Anion movements across lamprey (Lampetra fluviatilis) red cell membrane

Chloride and bicarbonate movements across lamprey red cell membrane were investigated. The halftime for equilibration of radioactive chloride across the red cell membrane was 2.46 h, and apparent permeability for chloride-36 was approximately 10(-9) cm X s-1, a value similar to that observed for lipid bilayers. Chloride movements were not affected by the anion exchange inhibitor, 4,4'-diisothiocyano-stilbene-2,2'-disulfonic acid (DIDS). Furthermore, intracellular buffering is effectively isolated from the extracellular compartment, as shown by the fact that practically no pH recovery occurred in the unbuffered extracellular medium after either acidification or alkalinization. These observations show that lamprey red cell membrane is quite impermeable to bicarbonate and other acid/base equivalents.     

Shift of Chloride Cell Distribution during Early Life Stages in Seawater-Adapted Killifish, Fundulus heteroclitus

The shift of chloride cell distribution was investigated during early life stages of seawater-adapted killifish (Fundulus heteroclitus). Chloride cells were detected by immunocytochemistry with an an-tiserum specific for Na(+), K(+)-ATPase in whole-mount preparations and paraffin sections. Chloride cells first appeared in the yolk-sac membrane in the early embryonic stage, followed by their appearance in the body skin in the late embryonic stage. Immunoreactive chloride cells in the yolk-sac membrane and body skin often formed multicellular complexes, as evidenced by the presence of more than one nucleus. The principal site for chloride cell distribution shifted from the yolk-sac membrane and body skin during embryonic stages to the gill and opercular membrane in larval and later developmental stages. Our observations suggest that killifish embryos and newly-hatched larvae could maintain their ion balance through chloride cells present in the yolk-sac membrane and body skin until branchial and opercular chloride cells become functional.     

Chloride conductance in membrane vesicles from human placenta using a fluorescent probe. Implications for cystic fibrosis

Previous evidence suggests that the molecular defect in cystic fibrosis (CF) could reside in an altered chloride conductance of epithelial tissues. Since the brush border of the syncytiotrophoblast of the chorionic villi of human placenta is an abundant source of epithelial membranes and it is unaltered by secondary pathology or treatment we chose to characterize its chloride conductance and to compare it in normal and CF membranes. Chloride transport was studied in microvillar vesicles (MVV) by the quenching of the fluorescent probe 6-methoxy-N-(3-sulfopropyl)quinolinium (SPQ). Chloride conductance at 23 degrees C: (a) increased by 39% under a membrane potential change of 70 mV; (b) was inhibited by diphenylamine 2-carboxylate (Ki = 150 microM); (c) displayed an activation energy of 3.5 kcal.mol-1. The comparison of the chloride conductance for an inwardly directed gradient of 150 mM Cl- at 23 degrees C (membrane potential set at 0 mV) between CF and control membranes was not significantly different. These findings demonstrate the presence of a chloride conductive pathway in microvillar vesicles from human placenta and preliminary results exclude major differences in the conductance of CF derived material in the absence of neurohormonal stimuli.     

Presynaptic Glycine Receptors Influence Plasma Membrane Potential and Glutamate Release

Glycine is a classical inhibitory neurotransmitter however presynaptic glycine receptors have rather depolarizing action. Reasons for latter phenomenon are unknown. In the present paper we have investigated how glycine influences cytosolic chloride level monitored by fluorescent dye SPQ, membrane potential monitored by fluorescent dye DiSC3(5) and [¹⁴C]-glutamate release in synaptosomes. We estimated that cytosolic chloride concentration in synaptosomes was about 52 ± 1 mM. Glycine (1 mM) induced chloride efflux and caused slow plasma membrane depolarization. Chloride efflux was almost completely blocked by 100 μM strychnine whilst glycine-induced depolarization was only partially. We also showed that 1 mM glycine induced [¹⁴C]-glutamate release via a strychnine-insensitive pathway. Hence we have concluded that glycine was able to induce two independent effects in synaptosomes: (1) Chloride efflux with following depolarization. This efflux was sensitive to strychnine and thereby is probably conducted through glycine-gated ion channels. (2) Glutamate release seems to be mediated by glycine transporters.     

Chloride reabsorption by renal proximal tubules of necturus

Summary Movement of Cl from the lumen ofNecturus proximal tubule into the cells is mediated and dependent on the presence of luminal Na. Intracellular Cl activity was monitored with ion selective microelectrodes. In Cl Ringer's perfused kidneys, cell Cl activity was 24.5±1.1mm, 2 to 3 times higher than that predicted for passive distribution. When luminal NaCl was partially replaced by mannitol (capillaries perfused with Cl Ringer's) cell Cl decreased showing a sigmoidal dependence on luminal NaCl. Peritubular membrane potential was unaltered. Sulfate Ringer's perfusion of the kidneys washed out all cell Cl but did not alter peritubular membrane potential. Chloride did not enter the cell when the tubule lumen was perfused with 100mm KCl, LiCl, or tetramethylammonium Cl. Luminal perfusion of NaCl caused cell Cl to rise rapidly to the same value as the controls in the Cl Ringer's experiments. Perfusion of the tubule lumen with mixtures of NaCl and Na₂SO₄, while the capillaries contained sulfate Ringer's yielded a sigmoidal dependence of cell Cl on luminal NaCl activity. Chloride movement from the lumen into the proximal tubule cells required approximately equal concentrations of Na and Cl. Current clamp experiments indicated that intracellular chloride activity was insensitive to alterations in liminal membrane potential, suggesting that chloride entry was electrically neutral. The transcellular chloride flux was calculated to constitute about one half of the normal chloride reabsorption rate. We conclude that the cell Cl activity is primarily determined by the NaCl concentration in the tubule lumen and that Cl entry across the luminal membrane is mediated.     

血管内皮细胞容量激活的氯通道

氯通道是血管内皮细胞上主要的离子通道,容量激活的氯通道是其中一种主要类型并广为研究。已经主宰容量激活的氯通道在维持静息膜电位,调节细胞内钙、ｐＨ值,影响细胞增殖和分化中起着重要的作用。本文综述了血管内皮细胞容量激活氯通道的基本电生理及分子生物学特性,并初步探讨该通道的调节机制。     

Blockage of chloride channels by HEPES buffer

Chloride channels of neurons of Drosophila are blocked when the cytoplasmic side of the membrane is exposed to the commonly used buffering agents 4-(2-hydroxyethyl)-1-piperazine ethanesulphonic acid (HEPES) and 4-morpholinepropanesulphonic acid (MOPS). In the presence of these compounds, chloride channels appear to function as a complex of multiple protochannels.     

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.     

血管内皮细胞的Cl-通道--电特性和有关细胞功能

内皮细胞在心血管系统具有重要功能,除通过分泌内皮舒张因子－－一氧化氮（ＮＯ）及收缩性物质内皮素等控制血管平滑肌张力外,并能调节血管通透性。近年来发现内皮细胞上的Ｃ１＾－通道能调节细胞体积和细胞膜电位的稳定性。通过离子通道调控膜电位一机理,能较好理解血管内皮的功能,并可望由此开拓新型血管药物。本文综述了内皮细胞的Ｃ１＾－通道的电生理特性、类别,并探讨该通道调控细胞体积,ＮＯ的分泌及调控细胞膜电位的可     

Evidence for two conductance/exchange pathways for chloride in rat parotid secretory granules

Electron probe x-ray microanalysis was used to determine that bromide is localized to rat parotid secretory granules at early stages of an in situ Cl/Br washout experiment. Chloride efflux and bromide influx across the secretory granule membrane occurred with a time order of minutes. Since the Cl washout data indicated minimal Cl binding within the granule, and therefore minimal Br binding, the Br localization results suggest the presence of two or more anion conductance/exchange pathways in the granule membrane for the Cl (Br) ion.     

Transport-related modulation of the membrane properties of toad urinary bladder epithelium.

Impedance analysis and transepithelial electrical measurements were used to assess the effects of the apical membrane Na+ channel blocker amiloride and anion replacement on the apical and basolateral membrane conductances and areas of the toad urinary bladder (Bufo marinus). Mucosal amiloride addition decreased both apical and basolateral membrane conductances (Ga and Gbl, respectively) with no change in membrane capacitances (Ca and Cbl). Consequently, the specific conductances of these membranes decreased without significant changes in membrane area. Following amiloride removal, an increase was obtained in the steady-state rate of sodium transport compared to values before amiloride addition. This increase was independent of the initial transport rate, suggesting activation of a quiescent pool of apical sodium channels. Chloride replacement by acetate or gluconate had no significant effects on apical or basolateral membrane capacitances. The effects of these replacements on membrane conductances depended on the anion species. Gluconate (which induces cell shrinkage) decreased both membrane conductances. In contrast, acetate (which induces cell swelling) increased Ga and had no effect on Gbl. The increase in the apical membrane conductance was due to an increase in the amiloride-sensitive Na+ conductance of this membrane. In summary, mucosal amiloride addition or chloride replacements led to changes in membrane conductances without significant effects on net membrane areas.     

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.     

Overexpressed chloride intracellular channel protein CLIC4 (p64H1) is an essential component of novel plasma membrane anion channels

Chloride intracellular channel protein CLIC4 is a putative organellar anion channel or channel regulator with an unusual dual cytoplasmic and integral membrane localisation. To investigate its contribution to cellular anion channel activity, the protein was overexpressed in stably transfected HEK-293 cells. Patch-clamp recording revealed CLIC4-associated indanyloxyacetic acid-sensitive (IC(50) approximately 100 microM) plasma membrane currents showing mild outward rectification, and novel low conductance (approximately 1pS) CLIC4-associated anion channels were resolved at the single-channel level. The CLIC4-associated channels were inhibited by anti-CLIC4 antibodies, including a monoclonal antibody directed against a FLAG epitope fused to the C-terminus of CLIC4, but only when these were applied to the cytoplasmic (not the external) face of the membrane. CLIC4 is thus an essential molecular component of novel cellular anion channels and the C-terminus of the integral membrane form of CLIC4 is cytoplasmic.     

Effects of monocarboxylates and external pH on some parameters of insect muscle fibres

The resting membrane potential and the conductance of flight muscle fibres of the butterfly Pieris brassicae were measured by means of two intracellular electrodes. The intracellular potassium, chloride, and hydrogen ion concentrations were estimated by measuring the concentrations in diluted muscle homogenates. Chloride in the bath was replaced in part by monocarboxylates and the pH was subsequently lowered. Replacement of chloride by propionate caused decrease in the internal chloride concentration, a marked hyperpolarization and a small increase in conductance. Lowering the pH in the propionate saline caused an additional decrease in the internal chloride concentration, an increase in the internal hydrogen ion concentration, a marked depolarization and a concurrent decrease in conductance. This was followed by an irreversible increase in conductance. With glycolate the effects on the membrane parameters were small and with pyruvate no effect was observed.     

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.     

Loss of the ClC-7 chloride channel leads to osteopetrosis in mice and man

Chloride channels play important roles in the plasma membrane and in intracellular organelles. Mice deficient for the ubiquitously expressed ClC-7 Cl(-) channel show severe osteopetrosis and retinal degeneration. Although osteoclasts are present in normal numbers, they fail to resorb bone because they cannot acidify the extracellular resorption lacuna. ClC-7 resides in late endosomal and lysosomal compartments. In osteoclasts, it is highly expressed in the ruffled membrane, formed by the fusion of H(+)-ATPase-containing vesicles, that secretes protons into the lacuna. We also identified CLCN7 mutations in a patient with human infantile malignant osteopetrosis. We conclude that ClC-7 provides the chloride conductance required for an efficient proton pumping by the H(+)-ATPase of the osteoclast ruffled membrane.     

Characterization of a distinct membrane bound dipeptidyl carboxypeptidase inactivating enkephalin in brain

A dipeptidyl carboxypeptidase distinct from the angiotensin converting enzyme (EC 3.4.15.1) was isolated from membrane preparations of rabbit brain. The enzyme cleaved enkephalin at the Gly-Phe bond, releasing either Phe-Leu from Leu-enkephalin or Phe-Met from Met-enkephalin, and also acted on bradykinin, releasing the terminal dipeptide Phe-Arg. In contrast to the converting enzyme, however, this dipeptidyl carboxypeptidase did not act on angiotensin-1, and it did not degrade hippuryl-His-Leu. Chloride ions did not affect its activity, but the enzyme was inhibited by metal chelating agents. The enzyme was not inhibited by captopril (SQ 14225) or by SQ 20881. Kinetic studies indicated a Km for this enzyme of 0.14 mM with Leu-enkephalin and 0.12 mM with bradykinin as substrates. Present data indicate that more than one enzyme is present in brain membrane fractions acting as dipeptidyl carboxypeptidases inactivating enkephalin; these data suggest multiple roles for such enzymes in the regulation of peptide metabolism.     

Solubilization and functional reconstitution of a chloride channel fromTorpedo californica electroplax

Summary Chloride channels were detergent-extracted fromTorpedo electroplax plasma membrane vesicles and reconstituted into liposomes by rapid detergent removal and a freeze-thawsonication procedure. Concentrative uptake of³⁶Cl^–, driven by a Cl^– gradient was used to determine conductance properties of reconstituted channels. Chloride flux assayed by this method is strongly selective for Cl^– over cations, is blocked by SCN^–, inactivated by treatment with DIDS, and exhibits an anion selectivity sequence Cl^–>Br^–>F^–>SO ₄ ^2– , as does the voltagegated Cl^– channel fromTorpedo observed in planar lipid bilayers. The channels are localized to the noninnervated face of the electrocyte, and a novel trapped-volume method is used to estimate a channel density on the order of 500 pmol/mg protein. An initial fractionation of the membrane extract by anion exchange chromatography yields fivefold enrichment of the channel activity.     

Outer-membrane protein PhoE from Escherichia coli forms anion-selective pores in lipid-bilayer membranes

Porin PhoE of the outer membrane of Escherichia coli was isolated and purified. Reconstitution experiments with lipid bilayer membranes showed that this protein formed pores which had a single channel conductance of 210 pS at 0.1 M KCl. The PhoE pores were obviously not voltage-controlled or regulated. In contrast to pores formed by the OmpF porin from E. coli the PhoE channel was found to be anion-selective at neutral pH. Chloride is about three to ten times more permeable through the pore than alkali ions. On the basis of the observed pH dependence of the permeability ratio of anions and cations, this anionic selectivity is explained by the assumption that the PhoE pore contains an excess of fixed positive charges.     

A chloride-activated Na(+)/HCO(3)(-)-coupled transport activity in corneal endothelial membranes

Investigations of corneal endothelium were made to resolve the apparent contradiction of the presence of sodium/bicarbonate cotransporter (NBC) in fresh and cultured cells and NBC's reported absence in isolated plasma membrane vesicles. Gradient-driven ion fluxes into the vesicles were measured. Short-term incubations (0-30 s) showed the presence of a bicarbonate-dependent inward sodium flux (BDSF), which was active when the insides of the vesicles were preloaded with chloride ions. The BDSF was absent if chloride was present only externally to the vesicles. Chloride at concentrations between 30 and 40 mM inside the vesicle had its maximum effect on BDSF. Other anions (acetate, thiocyanate, or gluconate) inside the vesicles did not mimic the chloride effect. Associated with the net inward sodium flux was a net inward bicarbonate flux. Hill plots of sodium influx with respect to external bicarbonate concentrations indicated that the stoichiometry of the net transfer was 1.7 +/- 0.2 (mean +/- standard error, n = 5) bicarbonate ions for each sodium ion transported. There was no net chloride flux found across the membrane vesicles. The finding of a novel chloride-activated NBC activity fully resolves the apparent contradiction between whole-cell and membrane vesicle preparations.