlorothiazide (8.2 +/- 11.5%, P less than 0.001). The fraction of delivered sodium reabsorbed along the collecting duct was decreased from 78.5 +/- 4.9% in controls to 37.2 +/- 12.4% (P less than 0.005) in thiazide-treated rats and fluid reabsorption was decreased from 59.4 +/- 4.0% in controls to 31.9 +/- 5.1% (P less than 0.005). Small but significant potassium secretion into the IMCD occurred with hydrochlorothiazide, probably secondary to the marked increase in potassium delivery to the duct. Increased potassium excretion could account for a maximum of 50% of chloriuresis with hydrochlorothiazide. The observation that thiazide diuretics decrease chloride, sodium, and fluid reabsorption in the medullary collecting duct, like the recently demonstrated inhibitory effect of furosemide on this nephron segment, has significant implications for the rationale for diuretic use.     

Profound hypokalemia and hypochloremic metabolic alkalosis during thiazide therapy in a child with Pendred syndrome

Pendred syndrome is a recessive autosomal disorder characterized by thyroid goiter and sensorineural hearing loss. The Pendred syndrome gene (SLC26A4) encodes a new anion exchanger named pendrin which mediates iodide transport by thyrocytes and regulates ion and fluid transport by the endolymphatic sac epithelium. Pendrin defects result in inner ear malformations, with enlargement of the endolymphatic sac and duct in association with a large vestibular aqueduct. Furthermore, patients may develop endolymphatic hydrops requiring diuretic therapy, mainly in the form of thiazides. Pendrin could also account for apical Cl(-)/ HCO3(-) exchange at level of intercalated cells of the cortical collecting duct in the kidneys, however, humans with Pendred syndrome have no symptoms attributable to renal pendrin abnormalities in basal conditions. We report the case of a child with Pendred syndrome and intercurrent endolymphatic hydrops, who developed profound hypokalemia and severe hypochloremic metabolic alkalosis (potassium 1.7, chloride 70, sodium 129, HCO3 43.8, base excess +17.8 mmol/l, pH 7.52) following thiazide therapy. In subjects with Pendred syndrome thiazide therapy seems to provoke more severe Cl(-) and extracellular volume depletion. A possible explanation could be the defective action of the disrupted pendrin, which exacerbates the effects of the inhibition of C1(-) reabsorption mediated by the thiazide-sensitive NaCl cotransporter (SLC12A3).     

Localization of inward rectifier potassium channel Kir7.1 in the basolateral membrane of distal nephron and collecting duct

Inward rectifier potassium channels (Kir) play an important role in the K(+) secretion from the kidney. Recently, a new subfamily of Kir, Kir7.1, has been cloned and shown to be present in the kidney as well as in the brain, choroid plexus, thyroid, and intestine. Its cellular and subcellular localization was examined along the renal tubule. Western blot from the kidney cortex showed a single band for Kir7.1 at 52 kD, which was also observed in microdissected segments from the thick ascending limb of Henle, distal convoluted tubule (DCT), connecting tubule, and cortical and medullary collecting ducts. Kir7.1 immunoreactivity was detected predominantly in the DCT, connecting tubule, and cortical collecting duct, with lesser expression in the thick ascending limb of Henle and in the medullary collecting duct. Kir7.1 was detected by electron microscopic immunocytochemistry on the basolateral membrane of the DCT and the principal cells of cortical collecting duct, but neither type A nor type B intercalated cells were stained. The message levels and immunoreactivity were decreased under low-K diet and reversed by low-K diet supplemented with 4% KCl. By the double-labeling immunogold method, both Kir7.1 and Na(+), K(+)-ATPase were independently located on the basolateral membrane. In conclusion, the novel Kir7.1 potassium channel is located predominantly in the basolateral membrane of the distal nephron and collecting duct where it could function together with Na(+), K(+)-ATPase and contribute to cell ion homeostasis and tubular K(+) secretion.     

Origin and fate of pendrin-positive intercalated cells in developing mouse kidney

Pendrin is an apical anion exchanger found in type B and nonA-nonB intercalated cells that is involved in bicarbonate secretion. The purpose of this study was to establish the origin and fate of pendrin-positive intercalated cells in the mouse kidney. Using immunohistochemistry, we found that pendrin-positive cells first appeared in the connecting tubule at embryonic day 14 (E14) and subsequently in the medullary collecting duct at E18. Most of the pendrin-positive cells in the connecting tubule were nonA-nonB intercalated cells, wheras those in the medullary collecting duct were type B intercalated cells. In the cortical collecting duct, pendrin-positive cells appeared in the inner part at day 4 after birth and in the outer part at day 7. Pendrin-positive cells gradually disappeared by apoptosis from the inner part of the medullary collecting duct two weeks after birth. Using 5-bromo-2'deoxy-uridine (BrdU) to follow cell proliferation, we determined that selective proliferation of pendrin-positive intercalated cells does not occur; instead, these cells may arise from undifferentiated precursor cells from separate foci, one in the connecting tubule and one in the collecting duct.     

Regulation of acid-base transporters by vasopressin in the kidney collecting duct of Brattleboro rat

AIM: The objective of these studies was to examine the effects of long-term vasopressin treatment on acid-base transporters in the collecting duct of rat kidney. METHODS: Brattleboro rats were placed in metabolic cages and treated with daily injections of 1-desamino-8-D-arginine vasopressin (dDAVP), a selective V2-receptor agonist, or its vehicle (control) for up to 8 days. RESULTS: dDAVP treatment resulted in a significant reduction in serum bicarbonate concentration, and caused the upregulation of key ammoniagenesis enzymes, along with increased urinary NH4+ excretion. Northern hybridization and immunofluorescence labeling indicated a significant increase (+80%) in mRNA expression of the apical Cl-/HCO3- exchanger pendrin (PDS), along with a sharp increase in its protein abundance in B-type intercalated cells in the cortical collecting duct in dDAVP-treated rats. In the inner medullary collecting duct, the abundance of basolateral Cl-/HCO3- exchanger (AE1) and apical H+-ATPase was significantly reduced in dDAVP-treated rats. Kidney renin mRNA increased significantly and correlated with an increase in serum aldosterone levels in dDAVP-injected rats. Serum corticosterone levels were, however, reduced and correlated with increased mRNA levels of renal 11beta-hydroxysteroid dehydrogenase-2 (11beta-HSD2) and decreased mRNA expression of 11beta-hydroxylase in the adrenal gland of dDAVP-injected rats. CONCLUSION: Chronic administration of dDAVP to Brattleboro rats is associated with the upregulation of PDS and downregulation of H+-ATPase and AE1 in the collecting duct, along with increased ammoniagenesis. Stimulation of the renin-angiotensin-aldosterone system and/or decreased glucocorticoid levels likely plays a role in the transduction of these effects.     

Immunocytochemical localization of vitamin D-dependent calcium-binding protein in renal tubules of rabbit, rat, and chick

Vitamin D-dependent calcium-binding protein (CaBP) was localized in tissue sections of kidneys from rabbits, rats, and chicks using antiserum specific for chick intestinal CaBP. In rabbit kidney, CaBP was present in all cells of the distal convoluted tubule and most cells of the connecting tubule. Fewer, but still a majority, of the cells of cortical collecting ducts contained CaBP. The intensity of immunochemical staining and the number of stained cells decreased markedly in medullary collecting ducts, and only a few collecting duct cells contained CaBP at the junction of the inner and outer medulla. In the rat kidney, CaBP was present in all distal convoluted tubule cells, but the immunochemical staining was less intense than in the rabbit. The protein also was found in most connecting tubule cells of the rat; however, only a few collecting duct cells in the superficial corte of the rat contained CaBP. CaBP was essentially absent from mid- to deep-cortical collecting duct cells, while a very few collecting duct cells always contained CaBP at the junction of the inner and outer stripes of the outer medulla. In the chick, CaBP was present in distal convoluted tubule cells as the distal convoluted tubule coursed adjacent to the central vein. CaBP was absent from chick collecting duct cells. In all three species CaBP was not detected in the other portions of the nephron.     

Compensatory hypertrophy and adaptation in the cortical collecting duct

The cortical collecting duct (CCD) undergoes hypertrophy and functional adaptation following reduction of renal mass. The nature and mechanisms of these changes have been investigated using microperfusion of isolated CCD from rabbit remnant kidneys. By 1 week after reduction of renal mass, tubule hypertrophy and increased sodium transport are fully developed. The transport adaptations are specific or selective, since bicarbonate transport in these CCD is unchanged. Mineralocorticoids may play an important role in the hypertrophy and increased sodium transport, since plasma aldosterone increases early after reduction of renal mass. Also, adrenalectomy abolishes the changes in size and sodium transport, even with supplementation of aldosterone to unstressed physiologic levels. Epidermal growth factor also has immediate effects on CCD sodium transport; however, the direction of the effect is opposite--an inhibition of transport.     

Effects of in vitro aldosterone on the rabbit cortical collecting tubule

Considerable evidence indicates that the cortical collecting tubule is a target epithelium for aldosterone. Isolated perfused cortical collecting tubules from rabbits given large doses of deoxycorticosterone acetate (DOCA) for several days, or whose endogenous production of aldosterone is increased by dietary means, exhibit large lumen-negative transepithelial voltages, increased sodium (Na) absorption, and increased potassium (K) secretion compared with tubules from normal animals. However, controversy exists regarding the response of this nephron segment to acute in vitro administration of aldosterone. To address this issue we performed three groups of experiments: 1) clearance experiments on adrenalectomized rabbits to determine the minimum time required after in vivo aldosterone administration before significant changes in sodium excretion are observed; 2) microperfusion experiments on cortical collecting tubules from normal and adrenalectomized rabbits in which transepithelial voltage was measured before and after adding aldosterone to the bath; 3) microperfusion experiments on cortical collecting tubules from adrenalectomized rabbits in which transepithelial voltage, sodium and potassium flux were measured before and after in vitro exposure to aldosterone or dexamethasone. The clearance studies demonstrate that after a 2 hr latent period aldosterone produces significant antinatriuresis without change in K excretion. In vitro studies failed to reveal a steroid-induced change in the transepithelial voltage of cortical collecting tubules from either normal or adrenalectomized rabbits. However, aldosterone added in vitro to collecting tubules from adrenalectomized rabbits produced an increase in net Na absorption without a significant change in voltage or K secretion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Up-regulation of organic anion transporter 1 protein is induced by chronic furosemide or hydrochlorothiazide infusion in rat kidney.

BACKGROUND: Thiazide and loop diuretics are secreted from the proximal tubule via the organic anion transport system to reach their principal sites of action. Recently, a multispecific organic anion transporter 1 (OAT1) was identified in rat kidney and was localized to the basolateral membrane of the S2 segment in the proximal tubule. We postulated that interactions between thiazide or loop diuretics and OAT1 may play a role in the adaptation to long-term diuretic use, and investigated whether OAT1 is regulated in vivo by chronic administration of diuretics at the protein level. METHODS: Semi-quantitative immunoblotting and immunohistochemistry were carried out in kidneys from male Sprague-Dawley rats using a polyclonal peptide-derived antibody to OAT1. Furosemide (12 mg/day/rat, n = 6), hydrochlorothiazide (3.75 mg/day/rat, n = 6) or vehicle (1.7% ethanolamine, n = 6) were infused subcutaneously for 7 days using osmotic minipumps. Experimental and vehicle-control rats were pair-fed, and two bottles of drinking water were provided, one containing tap water and the other containing a solution of 0.8% NaCl with 0.1% KCl. RESULTS: Overt diuretic responses were observed to both furosemide and hydrochlorothiazide infusions. There were no differences in body weight or creatinine clearance between the experimental and control rats. Although OAT1 protein abundance in cortical homogenates was increased by furosemide infusion (271 +/- 35 vs 100 +/- 15%, P < 0.05), Na-K-ATPase alpha1 subunit protein abundance was not affected (113 +/- 14 vs 100 +/- 8%, P = 0.42). Immunohistochemical localization in tissue sections confirmed a strong increase in OAT1 expression in the basolateral membrane of the S2 segment of proximal tubule. OAT1 protein abundance in cortical homogenates was also increased by hydrochlorothiazide infusion (181 +/- 25 vs 100 +/- 7%, P < 0.01), whereas Na-K-ATPase alpha1 subunit protein abundance was not affected (105 +/- 4 vs 100 +/- 4%, P = 0.34). CONCLUSION: Chronic furosemide or hydrochlorothiazide infusion caused increases in OAT1 protein abundance in rat kidney. These results suggest that OAT1 may be up-regulated in vivo by substrate stimulation at the protein level.