Chloride uptake by brush border membrane vesicles isolated from rabbit renal cortex. Coupling to proton gradients and K+ diffusion potentials

Cytoplasmic pH regulation in canine renal proximal tubule cells

The precise mechanisms by which the mammalian kidney proximal tubule transports H+ and HCO3- and regulates cytosolic pH (pHi) remain in doubt, though both a H+-ATPase pump and Na+/H+ exchange at the luminal membrane are known to function in the export of protons. The mechanisms of HCO3- transport are less clear though recent reports suggest an important role for an electrogenic Na+/HCO3- symport in the basolateral membrane. The importance of chloride-dependent bicarbonate transport is unknown. In the present studies, the pH-sensitive fluorescent dye, bis-(carboxyethyl)-carboxyfluorescein (BCECF) has been used to study pHi changes in suspensions of canine proximal tubule cells following acidification or alkalinization of the cytosol. Cells were acid-loaded to pH 6.5 by exposure to the H+/K+ ionophore, nigericin. Following removal of nigericin, pHi returned to basal levels (pHi = 7.1) when the cells were resuspended in a buffer containing 100 mM Na+. This recovery was blocked by removal of Na+ or addition of 0.2 mM amiloride to the cell suspension. In the presence of 0.2 mM amiloride and Na+, partial excretion of the acid load occurred if the buffer also contained HCO3-/CO2, but this effect was blocked by the removal of Na+ or the addition of 1 mM 4-acetomido-4'-isothiocyano-2,2'-stilbene disulfonic acid (SITS). When cell membrane potential was monitored in these experiments using the potential-sensitive fluorescent dye, bis-(1,3-dibutylbarbiturate) trimethine oxonol, the increase in pHi seen in the presence of Na+ was found to be electroneutral, whereas when that occurred in the presence of Na+, amiloride and HCO3-/CO2 was associated with membrane hyperpolarization.(ABSTRACT TRUNCATED AT 250 WORDS)

Apical membrane chloride/base exchange in the rat proximal convoluted tubule

To examine whether Cl/base exchange is present on the apical membrane of the proximal convoluted tubule, cell pH was measured fluorometrically in the in vivo microperfused rat proximal tubule with (2',7')-bis(carboxyethyl)-(5,6)-carboxyfluorescein. The effect of luminal chloride addition was examined in tubules perfused symmetrically with chloride-free solutions. In the absence of inhibitors, luminal chloride addition did not affect cell pH. However, after inhibition of basolateral membrane anion transport with peritubular 4-acetamido-4'-isothiocyano-(2,2')-disulfonic-stilbene (to amplify effects of apical membrane transport on cell pH), luminal chloride addition caused a small cell acidification (delta pHi = 0.02). When 1 mM formate was added to the solutions, luminal chloride addition caused a larger change in cell pH (delta pHi = 0.06) that was inhibited by (4,4')-diisothiocyano-(2,2')-disulfonic-stilbene. This stimulation of Cl/base exchange was not seen with 1 mM acetate addition. These results demonstrate apical membrane Cl/base exchange, a significant fraction of which is dependent on the presence of formate and probably represents Cl/formate exchange.

Effect of formate on volume reabsorption in the rabbit proximal tubule

Studies on microvillus membrane from rabbit kidney cortex suggest that chloride absorption may occur by chloride/formate exchange with recycling of formic acid by nonionic diffusion. We tested whether this transport mechanism participates in active NaCl reabsorption in the rabbit proximal tubule. In proximal tubule S2 segments perfused with low HCO-3 solutions, the addition of formate (0.25-0.5 mM) to the lumen and the bath increased volume reabsorption (JV) by 60%; the transepithelial potential difference remained unchanged. The effect of formate on JV was completely reversible and was inhibited both by ouabain and by luminal 4,4'-diisothiocyanostilbene-2,2'-disulfonate. Formate (0.5 mM) failed to stimulate JV in early proximal convoluted tubules perfused with high HCO-3 solutions. As measured by miniature glass pH microelectrodes, this lack of formate effect on JV was related to a less extensive acidification of the tubule fluid when high HCO-3 solutions were used as perfusate. These data suggest that chloride/formate exchange with recycling of formic acid by nonionic diffusion represents a mechanism for active, electroneutral NaCl reabsorption in the proximal tubule.

Mechanism of coupling between Cl- and OH- transport in renal brush-border membranes

The coupling mechanism for Cl- and H+/OH- transport in renal brush-border vesicles was examined from intravesicular pH changes following imposed H+ and Cl- gradients. Vesicles were loaded with 6-carboxyfluorescein and exposed to H+ gradients and Cl-, gluconate, or sulfate gradients, each with and without a K+/valinomycin voltage clamp. Parallel experiments were performed with vesicles equilibrated with 10 mM HCO3- or 5 mM formate. Rate of H+/OH- transport was determined from the initial rate of change in 6-carboxyfluorescein fluorescence, vesicle buffer capacity and the relationship between fluorescence and vesicle pH. In contrast to gluconate or sulfate, Cl- caused enhanced H+/OH- transport under all conditions. This difference was eliminated with voltage clamping in the presence of gluconate, SO4(2-), or HCO3-, but not in the presence of formate. These findings were not affected by the method of preparation of the vesicles. Electrically coupled Cl-/OH- transport was not inhibited by 100 microM DIDS (4,4'-diisothiocyanostilbene-2,2'-disulfonate) or 100 microM DBDS (4,4'-dibenzamidostilbene-2,2'-disulfonate). SITS (4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonate) was found to be a protonophore at concentrations greater than 500 microM. As a control for the method, we demonstrated amiloride inhibitable, electroneutral Na+-H+ exchange (H+ flux = 107 +/- 9 nmol/s per mg, 100 mM Na+) and electroneutral, DBDS inhibitable Cl(-)-HCO3- exchange in sealed human red blood cell ghosts. Therefore, electroneutral Cl(-)-OH- or HCO3- exchange does not measurably contribute to Cl- transport in the proximal tubule brush border. Cl(-)-formate exchange with formic acid recycling appears to be the only electroneutral coupling mechanism between Cl- and OH- transport demonstrable in renal brush-border membrane vesicles.

Role of peritubular capillary forces in the renal action of carbonic anhydrase inhibitor

Micropuncture study was performed in Munich-Wistar rats to assess peritubular capillary Starling forces in renal superficial cortex during suppression of proximal fluid reabsorption by carbonic anhydrase inhibitor. Administration of benzolamide (2 mg/kg/hr, i.v., Group 1, N = 7 rats) caused not only reduction in absolute rate of proximal fluid reabsorption (APR, from 26.7 +/- 4.0 nl/min to 17.7 +/- 3.6, P less than 0.001), but also an increase in peritubular transcapillary hydraulic-pressure difference (from 10.0 +/- 0.5 mm Hg to 15.2 +/- 0.5, P less than 0.001). In a separate group of seven rats (Group 2), these parameters did not change significantly without benzolamide treatment. In Group 1 rats, an attempt was made to nullify the benzolamide-induced reduction in the peritubular capillary net reabsorptive forces by infusing hyperoncotic high-hematocrit blood. Following this treatment, while benzolamide administration was continued, values for APR returned to levels (25.6 +/- 4.8 nl/min) nearly identical to those measured prior to benzolamide administration, in association with a rise in peritubular transcapillary oncotic pressure difference. A separate group of six rats treated in a fashion identical to that of Group 1 showed continued suppression of carbonic anhydrase activity following blood infusion as indicated by low levels of whole kidney bicarbonate reabsorption rate. Peritubular capillary reabsorption coefficient was calculated based on the measured values for Starling forces in Group 1 and were unaffected throughout the study. Continued benzolamide administration alone without the treatment of hyperoncotic blood did not change APR significantly (Group 3, N = 7 rats).(ABSTRACT TRUNCATED AT 250 WORDS)

Two independent anion transport systems in rabbit mandibular salivary glands

Cholinergically stimulated Cl and HCO3 transport in perfused rabbit mandibular glands has been studied with extracellular anion substitution and administration of transport inhibitors. In glands perfused with HCO3-free solutions, replacement of Cl with other anions supported secretion in the following sequence: Br = greater than Cl greater than I = greater than NO3 greater than isethionate. Furosemide, 1.0 and 0.1 mmol/l, inhibited Cl-supported secretion by 97-99% and 70-78%, respectively. SITS, 0.1 mmol/l, had no effect and amiloride, 1.0 mmol/l, caused a 55-65% inhibition. Addition of SITS to amiloride-treated glands produced no further effect. In glands perfused with Cl-free solutions, but containing 25 mM HCO3, amiloride, 1.0 mmol/l, inhibited secretion by 95% and methazolamide, 0.1 mmol/l, by 55%. In glands perfused with solutions containing both HCO3 and Cl, furosemide had smaller effects than in glands perfused with solutions containing only Cl - a dose of 1.0 mmol/l inhibited 60% of the initial fast phase of secretion, and 90% of the later plateau phase, while a dose of 0.1 mmol/l inhibited 30% of the initial phase, but had no effect on the plateau. SITS, 0.1 mmol/l, actually stimulated secretion by about 30%, but when infused in addition to furosemide (0.1 mmol/l), it inhibited by about 20%. Amiloride (1.0 mmol/l) caused no inhibition. The results suggest that there are at least three distinct carriers in the rabbit mandibular gland. One is a furosemide-sensitive Na-coupled Cl (probably Na-K-2Cl) symport, responsible for the bulk of normal secretion. The others are an amiloride-sensitive Na-H antiport and a SITS-sensitive Cl-HCO3 antiport.

Biotin uptake mechanisms in brush-border and basolateral membrane vesicles isolated from rabbit kidney cortex

Biotin transport was studied using brush-border and basolateral membrane vesicles isolated from rabbit kidney cortex. An inwardly directed Na+ gradient stimulated biotin uptake into brush-border membrane vesicles and a transient accumulation of the anion against its concentration gradient was observed. In contrast, uptake of biotin by basolateral membrane vesicles was found to be Na+-gradient insensitive. Generation of a negative intravesicular potential by valinomycin-induced K+ diffusion potentials or by the presence of Na+ salts of anions of different permeabilities enhanced biotin uptake by brush-border membrane vesicles, suggesting an electrogenic mechanism. The Na+ gradient-dependent uptake of biotin into brush-border membrane vesicles was saturable with an apparent Km of 28 microM. The Na+-dependent uptake of tracer biotin was significantly inhibited by 50 microM biotin, and thioctic acid but not by 50 microM L-lactate, D-glucose, or succinate. Finally, the existence in both types of membrane vesicles of a H+/biotin- cotransport system could not be demonstrated. These results are consistent with a model for biotin reabsorption in which the Na+/biotin- cotransporter in luminal membranes provides the driving force for uphill transport of this vitamin.

The plasma membrane sodium-hydrogen exchanger and its role in physiological and pathophysiological processes

The plasma membranes of most if not all vertebrate cells contain a transport system that mediates the transmembrane exchange of sodium for hydrogen. The kinetic properties of this transport system include a 1:1 stoichiometry, affinity for lithium and ammonium ion in addition to sodium and hydrogen, the ability to function in multiple 1:1 exchange modes involving these four cations, sensitivity to inhibition by amiloride and its analogues, and allosteric regulation by intracellular protons. The plasma membrane sodium-hydrogen exchanger plays a physiological role in the regulation of intracellular pH, the control of cell growth and proliferation, stimulus-response coupling in white cells and platelets, the metabolic response to hormones such as insulin and glucocorticoids, the regulation of cell volume, and the transepithelial absorption and secretion of sodium, hydrogen, bicarbonate and chloride ions, and organic anions. Preliminary evidence raises the possibility that the sodium-hydrogen exchanger may play a pathophysiological role in such diverse conditions as renal acid-base disorders, essential hypertension, cancer, and tissue or organ hypertrophy. Thus, future research on cellular acid-base homeostasis in general, and on plasma membrane sodium-hydrogen exchange in particular, will enhance our understanding of a great variety of physiological and pathophysiological processes.

Evaluation of ion gradient-dependent H+ transport systems in isolated enterocytes from the chick

The experiments reported here evaluate the capability of isolated intestinal epithelial cells to accomplish net H+ transport in response to imposed ion gradients. In most cases, the membrane potential was kept constant by means of a K+ plus valinomycin "voltage clamp" in order to prevent electrical coupling of ion fluxes. Net H+ flux across the cellular membrane was examined at pH 6.0 (the physiological lumenal pH) and at pH 7.4 using methylamine distribution or recordings of changes in media pH. Results from both techniques suggest that the cells have an Na+/H+ exchange system in the plasma membrane that is capable of rapid and sustained changes in intracellular pH in response to an imposed Na+ gradient. The kinetics of the Na+/H+ exchange reaction at pH 6.0 [Kt for Na+ = 57 mM, Vmax = 42 mmol H+/liter 30MG (3-O-methylglucose) space/min] are dramatically different from those at pH 7.4 (Kt for Na+ = 15 mM, Vmax = 1.7 mmol H+/liter 30MG space/min). Experiments involving imposed K+ gradients suggest that these cells have negligible K+/H+ exchange capability. They exhibit limited but measurable H+ conductance. Anion exchange for base equivalents was not detected in experiments performed in media nominally free of bicarbonate.

Techniques for studying biliary secretion: electrolytes in bile

A major limitation in understanding bile formation has been technical. The liver and ductular epithelium are relatively inaccessible, necessitating indirect techniques of uncertain validity. This is well seen in attempts to define the role of electrolyte secretion in bile. It is widely agreed that bile salts stimulate a component of canalicular flow and that inorganic electrolyte secretion is stimulated by bile salts. The choleretic efficiency of a bile salt is directly related to the magnitude of the electrolyte effect. But there is no consensus regarding how and where bile salts stimulate electrolyte secretion. Some evidence points to a paracellular route by processes of solvent drag and diffusion. Other studies suggest stimulation of specific transcellular electrolyte pathways. It has been believed that canalicular bile salt-independent bile flow is generated by active blood-to-bile electrolyte transport. Actually, available methods do not permit us to conclude with absolute certainty that there is canalicular bile salt-independent flow, although there is considerable evidence for it. New studies suggest that electrolyte transport in this type of flow is passive and that flow is due to transport of organic anions. Ductular flow does seem to be due to active transport of electrolytes, particularly bicarbonate. Better and more direct techniques are required to settle the controversies in this area.

Sodium chloride absorption by the urinary bladder of the winter flounder. A thiazide-sensitive, electrically neutral transport system

The urinary bladder of the winter flounder absorbs NaCl by a process independent of the transepithelial voltage. In contrast to most other epithelia which have a neutral NaCl-absorptive system, the flounder bladder has a high transepithelial resistance. This feature simplifies analysis of the cellular transport system because the rate of ion transfer through the paracellular pathway is rather low. Experiments were designed to distinguish among three possible mechanisms of neutral NaCl absorption: (a) Na/K/2Cl cotransport; (b) parallel Na/H and Cl/OH exchange; (c) and simple NaCl cotransport. A clear interdependency of Na and Cl for net absorption was demonstrated. NaCl absorption was not dependent on mucosal K and was minimally sensitive to loop diuretics. Thus a Na/K/2Cl transport system was unlikely. The mechanism was not parallel exchange as evidenced by insensitivity to amiloride and to 4,4'-diisothiocyano-2,2'-disulfonic stilbene, an inhibitor of anion exchange. In addition, inhibitors of carbonic anhydrase had no effect. Net absorption was almost completely abolished by hydrochlorothiazide (0.1 mM). Its action was rapid, reversible, and effective only from the mucosal surface. Metolazone, a structurally dissimilar diuretic in the benzothiadiazide class had qualitatively similar actions. The mechanism of NaCl absorption in this tissue appears to be a simple interdependent process. Its inhibition by thiazide diuretics appears to be a unique feature. The flounder bladder may be a model for NaCl absorption in the distal renal tubule.

Evidence for neutral transcellular NaCl transport and neutral basolateral chloride exit in the rabbit proximal convoluted tubule

The electrical nature of active NaCl transport and the significance of a basolateral membrane chloride conductance were examined in isolated perfused rabbit proximal convoluted tubules (PCT). PCT were perfused with a high chloride solution that simulated late proximal tubular fluid and were bathed in an albumin solution that simulated rabbit serum in the control and recovery periods. The electrical nature of NaCl transport was examined by bathing the tubules in a high chloride albumin solution where there were no anion gradients. Volume reabsorption (Jv) during the control and recovery period was 0.56 and 0.51 nl/mm X min, respectively, and 0.45 nl/mm X min when the tubules were bathed in a high chloride bath. The transepithelial potential difference (PD) during the control and recovery periods averaged 2.3 mV, but decreased to 0.0 mV in the absence of anion gradients, which indicated that NaCl transport is electroneutral. Further evidence that NaCl transport is electroneutral was obtained by examining the effect of addition of 0.01 mM ouabain in PCT perfused and bathed with high chloride solutions. The Jv was 0.54 nl/mm X min in the control period and not statistically different from zero after inhibition of active transport. The PD was not different from zero in both periods. Two groups of studies examined the role of basolateral membrane Cl- conductance in NaCl transport. First, depolarizing the basolateral membrane with 2 mM bath Ba++ did not significantly affect Jv or PD. Second, the effect of the presumptive Cl- conductance inhibitor anthracene-9-CO2H was examined. Anthracene-9-CO2H did not significantly affect Jv or PD. In conclusion, these data show that NaCl transport in the PCT is electroneutral and transcellular and provide evidence against a significant role for basolateral membrane chloride conductance in the rabbit PCT.

Na/H- and Cl/OH-exchange in rat jejunal and rat proximal tubular brush border membrane vesicles. Studies with acridine orange

The quenching of the acridine orange fluorescence was used to monitor the formation and/or dissipation of a delta pH in brush border vesicles isolated from rat kidney cortex or rat jejunum. Similar findings were obtained with both brush border membrane vesicle preparations. Acridine orange fluorescence was quenched by a preset delta pH (intravesicular acid) or by the ionophore (valinomycin/CCCP) dependent development of a delta pH (intravesicular acid) under conditions of potassium efflux. Under sodium efflux conditions, an acidification of the intravesicular space occurred: a) due to indirect (electrical) coupling of sodium and proton fluxes; b) due to directly coupled sodium/proton exchange. The initial rate of the dissipation of a preset delta pH was accelerated by pulse injections of sodium in a saturable manner; lithium partially replaced sodium. The sodium dependent acceleration in the rate of dissipation of a preset delta pH was not altered by replacing gluconate with chloride. Amiloride was an inhibitor of directly coupled sodium/proton exchange. An inwardly directed chloride gradient did not induce intravesicular acidification. The initial rate of the dissipative proton fluxes (preset delta pH) was slightly accelerated by an outwardly directed chloride gradient. Sodium/proton exchange dependent acidification of the intravesicular space was not altered by replacing gluconate with chloride. These results clearly document the existence of sodium/proton exchange in both renal and intestinal brush border membrane vesicles. In contrast, Cl/OH exchange--under our experimental conditions--must have a much smaller rate than Na/H exchange.

Proton transport and cell function

The past five years have witnessed an explosion of information on the many and varied roles of H+ transport in cell function. H+ transport is involved in three broad areas of cell function: (a) maintenance and alteration of intracellular pH for initiation of specific cellular events, (b) generation of pH gradients in localized regions of the cell, including gradients involved in energy transduction, and (c) transepithelial ion transport. These processes each involve one or more of several H+ translocating mechanisms. The first section of this review will discuss these H+ translocating mechanisms and the second part will deal with the cellular functions controlled by H+ transport.

Na+-H+ exchange and Na+ entry across the apical membrane of Necturus gallbladder

The role of Na+-H+ exchange in Na+ transport across the apical membrane was evaluated in Necturus gallbladder epithelium by means of intracellular Na+ activity (aNai) and 22Na+ uptake measurements. Under control conditions, complete replacement of Na+ in the mucosal solution with tetramethylammonium reduced aNai from 14.0 to 6.9 mM in 2 min (P less than 0.001). Mucosal addition of the Na+-H+ exchange inhibitor amiloride (10(-3) M) reduced aNai from 15.0 to 13.3 mM (P less than 0.001), whereas bumetanide (10(-5) and 10(-4) M) had no effect. Na+ influx across the apical membrane was studied by treating the tissues with ouabain, bathing them in Na-free solutions, and suddenly replacing the mucosal solution with an Na-containing solution. When the mucosal solution was replaced with Na-Ringer's, aNai increased at approximately 11 mM/min. This increase was inhibited by 54% by amiloride (10(-3) M, P less than 0.001) and was unaffected by bumetanide (10(-5) M). Amiloride-inhibitable Na+ fluxes across the apical membrane were also induced by the imposition of pH gradients. Na+ influx was also examined in tissues that had not been treated with ouabain. Under control conditions, 22Na+ influx from the mucosal solution into the epithelium was linear over the first 60 s and was inhibited by 40% by amiloride (10(-3) M, P less than 0.001) and by 19% by bumetanide (10(-5) M, P less than 0.025). We conclude that Na+-H+ exchange is a major pathway for Na+ entry in Necturus gallbladder, which accounts for at least half of apical Na+ influx both under transporting conditions and during exposure to ouabain. Bumetanide-inhibitable Na+ entry mechanisms may account for only a smaller fraction of Na+ influx under transporting conditions, and cannot explain influx in ouabain-treated tissues. These results support the hypothesis that NaCl entry results primarily from the operation of parallel Na+-H+ and Cl--HCO-3 exchangers, and not from a bumetanide-inhibitable NaCl cotransporter.

The intracellular chloride activity of rat kidney proximal tubular cells

The intracellular Cl- activity was determined in rat kidney proximal tubular cells in vivo, using single-barreled Cl- sensitive microelectrodes filled with Corning no. 477913 liquid ion exchanger resin to measure VCl and using - in separate experiments - conventional KCl-filled microelectrodes to measure the membrane potential, Vm. After correction for interference from other anions on VCl the intracellular Cl- activity averaged 13.1 mmol X l-1 SD +/- 4.5 mmol X l-1 (n = 96). This value is approximately two-fold higher than the intracellular equilibrium activity which can be calculated from the extracellular Cl- activity of 90-103 mmol X l-1 and Vm of -71.2 mV, SD +/- 4.9 mV (n = 23) to amount to 6.3 to 6.7 mmol X l-1. Since both cell membranes are permeable for Cl- ions, as concluded from luminal and/or peritubular Cl- substitution experiments, we conclude that the cellular Cl- accumulation above equilibrium results from transcellular active Cl- transport, the detailed mechanism of which is presently not known. From the slow decline of intracellular Cl- concentration after substitution of luminal Cl- by gluconate, however, we deduce that transcellular Cl- absorption is of minor importance in surface tubules of rat kidney under free flow and that the major part of transtubular Cl- flux is passive and paracellular.

Proton pathways in rat renal brush-border and basolateral membranes

The quenching of acridine orange fluorescence was used to monitor the formation and dissipation of pH gradients in brush-border and basolateral membrane vesicles isolated from rat kidney cortex. The fluorescence changes of acridine orange were shown to be sensitive exclusively to transmembrane delta pH and not to membrane potential difference. In brush-border membrane vesicles, an Na+ (Li+)-H+ exchange was confirmed. At physiological Na+ concentrations, 40-70% of Na+-H+ exchange was mediated by the electroneutral Na+-H+ antiporter; the remainder consisted of Na+ and H+ movements through parallel conductive pathways. Both modes of Na+-H+ exchange were saturable, with half-maximal rates at about 13 and 24 mM Na+, respectively. Besides a Na+ gradient, a K+ gradient was also able to produce an intravesicular acidification, demonstrating conductance pathways for H+ and K+ in brush-border membranes. Experiments with Cl- or SO2-4 gradients failed to demonstrate measurable Cl--OH- or SO2-4-OH- exchange by an electroneutral antiporter in brush-border membrane vesicles; only Cl- conductance was found. In basolateral membrane vesicles, neither Na+(Li+)-H+ exchange nor Na+ or K+ conductances were found. However, in the presence of valinomycin-induced K+ diffusion potential, H+ conductance of basolateral membranes was demonstrated, which was unaffected by ethoxzolamide and 4,4'-diisothiocyanostilbene-2,2-disulfonic acid. A Cl- conductance of the membranes was also found, but antiporter-mediated electroneutral Cl--OH- or SO2-4-OH- exchange could not be detected by the dye method. The restriction of the electroneutral Na+-H+ exchanger to the luminal membrane can explain net secretion of protons in the mammalian proximal tubule which leads to the reabsorption of bicarbonate.

Isolation of transporting plasma membrane vesicles from bovine tracheal epithelium

A method is described for isolating plasma membrane vesicles from bovine tracheal epithelium. The procedure yields highly purified apical membranes which are enriched 19-fold in the marker enzyme, alkaline phosphatase. Contamination of this fraction by other organelles is minimal. Basolateral membranes isolated from the same preparation have a 4-fold enrichment of (Na+ + K+)-ATPase and a 2-fold reduction in alkaline phosphatase specific activity compared to the starting material. Assays of Na+ uptake by the apical membrane vesicles demonstrate their suitability for transport studies. Transport of Na+ into an intravesicular space was demonstrated by (1) a linear inverse correlation between Na+ uptake and medium osmolarity; (2) complete release of accumulated Na+ by treatment with detergent; and (3) a marked temperature-dependence of Na+ uptake rate. Other features of Na+ transport were (1) inhibition by amiloride; (2) insensitivity to furosemide; and (3) anion-dependence of uptake rate with the following selectivity:SCN- greater than Cl- greater than gluconate-.

Basal-lateral membranes from rabbit renal cortex prepared on a large scale in a zonal rotor

Basal-lateral membranes from the renal cortex of the rabbit were isolated by sucrose gradient centrifugation in a zonal rotor which allows for a large-scale preparation of these membranes. A heterogeneous population of membranes (P4) which contained 29% of the (Na+ + K+)-ATPase found in the homogenate of renal cortex was prepared by differential centrifugation. When pellet P4 was subjected to centrifugation in a sucrose gradient the activity of (Na+ + K+)-ATPase, a marker for basal-lateral membranes, could be separated from enzymatic markers of other organelles. The specific activity of (Na+ + K+)-ATPase was enriched 12-fold at a density of 1.141 g/cm3. Membranes (P alpha) contained in the (Na+ + K+)-ATPase-rich fractions consisted primarily of closed vesicles which exhibited probenecid inhibitable transport of rho-aminohippurate. These membranes did not exhibit Na+-dependent, phlorizin-inhibitable D-glucose transport. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of proteins from P alpha revealed at least six major protein bands with molecular weights of 91000, 81000, 73000, 65000, 47000 and 38000. A small fraction of total alkaline phosphatase found in the homogenate was found in pellet P4. Membranes containing this alkaline phosphatase activity were distributed widely over the gradient, with peak activity found at a density of 1.141 g/cm3. In contrast, when brush borders were subjected to gradient centrifugation under the same conditions as P4, alkaline phosphatase was found in a narrow distribution, with peak activity at a density of 1.158 g/cm3. The principle subcellular localization of the alkaline phosphatase found in P4 could not be determined unambiguously from the data, but the activity did not seem to be primarily associated with classical brush borders.

Proton/hydroxyl transport in gastric and intestinal epithelia

Proton transport across the plasma membrane of the gastrointestinal epithelium occurs by various pathways. There is the permeability of H+ across the lipid components of the membranes, probably of minor significance at physiological pH, but at the pH of the secretory surface of the parietal cell a factor that cannot be neglected. Transport of H+ dependent on the protein components of the plasma membrane involves various mechanisms. For example Na+ :H+ or Cl- :HCO-3 antiport (exchange) are generally electroneutral mechanisms (i.e., neither affected by potential gradients nor affecting membrane conductance) that are widely distributed throughout the body. Plasma membranes may contain proton or bicarbonate conductances (i.e., gradients of either ion may be determined by the potential across the membrane). This type of pathway is often of minor significance, hence the electrical component of hydrogen ion gradients across the plasma membrane can often be neglected. In the case of the gastric parietal cell, proton transport depends on the activity of a specific ATPase. This ATPase may be present elsewhere in the intestinal tract. This review will consider many of these proton pathways. In the case of brush border pathways, some of the data presented on Na+ :H+ antiport wil be derived from studies done on renal brush border rather than those of the small intestine, on the assumption that the properties of the antiporter are similar in the two tissues.

Membrane transport in the proximal tubule and thick ascending limb of Henle's loop: mechanisms and their alterations

Over the past few years, our knowledge on renal tubular transport mechanisms has increased considerably. Due to new technical developments, it is now possible to understand in part transepithelial transport and its pathological and pharmacological alterations at the level of the cell membranes. Different membrane transport mechanisms are discussed in this article, whereby sodium coupled solute transport in the proximal tubule and sodium chloride transport in the thick ascending limb of Henle's loop are taken as examples. It is indicated that an altered function of the kidney can often be equated with an alteration of the membrane transport.

Ion pathways in renal brush border membranes

The absorbance change of the weak base dye probe, Acridine orange, was used to monitor alterations of pH gradients across renal brush border membrane vesicles. The presence of Na+/H+ or Li+/H+ exchange was demonstrated by diluting Na2SO4 or Li2SO4 loaded vesicles into Na+-or Li+-free solutions, which caused dye uptake. About 20% of the uptake was abolished by lipid permeable cations such as valinomycin-K+ or tetraphenylphosphonium, indicating perhaps the presence of a finite Na+ conductance smaller than electroneutral Na+/H+ exchange. The protonophore tetrachlorosalicylanilide raised the rate of dye uptake under these conditions, hence the presence of an Na+ conductance greater than the H+ conductance was suggested. K+ gradients also induced changes of pH, at about 10% of the Na+ or Li+ rate. Partial inhibition (21%) was seen with 0.1 mM amiloride indicating that K+ was a low affinity substrate for the Na+/H+ exchange. Acceleration both by tetrachlorosalicylanilide (2-fold) and valinomycin (4-fold) suggested the presence of 2 classes of vesicles, those with high and those with low K+ conductance. The larger magnitude of the valinomycin dependent signal suggested that 75% of the vesicles has a low K+ conductance. Inward Cl- gradients also induced acidification, partially inhibited by the presence of tetraphenylphosphonium, and accelerated by tetrachlorosalicylanilide. Thus both a Cl- conductance greater than the H+ conductance and a Cl-/OH- exchange were present. The rate of Na+/H+ exchange was amiloride sensitive with a pH optimum of 6.5 and an apparent Km for Na+ or Li+ of about 10 mM and an EA of 14.3 kcal per mol. A 61-fold Na2SO4 gradient resulted in a pH gradient of 1.64 units which increased to 1.8 with gramicidin. An equivalent NaCl gradient gave a much lower delta pH even in the presence of gramicidin showing that the H+ and Cl- pathways could alter the effect of the Na+/H+ exchange.

Disorders of proximal nephron function

The proximal nephron is responsible for reabsorbing 80 to 99 percent of several filtered solutes, including amino acids, glucose and bicarbonate. Separate, high-affinity sodium co-transport mechanisms are used. Increasing luminal concentration of each of these solutes stimulates its active transcellular reabsorption until there is saturation. Slightly less than half of the filtered chloride is reabsorbed, partly by passive mechanisms that are linked to the reabsorption of organic solutes and bicarbonate, as well as by less well defined independent cellular and/or paracellular mechanisms that appear to be sensitive to transepithelial osmotic pressure gradients. Proximal tubule reabsorption is isosmotic and isonatric, and about 50 to 60 percent of the filtered sodium and water in reabsorbed. Disorders or proximal nephron function include conditions in which luminal, cellular and/or peritubular factors affecting reabsorption are altered. Clinical disorders caused by modification of the luminal reabsorptive determinants include conditions in which tubular flow rate is increased or luminal composition is altered, as when non-reabsorbable solutes (mannitol) are filtered or when reabsorbable solutes (glucose) are filtered in concentrations exceeding their tubular transport capacity. Other disorders occur due to loss of affinity or capacity of the cellular active transport systems for specific solutes, such as amino acids (renal aminoacidurias), glucose (renal glycosurias) and bicarbonate (proximal renal tubular acidosis), or for all solutes (Fanconi syndrome). Finally, disorders due to changes in the peritubular factors affecting reabsorption include states of altered peritubular Starling forces or pH, which modify sodium chloride or sodium bicarbonate reabsorption, respectively.

Ions and energy metabolism in duck salt-gland: possible role of furosemide-sensitive co-transport of sodium and chloride

1. The effects of methacholine on net ionic movements and energy metabolism of the avian salt-gland have been studied, using slices of glands taken from salt-adapted Pekin ducks. The slices were equilibrated with media and drugs for 120 min at 1 degrees C before the experimental incubation at 38 degrees C.2. During incubation at 38 degrees C the slices accumulated K(+) and lost Na(+) and Cl(-). In the presence of methacholine, they retained more Na(+) and Cl(-) and accumulated less K(+), the maximal effects being given by 0.5-1.0 mM-methacholine. Similar results were obtained whether the medium contained 10 mM-Tris (used in most experiments) or 25 mM-HCO(3) (-) as the major buffer.3. The higher final levels of cell Na(+) and Cl(-) induced by methacholine were not seen when furosemide (1 mM) was also present. Methacholine did not induce a higher level of cell Na(+) when medium Cl(-) was replaced by I(-), NO(3) (-) or SO(4) (2-), and did not induce a higher Cl(-) content when medium Na(+) was replaced by choline or Li(+). The fall of K(+) accumulation caused by methacholine was also prevented by furosemide or by replacing Cl(-) in the medium with other anions. The anion-transport inhibitors, SCN(-) (up to 10 mM) and 4,4'-diisothiocyano-2,2'-disulphonic acid stilbene (DIDS) (up to 2 mM) did not prevent the effects of methacholine.4. Methacholine stimulated respiration and lowered the slice ATP contents, and these effects were both prevented by ouabain or furosemide. Ouabain, but not furosemide, also reduced the basal (i.e. in the absence of methacholine) rate of respiration and raised the ATP level. SCN(-) and DIDS had no effect on basal or stimulated respiration or on ATP contents.5. The respiratory stimulation and fall of ATP induced by methacholine were totally prevented if medium Na(+) was replaced by choline. Replacement of Na(+) by Li(+) caused some stimulation of basal respiration; it also permitted some loss of ATP in the presence of methacholine, but the loss was smaller than that seen in the normal Na(+) medium.6. The respiratory stimulation and fall of ATP induced by methacholine were prevented if medium Cl(-) was replaced by SO(4) (2-). The effects of methacholine were partially blocked when NO(3) (-) replaced Cl(-).7. The results are consistent with the stimulation by methacholine of a furosemide-sensitive, coupled entry of Na(+) and Cl(-) into the cells, associated with a loss of K(+). This would result in a stimulation of Na(+) extrusion by the ouabain-sensitive transport system for Na(+) and K(+) with increased consumption of ATP.