valinomycin and 5-nitro-2-(3-phenylpropylamino)benzoic-acid

It has been widely accepted that chloride ions moving along chloride channels act to dissipate the electrical gradient established by the electrogenic transport of H(+) ions performed by H(+)-ATPase into subcellular vesicles. Largely known in intracellular compartments, this mechanism is also important at the plasma membrane of cells from various tissues, including kidney. The present work was performed to study the modulation of plasma membrane H(+)-ATPase by chloride channels, in particular, CFTR and ClC-5 in kidney proximal tubule.. Using in vivo stationary microperfusion, it was observed that ATPase-mediated HCO(3)(-) reabsorption was significantly reduced in the presence of the Cl(-) channels inhibitor NPPB. This effect was confirmed in vitro by measuring the cell pH recovery rates after a NH(4)Cl pulse in immortalized rat renal proximal tubule cells, IRPTC. In these cells, even after abolishing the membrane potential with valinomycin, ATPase activity was seen to be still dependent on Cl(-). siRNA-mediated CFTR channels and ClC-5 chloride-proton exchanger knockdown significantly reduced H(+)-ATPase activity and V-ATPase B2 subunit expression.. These results indicate a role of chloride in modulating plasma membrane H(+)-ATPase activity in proximal tubule and suggest that both CFTR and ClC-5 modulate ATPase activity.

Topics: Ammonium Chloride; Animals; Anti-Bacterial Agents; Bicarbonates; Cell Line; Chloride Channels; Cystic Fibrosis Transmembrane Conductance Regulator; Kidney Tubules, Proximal; Nitrobenzoates; Rats; RNA Interference; RNA, Small Interfering; Vacuolar Proton-Translocating ATPases; Valinomycin

Various K(+) and Cl(-) channels are important in cell volume regulation and biliary secretion, but the specific role of cystic fibrosis transmembrane conductance regulator in cholangiocyte cell volume regulation is not known. The goal of this research was to study regulatory volume decrease (RVD) in bile duct cell clusters (BDCCs) from normal and cystic fibrosis (CF) mouse livers. Mouse BDCCs without an enclosed lumen were prepared as described (Cho, W. K. (2002) Am. J. Physiol. 283, G1320-G1327). The isotonic solution consisted of HEPES buffer with 40% of the NaCl replaced with isomolar amounts of sucrose, whereas hypotonic solution was the same as isotonic solution without sucrose. The cell volume changes were indirectly assessed by measuring cross-sectional area (CSA) changes of the BDCCs using quantitative videomicroscopy. Exposure to hypotonic solutions increased relative CSAs of normal BDCCs to 1.20 +/- 0.01 (mean +/- S.E., n = 50) in 10 min, followed by RVD to 1.07 +/- 0.01 by 40 min. Hypotonic challenge in CF mouse BDCCs also increased relative CSA to 1.20 +/- 0.01 (n = 53) in 10 min but without significant recovery. Coadministration of the K(+)-selective ionophore valinomycin restored RVD in CF mouse BDCCs, suggesting that the impaired RVD was likely from a defect in K(+) conductance. Moreover, this valinomycin-induced RVD in CF mice was inhibited by 5-nitro-2'-(3-phenylpropylamino)-benzoate, indicating that it is not from nonspecific effects. Neither cAMP nor calcium agonists could reverse the impaired RVD seen in CF cholangiocytes. Our conclusion is that CF mouse cholangiocytes have defective RVD from an impaired K(+) efflux pathway, which could not be reversed by cAMP nor calcium agonists.

Topics: 1-Methyl-3-isobutylxanthine; Angiogenesis Inhibitors; Animals; Bile Ducts; Buffers; Colforsin; Cyclic AMP; Cystic Fibrosis; Cystic Fibrosis Transmembrane Conductance Regulator; Electric Conductivity; HEPES; Immunohistochemistry; Ionophores; Liver; Male; Mice; Mice, Inbred C57BL; Mice, Transgenic; Microscopy, Fluorescence; Microscopy, Video; Nitrobenzoates; Potassium; Sodium Chloride; Time Factors; Valinomycin

The macula densa expresses a luminal Na(+)-K(+)-2Cl(-) cotransporter and a basolateral Cl(-) conductance. Although it is known that cotransport of Na(+), K(+), and Cl(-) is the first step in tubuloglomerular feedback (TGF), subsequent steps are unclear. We hypothesized that Na(+)-K(+)-2Cl(-) entry via the luminal Na(+)-K(+)-2Cl(-) cotransporter elevates intracellular Cl(-), increases electrogenic Cl(-) efflux across the basolateral membrane, and depolarizes the macula densa, initiating TGF. We perfused afferent arterioles with macula densa attached. The macula densa was perfused with solutions containing either 5 mM Na(+) and 3 mM Cl(-) (low NaCl) or 80 mM Na(+) and 77 mM Cl(-) (high NaCl). When the macula densa perfusate was changed from low to high NaCl, afferent arteriole diameter decreased from 15.8 +/- 0.8 to 13.1 +/- 0.7 mm (P < 0.05). Adding 10 microM furosemide to the macula densa lumen blocked TGF. When nystatin, a group I cation ionophore, was added to the macula densa lumen together with furosemide in the presence of low NaCl, it induced TGF (from 18.0 +/- 1.5 to 15.6 +/- 1.6 mm; P = 0.003). When valinomycin, a K(+)-selective ionophore, was added to the macula densa lumen together with furosemide in the presence of low NaCl containing 5 mM K(+), it did not induce TGF. Subsequent addition of 50 mM KCl to the macula densa perfusate induced TGF (from 21.7 +/- 0.8 to 17.5 +/- 1.3 mm; P = 0.0047; n = 6). Adding 50 mM KCl without valinomycin did not induce TGF. When 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB; 1 microM), a Cl(-) channel blocker, was added to the bath, it blocked TGF induced by high NaCl, but did not block TGF induced by valinomycin plus 50 mM KCl. NPPB did not alter afferent arteriole constriction induced by norepinephrine. We concluded that increased NaCl in the lumen of the macula densa leads to influx of Cl(-) via the Na(+)-K(+)-2Cl(-) cotransporter. The accelerated transport increases intracellular Cl(-). The subsequent exit of Cl(-) across the basolateral membrane via Cl( -) channels in turn leads to depolarization of the macula densa and thereby induces TGF.

Topics: Animals; Arterioles; Chloride Channels; Chlorides; Culture Techniques; Feedback, Physiological; Furosemide; Ion Transport; Ionophores; Kidney Glomerulus; Kidney Tubules, Distal; Nitrobenzoates; Nystatin; Potassium; Rabbits; Renal Circulation; Sodium; Sodium Potassium Chloride Symporter Inhibitors; Valinomycin

In isolated rhesus eccrine clear cells, regulatory volume decrease (RVD) occurs after osmotic swelling. RVD was completely inhibited by 1 mM quinidine, 200 nM charybdotoxin, 1 mM diphenylamine-2-carboxylic acid (DPC), or 0.1 mM 4-nitro-2(3-phenylpropyl-amino)benzoate. RVD was also inhibited in Ca(2+)-free medium by vinblastine (antimicrotubular agent), N-(6-aminohexyl)-5-chloro-1- naphthalenesulfonamide (W-7), or 0.1 mM 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS). Valinomycin reversed quinidine- and DIDS-induced inhibition of RVD but not the inhibition caused by Ca(2+)-free medium, DPC, vinblastine, or W-7. The cytosolic free Ca2+ concentration, as determined by the fura 2 method, increased from 220 nM in the control to 435 nM during RVD. Activation of both K+ and Cl-currents was also directly demonstrated with the whole cell current-voltage clamp method. DIDS inhibited swelling-induced K+, but not Cl-, currents and depolarized the membrane potential during RVD, further supporting the notion that DIDS inhibited swelling-activated K+, but not Cl-, pathways. We conclude that the observed RVD is mediated by the activation of conductive Ca(2+)-dependent K+ and Cl- pathways.

Topics: 4,4'-Diisothiocyanostilbene-2,2'-Disulfonic Acid; Animals; Biopsy; Calcium; Calmodulin; Cells, Cultured; Charybdotoxin; Chlorides; Eccrine Glands; Egtazic Acid; Homeostasis; Hypotonic Solutions; Macaca mulatta; Membrane Potentials; Nitrobenzoates; ortho-Aminobenzoates; Osmolar Concentration; Potassium; Scorpion Venoms; Skin; Sulfonamides; Valinomycin; Vinblastine

The effects of the Cl- channel blockers, NPPB, IAA94/95 and a number of related compounds on 36Cl- transport in membrane vesicles from bovine kidney cortex and rabbit ileum mucosa brush borders have been studied. These vesicles have been previously shown to be enriched in Cl- channel and Cl-/anion cotransport activity, respectively. Chloride transport was assayed in both types of vesicles by measuring the uptake of 36Cl- in response to an outwardly-directed Cl- concentration gradient. In kidney microsomes, a large proportion of the observed 36Cl- uptake was mediated by an electrogenic uniport and could be substantially reduced by clamping the membrane potential at zero mV using K+ and valinomycin. Chloride uptake was inhibited by both NPPB and IAA94/95 with apparent IC50 values of around 10 microM under optimal conditions (i.e., 4 min uptake at 4 degrees C). Under other conditions (e.g., 10 min uptake at 25 degrees C), where uptake had reached a steady-state level, much higher concentrations of inhibitor were required to cause inhibition. Therefore, previous differences in the reported potency of these compounds may, in part, have been due to the conditions under which Cl- uptake was measured. In addition, both NPPB and, to a lesser extent, IAA94/95 were found to have other effects on the vesicles, in that, when added at a concentration of 100 microM, they induced a leakage of pre-accumulated 36Cl-. This was probably caused by either dissipation of membrane potential or damage to the vesicle membranes. The sulphonic acid derivatives of NPPB and IAA94/95 (NPPB-S and ISA94/95, respectively) blocked 36Cl- uptake with around the same potency as NPPB and IAA94/95, but did not cause any non-specific Cl- leakage, when added at concentrations up to 100 microM. Inhibition of 36Cl- uptake by all four compounds was almost completely reversible. However, when vesicles were incubated with the inhibitors in the presence of an outward Cl- concentration gradient, or if vesicles were freeze/thawed in the presence of the compounds, inhibition could be only partially reversed. In rabbit brush border membrane vesicles, 36Cl- uptake was not reduced when the vesicles were voltage clamped using valinomycin and K+, and was therefore probably mediated by Cl-/Cl- exchange. However, despite the lack of effect of valinomycin, 36Cl- uptake was inhibited by both NPPB (approx. 80% inhibition at 100 microM) and, to a lesser extent, by IAA94/95 (approx. 30% inhibition at 100 microM).(ABS

Topics: Acetates; Animals; Biological Transport; Cattle; Chloride Channels; Chlorides; Glycolates; Ileum; Intracellular Membranes; Kidney Cortex; Membrane Proteins; Membranes; Microvilli; Mucous Membrane; Nitrobenzoates; ortho-Aminobenzoates; Rabbits; Radioisotopes; Valinomycin

To determine how cell calcium ([Ca2+]c) regulates apical Cl- channels, we measured the rate of 125-Iodide (125I-) efflux to assay Cl- channel activity in intact cells and examined cell-free membrane patches from cultured canine tracheal epithelial cells. The Ca2+ elevating agonist bradykinin and the calcium ionophore A23187 increased 125I- efflux. This response did not require prostaglandin production. Under several conditions, changes in [Ca2+]c were temporally dissociated from changes in channel activation: a transient increase in [Ca2+]c caused a prolonged stimulation of 125I- efflux. Neither Cl- channel activation nor open-channel probability was affected by varying internal [Ca2+] in excised membrane patches. Adenosine 3',5'-cyclic monophosphate (cAMP)- and Ca2(+)-dependent channel activation may be independent: cAMP-stimulated 125I- efflux did not require an increase in [Ca2+]c, Ca2(+)-stimulated efflux did not require an increase in cAMP, and simultaneous addition of A23187 and isoproterenol produced additive effects on 125I- efflux. The data suggest that an increase in [Ca2+]c activates Cl- channels, however, the effect of Ca2+ appears to be indirect, not involving a ligand-type interaction with the channel.

Topics: Animals; Bumetanide; Calcimycin; Calcium; Cells, Cultured; Chloride Channels; Chlorides; Cyclic AMP; Dogs; Epithelium; Indomethacin; Iodides; Ion Channels; Isoproterenol; Kinetics; Membrane Proteins; Muscle, Smooth; Nitrobenzoates; Potassium; Theophylline; Trachea; Valinomycin

The basolateral membrane of the thick ascending loop of Henle (TALH) of the mammalian kidney is characterized by its high content of Na+/K(+)-ATPase and a Cl- conductance, which function in parallel in salt reabsorption. In order to reconstitute the Cl- channels, TALH membrane vesicles were solubilized in 1% sodium cholate in buffer containing 200 mM KCl, followed by dilution with soybean lipids (final ratio of protein/detergent/lipid of 1:3:15 in mg) and removal of the detergent by gel filtration on Sephadex G-50. Cl- channel activity in the liposomes was determined by a 36Cl- uptake assay where the accumulation of the radioactive tracer against its chemical gradient is driven by the membrane potential (positive inside) generated by an outward Cl- gradient. The 36Cl- uptake by the KCl-loaded liposomes was dependent on the inclusion of membrane protein and was abolished by valinomycin, indicating the involvement of a conductive pathway. It was also inhibited by 36% by 100 microM 4,4'-diisothiocyanostilbene-2,2'-disulfonate (DIDS) and 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB). Solubilization of the Cl- channels in cholate was optimal in the presence of 200 mm KCl, but was found to decrease markedly at low ionic strength. SDS-PAGE analysis of the proteins extracted by cholate at high and low salt concentrations showed that the Cl- channel-containing high KCl extract was enriched in the 96 and 55 kDa alpha- and beta-subunits of the Na+/K(+)-ATPase (the major proteins in the membrane preparation) and several minor protein bands. Treatment of the membrane vesicles with the radioactive analogue of DIDS, [3H]2DIDS, labeled primarily a 65 and a 31 kDa protein. The solubilization of the 31 kDa protein by cholate depended markedly on the ionic strength and thus paralleled the solubilization pattern of Cl- channel activity. Furthermore, the labeling of the 31 kDa protein was prevented by nonradioactive DIDS and by NPPB but not by other compounds, indicating that it may be a Cl- channel component.

Topics: 4-Acetamido-4'-isothiocyanatostilbene-2,2'-disulfonic Acid; 4,4'-Diisothiocyanostilbene-2,2'-Disulfonic Acid; Animals; Cell Membrane; Chloride Channels; Chlorides; Chlorine; Chromatography, Gel; Kidney Tubules; Liposomes; Loop of Henle; Membrane Potentials; Membrane Proteins; Nitrobenzoates; Potassium Chloride; Radioisotopes; Sodium-Potassium-Exchanging ATPase; Solubility; Swine; Valinomycin