Cyclic AMP stimulation of calcium efflux from kidney,liver, and heart mitochondria

Summary The effect of cyclic AMP on subcellular calcium turnover was studied in isolated kidney, liver and heart mitochondria. The calcium concentration of the incubating medium was determined by fluorometric methods after its separation by millipore filtration. Liver and kidney mitochondria take up calcium in exchange for H⁺ and lower the medium calcium to 1 to 40×10^–6 m in less than 2 min. Cyclic AMP produces an instantaneous release of calcium from mitochondria and a rise in the steady-state calcium concentration of the medium. A new medium calcium level of 0.7 to 3×10^–4 m is achieved in less than 3 sec and is proportional to cyclic AMP concentrations between 10^–7 and 3×10^–6 m. Cyclic AMP is inactive above 5×10^–6 m and below 10^–7 m. Cyclic IMP, 5 AMP, dibutyryl cAMP are inactive at any concentration. Cyclic GMP is active at 10^–5 m and competitively inhibits cyclic AMP action. The same staedy-state calcium level is reached from higher or, lower calcium concentrations, i.e. whether cyclic AMP is added before or after the addition of calcium to the mitochondrial suspension. At low calcium or phosphate concentrations, the calcium released by cyclic AMP is immediately reaccumulated by the mitochondria is less than 2 min with a further release of H⁺. This pulse can be repeated by sequential additions of cyclic AMP. The transient or sustained response to cyclic AMP depends on the medium calcium x phosphate product and presumably on the presence or absence of calcium phosphate precipitate inside the mitochondria. These results support the hypothesis that cyclic AMP regulates cytoplasmic calcium by controlling the mitochondrial calcium efflux rate. This mechanism may be involved in the regulation of calcium transport and in some hormonal effects mediated by cyclic AMP.     

Effect of poly-L-lysine on potassium fluxes in red beet tissue

Summary Poly-L-lysine concentrations (10^–6 m) which cause slight leakage of pigment from beet cells completely disrupt the kinetics of^*K (labeled) absorption at 25°C in the range 0.01 to 50mm KCl. Lower concentrations of polylysine (10^–7 to 10^–9 m) interfere with potassium fluxes at both cell membranes, initially increasing efflux across the plasma membrane and decreasing the capacity of the cytoplasm to retain ions during flux experiments at 2°C. At 25°C, these concentrations of polylysine increase^*K (labeled) absorption from 0.2mm KCl, but not from 10mm KCl. These responses are discussed in relation to ion transport via the three-compartment in-series model proposed for plant cells. Particular emphasis is placed on the role of the plasma membrane in K transport from solutions of low concentration.     

Reconstitution of the native mitochondrial outer membrane in planar bilayers. Comparison with the outer membrane in a patch pipette and effect of aluminum compounds

Summary Detergent-free rat brain outer mitochondrial membranes were incorporated in planar lipid bilayers in the presence of an osmotic gradient, and studied at high (1 m KCl) and low (150 mm KCl) ionic strength solutions. By comparison, the main outer mitochondrial membrane protein, VDAC, extracted from rat liver with Triton X-100, was also studied in 150 mm KCl. In 1 m KCl, brain outer membranes gave rise to electrical patterns which resembled very closely those widely described for detergent-extracted VDAC, with transitions to several subconducting states upon increase of the potential difference, and sensitivity to polyanion. The potential dependence of the conductance of the outer membrane, however, was steeper and the extent of closure higher than that observed previously for rat brain VDAC. In 150 mm KCl, bilayers containing only one channel had a conductance of 700 ± 23 pS for rat brain outer membranes, and 890 ± 29 pS for rat liver VDAC. Use of a fast time resolution setup allowed demonstration of open-close transitions in the millisecond range, which were independent of the salt concentration and of the protein origin. We also found that a potential difference higher than approx. ± 60 mV induced an almost irreversible decrease of the single channel conductance to few percentages of the full open state and a change in the ionic selectivity. These results show that the behavior of the outer mitochondrial membrane in planar bilayers is close to that detected with the patch clamp (Moran et al., 1992, Eur. Biophys. J. 20:311–319).The neurotoxicological action of aluminum was studied in single outer membrane channels from rat brain mitochondria. We found that m concentrations of Al Cl₃ and aluminum lactate decreased the conductance by about 50%, when the applied potential difference was positive relative to the side of the metal addition.The authors thank Dr. O. Moran for helpful discussions, Dr. M. Colombini for a sample of polyanion, and the Sharing Company for financial support to Dr. T. M. This work was partly supported by funds from the Ministero dell' Universitá e della Ricerca Scientifica e Tecnologica of Italy.     

Current-voltage relationships of a sodium-sensitive potassium channel in the tonoplast ofChara corallina

Summary The membrane of mechanically prepared vesicles ofChara corallina has been investigated by patch-clamp techniques. This membrane consists of tonoplast as demonstrated by the measurement of ATP-driven currents directed into the vesicles as well as by the ATP-dependent accumulation of neutral red. Addition of 1mm ATP to the bath medium induced a membrane current of about 3.2 mA·m^–2 creating a voltage across the tonoplast of about –7 mV (cytoplasmic side negative). On excised tonoplast patches, currents through single K⁺-selective channels have been investigated under various ionic conditions. The open-channel currents saturate at large voltage displacements from the equilibrium voltage for K⁺ with limiting currents of about +15 and –30 pA, respectively, as measured in symmetric 250mm KCl solutions. The channel is virtually impermeable to Na⁺ and Cl^–. However, addition of Na⁺ decreases the K⁺ currents. TheI–V relationships of the open channel as measured at various K⁺ concentrations with or without Na⁺ added are described by a 6-state model, the 12 parameters of which are determined to fit the experimental data.     

Quinine Inhibits Mitochondrial ATP-regulated Potassium Channel from Bovine Heart

The mitochondrial ATP-regulated potassium (mitoK_ATP) channel has been suggested as trigger and effector in myocardial ischemic preconditioning. However, molecular and pharmacological properties of the mitoK_ATP channel remain unclear. In the present study, single-channel activity was measured after reconstitution of the inner mitochondrial membrane from bovine ventricular myocardium into bilayer lipid membrane. After incorporation, a potassium-selective current was recorded with mean conductance of 103 ± 9 pS in symmetrical 150 mM KCl. Single-channel activity of this reconstituted protein showed properties of the mitoK_ATP channel: it was blocked by 500 μM ATP/Mg, activated by the potassium-channel opener diazoxide at 30 μM, inhibited by 50 μM glibenclamide or 150 μM 5-hydroxydecanoic acid, and was not affected by the plasma membrane ATP-regulated potassium-channel blocker HMR1098 at 100 μM. We observed that the mitoK_ATP channel was blocked by quinine in the micromolar concentration range. The inhibition by quinine was additionally verified with the use of ⁸⁶Rb⁺ flux experiments and submitochondrial particles. Quinine inhibited binding of the sulfonylurea derivative [³H]glibenclamide to the inner mitochondrial membrane. We conclude that quinine inhibits the cardiac mitoK_ATP channel by acting on the mitochondrial sulfonylurea receptor.(P. Bednarczyk and A. Kicińska) These authors contributed equally to this work.This revised version was published online in August 2005 with a corrected cover date.     

Some effects of trinitrocresolate and valinomycin on Na and K transport across thin lipid bilayer membranes: A steady-state analysis with simultaneous tracer and electrical measurements

Summary This paper describes the effect of trinitrocresolate anions (TNC^–) on the electrical conductance (G _m ), and tracer-measured unidirectional Na and K fluxes (M _Na andM _K) across bilayers formed from sheep red cell lipids dissolved in decane. In the absence of TNC^–, typical low conductances were observed, while the cation fluxes were too low to measure by our techniques (<10^–12 moles cm^–2 sec^–1). In the presence of TNC^– (10^–2 m),G _m increased and TNC^– was the main charge carrier in the system. The cationic fluxes were also much increased, but the membranes showed no significant selectivity between K and Na. Furthermore, the Na and K fluxes were at least two orders of magnitude larger than the ionic fluxes calculated fromG _m . Thus, almost all of the K and Na transport across the membrane in the presence of TNC^– is electrically silent and is probably carried out as KTNC and NaTNC ion pairs.In the presence of valinomycin (10^–6 m) and no TNC^–, both the ion fluxes andG _m were 10³ times larger in KCl than in NaCl, thus exhibiting the characteristic high selectivity of valinomycin for K over Na. In the presence of both valinomycin (10^–6 m) and TNC^– (10^–2 m), this selectivity disappeared in that bothG _m andM _Na in the NaCl system were similar to the respective values in the KCl system. Even under these conditions, most of the Na is still transported by a process which does not carry charge.BothG _m andM _x increased alike and monotonically with increasing temperature over the range 7 to 30°C. In the absence of TNC^– the enthalpies of activation were invariably higher in KCl than in NaCl. Addition of TNC^– produced equal enthalpies of activation for both Na and K containing systems suggesting a common, temperature-dependent, ratedetermining step in charge transfer and the electrically silent cation fluxes.     

Evidence for a Na+/K+/Cl− cotransport system in basolateral membrane vesicles from the rabbit parotid

Summary Sodium (²²Na) transport was studied in a basolateral membrane vesicle preparation from rabbit parotid. Sodium uptake was markedly dependent on the presence of both K⁺ and Cl^– in the extravesicular medium, being reduced 5 times when K⁺ was replaced by a nonphysiologic cation and 10 times when Cl^– was replaced by a nonphysiologic anion. Sodium uptake was stimulated by gradients of either K⁺ or Cl^– (relative to nongradient conditions) and could be driven against a sodium concentration gradient by a KCl gradient. No effect of membrane potentials on KCl-dependent sodium flux could be detected, indicating that this is an electroneutral process. A KCl-dependent component of sodium flux could also be demonstrated under equuilibrium exchange conditions, indicating a direct effect of K⁺ and Cl^– on the sodium transport pathway. KCl-dependent sodium uptake exhibited a hyperbolic dependence on sodium concentration consistent with the existence of a single-transport system withK _m =3.2mm at 80mm KCl and 23°C. Furosemide inhibited this transporter withK _0.5=2×10^–4 m (23°C). When sodium uptake was measured as a function of potassium and chloride concentrations a hyperbolic dependence on [K] (Hill coefficient =1.31±0.07) were observed, consistent with a Na/K/Cl stoichiometry of 112. Taken together these data provide strong evidence for the electroneutral coupling of sodium and KCl movements in this preparation and strongly support the hypothesis that a Na⁺/K⁺/Cl^– cotransport system thought to be associated with transepithelial chloride and water movements in many exocrine glands is present in the parotid acinar basolateral membrane.     

Channel formation in phospholipid bilayer membranes by the toxin ofHeminthosporium maydis,race T

Summary Southern Corn Leaf Blight is caused by a toxin produced by a virulent form ofHelminthosporium maydis (Race T). The toxin has been shown to uncouple oxidative phosphorylation and dissipate Ca²⁺ gradients in mitochondria isolated from susceptible, but not resistant, corn. The possibility that the toxin acted by increasing the permeability of membranes to ions was tested using a planar bilayer membrane system. Addition of the toxin to the bilayer system, under voltage-clamp conditions, resulted in stepwise increases in current across the phospholipid bilayer, a response characteristic for channel formers. Single-channel conductance in 1m KCl is 27 pS which corresponds to 1.7×10⁷ ions sec^–1 channel^–1 at 100 mV applied potential. The toxin channels are: (i) fairly uniform in conductance, (ii) ideally selective for K⁺ over Cl^–, and (iii) most conductive to H⁺. The channel showed the following selectivity for alkali metal cations: Rb⁺>K⁺>Cs⁺>Na⁺>Li⁺ (169731) based on the most frequently observed conductance in 1m chloride salts. The toxin showed no voltage dependence over the range of –100 to +100 mV. Channel formation was also a property of a synthetic analog (Cmpd IV) of the toxin. The ability of the native toxin to form channels may be a mode of toxin action on mitochondrial membranes from susceptible corn.     

Reconstitution in planar lipid bilayers of a voltage-dependent anion-selective channel obtained from paramecium mitochondria

Summary We have incorporated into planar lipid bilayer membranes a voltage-dependent, anion-selective channel (VDAC) obtained fromParamecium aurelia. VDAC-containing membranes have the following properties: (1) The steady-state conductance of a many-channel membrane is maximal when the transmembrane potential is zero and decreases as a steep function of both positive and negative voltage. (2) The fraction of time that an individual channel stays open is strongly voltage dependent in a manner that parallels the voltage dependence of a many-channel membrane. (3) The conductance of the open channel is about 500 pmho in 0.1 to 1.0m salt solutions and is ohmic. (4) The channel is about 7 times more permeable to Cl^– than to K⁺ and is impermeable to Ca⁺⁺. The procedure for obtaining VDAC and the properties of the channel are highly reproducible.VDAC activity was found, upon fractionation of the paramecium membranes, to come from the mitochondria. We note that the published data on mitochondrial Cl^– permeability suggest that there may indeed be a voltage-dependent Cl^– permeability in mitochondria.The method of incorporating VDAC into planar lipid bilayers may be generally useful for reconstituting biological transport systems in these membranes.     

Coupling mechanisms in anionic substrate transport across the inner membrane of rat-liver mitochondria

The translocation of P_i, malate, -oxoglutarate, and citrate across the inner membrane of rat-liver mitochondria has been studied. Investigation on the effect of pH on anionic substrate translocation across the mitochondrial membrane shows that their distribution across the inner membrane can be governed by transmembrane pH difference. However, evidence is presented that the translocation of P_i, but not that of malate, -oxoglutarate, or citrate can bedirectly coupled to an OH^– counterflux (H₂PO ₄ ^– –OH^– exchange-diffusion). and malate-tricarboxylate exchange-diffusion reactions is directly demonstrated. The study of the effect of uncouplers on the efflux from mitochondria of substrate anions, in the absence of counteranion, and on the anion exchange-diffusions shows that uncouplers act in at least two ways: they promote the efflux of P_i from mitochondria and inhibitdirectly the exchange-diffusion reactions. The kinetics of this inhibition are described. These results are discussed in the light of previous work on the effect of uncouplers on the distribution of substrate anions across the inner membrane of isolated mitochondria. Coupling mechanisms in substrate anion translocation and aspects of the energetics of anion translocation are discussed.     

Dissociation of yeast ribosomes; The effects of hydrostatic pressure and KCl

The dissociation of free ribosomes at elevated concentrations of KCl is dependent on hydrostatic pressure. The pressure necessary for the dissociation is determined for KCl concentrations ranging from 0.1–0.4 m. It varies between 425 kg cm^-2 at 0.1 m and 10 kg cm^-2 at 0.4 m. The partial dissociation of complex ribosomes in KCl is dependent on hydrostatic pressure in the same way as the complete dissociation of free ribosomes. Therefore, it is concluded that mRNA and peptidyl-tRNA do not contribute to the stability of the ribosome under these conditions.     

Evidence for two compartments of exchangeable calcium in isolated rat liver mitochondria obtained using a45Ca exchange technique in the presence of magnesium,phosphate, and ATP at 37°C

Summary The distribution of calcium between isolated rat liver mitochondria and the extramitochondrial medium at 37°C and in the presence of 2mm inorganic phosphate, 3mm ATP, 0.05 or 1.1mm free magnesium and a calcium buffer, nitrilotriacetic acid, was investigated using a⁴⁵Ca exchange technique. The amounts of⁴⁰Ca in the mitochondria and medium were allowed to reach equilibrium before initiation of the measurement of⁴⁵Ca exchange. At 0.05mm free magnesium and initial extramitochondrial free calcium concentrations of between 0.15 and 0.5 m, the mitochondria accumulated calcium until the extramitochondrial free calcium concentration was reduced to 0.15 m. Control experiments showed that the mitochondria were stable under the incubation conditions employed. The⁴⁵Ca exchange data were found to be consistent with a system in which two compartments of exchangeable calcium are associated with the mitochondria. Changes in the concentration of inorganic phosphate did not significantly affect the⁴⁵Ca exchange curves, whereas an increase in the concentration of free magnesium inhibited exchange. The maximum rate of calcium outflow from the mitochondria was estimated to be 1.7 nmol/min per mg of protein, and the value ofK _0.5 for intramitochondrial exchangeable calcium to be about 1.6 nmol per mg of protein. Ruthenium Red decreased the fractional transfer rate for calcium inflow to the mitochondria while nupercaine affected principally the fractional transfer rates for the transfer of calcium between the two mitochondrial compartments. The use of the incubation conditions and⁴⁵Ca exchange technique described in this report for studies of the effects of agents which may alter mitochondrial calcium uptake or release (e.g., the pre-treatment of cells with hormones) is briefly discussed.     

Kinetic studies on the stimulation of Na+−H+ exchange activity in renal brush border membranes isolated from thyroid hormone-treated rats

Summary Na⁺–H⁺ exchange activity in renal brush border membrane vesicles isolated from hyperthyroid rats was increased. When examined as a function of [Na⁺], treatment altered the initial rate of Na⁺ uptake by increasingV _m (hyperthyroid, 18.9±1.1 nmol Na⁺ · mg^–1 · 2 sec^–1; normal, 8.9±0.3 nmol Na⁺ · mg^–1 · 2 sec^–1), and not the apparent affinityK _Na ⁺ (hyperthyroid, 7.3±1.7mm; normal, 6.5±0.9mm). When examined as a function of [H⁺] and at a subsaturating [Na⁺] (1mm), hyperthyroidism resulted in the proportional increase in Na⁺ uptake at every intravesicular pH measured. A positive cooperative effect on Na⁺ uptake was found with increased intravesicular acidity in vesicles from both normal and hyperthyroid rats. When the data were analyzed by the Hill equation, it was found that hyperthyroidism did not change then (hyperthyroid, 1.2±0.06; normal, 1.2±0.07) or the [H⁺]_0.5 (hyperthyroid, 0.39±0.08 m; normal, 0.44±0.07 m) but increased the apparentV _m (hyperthyroid, 1.68±0.14 nmol Na⁺ · mg^–1 · 2 sec^–1; normal 0.96±0.10 nmol Na⁺ · mg^–1 · 2 sec^–1). The uptake of Na⁺ in exchange for H⁺ in membrane vesicles from normal and hyperthyroid animals was not influenced by membrane potential. H⁺ translocation or debinding was rate limiting for Na⁺–H⁺ exchange since Na⁺–Na⁺ exchange activity was greater than Na⁺–H⁺ exchange activity. Hyperthyroidism caused a proportional increase and hypothyroidism caused a proportional decrease in Na⁺–Na⁺ and Na⁺–H⁺ exchange. We conclude that hyperthyroidism leads to either an increase in the number of functional exchangers in the membrane or exactly proportional increases in the rate-limiting steps for Na⁺–Na⁺ and Na⁺–H⁺ exchange activity.     

cAMP-activated chloride channel in the basolateral membrane of the thick ascending limb of the mouse kidney

Summary The properties of an anion-selective channel observed in basolateral membranes of microdissected, collagenase-treated, cortical thick ascending limbs of Henle's loop from mouse kidney were investigated using patch-clamp single-channel recording techniques. In basal conditions, single Cl^– currents were detected in 8% of cell-attached and excised, inside-out, membrane patches whereas they were observed in 24% of cell-attached and 67% of inside-out membrane patches when tubular fragments were preincubated with Forskolin (10^–5 m) or 8-bromo-cAMP (10^–4 m) and isobutylmethylxanthine (10^–5 m). The channel exhibited a linear current-voltage relationship with conductances of about 40 pS in both cell-attached and cell-free membrane configurations. AP _Na ⁺ P _Cl ^–ratio of 0.05 was estimated in the presence of a 142/42mm NaCl concentration gradient applied to inside-out membrane patches. Anionic selectivity of the channel followed the sequence Cl^–>Br^–>No ₃ ^– F^–; gluconate was not a permeant species. The open-state probability of the channel increased with membrane depolarization in cell-attached, i.e.,in situ membrane patches. In excised, inside-out, membrane patches, the channel was predominantly open with the open-state probability close to 0.8 over the whole range of potentials tested (–60 to +60 mV). The channel activity was not a function of internal calcium concentration between 10^–9 and 10^–3 m. We suggest that this Cl^– channel, whose properties are distinct from those in other epithelia, could account for the well-documented conductance which mediates Cl^– exit in the basolateral step of NaCl absorption in thick ascending limb of Henle's loop.     

Modification of valinomycin-mediated bilayer membrane conductance by 4,5,6,7-tetrachloro-2-methylbenzimidazole

Summary The compound, 4,5,6,7-tetrachloro-2-methylbenzimidazole (TMB), has been found to markedly modify the steady-state valinomycin-mediated conductance of potassium (K⁺) ions through lipid bilayer membranes. TMB alone does not contribute significantly to membrane conductance, being electrically neutral in solution. In one of two classes of experiments (I), valinomycin is first added to the aqueous phases then changes of membrane conductance accompanying stepwise addition of TMB to the water are measured. In a second class of experiments (II), valinomycin is added to the membrane-forming solution, follwed by TMB additions to the surrounding water. In both cases membrane conductance shows an initial increase with increasing TMB concentration which is more pronounced at lower K⁺ ion concentration. At TMB concentrations in excess of 10^–5 m, membrane conductance becomes independent of K⁺ ion concentration, in contrast to the linear dependence observed at TMB concentrations below 10^–7 m. This transition is accompanied by a change of high field current-voltage characteristics from superlinear (or weakly sublinear) to a strongly sublinear form. All of these observations may be correlated by the kinetic model for carriermedicated transport proposed by Läuger and Stark (Biochim. Biophys. Acta 211:458, 1970) from which it may be concluded that valinomycin-mediated ion transport is limited by back diffusion of the uncomplexed carrier at high TMB concentrations. Experiments of class I reveal a sharp drop of conductance at high (>10^–5 m) TMB concentration, not seen in class II experiments, which is attributed to blocked entry of uncomplexed carrier from the aqueous phases. Valinomycin initially in the membrane is removed by lateral diffusion to the surrounding torus. The time dependence of this removal has been studied in a separate series of experiments, leading to a measured coefficient of lateral diffusion for valinomycin of 5×10^–6 cm²/sec at 25°C. This value is about two orders of magnitude larger than the corresponding coefficient for transmembrane carrier diffusion, and provides further evidence for localization of valinomycin in the membrane/solution interfaces.     

Evidence for permanent water channels in the basolateral membrane of an ADH-sensitive epithelium

Summary The transepithelial water permeability in frog urinary bladder is believed to be essentially dependent on the ADH-regulated apical water permeability. To get a better understanding of the transmural water movement, the diffusional water permeability (P _d) of the basolateral membrane of urinary bladder was studied. Access to this post-luminal barrier was made possible by perforating the apical membrane with amphotericin B. The addition of this antibiotic increasedP _d from 1.12±0.10×10^–4 cm/sec (n=7) to 4.08±0.33×10^–4 cm/sec (n=7). The effect of mercuric sulfhydryl reagents, which are commonly used to characterize water channels, was tested on amphotericin B-treated bladders. HgCl₂ (10^–3 m) decreasedP _d by 52% andpara-chloromercuribenzoic acid (pCMB) (1.4×10^–4 m) by 34%. The activation energy for the diffusional water transport was found to increase from 4.52±0.23 kcal/mol (n=3), in the control situation, to 9.99±0.91 kcal/mol (n=4) in the presence of 1.4×10^–4 m pCMB. Our second approach was to measure the kinetics of water efflux, by stop-flow light scattering, on isolated epithelial cells from urinary bladders.pCMB (0.5 or 1.4×10^–4 m) was found to inhibit water exit by 91±2%. These data strongly support the existence of proteins responsible for water transport across the basolateral membrane, which are permanently present.     

Alpha and beta adrenergic agonists stimulate water absorption in the rat proximal tubule

Summary Simultaneous capillary and luminal microperfusion studies were performed in the rat proximal tubule to determine the effects of the beta agonist isoproterenol and the alpha agonist phenylephrine on water absorption. Capillary and luminal perfusion solutions were composed such that organic solutes were not present, no bicarbonate was present in the lumen, and no chloride gradient was imposed. Under such conditions, water absorption (Jv) averaged 0.36±0.11 nl·min^–1·mm^–1. The addition of isoproterenol to the capillary solution in concentrations of 10^–6 and 10^–4 m resulted in significantly higherJv's of 0.68±0.10 and 0.71±0.11 nl·min^–1·mm^–1, respectively. The enhancing effect of isoproterenol was inhibited by the beta blocker propranolol (10^–4 m), but not by the alpha blocker phentolamine (10^–7 m). The addition of phenylephrine (10^–6 m) to the capillary perfusion solution also resulted in a significantly higherJv of 0.84±0.14 nl·min^–1·mm^–1, an effect inhibited by phentolamine (10^–7 m), but not by propranolol (10^–4 m). Neither phentolamine nor propranolol alone in the concentrations indicated had an effect on water absorption. These experiments indicate that both alpha and beta agonists stimulate water absorption in the superficial proximal tubule of the rat. This effect appears to be relatively specific for each class of agonist, as demonstrated by the effects of the specific antagonists.     

Volume-dependent Glutamate Permeation Depends on Transmembrane Ionic Strength and Extracellular Cl<Superscript>−</Superscript>

Many mammalian cells regulate their volume by the osmotic movement of water directed by anion and cation flux. Ubiquitous volume-dependent anion currents permit cells to recover volume after swelling in response to a hypotonic environment. This study addressed competition between glutamate (Glu) and Cl^– permeation in volume-activated anion currents in order to provide insight into the ionic requirements for volume regulation, volume-dependent anion channel activity and to the architecture of the channel pore. The effect of changing the intracellular molar fraction (MF) of Glu and Cl^– on conductance and relative anion permeability was evaluated as a function of the extracellular permeant anion and/or the ionic strength. Relative permeability of Glu to Cl^– was determined by measuring reversal potentials under defined ionic conditions. Under conditions with high (150 mM) or low (50 mM) ionic strength solutions on both sides of the membrane, Cl^– was always more permeable than Glu. When a transmembrane ionic strength gradient (150 mM extracellular: 50 mM intracellular) was set to drive water into the cell, and in the presence of extracellular Cl^–, Glu became up to 16-fold more permeable than Cl^–. Replacement of extracellular Cl^– with Glu abolished this effect. These results indicate that it is possible for Glu to move into the extracellular environment during volume-regulatory events and they support the emerging role of glutamate as a modulator of anion channel activity.     

Chloride-activated water permeability in the frog corneal epithelium

We have previously reported that the isolated frog corneal epithelium (a Cl^–-secreting epithelium) has a large diffusional water permeability (P_dw 1.8×10^–4 cm/s). We now report that the presence of Cl^– in the apical-side bathing solution increases the diffusional water flux, J_dw (in both directions) by 63% from 11.3 to 18.4 l min^–1 · cm^–2 with 60 mm [Cl] exerting the maximum effect. The presence of Cl^– in the basolateral-side bathing solution had no effect on the water flux. In Cl^–-free solutions amphotericin B increased J_dw by 29% but only by 3% in Cl^–-rich apical-side bathing solution, suggesting that in Cl^–-rich apical side bathing solution, the apical barrier is no longer rate limiting. Apical Br^– (75 mm) also increased J_dw by 68%. The effect of Cl^– on J_dw was observed within 1 min after its addition to the apicalside bathing solution. HgCl₂ (0.5 mm) reduced the Cl^–-increased P_dw by 31%. The osmotic permeability (P_f) was also measured under an osmotic gradient yielding values of 0.34 and 2.88 (x 10^–3 cm/s) in Cl^–-free and Cl^–-rich apical-side bathing solutions respectively. It seems that apical Cl^–, or Cl^– secretion into the apical bath could activate normally present but inactive water channels. In the absence of Cl^–, water permeability of the apical membrane seems to be limited to the permeability of the lipid bilayer.This work was supported by National Eye Institute grants EY-00160 and EY-01867.     

High-conductance K+ channel in pancreatic islet cells can be activated and inactivated by internal calcium

Summary The Ca²⁺-activated K⁺ channel in rat pancreatic islet cells has been studied using patch-clamp single-channel current recording in excised inside-out and outside-out membrane patches. In membrane patches exposed to quasi-physiological cation gradients (Na⁺ outside, K⁺ inside) large outward current steps were observed when the membrane was depolarized. The single-channel current voltage (I/V) relationship showed outward rectification and the null potential was more negative than –40 mV. In symmetrical K⁺-rich solutions the single-channelI/V relationship was linear, the null potential was 0 mV and the singlechannel conductance was about 250 pS. Membrane depolarization evoked channel opening also when the inside of the membrane was exposed to a Ca²⁺-free solution containing 2mm EGTA, but large positive membrane potentials (70 to 80 mV) were required in order to obtain open-state probabilities (P) above 0.1. Raising the free Ca²⁺ concentration in contact with the membrane inside ([Ca²⁺]_i) to 1.5×10^–7 m had little effect on the relationship between membrane potential andP. When [Ca²⁺]_i was increased to 3×10^–7 m and 6×10^–7 m smaller potential changes were required to open the channels. Increasing [Ca²⁺]_i further to 8×10^–7 m again activated the channels, but the relationship between membrane potential andP was complex. Changing the membrane potential from –50 mV to +20 mV increasedP from near 0 to 0.6 but further polarization to +50 mV decreasedP to about 0.2. The pattern of voltage activation and inactivation was even more pronounced at [Ca²⁺]_i=1 and 2 m. In this situation a membrane potential change from –70 to +20 mV increasedP from near 0 to about 0.7 but further polarization to +80 mV reducedP to less than 0.1. The high-conductance K⁺ channel in rat pancreatic islet cells is remarkably sensitive to changes in [Ca²⁺]_i within the range 0.1 to 1 m which suggests a physiological role for this channel in regulating the membrane potential and Ca²⁺ influx through voltage-activated Ca²⁺ channels.