Noise analysis and single-channel observations of 4 pS chloride channels in human airway epithelia.

Apical membranes of human airway epithelial cells have significant chloride permeability, which is reduced in cystic fibrosis (CF), causing abnormal electrochemistry and impaired mucociliary clearance. At least four types of chloride channels have been identified in these cells, but their relative roles in total permeability and CF are unclear. Noise analysis was used to measure the conductance of chloride channels in human nasal epithelial cells. The data indicate that channels with a mean conductance of 4.5 pS carry most of the chloride current, and that the mean number of such channels per cell is approximately 4,000. Chloride channels in this conductance range were also seen in single-channel recordings.     

Single channel H+ currents through reconstituted chloroplast ATP synthase CF0-CF1.

The purified chloroplast ATP synthase (CF(0)-CF(1)) was reconstituted into azolectin liposomes from which bilayer membranes on the tip of a glass pipette ('dip stick technique')and planar bilayer membranes were form ed. The CF(0)-CF(1) facilitated ion conductance through the bilayer membranes. Our results clearly indicated that the observed single channel currents were carried by H+ through the isolated and reconstituted chloroplast ATPase. We demonstrated that in proteoliposomes it is the whole enzyme complex CF(0)-CF(1) and not the membrane sector CF(0) alone that constitutes a voltagegated, proton-selective channel with a high conductance of 1-5 pS at pH 5.5-8.0. After removal of CF(1) from the liposomes by NaBr treatment the membrane sector CF(0) displayed various kinds of channels also permeable to monovalent cations. The open probability P(0) of the CF(0)-CF(1) channel increased considerable with increasing membrane voltage [from P(0) less than or equal to 1% (V(m) less than or equal to 120 mV) to P(0) less than or equal to 30% (120 mV less than or equal to Vm 200 mV)]. In the presence of ADP (3 microM) and P(i) (5 microM), which specifically bind to CF(1), the open probability decreased and venturicidin (1 microM), a specific inhibitor of H+ flow through CF(0) in thylakoid membranes, blocked the channel almost completely. Our results, which reveal a high channel unit conductance, and at membrane voltages less than 100 mV low open probability with concomitant mean open times in the micros timescale (less than 100 micros) for the energy coupling in the enzyme complex. At physiological membrane voltages for photophosphorylation (about 30 mV) the enzyme complex would then display a time-averaged conductance of about 1 fS.     

The proton channel, CF0, in thylakoid membranes. Only a low proportion of CF1-lacking CF0 is active with a high unit conductance (169 fS)

We investigated the conductance of pea thylakoid membranes and their capacity for photophosphorylation as function of the extraction of chloroplast coupling factor CF1. The degree of extraction was varied via the incubation time in EDTA-containing hypo-osmolar medium and was measured by rocket electroimmunodiffusion. The conductance of thylakoid membranes was measured by flash kinetic spectrophotometry. The time course of extraction followed the time course of thylakoid swelling. Contrary to expectation increasing loss of CF1 did not primarily increase the velocity of proton efflux from each vesicle. Instead proton-tight vesicles were converted to leaky ones, which lost phosphorylating activity. Two subpopulations occurred, although both types of vesicles, leaky and proton-tight ones, were CF1-depleted to a similar degree. This implied that only a small fraction of CF1-lacking CF0 was functional as a proton channel. Tight vesicles had no functional channels while leaky ones had at least one. We determined the proportion of tight vesicles in three independent ways: via the residual phosphorylation activity, via measurements of proton efflux and via measurements of the electric relaxation across the membrane. The results obtained were identical. A statistical evaluation of the data led us to the following conclusions. EDTA treatment produced vesicles containing approximately 10(5) chlorophyll molecules, equivalent to a total of approximately 100 CF0CF1 per vesicle. Even at the highest degree of extraction (75% of total CF1 extracted) only 2.5 out of 75 exposed CF0 per vesicle were proton-conducting. The unit conductance of one open CF0 channel was 169 +/- 18 fS at pH 7.5 and room temperature. At an electrical driving force of 100 mV this was equivalent to the passage of approximately 10(5) protons/s. The most important consequence of this relatively high unit conductance was that a single open CF0 channel was capable of dissipating the protonmotive force of one vesicle, thereby deactivating the whole remaining catalytic capacity of this vesicle.     

Membrane chloride transport measured using a chloride-sensitive fluorescent probe

Transport of chloride across cell membranes through exchange, cotransport, or conductive pathways is a subject of great biological importance. Current methods of measurement are restricted in their sensitivity, time resolution, and applicability. A new transport measurement technique has been developed on the basis of the fluorescence quenching by chloride of the dye 6-methoxy-N-(3-sulfopropyl)quinolinium (SPQ). SPQ fluorescence quenching by chloride is rapid (less than 1 ms) and sensitive, with a greater than 50% decrease in fluorescence at 10 mM chloride. SPQ fluorescence is not altered by other physiological anions or by pH and can be used to measure both neutral and conductive transport processes. The high water solubility and membrane permeability properties of SPQ make it ideal for use in both membrane vesicles and cells. Chloride transport determined with SPQ was validated by measurement of erythrocyte chloride/anion exchange and membrane vesicle chloride conductance.     

17b-Estradiol and Tamoxifen Regulate a Maxi-Chloride Channel from Human Placenta

Steroid hormones have been implicated in the modulation of several transport processes, including conductive chloride transport in epithelial cells. Micromolar concentrations of these hormones have been determined in blood of pregnant women. The purpose of this work was to explore the effects of 17beta-Estradiol, a steroid hormone, on the biophysical properties of the Maxi chloride channel present in apical membranes from human placental syncytiotrophoblast. Apical membrane chloride channels from human term placentas were reconstituted in giant liposomes suitable for electrophysiologic studies by the patch-clamp method. Low micromolar concentrations of 17beta-Estradiol inhibit the Maxi chloride channels in excised patches in a potential-dependent manner. The addition of 1 mM 17beta-Estradiol to the bath solution decreased the total current in the patch from 100% control to 71% at -40 mV holding potential and the current was not affected by 17beta-Estradiol at + 40 mV. However, the presence of the hormone did not affect the single-channel conductance, therefore its effect must be due to modulation of its open probability (Po). Interestingly, 17alpha-Estradiol did not change the total current in the patch. Tamoxifen, an antiestrogen, also showed inhibition, but in a voltage-independent manner. Our results suggest that the Maxi Cl- channel from human term placenta may be regulated by direct interaction of both compounds with the channel. From a functional point of view, the control of these channels by steroid hormones may be of great importance in placental physiology and their regulation may help to unravel their possible role in transplacental transport.     

Correlation of results of immunocytochemical, electrophysiologic, and molecular studies in patients with cystic fibrosis

In 13 cystic fibrosis (CF) patients of 5 to 23 years of age with a known mutation spectrum of gene CFTR, sweat chloride values and nasal-potential differences (NPD) were measured and localization characteristics of the protein product of gene CFTR in the cells of nasal epithelium were studied. Sweat Chloride values were normal or boundary (24 to 62 mM/l) in six CF patients. In seven CF patients, these values were significantly above the estimates for the control group. On average, the NPD values were -44.7 +/- 2.2 mV (from -32.5 to -68.9 mV) and -17.2 +/- 1.8 mV (from -6.8 to -30.2 mV) in CF patients and the control group, respectively. Histochemical studies clearly revealed the localization of the CFTR protein on the apical membrane of the nasal epithelium. Depending on the type of mutation, the protein product of gene CFTR was either absent or regularly distributed in the cytoplasm in CF patients; it was not detected in the apical membrane. Thus, NPD measurements and the analysis of the localization of the protein product of gene CFTR in scrapes of nasal epithelium were shown to be additional, highly informative methods of CF diagnostics.     

Membrane potential of primitive red cells from chick embryo is a proton potential

The membrane potential of primitive red cells from 4- and 6-day old chick embryos has been determined using the fluorescent dye Dis-C3-(5). At day 4 the membrane potential Em was -44 mV for pH 7.4 and 20 degrees C and -36 mV at day 6. Both values are far removed from the equilibrium potential for chloride, which is about -14 mV at day 6. Changes in the external potassium, sodium or chloride concentration were without effect on the membrane potential, except at very high potassium concentrations, where a small but significant depolarization was observed at day 6. The measurements gave the same results in the absence or presence of the anion exchange blocking agent DIDS. Three pieces of evidence indicate that the membrane potential of primitive red cells is primarily caused by an electrogenic H+ conductance: 1) The measured membrane potential of -36 mV at day 6 is close to the previously determined proton equilibrium potential (Baumann and Haller, 1983) EH + of -36 mV. 2) Addition of the electrosilent Cl-/OH- exchanger tributyltin causes a significant depolarization of about 20 mV at day 4 and about 14 mV at day 6. 3) Measurement of hydrogen ion fluxes demonstrate a potential dependent proton conductance, which increases with depolarization. These results indicate that large qualitative differences exist with regard to the mechanisms involved in the generation of membrane potential and hydrogen distribution between red cell and plasma of embryonic and adult chicken.     

Intracellular chloride activity and membrane potential in stripped frog skin (Rana temporaria)

The regulation of cell chloride activity in frog skin was investigated using double barrelled Cl--microelectrodes to measure cell membrane potentials and chloride activity in the isolated frog epidermis. Experiments were done under short-circuit conditions, impaling cells from the serosal side. The basic electrophysiological parameters of the isolated skin were similar to those reported in the literature for whole preparations. Intracellular chloride activity was on average 21.9 mM and membrane potential was about 57 mV, implying that chloride was distributed away from its electrochemical equilibrium (i.e., concentrated inside the cells). Chloride activity decreased after removal of either Cl- or Na+ from the serosal bathing solution, with no change in membrane potential. The chloride permeability of the serosal membrane was calculated to be 2.6 X 10(-6) cm X s-1 which represents about 1/4 of the total conductance of the serosal membrane. We suggest that an electrically silent sodium-dependent uphill transport of chloride is present at the basolateral membrane of the frog skin, which accounts for the non-passive distribution of chloride.     

叶绿体H^＋—ATP酶在平板脂双层上重组及其质子传导的研究

从菠菜(Spinacia oleracea Mill.)叶中分离获得H~ -ATP酶(CF_0-CF_1)复合体。将CF_0-CF_1重组于平板脂双层上,在电压钳位下,研究CF_0～CF_1的质子传导性能,观察到:(1)当CF_0-CF_1重组于平板脂双层上后,平板膜电阻由10～20GΩ立即下降到1GΩ左右。(2)溶液中蛋白质(CF_0-CF_1)浓度在2mg/L下可记录到单通道电流的涨落,单位电导约在5～10pS。(3)通道电流随膜两侧ΔpH变化而改变,在ΔpH为2～4时,膜电流随ΔpH增加而增大,在ΔpH为4.5时膜电流呈现回落。(4)质子传导抑制剂Dicyclohexyl-carbodiimide(DCCD)显示出迅速地且不可逆地阻断通道电流。(5)无金属离子的溶液中,跨膜(BLM)的ΔpH为3时,在0～ 150mV钳位下,镁离子比钙离子所引起的CF_0-CF_1的通道电流要大得多。以上结果不仅表明CF_0-CF_1已成功地组装于人工膜上,而且也显示出镁离子直接参与了质子传导过程。     

Annexin 6 modulates the maxi-chloride channel of the apical membrane of syncytiotrophoblast isolated from human placenta

The syncytiotrophoblast separates the maternal and fetal blood and constitutes the primary barrier for maternal-fetal transport. The Maxi-chloride channel from the apical membrane of the syncytiotrophoblast plays a role in the chloride conductance. Annexins can play an important role in the regulation of membrane events. In this study we evaluate the role of annexin 6 in the Maxichloride channel properties. The results showed that annexin 6 is bound in the apical placenta membranes in a calcium-dependent phospholipid-binding manner but also in a calcium-independent fashion. The neutralization of annexin 6 decreased the total current by 39 +/- 1.9% in the range of +/-80 mV, and the currents decrease with the time. The single-channel slope conductance was decreased from 253 +/- 7.4 pS (control) to 105 +/- 13 pS, and the amplitude decreased by 50%. The open probability was also affected when higher voltage steps were used, changes in either the positive or negative direction induced the channel to close, and the open probability (P(o)) did not decrease. In channels with neutralized annexin 6, it was maintained at 1 at +/-40 mV and at +/-80 mV. These results suggest that endogenous annexin 6 could regulate the Maxi-chloride channel. The results obtained with normal placentae, in which annexin 6 was neutralized, are similar to those described for the Maxi-chloride channel isolated from pre-eclamptic placenta. Together these data suggest that annexin 6 could play an important role in ion transport of the placenta.     

Epithelial chloride channel. Development of inhibitory ligands

Chloride channels are present in the majority of epithelial cells, where they mediate absorption or secretion of NaCl. Although the absorptive and secretory channels are well characterized in terms of their electrophysiological behavior, there is a lack of pharmacological ligands that can aid us in further functional and eventually molecular characterization. To obtain such ligands, we prepared membrane vesicles from bovine kidney cortex and apical membrane vesicles from trachea and found that they contain a chloride transport process that is electrically conductive. This conductance was reduced by preincubating the vesicles in media containing ATP or ATP-gamma-S, but not beta-methylene ATP, which suggests that the membranes contain a kinase that can close the channels. We then screened compounds derived from three classes: indanyloxyacetic acid (IAA), anthranilic acid (AA), and ethacrynic acid. We identified potent inhibitors from the IAA and the AA series. We tritiated IAA-94 and measured binding of this ligand to the kidney cortex membrane vesicles and found a high-affinity binding site whose dissociation constant (0.6 microM) was similar to the inhibition constant (1 microM). There was a good correlation between the inhibitory potency of several IAA derivatives and their efficacy in displacing [3H]IAA-94 from its binding site. Further, other chloride channel inhibitors, including AA derivatives, ethacrynic acid, bumetanide, and DIDS, also displaced the ligand from its binding site. A similar conductance was found in apical membrane vesicles from bovine trachea that was also inhibited by IAA-94 and AA-130B, but the inhibitory effects of these compounds were weaker than their effects on the renal cortex channel. The two drugs were also less potent in displacing [3H]IAA-94 from the tracheal binding site.     

Proton-Conductivity of CF0-CF1 Reconstructed into Planar Lipid Bilayer

The proton conductable ATP synthase (CF0-CF1) is the key enzyme of energy conversion in the membrane of bacteria, mitochondria and chloroplast. In spite of a large body of studies, the structure and molecular mechanism of ATP synthases are still elusive. In order to learn the mechanism of ATP synthases, the authors used voltage-olamp technique to study the effect of different conditions on the proton conductance of F0-F1 into planar lipid bilayer membrane. The results obtained were as follows: (1) When CF0-CF1 was reconstructed into planar lipid bilayer membrane, the resistance decreased by 10 times. (2) Channel-like current was recorded at the low concentration of CF0-CFl(protein 2 mg/L) in the solution. (3) In metal ion-free solution, the channel currents changed with the trans-membrane proton gradient (ApH). Under holding potential from 0 to + 150 mV, the stimulation of △pH on channel current increased with a rise in the ApH from 2 to 4, the stimulation of 4.5 △pH on channel current was weaker than that of △pH 4.0. (4) The proton conduetance inhibitor, dicyclohexylcarbodiimide (DCCD), showed a rapid and irreversible inhibition effect on the channel current. (5) In metal ion-free solution (10 mmol/L Tris-HC1), when the ApH across the black lipid membrane (BLM) maintained at 3.0, the addition of Mg2 + caused a alger channel current of CF0-CF1 than the addition of Ca2+ , with holding potential from 0 to + 150 mV. The results indicated that reconstruction of CF0-CF1 was successful and Mg2 + was directly involved in the proton conductance pathways.     

Adenosine triphosphate synthesis by electrochemical proton gradient in vesicles reconstituted from purified adenosine triphosphatase and phospholipids of thermophilic bacterium.

Vesicles were reconstituted from a purified dicyclohexyl-carbodiimide-sensitive ATPase complex (TF0-F1) and phospholipids of a thermophilic bacterium PS3. These vesicles synthesized ATP from ADP and Pi with energy from an electrochemical proton gradient (delta-micronH+) formed by a pH gradient and an electrical potential across their membranes. Maximal ATP synthesis was achieved by incubating the vesicles in malonate at pH 5.5 with valinomycin, and then rapidly transferring them to a solution of pH 8.4 and 150 mM K+. Under these conditons ATP synthesis continued at a decreasing rate for 30 s at 40 degrees. Appreciable formation of ATP (40 to 150 nmol/mg of TF0-F1) occurred at an initial delta-micronH+ above 205 mV and moderate formation at an initial value above 180 mV. ATP hydrolysis by the vesicles produced a delta-micronH+, and the additions of 32Pi and hexokinase to them resulted in 32Pi esterification. Analysis of the time courses of 32Pi esterification and decays of the pH difference and membrane potential, followed using 9-aminoacridine and 8-anilinonaphthalene-1-sulfonate, respectively, as probes, showed a relationship between delta-micronH+ and the rate of ATP synthesis. These results demonstrate that purified TF0-F1 is itself a reversible H+-translocating ATPase of oxidative phosphorylation.     

Cystic fibrosis transmembrane conductance regulator in human and mouse red blood cell membranes and its interaction with ecto-apyrase

Elevated blood ATP and increased red blood cell (RBC) ATP transport is associated with cystic fibrosis (CF). In this report, we demonstrate the presence of the wild-type and the DeltaF508 mutant form of the CF transmembrane conductance regulator protein in RBC membranes and its putative interaction with ecto-apyrase, an ATP hydrolyzing enzyme also present in the RBC membrane. RBC membranes of control and DeltaF508 individuals and of wild-type and CF transmembrane conductance regulator-knockout mice were examined by immunoblot using several antibodies directed against different epitopes of this protein. These experiments indicated that human RBC membranes contain comparable amounts of the wild-type CF transmembrane conductance regulator protein and the DeltaF508 mutant form of the protein, respectively. CF transmembrane conductance regulator protein was also detected in wild-type mouse RBC membranes but not in the gene knockout mouse RBC membranes. Antibodies directed against ecto-apyrase co-immunoprecipitated CF transmembrane conductance regulator protein of human RBC membranes indicating a physical interaction between these two membrane proteins consistent with ATP transport and extracellular hydrolysis. We conclude that RBCs are a significant repository of CF transmembrane conductance regulator protein and should provide a novel system for evaluating its expression and function.     

Turnover of the cystic fibrosis transmembrane conductance regulator (CFTR): Slow degradation of wild-type and ΔF508 CFTR in surface membrane preparations of immortalized airway epithelial cells

The protein product of the cystic fibrosis (CF) gene, termed the cystic fibrosis transmembrane conductance regulator (CFTR), is known to function as an apical chloride channel at the surface of airway epithelial cells. It has been proposed that CFTR has additional intracellular functions and that there is altered processing of mutant forms. In examining these functions we found a stable form of CFTR with slow turnover in surface membrane preparations from CF and non-CF immortalized airway epithelial cell lines. The methods used to study the turnover of CFTR were pulse/chase experiments utilizing saturation labeling of [³⁵S]Met with chase periods of 5–24 h in the presence of 8 mM Met and cell fractionation techniques. Preparations of morphologically identifiable surface membranes were compared to total cell membrane preparations containing intracellular membranes. Surface membrane CFTR had lower turnover defined by pulse/chase ratios than that of the total cell membrane preparations. Moreover, mutant CFTR was stable in the surface membrane fraction with little degradation even after a 24 h chase, whereas wild-type CFTR had a higher pulse/chase ratio at 24 h. In the presence of 50 μM castanospermine, which is an inhibitor of processing α-glucosidases, a more rapid turnover of mutant CFTR was found in the total cell membrane preparation, whereas wild-type CFTR had a lower response. The results are compatible with a pool of CFTR in or near the surface membranes which has an altered turnover in CF and a glycosylation-dependent alteration in the processing of mutant CFTR. © 1996 Wiley-Liss, Inc.     

Ca(2+)-dependent and Ca2+ release-dependent excitation in leech photoreceptors: evidence from a novel "inside-out" cell model

We have developed a novel, electrophysiologically intact and light-sensitive "inside-out" cell model (IOCM) of microvillar photoreceptors of the leech Hirudo medicinalis. Light responses recorded from the IOCM with sharp microelectrodes are depolarizations with amplitudes of up to 50-60 mV. In darkness, graded elevations of the free Ca(2+) concentration in the "intracellular medium" (ICM) reversibly increase the conductance of the microvillar membrane leading to Ca(2+)-induced graded voltage changes up to approximately 50 mV. The threshold for Ca(2+)-induced voltage changes is approximately 0.06 microM, EC(50) is approximately 1.2 microM, and saturation occurs at approximately 20 microM free Ca(2+). Small Ca(2+) elevations (<0.6 microM) produce discrete waves of depolarization resembling quantum bumps. Stimulating IOCMs with short (20-ms) and long (5-s) light stimuli produces transient light responses (repolarization within ca. 200 ms) in an ICM containing only 10nM free Ca(2+). At 0.44 microM free Ca(2+) in the ICM, the microvillar membrane depolarizes by 10-20 mV and responses to 5-s light steps have an initial transient component and a plateau component, similar to responses in intact cells. Generation of the plateau component in IOCMs is suppressed by heparin and cyclopiazonic acid (CPA), agents that block inositol 1,4,5-trisphosphate (Ins(1,4,5)P(3))-induced Ca(2+) release from and Ca(2+) uptake into the endoplasmic reticulum (ER). These results indicate that there is a Ca(2+)-dependent conductance in the microvillar membrane and that the light-induced Ins(1,4,5)P(3)- and Ca(2+) release-mediated intracellular Ca(2+) elevation in leech photoreceptors contributes to the generation of the receptor potential, particularly the plateau component of responses to long steps of light.     

The electrical potential profile of gallbladder epithelium.

In this study the relative ionic permeabilities of the cell membranes of Necturus gallbladder epithelium have been determined by means of simultaneous measurement of transmural and transmucosal membrane potential differences (PD) and by ionic substitution experiments with sodium, potassium and chloride ions. It is shown that the mucosal membrane is permeable to sodium and to potassium ions. The baso-lateral membrane PD is only sensitive to potassium ions. In both membranes chloride conductance is negligible or absent. The ratio of the resistances of the mucosal and baso-lateral membranes, RM/RS, increases upon reducing the sodium concentration in the mucosal solution. The same ratio decreases when sodium is replaced by potassium which implies a greater potassium than sodium conductance in the mucosal membrane. The relative permeability of the shunt for potassium, sodium and chloride ions is: PK/PNa/PCl=1.81:1.00:0.32. From the results obtained in this study a value for the PK/PNa ratio of the mucosal membrane could be evaluated. This ratio is 2.7. From the same data the magnitude of the electromotive forces generated across the cell membranes could be calculated. The EMF's are -15mV across the mucosal membrane and -81mV across the baso-lateral one. Due to the presence of the low resistance shunt the transmucosal membrane PD is -53.2mV (cell inside negative) and the transmural PD is +2.6mV (serosal side positive). The change in potential profile brought about by the low resistance shunt favors passive entry of Na ions into the cell across the mucosal membrane. Calculations show that this passive Na influx is maximally 64% of the net Na flux estimated from fluid transport measurements. The C-1 conductive of the baso-lateral membrane is too small to allow electrogenic coupling of C1 with Na transport across this membrane. Experiments with rabbit gallbladder epithelium indicate that the membrane properties in this tissue are qualitatively similar to those of Necturus gallbladder epithelium.     

Exchange diffusion,electrodiffusion and rectification in the chloride transport pathway of frog skin

Measurements of chloride flux ratios across frog skin at different clamping voltages showed that chloride transport at clamping voltages from 0 mV to and beyond the spontaneous potential is probably electrodiffusion. At reversed potentials a significant fraction of chloride transport could be described formally as exchange diffusion. Chloride conductance was found to be highly voltage dependent, being largest at hyperpolarizing clamping voltages. The transition from the less conducting state to the more conducting one was studied by recording the time course of the current after a step change in clamping voltage from 0 mV to hyperpolarizing voltages. The shape of the curve is sigmoidal, and the relative rate of change of current increases with increasing hyperpolarization. It is proposed that the change in conductance is governed by the same mechanism as in the toad skin, namely a change in chloride permeability due to voltage gating of chloride channels. The time course of transepithelial conductance after addition of amiloride to the outside solution indicates that a fraction of the decrease in conductance is due to closure of chloride channels caused by the change in intracellular potential due to the inhibition of the sodium channels.     

The shark rectal gland: a model for the active transport of chloride.

The rectal gland of the spiny dogfish, Squalus acanthias, provides an easily studied model of active chloride transport powered indirectly by Na-K-ATPase. Co-transport of sodium with chloride can be demonstrated in membrane vesicles isolated from basolateral membranes of the gland. Chloride secretion is under the hormonal control of vasoactive intestinal peptide, and possibly other agents, via adenyl cyclase and cyclic AMP. A similar mechanism is probably responsible for the active transport of chloride across other biological membranes.     

cAMP-Dependent protein kinase inhibits the chloride conductance in apical membrane vesicles of hunman placenta

Summary The role of adenosine 3,5-monophosphate (cAMP) dependent protein kinase (PK-A) on the Cl^– conductance has been studied in the apical membrane vesicles purified from the chorionic villi of human placenta. In order to phosphorylate the cytosolic side of the membranes, vesicles have been hypotonically lysed, loaded with 100nm catalytic subunit of PK-A purified from human placenta and 1mm of the phosphatase resistant adenosine 5-thiotriphosphate (ATP-gamma-S) and resealed. Cl^– conductance has been measured by the quenching of the fluorescent probe 6-methoxy-N-(3-sulfopropyl) quinolinium (SPQ) at 23°C with membrane potential clamped at 0 mV. The actual volume of the resealed vesicles was measured in each experiment by trapping an impermeable radioactive molecule ([¹⁴C]-sucrose) and included in each Cl^– flux calculation. In 19 independent experiments, the mean Cl^– conductance in placental membranes in the absence of phosphorylation was 3.67±3.18 whereas with the addition of PK-A and ATP-gamma-S it was 1.97±1.75 nmol·sec^–1·(mg protein)^–1 (mean±sd). PK-A dependent phosphorylation reduced the Cl^– conductance in 14/19 experiments. The same protocol applied to the apical membranes of bovine trachea, where PK-A is known to activate the Cl^– channels, confirmed that the PK-A dependent phosphorylation increased the Cl^– conductance in 11/13 experiments, from 1.01±0.61 to 1.85±0.99 nmol·sec^–1·(mg protein)^–1(mean±sd). These studies indicate that the PK-A dependent phosphorylation inhibits one or more Cl^– channel(s) of the apical membranes of human placenta.