Calcium-dependent chloride current activated by hyposmotic stress in rat lacrimal acinar cells

We have identified a whole-cell Cl^– current activated by hyposmotic stress in rat lacrimal acinar cells using the patch-clamp technique. Superfusion of isolated single cells with hyposmotic solution (80% of control osmolarity) caused a gradual increase of the current, which was reversed on return to the control solution. The current-voltage relationship showed outward rectification, and the current showed time and voltage dependence: slowly activated by depolarizing voltages and rapidly inactivated by hyperpolarizing voltages. The increase in current was not observed when intracellular Ca²⁺ was chelated with EGTA. It was also inhibited by the absence of extracellular Ca²⁺, or the presence of gadolinium ions (20 m Gd³⁺). We conclude that in rat lacrimal acinar cells hyposmotic stress activates Ca²⁺-dependent Cl^– channels as a result of Ca²⁺ influx through a Gd³⁺-sensitive pathway. The Cl^– channels involved appear to be indistinguishable from those activated by muscarinic stimulation. The inhibitory effect of Gd³⁺ suggests that stretch-activated nonselective cation channels may be responsible for the Ca²⁺ influx.The authors are grateful to Prof. R.M. Case, Dr. A.C. Elliott and Dr. K.R. Lau for helpful discussion. This work was supported by the US Cystic Fibrosis Foundation, Wellcome Trust and Medical Research Council.     

Volume-activated chloride channels in neuroblastoma cells are blocked by the antiestrogen toremifene

Summary The presence of volume-activated chloride channels has been examined in neuroblastoma C1300 cells using the whole-cell configuration of the patch-clamp technique. Chloride channels could not be detected under isotonic conditions. However, hypotonic challenge induced slowly developed inward and outward anionic currents that exhibited outward rectification and inactivation at the most depolarizing potentials, features that were similar to the currents described in other cell preparations where volume-activated Cl^– channels have been associated with the expression of P-glycoprotein. This hypotonicity-activated Cl^– currents could be reversibly blocked by extracellular exposure to toremifene, a novel synthetic antioestrogen. The fact that toremifene and its analog tamoxifen, have been shown to block P-glycoprotein-associated chloride channels and to reverse P-glycoprotein associated multidrug resistance in a number of cell lines suggest that P-glycoprotein could be involved in the generation of hypotomic-induced chloride conductance in neuroblastoma cells.     

Chloride channel blockers activate an endogenous cationic current in oocytes of<Emphasis Type="Italic"> Bufo arenarum</Emphasis>

A two-electrode, voltage-clamp technique was used to measure the effect of the Cl^– channel blockers, 9-anthracene carboxylic acid and niflumic acid, upon the ionic currents of oocytes of the South American toad Bufo arenarum. The main results were: (1) both blockers produced a reversible increase of the outward currents on a dose-dependent manner; (2) the activated outward current was voltage dependent; (3) the 9-anthracene carboxylic acid-sensitive current was blocked with barium; and (4) the effect of 9-anthracene carboxylic acid was more pronounced in a zero-K⁺ solution than in standard (2 mmol l^–1) or high (20 mmol l^–1) K⁺ solutions, indicating that a K⁺ conductance is activated. The effect of the Cl^– channel blockers could be due to a direct interaction with endogenous cationic channels. Another possible explanation is that Cl^– that enter the cell during depolarizing steps in control solution inhibit this cationic conductance; thus, the blockade of Cl^– channels by 9-anthracene carboxylic acid and niflumic acid would remove this inhibition, allowing the cationic current to flow freely.Abbreviations 9-AC 9-anthracene carboxylic acid - E_r reversal potential - NA niflumic acid - NSC non-selective cation channel     

Acid-Sensitive Outwardly Rectifying Anion Channels in Human Erythrocytes

Acid-sensitive outwardly rectifying anion channels (ASOR) have been described in several mammalian cell types. The present whole-cell patch-clamp study elucidated whether those channels are expressed in erythrocytes. To this end whole-cell recordings were made in human erythrocytes from healthy donors treated with low pH and high osmotic pressure. When the pipette solution had a reduced Cl⁻ concentration, treatment of the cells with Cl⁻-containing normal and hyperosmotic (addition of sucrose and polyethelene glycol 1000 [PEG-1000] to the Ringer) media with low pH significantly increased the conductance of the cells at positive voltages. Channel activity was highest in the PEG-1000 media (95 and 300 mM PEG-1000, pH 4.5 and 4.3, respectively) where the current–voltage curves demonstrated strong outward rectification and reversed at −40 mV. Substitution of the Cl⁻-containing medium with Cl⁻-free medium resulted in a decrease of the conductance at hyperpolarizing voltages, a shift in reversal potential (to 0 mV) and loss of outward rectification. The chloride currents were inhibited by chloride channels blockers DIDS and NPPB (IC₅₀ for both was ~1 mM) but not with niflumic acid and amiloride. The observations reveal expression of ASOR in erythrocytes.     

Whole-cell and single-channel currents across the plasmalemma of corn shoot suspension cells

Summary Whole-cell sealed-on pipettes have been used to measure electrical properties of the plasmalemma surrounding protoplasts isolated from Black Mexican sweet corn shoot cells from suspension culture. In these protoplasts the membrane resting potential (V _m ) was found to be –59±23 mV (n=23) in 1mm K _o ^– . The meanV _m became more negative as [K^–] _o decreased, but was more positive than the K⁺ equilibrium potential. There was no evidence of electrogenic pump activity. We describe four features of the current-voltage characteristic of the plasmalemma of these protoplasts which show voltagegated channel activity. Depolarization of the whole-cell membrane from the resting potential activates time- and voltage-dependent outward current through K⁺-selective channels. A local minimum in the outward current-voltage curve nearV _m =150 mV suggests that these currents are mediated by two populations of K⁺-selective channels. The absence of this minimum in the presence of verapamil suggests that the activation of one channel population depends on the influx of Ca²⁺ into the cytoplasm. We identify unitary currents from two K⁺-selective channel populations (40 and 125 pS) which open when the membrane is depolarized; it is possible that these mediate the outward whole-cell current. Hyperpolarization of the membrane from the resting potential produces time- and voltage-dependent inward whole-cell current. Current activation is fast and follows an exponential time course. The current saturates and in some cases decreases at membrane potentials more negative than –175 mV. This current is conducted by poorly selective K⁺ channels, whereP _Cl/P _K=0.43±0.15. We describe a low conductance (20 pS) channel population of unknown selectivity which opens when the membrane is hyperpolarized. It is possible that these channels mediate inward whole-cell current. When the membrane is hyperpolarized to potentials more negative than –250 mV large, irregular inward current is activated. A third type of inward whole-cell current is briefly described. This activates slowly and with a U-shaped current-voltage curve over the range of membrane potentials –90<V _m <0 mV.     

Cell swelling activates K+ and Cl− channels as well as nonselective,stretch-activated cation channels in ehrlich ascites tumor cells

Summary Cell-attached patch-clamp recordings from Ehrlich ascites tumor cells reveal nonselective cation channels which are activated by mechanical deformation of the membrane. These channels are seen when suction is applied to the patch pipette or after osmotic cell swelling. The channel activation does not occur instantaneously but within a time delay of 1/2 to 1 min. The channel is permeable to Ba²⁺ and hence presumably to Ca²⁺. It seems likely that the function of the nonselective, stretch-activated channels is correlated with their inferred Ca²⁺ permeability, as part of the volume-activated signal system. In isolated insideout patches a Ca²⁺-dependent, inwardly rectifying K⁺ channel is demonstrated. The single-channel conductance recorded with symmetrical 150 mm K⁺ solutions is for inward current estimated at 40 pS and for outward current at 15 pS. Activation of the K⁺ channel takes place after an increase in Ca²⁺ from 10^–7 to 10^–6 m which is in the physiological range. Patch-clamp studies in cellattached mode show K⁺ channels with spontaneous activity and with characteristics similar to those of the K⁺ channel seen in excised patches. The single-channel conductance for outward current at 5 mm external K⁺ is estimated at about 7 pS. A K⁺ channel with similar properties can be activated in the cellattached mode by addition of Ca²⁺ plus ionophore A23187. The channel is also activated by cell swelling, within 1 min following hypotonic exposure. No evidence was found of channel activation by membrane stretch (suction). The time-averaged number of open K⁺ channels during regulatory volume decrease (RVD) can be estimated at 40 per cell. The number of open K⁺ channels following addition of Ca²⁺ plus ionophore A23187 was estimated at 250 per cell. Concurrent activation in cell-attached patches of stretch-activated, nonselective cation channels and K⁺ channels in the presence of 3 mm Ca²⁺ in the pipette suggests a close spatial relationship between the two channels. In excised inside-out patches (with NMDG chloride on both sides) a small 5-pS chloride channel with low spontaneous activity is observed. The channel activity was not dependent on Ca²⁺ and could not be activated by membrane stretch (suction). In cell-attached mode singlechannel currents with characteristics similar to the channels seen in isolated patches are seen. In contrast to the channels seen in isolated patches, the channels in the cell-attached mode could be activated by addition of Ca²⁺ plus ionophore A23187. The channel is also activated by hypotonic exposure with a single-channel conductance at 7 pS (or less) and with a time delay at about 1 min. The number of open channels during RVD is estimated at 80 per cell. Two other types of Cl^– channels were regularly recorded in excised inside-out patches: a voltage-activated 400-pS channel and a 34-pS Cl^– channel which show properties similar to the Cl^– channel in the apical membrane in human airway epithelial cells. There is no evidence for a role in RVD for either of these two channels.     

A novel Cl− conductance in cultured chick cardiac myocytes: Role of intracellular Ca2+ and cAMP

Cl^– conductance in cultured embryonic chick cardiac myocytes was characterized using whole-cell patch clamp techniques. Following elimination of cation currents in Na⁺and K⁺-free internal and external solutions, the basal whole-cell current was predominantly a Cl^– current. Cl^–-sensitive current (I _Cl) was defined as the difference between the whole-cell currents recorded in normal and low [Cl^–] _o when measured in the same cell. The whole-cell current in the absence or presence of 10 m cAMP was time independent, displayed outward rectification with the pipette [Cl^–] < 40 mm, and was not saturated with a physiological Cl^– gradient. The Cl^– current was also activated by 1 m forskolin and inhibited by 0.3 mm anthracene-9-carboxylic acid (9-AC). Forskolin was less effective than cAMP (internal dialysis) in activating the Cl^– current. The cAMP- or forskolin-activated and basal Cl^– current were reasonably fit by the Goldman-Hodgkin-Katz equation. The calculated P _Cl in the presence of cAMP was increased by fiveto sixfold over the basal level. In the presence of 5 mm EGTA to decrease free [Ca²⁺] _i , the whole-cell current could not be stimulated by cAMP, forskolin or IBMX (0.1 mm). These data suggest that cultured chick cardiac myocytes have a low basal Cl^– conductance, which, as in some mammalian cardiac ventricular myocytes, can be activated by cAMP. However, this study shows that the activation process requires physiological free [Ca²⁺] _i .This study was supported by grants from the National Institutes of Health (HL-17670, HL-27105 and HL-07107) for M.L. and by Institutional funds of the University of Arkansas for Medical Sciences for S.L.We thank Meei-Yueh Liu, Kathleen Mitchell, and Shirley Revels for their technical assistance.     

A channel that allows inwardly directed fluxes of anions in protoplasts derived from wheat roots

An anion channel that only allows outward current flow (anion influx) has been identified in protoplasts derived from wheat (Triticum aestivum L., Triticum turgidum L.) roots. The anion outward rectifier (anion OR) measured by patch-clamp of whole cells activated very quickly, usually reaching a steady-state level in less than 100 ms and was easily distinguished from the cation outward rectifier (cation OR) which activated more slowly during membrane depolarisation. The anion OR is permeable to NO ₃ ^– and Cl^–, moderately permeable to I^–, and relatively impermeable to H₂PO₄/^– and ClO₄/^–. An anomalous mole-fraction effect between ClO_4/ ^– and Cl^– was observed on the outward current, indicating that the channel is a multi-ion pore. The anion OR is gated by both voltage and external anion concentration such that it activates near to the equilibrium potential for the permeant anion. It activated at more negative membrane potentials when NO ₃ ^– was substituted for Cl^– in the external medium, indicating that the channel may function to allow NO ₃ ^– influx under luxuriant external NO ₃ ^– concentrations. For most experiments, K⁺ and Cl^– were the main cation and anion in solution, and under these conditions it appeared likely that the anion OR functioned in membrane-potential regulation by facilitating a Cl^– influx at membrane potentials more positive than the chloride reversal potential (E_Cl). If E_Cl was more negative than the K⁺ reversal potential (E_K) then the anion OR dominated but both the anion and cation ORs occurred together when the membrane potential difference (V_m) was positive of both E_Cl and E_K. The cation OR was inhibited by increasing external Cl^– concentrations, but the anion OR was not affected by external K⁺ or Na⁺ concentration. The anion-transport inhibitors, zinc and phenylglyoxal were ineffective in blocking the anion OR. 4,4-Di-isothiocyanostilbene-2, 2-disulfonic acid (DIDS) irreversibly blocked about 34% of the current when applied extracellularly at a concentration of 25 M, and about 69% at a concentration of 200 M. However, DIDS (200 M) also occasionally acted as an irreversible blocker of the cation OR. Perchlorate blocked irreversibly 75% of the current at an external concentration of 10 mM and did not block the cation OR. Whole-cell currents also indicated that the anion OR was insensitive to external pH (pH=5–7) and calcium concentration ([Ca²⁺]=0.1–10 mM). Increasing intracellular calcium concentration significantly increased the occurrence of the fast outward current in whole cells (P < 0.005, X² test). With approximately 10 nM calcium inside the cell the anion outward current was observed in 64% (n = 45) of cells and with 50 nM calcium inside the cell the anion current was observed in 88% (n = 69) of cells. Single-anion OR channels observed in outside-out patches had a conductance in 300 mM KCl (external) of about 4 pS. When voltage pulses were applied to outside-out patches the average currents were similar to those observed in whole cells. The significance of the anion OR as a likely route for Cl uptake in high salinities is discussed.Abbreviations Bath solution bathing the extracellular face of the membrane - DIDS (4,4-diisothiocyanostilbene-2,2-disulfonic acid) - E_x reversal potential for ion x - OR outward rectifier - Pip solution inside the pipette - TEACl (tetraethyl-ammonium chloride) - V_m membrane potential difference We thank the Australian Research Council for financial support, G.P. Findlay and A. Garrill for helpful discussions, and K. Morris and D. Mackenzie for expert technical assistance. M.S. was supported by an Australian Postgraduate Research Award.     

Cl− channels in basolateral renal medullary vesicles: V. Comparison of basolateral mTALH Cl− channels with apical Cl− channels from jejunum and trachea

Summary Cl^– channels from basolaterally-enriched rabbit outer renal medullary membranes are activated either by increases in intracellular Cl^– activity or by intracellular protein kinase A (PKA). Phosphorylation by PKA, however, is not obligatory for channel activity since channels can be activated by intracellular Cl^– in the absence of PKA. The PKA requirement for activation of Cl^– channels in certain secretory epithelia is, in contrast, obligatory. In the present studies, we examined the effects of PKA and intracellular Cl^– concentrations on the properties of Cl^– channels obtained either from basolaterally-enriched vesicles derived from highly purified suspensions of mouse medullary thick ascending limb (mTALH) segments, or from apical membrane vesicles obtained from two secretory epithelia, bovine trachea and rabbit small intestine. Our results indicate that the Cl^– channels from mTALH suspensions were virtually identical to those previously described from rabbit outer renal medulla. In particular, an increase in intracellular (trans) Cl^– concentration from 2 to 50 mm increased both channel activity (P _o) and channel conductance (g _Cl, pS). Likewise, trans PKA increased mTALH Cl^– channel activity by increasing the activity of individual channels when the trans solutions were 2 mm Cl. Under the latter circumstance, PKA did not activate quiescent channels, nor did it affect g _Cl. Moreover, when mTALH Cl^– channels were inactivated by reducing cis Cl^– concentrations to 50 mm, cis PKA addition did not affect P _o. These results are consistent with the view that these Cl^– channels originated from basolateral membranes of the mTALH.Cl^– channels from apical vesicles from trachea and small intestine were completely insensitive to alterations in trans Cl^– concentrations and demonstrated markedly different responses to PKA. In the absence of PKA, tracheal Cl^– channels inactivated spontaneously after a mean time of 8 min; addition of PKA to trans solutions reactivated these channels. The intestinal Cl^– channels did not inactivate with time. Trans PKA addition activated new channels with no effect on basal channel activity. Thus the regulation of Cl^– channel activity by both intracellular Cl^– and by PKA differ in basolateral mTALH Cl^– channels compared to apical Cl^– channels from either the tracheal or small intestine.We acknowledge the able technical assistance of Steven D. Chasteen. Clementine M. Whitman provided her customary excellent secretarial assistance. This work was supported by Veterans Administration Merit Review Grants to T.E. Andreoli and to W.B. Reeves. C.J. Winters is a Veterans Administration Associate Investigator.     

Acetylcholine activates a chloride channel as well as glutamate and GABA

Summary In conventional two microelectrode experiments, acetylcholine had qualitatively the same effect as GABA and glutamate on membrane potential and input resistance of muscle fibres of the opener and intrinsic stomach muscles of crayfish (Austropotamobius torrentium). In patch-clamp experiments, acetylcholine occasionally elicited single channel openings in cell-attached patches on these muscles. If outside-out patches were excised and the Cl^– concentration was high on both sides of the membrane, acetylcholine at concentrations of 1 nM regularly elicited single channel currents. The amplitude of single channel currents depended strongly on the intracellular concentration of Cl^–. The reversal potential of the channel, determined after replacing intracellular K⁺ with Cs⁺, corresponded to the Nernst potential for Cl^–. The voltage dependence and the reversal potential of single channel current amplitudes elicited by ACh, glutamate and GABA were identical. The distribution of life times of openings (>1 ms) elicited by ACh and glutamate could be fitted by a single exponential with a time constant of about 2.5 ms, corresponding to the mean open time. ACh and glutamate applied to the same outside-out patch showed cross-desensitization, and thus ACh and glutamate activate the same channels. An excitatory, cationic ACh-activated channel could not be identified. Permeabilities of the chloride channel were calculated according to the Goldman-Hodgkin-Katz equation at different membrane potentials. Negative single channel current amplitudes (inward currents) could be fitted with a permeability of ₂= 3.9×10^–14 cm³s^–1. For positive currents (outward) the channel had a permeability of ₁= 1.4× 10^–14 cm³s^–1. The permeability of the channel declined from 16×10^–14 cm³s^–1 to 2.3×10^–14 cm³s^–1 if the intracellular Cl^–-concentration was raised from 6 to 257 mM. The activation elicited by acetylcholine was inhibited by extracellular Ca⁺⁺. The mean current activated by ACh was reduced by a factor of 50 if the extracellular concentration of Ca⁺⁺ was raised from 0.1 mM to the physiological concentration of 13.5 mM.     

Conductance states activated by glycine and GABA in rat cultured spinal neurones

Summary The conductance properties of single Cl^– channels activated by glycine and gamma-aminobutyric acid (GABA) were examined in rat spinal cord neurones grown in cell culture. The majority (85%) of spinal neurones were sensitive to both glycine and GABA as were most (83%) outside-out patches tested. Glycine and GABA activated multiple conductance state Cl^– channels with linear current-voltage properties when the chloride activities of the solutions bathing both sides of the membrane were similar. Glycine activated six distinct conductance states with conductances of 14, 20, 30, 43, 64 and 93 pS, whereas GABA activated five states with conductances of 13, 20, 29, 39 and 71 pS. The 30 and 43 pS states and the 20 and 29 pS states were observed most frequently with glycine and GABA, respectively. As the values of the glycine- and GABA-activated conductance states form a geometric progression when arranged in ascending order, we concluded that the channels do not consist of a cluster of identical pores. Additional conductance states (50 and 100 pS) were activated by glycine occasionally. The similarity between the conductances of the states activated by the two transmitters is consistent with the proposal that they both activate the same type of Cl^– channel.     

Swelling-activated Chloride and Potassium Conductance in Primary Cultures of Mouse Proximal Tubules. Implication of KCNE1 Protein

Volume-sensitive chloride and potassium currents were studied, using the whole-cell clamp technique, in cultured wild-type mouse proximal convoluted tubule (PCT) epithelial cells and compared with those measured in PCT cells from null mutant kcne1 –/– mice. In wild-type PCT cells in primary culture, a Cl^– conductance activated by cell swelling was identified. The initial current exhibited an outwardly rectifying current-voltage (I-V) relationship, whereas steady-state current showed decay at depolarized membrane potentials. The ion selectivity was I^– > Br^– > Cl^– >> gluconate. This conductance was sensitive to 1 mM 4,4-Diisothiocyanostilbene-2,2-disulfonic acid (DIDS), 0.1 mM 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB) and 1 mM diphenylamine-2-carboxylate (DPC). Osmotic stress also activated K⁺ currents. These currents are time-independent, activated at depolarized potentials, and inhibited by 0.5 mM quinidine, 5 mM barium, and 10 µM clofilium but are insensitive to 1 mM tetraethylammonium (TEA), 10 nM charybdotoxin (CTX), and 10 µM 293B. In contrast, the null mutation of kcne1 completely impaired volume-sensitive chloride and potassium currents in PCT. The transitory transfection of kcne1 restores both Cl^– and K⁺ swelling-activated currents, confirming the implication of KCNE1 protein in the cell-volume regulation in PCT cells in primary cultures.     

Activation of a nonselective cation channel by swelling in atrial cells

Cell swelling has been shown to increase the permeability of the plasma membrane to ions such as K⁺, Na⁺, Ca²⁺ or Cl^– in many types of cells. In cardiac cells, swelling has been reported to increase Cl^– conductance, but whether cation-selective currents are activated by swelling is not known. Low Cl^– or Cl^–-free solutions were used to study the presence of such currents. Lowering the osmolarity of the extracellular medium from 299 to 219 mOsm resulted in cell swelling and concurrent activation of a cation-selective whole-cell current. When cell-attached patches were formed on swollen cells, opening of bursting single channel currents were observed in 18% of the patches studied. Ion substitution experiments indicated that the channel discriminated poorly among monovalent cations, and was impermeable to Cl^–. The channel was permeable to Ca²⁺. In symmetrical 140 mM K⁺, the current-voltage relation was linear with a single channel conductance of 36 ± 3 pS. Depolarization increased channel open probability. Interestingly, depending on the membrane patch studied, application of negative pressure to the pipette caused either an increase or a decrease in the open probability of the channel already activated by swelling. Thus, the sensitivity to tension of the swelling-activated channel was different from those of previously reported stretch-activated channels. These findings suggest that nonselective cation channels exist in rat atrial cells and may be involved in swelling-induced changes in cell function.Dr. Kim is an Established Investigator of the American Heart Association.     

Activation by Angiotensin II of Ca2+-dependent K+ and Cl− Currents in Zona Fasciculata Cells of Bovine Adrenal Gland

The effects of angiotensin II (100 nm) on the electrical membrane properties of zona fasciculata cells isolated from calf adrenal gland were studied using the whole cell patch recording method. In current-clamp condition, angiotension II induced a biphasic membrane response which began by a transient hyperpolarization followed by a depolarization more positive than the control resting potential. These effects were abolished by Losartan (10⁻⁵ m), an antagonist of angiotensin receptors of type 1. The angiotensin II-induced transient hyperpolarization was characterized in voltage-clamp condition from a holding potential of −10 mV. Using either the perforated or the standard recording method, a transient outward current accompanied by an increase of the membrane conductance was observed in response to the hormonal stimulation. This outward current consisted of an initial fast peak followed by an oscillating or a slowly decaying plateau current. In Cl⁻-free solution, the outward current reversed at −78.5 mV, a value close to E _K. It was blocked by external TEA (20 mm) and by apamin (50 nm). In K⁺-free solution, the transient outward current, sensitive to Cl⁻ channel blocker DPC (400 μm), reversed at −52 mV, a more positive potential than E _Cl. Its magnitude changed in the same direction as the driving force for Cl⁻. The hormone-induced transient outward current was never observed when EGTA (5 mm) was added to the pipette solution. The plateau current was suppressed in nominally Ca²⁺-free solution (47% of cells) and was reversibly blocked by Cd²⁺ (300 μm) but not by nisoldipine (0.5–1 μm) which inhibited voltage-gated Ca²⁺ currents identified in this cell type. The present experiments show that the transient hyperpolarization induced by angiotensin II is due to Ca²⁺-dependent K⁺ and Cl⁻ currents. These two membrane currents are co-activated in response to an internal increase of [Ca²⁺] _i originating from intra- and extracellular stores. Received: 29 May 1997/Revised: 4 November 1997     

Activation by hyperpolarization and atypical osmosensitivity of a Cl− current in rat osteoblastic cells

During whole-cell recording of rat osteoblastic cells with high-Cl^– internal solutions, 10 sec hyperpolarizing jumps from 0 mV induce a slow inward current relaxation, which is shown to be carried by hyperpolarization-activated Cl^– channels. This relaxation increases and becomes faster with stronger hyperpolarizations. It is insensitive to Cs⁺ ions but is blocked in a voltage-dependent manner by 4,4-diisothiocyanatostilbene-2, 2-disulfonic acid (DIDS) 1 mm and is reduced by 5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB) 0.1 mm. Cd²⁺ ions are potent blockers of this current, blocking completely above 300 m. The amplitude of the Cl^– current activated by a given hyperpolarization increases during the first 10–20 min of whole-cell recording. This evolution and the fact that some recently cloned Cl^– channels have been reported to be activated both by hyperpolarization and by external hyposmolarity led us to investigate the effects of external osmolarity. Reducing the external osmolarity induces a large Cl^– current. However, this hyposmolarity-induced Cl^– current and the hyperpolarization-activated Cl^– current are shown to be distinct; 1,9-dideoxy forskolin selectively blocks the hyposmolarity-activated current. We show that the hyperpolarization-activated Cl^– current is osmosensitive, but in an unusual way: it is reduced by external hyposmolarity and is increased by external hyperosmolarity. Furthermore, these modulations are more pronounced for small hyperpolarizations. The osmosensitivity of the hyperpolarization-activated Cl^– current suggests a mechanosensitivity (activation by positive external pressure) that is likely to be physiologically important to bone cells.We wish to thank P. Ascher and B. Barbour for useful comments.     

Chloride currents inChara—A patch-clamp study

Summary Ionic current steps were recorded with the patch-clamp technique from algal cells that had been prepared without enzyme treatment. Inward current steps with different conductance levels occurred, the lowest level being 7 pS. There were complex transitions between levels indicating either a lack of independence between single channels, or sublevels of a much larger conductance unit. The reversal potential was consistent with the permeant ion being Cl^–. Furthermore, when a different concentration of Cl^– was used in the patch electrode the reversal potential of the inward current shifted in a manner consistent with a Nernstian change in the Cl^– reversal potential. The frequency of the current steps was voltage dependent and suggestive of the hyperpolarization-activated Cl^– currents reported in voltage-clamp studies. Outward current steps, with conductances of 38 pS, were recorded when the membrane patch was depolarized by more than +120 mV. Their amplitude and frequency increased at more positive potentials. The current was probably carried by an efflux of cations through a different set of channels. The resting membrane potential, measured unambiguously without contamination from the tonoplast, was –190±5 mV.     

Voltage-gated ion conductances corresponding to regenerative positive and negative spikes in the dinoflagellateNoctiluca miliaris

Depolarization-activated and hyperpolarization-activated ion conductances in the membrane of a marine dinoflagellateNoctiluca miliaris were examined under voltage-clamp conditions.Noctiluca exhibited a transient inward current in response to a step depolarization from a holding potential level of –80 mV to a potential level more positive than –50 mV. The I–V relationship for the current exhibited typical N-shaped characteristics similar to those of most excitable membranes. The current was inactivated by a membrane depolarization. The reversal potential of the current shifted in hyperpolarizing direction when the external Na⁺ concentration was lowered. The transient inward current is assumed to be responsible for the Na⁺-dependent positive spike in non-clamped specimens ofNoctiluca.Noctiluca exhibited a transient outward current in response to a step hyperpolarization from a holding potential level of –20 mV to a potential level more negative than –30 mV. The I–V relationship for the current was a typical N-shape as if it was turned 180° around its origin. The outward current showed a two-step exponential time-decay. The outward current was inactivated by a membrane hyperpolarization. The reversal potential shifted in the depolarizing direction when the external Cl^– concentration was lowered. The transient outward current is responsible for the Cl^–-dependent negative spike in non-clamped specimens ofNoctiluca.Abbreviations ASW artificial seawater - TRP tentacle regulating potentials - TTX tetrodotoxin     

The Ca2+-induced leak current in Xenopus oocytes is indeed mediated through a Cl− channel

Defolliculated oocytes of Xenopus laevis responded to removal of external divalent cations with large depolarizations and, when voltage clamped, with huge currents. Single channel analysis revealed a Cl^– channel with a slope conductance of about 90 pS at positive membrane potentials with at least four substates. Single channel amplitudes and mean channel currents had a reversal potential of approximately –15 mV as predicted by the Nernst equation for a channel perfectly selective for Cl^–. Readdition of Ca²⁺ immediately inactivated the channel and restored the former membrane potential or clamp current. The inward currents were mediated by a Ca²⁺ inactivated Cl^– channel (CaIC). The inhibitory potency of Ca²⁺ was a function of the external Ca²⁺ concentration with a half maximal blocker concentration of about 20 m.These channels were inhibited by the Cl^– channel blockers flufenamic acid, niflumic acid and diphenylamine-2-carboxylate (DPC). In contrast, 4,4-acetamido-4-isothiocyanatostilbene-2,2-disulfonicacid (SITS), another Cl^– channel blocker, led to activation of this Cl^– channel. Like other Cl^– channels, the CaIC was activated by cytosolic cAMP. Extracellular ATP inhibited the channel while ADP was without any effect. Injection of phorbol 12-myristate 13-acetate (PMA), a protein kinase C activating phorbol ester, stimulated the Cl^– current. Cytochalasin D, an actin filament disrupting compound, reversibly decreased the clamp current demonstrating an influence of the cytoskeleton.The results indicate that removal of divalent cations activates Cl^– channels in Xenopus oocytes which share several features with Cl^– channels of the CLC family. The former so-called leak current of oocytes under divalent cation-free conditions is nothing else than an activation of Cl^– channels.The microelectrode measurements are part of the PhD thesis of K. Liebold; the patch clamp contributions are part of the PhD thesis of F.W. Reifarth. This study was supported by the Deutsche Forschungsgemeinschaft (We1858/2-l) and by Sonderforschungsbereich 249.     

Voltage-gated chloride currents in cultured canine tracheal epithelial cells

Summary Chloride ions (Cl^–) are concentrated in airway epithelial cells and subsequently secreted into the tracheal lumen by downhill flux through apical Cl^– channels. We have studied Cl^– currents in cultured canine tracheal cells using the whole-cell voltage-clamp technique. Ultrastructural techniques demonstrated that the cells used in the electrophysiological experiments possessed apical membrane specializations known to be present in the intact, transporting cell type. Cultured cells 2–6 days old were characterized by an input resistance of 3.4±0.8 G (n=11) and a capacitance of 63.8±10.8 pF (n=26). A comparison of 3 and 4 day-old cells with 5 and 6 day-old cells showed that the input resistance decreased almost 50%, and the cell capacitance and the inward and outward currents increased concomitantly approximately 200%. Cultured cells 3–4 days old held at –40 mV produced currents of 196±22 pA at 50 mV and –246±27 pA at –90 mV (n=212) with pipette and bath solutions containing primarily 140 KCl and 140 NaCl, respectively. The chloride channel blocker diphenylamine-2-carboxylate (DPC, 100 m) suppressed whole-cell currents by 76.8% at 60 mV; however, currents were unaffected by the stilbenes SITS (1mm) and DNDS (1–30 m). Replacement of K⁺ with Cs⁺ in the pipette solution did not affect the outward current, the current reversal potential, or the input resistance of the cells, indicating that the current was not significantly K⁺ dependent when the intrapipette solution was buffered to a Ca²⁺ concentration of 20nm. The Cl^–/Na⁺ permeability ratio was estimated to be greater than 11 as calculated from reversal potential measurements in the presence of an internal to external NaCl concentration ratio of 12. Current equilibrium permeabilities, relative to Cl^– were: I^– (2.9)NO ₃ ^– (1.1)Br^– (1.1)Cl^– (1.0)F^– (0.93)MeSO ₄ ^– (0.19)gluconate (0.18)aspartate (0.14). Depolarizations to potentials greater than 20 mV elicited a time-dependent component in the outward current in 71% of the cells studied. Currents inactivated with a double exponential time course at the most depolarized voltages. Recovery from inactivation was fast, holding potential-dependent, and followed a double exponential time course. Current amplitude was increased via a cAMP-dependent pathway as has been demonstrated for single Cl-selective channels in cell-attached patches from cultured canine and human tracheal epithelial cells. Forskolin, an activator of adenylate cyclase, produced a 260% increase in the outward current at +50 mV. In summary, cultured canine tracheal cells have a single resting conductance that is Cl^– selective, voltage-dependent, and modulated by a cAMP-dependent mechanism. This preparation appears to be appropriate for analysis of cellular modulation of airway Cl^– channels and Cl^– secretion.     

Single chloride-permeable channels of large conductance in cultured cardiac cells of new-born rats

Large conductance channels were observed in the membrane of cultured cardiac cells of newborn rats studied with the patch-clamp technique in cell-attached and inside-out configurations. These channels were observed in 4% of the patches. In the cell-attached configuration they exhibited outward rectification and partial inactivation. In the inside-out configuration no rectification occurred but inactivation was present, mainly during hyperpolarizations. Two channels with large single unit conductances (400–450 pS) and one with a smaller conductance (200–250 pS) were frequently observed in the same patch. The two large channels generally had different kinetics. Under steady-state conditions the opening probability of the faster channel appeared to be voltage-independent. The slower channel was activated by depolarization. In asymmetrical solutions the permeability ratios P _Na/P _Cl were 0.03 and 0.24 for the larger and smaller channels, respectively; corresponding values for P _Ba/P _Cl were 0.04 and 0.09. It is proposed that in cardiac membranes the chloride permeability system is composed of widely dispersed microclusters forming grouped channels of different types and sizes.