Identification of High-Affinity Slow Anion Channel Blockers and Evidence for Stomatal Regulation by Slow Anion Channels in Guard Cells

Slow anion channels in the plasma membrane of guard cells have been suggested to constitute an important control mechanism for long-term ion efflux, which produces stomatal closing. Identification of pharmacological blockers of these slow anion channels is instrumental for understanding plant anion channel function and structure. Patch clamp studies were performed on guard cell protoplasts to identify specific extracellular inhibitors of slow anion channels. Extracellular application of the anion channel blockers NPPB and IAA-94 produced a strong inhibition of slow anion channels in the physiological voltage range with half inhibition constants (K1/2) of 7 and 10 [mu]M, respectively. Single slow anion channels that had a high open probability at depolarized potentials were identified. Anion channels had a main conductance state of 33 [plus or minus] 8 pS and were inhibited by IAA-94. DIDS, which has been shown to be a potent blocker of rapid anion channels in guard cells (K1/2 = 0.2 [mu]M), blocked less than 20% of peak slow anion currents at extracellular or cytosolic concentrations of 100 [mu]M. The pharmacological properties of slow anion channels described here differ from those recently described for rapid anion channels in guard cells, fortifying the finding that two highly distinct types or modes of voltage- and second messenger-dependent anion channel currents coexist in the guard cell plasma membrane. Bioassays using anion channel blockers provide evidence that slow anion channel currents play a substantial role in the regulation of stomatal closing. Interestingly, slow anion channels may also function as a negative regulator during stomatal opening under the experimental conditions applied here. The identification of specific blockers of slow anion channels reported here permits detailed studies of cell biological functions, modulation, and structural components of slow anion channels in guard cells and other higher plant cells.     

Distinct pH regulation of slow and rapid anion channels at the plasma membrane of Arabidopsis thaliana hypocotyl cells

Variations in both intracellular and extracellular pH are known to be involved in a wealth of physiological responses. Using the patch-clamp technique on Arabidopsis hypocotyl cells, it is shown that rapid-type and slow-type anion channels at the plasma membrane are both regulated by pH via distinct mechanisms. Modifications of pH modulate the voltage-dependent gating of the rapid channel. While intracellular alkalinization facilitates channel activation by shifting the voltage gate towards negative potentials, extracellular alkalinization shifts the activation threshold to more positive potentials, away from physiological resting membrane potentials. By contrast, pH modulates slow anion channel activity in a voltage-independent manner. Intracellular acidification and extracellular alkalinization increase slow anion channel currents. The possible role of these distinct modulations in physiological processes involving anion efflux and modulation of extracellular and/or intracellular pH, such as elicitor and ABA signalling, are discussed.     

Antibodies to the CFTR modulate the turgor pressure of guard cell protoplasts via slow anion channels

The plasma membrane guard cell slow anion channel is a key element at the basis of water loss control in plants allowing prolonged osmolite efflux necessary for stomatal closure. This channel has been extensively studied by electrophysiological approaches but its molecular identification is still lacking. Recently, we described that this channel was sharing some similarities with the mammalian ATP-binding cassette protein, cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel [Leonhardt, N. et al. (1999) Plant Cell 11, 1141-1151]. Here, using the patch-clamp technique and a bioassay, consisting in the observation of the change in guard cell protoplasts volume, we demonstrated that a functional antibody raised against the mammalian CFTR prevented ABA-induced guard cell protoplasts shrinking and partially inhibited the slow anion current. Moreover, this antibody immunoprecipitated a polypeptide from guard cell protein extracts and immunolabeled stomata in Vicia faba leaf sections. These results indicate that the guard cell slow anion channel is, or is closely controlled by a polypeptide, exhibiting one epitope shared with the mammalian CFTR.     

Anion Selectivity of Slow Anion Channels in the Plasma Membrane of Guard Cells (Large Nitrate Permeability)

Closing of stomatal pores in the leaf epidermis of higher plants is mediated by long-term release of potassium and the anions chloride and malate from guard cells and by parallel metabolism of malate. Previous studies have shown that slowly activating anion channels in the plasma membrane of guard cells can provide a major pathway for anion efflux while also controlling K+ efflux during stomatal closing: Anion efflux produces depolarization of the guard cell plasma membrane that drives K+ efflux required for stomatal closing. The patch-clamp technique was applied to Vicia faba guard cells to determine the permeability of physiologically significant anions and halides through slow anion channels to assess the contribution of these anion channels to anion efflux during stomatal closing. Permeability ratio measurements showed that all tested anions were permeable with the selectivity sequence relative to Cl- of NO3- > Br- > F- ~ Cl- ~ I- > malate. Large malate concentrations in the cytosol (150 mM) produced a slow down-regulation of slow anion channel currents. Single anion channel currents were recorded that correlated with whole-cell anion currents. Single slow anion channels confirmed the large permeability ratio for nitrate over chloride ions. Furthermore, single-channel studies support previous indications of multiple conductance states of slow anion channels, suggesting cooperativity among anion channels. Anion conductances showed that slow anion channels can mediate physiological rates of Cl- and initial malate efflux required for mediation of stomatal closure. The large NO3- permeability as well as the significant permeabilities of all anions tested indicates that slow anion channels do not discriminate strongly among anions. Furthermore, these data suggest that slow anion channels can provide an efficient pathway for efflux of physiologically important anions from guard cells and possibly also from other higher plant cells that express slow anion channels.     

Sulfate Is Both a Substrate and an Activator of the Voltage-Dependent Anion Channel of Arabidopsis Hypocotyl Cells

On the basis of the anion content of in vitro-cultured Arabidopsis plantlets, we explored the selectivity of the voltage-dependent anion channel of the plasma membrane of hypocotyl cells. In the whole-cell configuration, substitution of cytosolic Cl(-) by different anions led to the following sequence of relative permeabilities: NO(3)(-) (2.6) >/= SO(4)(2-) (2.0) > Cl(-) (1.0) > HCO(3)(-) (0.8) > malate(2-) (0.03). Large whole-cell currents were measured for NO(3)(-) and SO(4)(2-), about five to six times higher than the equivalent Cl(-) currents. Since SO(4)(2-) is usually considered to be a weakly permeant or non-permeant ion, the components of the large whole-cell current were explored in more detail. Aside from its permeation through the channel with a unitary conductance, about two-thirds that of Cl(-), SO(4)(2-) had a regulatory effect on channel activity by preventing the run-down of the anion current both in the whole-cell and the outside-out configuration, increasing markedly the whole-cell current. The fact that the voltage-dependent plasma membrane anion channel of hypocotyl cells can mediate large NO(3)(-) and SO(4)(2-) currents and is regulated by nucleotides favors the idea that this anion channel can contribute to the cellular homeostasis of important metabolized anions.     

An anion current at the plasma membrane of tobacco protoplasts shows ATP-dependent voltage regulation and is modulated by auxin

Plasma membrane ion channels of protoplasts from tobacco cell suspensions were characterized by patch-clamp experiments. In the whole-cell configuration, a voltage-dependent current with a current maximum around −90 mV was observed that displayed a reversal potential close to the Nernst potential for chloride. This whole-cell current was identified as an anion current by replacing the internal Cl⁻ with glutamate. The t obacco s uspension a nion c hannel (TSAC) was characterized by fast activation/deactivation and slow inactivation kinetics with voltage-dependent time constants in the range of milliseconds and seconds, respectively. Among the plant channels, TSAC exhibits original properties in terms of phosphorylation-dependent voltage regulation while sharing similarities with the fast anion channel from stomatal guard cells (GCAC1). The voltage dependence of the whole-cell current reflecting the fast deactivation of the current at potentials of less than −100 mV was observed only in the presence of internal ATP or when ATP was replaced by the protein phosphatase inhibitor okadaic acid, and was suppressed by staurosporine. This suggests that protein phosphorylation may be involved in regulating the activity of the anion channel. As observed on GCAC1 the active auxin 1-NAA caused a time- and concentration-dependent shift of the activation potential of TSAC. In addition, TSAC reacted to the auxin agonist antibody D16 providing evidence for the recognition of the auxin signal at the outer face of the plasma membrane.     

ATP binding cassette modulators control abscisic acid-regulated slow anion channels in guard cells

In animal cells, ATP binding cassette (ABC) proteins are a large family of transporters that includes the sulfonylurea receptor and the cystic fibrosis transmembrane conductance regulator (CFTR). These two ABC proteins possess an ion channel activity and bind specific sulfonylureas, such as glibenclamide, but homologs have not been identified in plant cells. We recently have shown that there is an ABC protein in guard cells that is involved in the control of stomatal movements and guard cell outward K+ current. Because the CFTR, a chloride channel, is sensitive to glibenclamide and able to interact with K+ channels, we investigated its presence in guard cells. Potent CFTR inhibitors, such as glibenclamide and diphenylamine-2-carboxylic acid, triggered stomatal opening in darkness. The guard cell protoplast slow anion current that was recorded using the whole-cell patch-clamp technique was inhibited rapidly by glibenclamide in a dose-dependent manner; the concentration producing half-maximum inhibition was at 3 &mgr;M. Potassium channel openers, which bind to and act through the sulfonylurea receptor in animal cells, completely suppressed the stomatal opening induced by glibenclamide and recovered the glibenclamide-inhibited slow anion current. Abscisic acid is known to regulate slow anion channels and in our study was able to relieve glibenclamide inhibition of slow anion current. Moreover, in epidermal strip bioassays, the stomatal closure triggered by Ca2+ or abscisic acid was reversed by glibenclamide. These results suggest that the slow anion channel is an ABC protein or is tightly controlled by such a protein that interacts with the abscisic acid signal transduction pathway in guard cells.     

ABA depolarizes guard cells in intact plants, through a transient activation of R- and S-type anion channels

During drought, the plant hormone abscisic acid (ABA) induces rapid stomatal closure and in turn reduces transpiration. Stomatal closure is accompanied by large ion fluxes across the plasma membrane, carried by K+ and anion channels. We recorded changes in the activity of these channels induced by ABA, for guard cells of intact Vicia faba plants. Guard cells in their natural environment were impaled with double-barrelled electrodes, and ABA was applied via the leaf surface. In 45 out of 85 cells tested, ABA triggered a transient depolarization of the plasma membrane. In these cells, the membrane potential partially recovered in the presence of ABA; however, a full recovery of the membrane potentials was only observed after removal of ABA. Repetitive ABA responses could be evoked in single cells, but the magnitude of the response varied from one hormone application to the other. The transient depolarization correlated with the activation of anion channels, which peaked 5 min after introduction of the stimulus. In guard cells with a moderate increase in plasma membrane conductance (DeltaG < 5 nS), ABA predominantly activated voltage-independent (slow (S)-type) anion channels. During strong responses (DeltaG > 5 nS), however, ABA activated voltage-dependent (rapid (R)-type) in addition to S-type anion channels. We conclude that the combined activation of these two channel types leads to the transient depolarization of guard cells. The nature of this ABA response correlates with the transient extrusion of Cl- from guard cells and a rapid but confined reduction in stomatal aperture.     

The Estimation of Rapid Rate Constants from Current-Amplitude Frequency Distributions of Single-Channel Recordings

A method is described for estimating rapid rate constants from the distributions of current amplitude observed in single-channel electrical recordings. It has the advantages over previous, similar approaches that it can accommodate both multistate kinetic models and adjustable filtering of the data using an 8-pole Bessel filter. The method is conceptually straightforward: the observed distributions of current amplitude are compared with theoretical distributions derived by combining several simplifying assumptions about the underlying stochastic process with a model of the filter and electrical noise. Parameters are estimated by approximate maximum likelihood. The method was used successfully to estimate rate constants for both a simple two-state kinetic model (the transitions between open and closed states during the rapid gating of an outward-rectifying K⁺-selective channel in the plasma membrane of Acetabularia) and a complex multistate kinetic model (the blockade of the maxi cation channel in the plasma membrane of rye roots by verapamil). For the two-state model, parameters were estimated well, provided that they were not too fast or too slow in relation to the sampling rate. In the three-state model the precision of estimates depended in a complex way on the values of all rate parameters in the model. Received: 4 October 1996/Revised: 2 September 1997     

Characterisation of three pathways for osmolyte efflux in human erythroleukemia cells

Cell volume decrease is a key step during differentiation of erythroid cells. This could arise from membrane transporter activation leading to a loss of cell osmolytes; however, the pathways involved are poorly understood. We have characterised Cl(-)-independent K(+) and (3)H-taurine efflux from the erythroleukemia cell line, K562. K(+) efflux (measured using (86)Rb(+)) from pre-loaded cells subjected to hypo-osmotic challenge demonstrated two phases, a rapid increase in K(+) efflux followed by a smaller slower increase. Swelling-activated taurine efflux only demonstrated a single phase. Both phases of K(+) efflux were significantly (P<0.05) blocked by anion channel inhibitor 5-nitro-2-(3-phenypropylamino)-benzoic acid (NPPB). However the antiestrogen, tamoxifen, only inhibited the slow late phase. The initial rapid phase had a higher IC(50) for NPPB inhibition than the slow phase, and was insensitive to protein kinases inhibitors KN-62, wortmannin and PD98059. For the slow K(+) efflux phase, the IC(50) for NPPB inhibition and the inhibition by KN-62, wortmannin, genistein or PD98059, were very similar to those measured for the hypo-osmotically-activated taurine efflux. With NPPB (100 microM) present, the slow K(+) efflux phase was further significantly decreased by the Ca(2+) chelator BAPTA-AM or by the Ca(2+)-activated K(+) channel blockers clotrimazole and charybdotoxin but not by apamin. Thus, at least 3 Cl(-)-independent pathways are involved: (a) a tamoxifen-sensitive and taurine-permeable anion channel; (b) a tamoxifen-insensitive and taurine-impermeable K(+) efflux pathway; and (c) a subtype of Ca(2+)-activated K(+) channel. Any or all of these could be involved in the cell volume decrease associated with differentiation in K562 cells.     

Modulation of nerve membrane sodium channels by chemicals

1. Modulations of sodium channel kinetics by grayanotoxins and pyrethroids have been studied using voltage clamped, internally perfused giant axons from crayfish and squid. 2. Grayanotoxin I and alpha-dihydrograyanotoxin II greatly depolarize the nerve membrane through an increase in resting sodium channel permeability to sodium ions. 3. Grayanotoxins modify a fraction of sodium channel population to give rise to a slow conductance increase with little or no inactivation, and the slow conductance-membrane potential curve is shifted toward hyperpolarization. This accounts for the depolarization. 4. The tail current associated with step repolarization during the slow current in grayanotoxins decays with a dual exponential time course. 5. (+)-trans tetramethrin and (+)-trans allethrin also modify a fraction of sodium channel population in generating a slow current, which attains a maximum slowly and decays very slowly during a maintained depolarizing step. The membrane is depolarized only slightly. 6. The tail current associated with step repolarization during the slow current in the pyrethroids is very large in initial amplitude and decays very slowly. 7. The rate at which the sodium channel arrives at the modified open state in the presence of pyrethroids is expressed by a dual exponential function, and the slow phase disappears following removal of the sodium inactivation mechanism by internal perfusion of pronase. 8. A kinetic model is proposed to account for the actions of both grayanotoxins and pyrethroids on sodium channels. Both chemicals interact with the channel at both open and closed states to yield a modified open state which results in a slow sodium current.     

ATP-Dependent Regulation of an Anion Channel at the Plasma Membrane of Protoplasts from Epidermal Cells of Arabidopsis Hypocotyls

Although Arabidopsis is the object of many genetic and molecular biology investigations, relatively few studies deal with regulation of its transmembrane ion exchanges. To clarify the role of ion transport in plant development, organ-and tissue-specific ion channels must be studied. We identified a voltage-dependent anion channel in epidermal cells of Arabidopsis hypocotyls, thus providing a new example of the occurrence of voltage-dependent anion channels in a specific plant cell type distinct from the stomatal guard cell. The Arabidopsis hypocotyl anion channel is able to function under two modes characterized by different voltage dependences and different kinetic behaviors. This switch between a fast and a slow mode is controlled by ATP. In the presence of intracellular ATP (fast mode), the channels are closed at resting potentials, and whole-cell currents activate upon depolarization. After activation, the anion current deactivates rapidly and more and more completely at potentials negative to the peak. In the absence of ATP, the current switches from this fast mode to a mode characterized by a slow and incomplete deactivation at resting potentials. In addition, the whole-cell currents can be correlated with the activity of single channels. In the outside-out configuration, the presence of ATP modulates the mean lifetimes of the open and closed states of the channel at hyperpolarized potentials, thus controlling its open probability. The fact that ATP-dependent voltage regulation was observed in both whole-cell and outside-out configurations suggests that a single type of anion channel can switch between two modes with distinct functional properties.     

Cardiac Na currents and the inactivating, reopening, and waiting properties of single cardiac Na channels

Tetrodotoxin (TTX)-sensitive Na currents were examined in single dissociated ventricular myocytes from neonatal rats. Single channel and whole cell currents were measured using the patch-clamp method. The channel density was calculated as 2/micron 2, which agreed with our usual finding of four channels per membrane patch. At 20 degrees C, the single channel conductance was 20 pS. The open time distributions were fit by a single-exponential function with a mean open time of approximately 1.0 ms at membrane potentials from -60 to -40 mV. Averaged single channel and whole cell currents were similar when scaled and showed both fast and slow rates of inactivation. The inactivation and activation gating shifted quickly to hyperpolarized potentials for channels in cell-attached as well as excised patches, whereas a much slower shift occurred in whole cells. Slowly inactivating currents were present in both whole cell and single channel current measurements at potentials as positive as -40 mV. In whole cell measurements, the potential range could be extended, and slow inactivation was present at potentials as positive as -10 mV. The curves relating steady state activation and inactivation to membrane potential had very little overlap, and slow inactivation occurred at potentials that were positive to the overlap. Slow inactivation is in this way distinguishable from the overlap or window current, and the slowly inactivating current may contribute to the plateau of the rat cardiac action potential. On rare occasions, a second set of Na channels having a smaller unit conductance and briefer duration was observed. However, a separate set of threshold channels, as described by Gilly and Armstrong (1984. Nature [Lond.]. 309:448), was not found. For the commonly observed Na channels, the number of openings in some samples far exceeded the number of channels per patch and the latencies to first opening or waiting times were not sufficiently dispersed to account for the slowly inactivating currents: the slow inactivation was produced by channel reopening. A general model was developed to predict the number of openings in each sample. Models in which the number of openings per sample was due to a dispersion of waiting times combined with a rapid transition from an open to an absorbing inactivated state were unsatisfactory and a model that was more consistent with the results was identified.     

Glucose-sensitive conductances in rat pancreatic beta-cells: contribution to electrical activity

The perforated patch technique was used to assess the relative contribution of K(ATP) channel activity, assessed from input conductance (G(input)), and volume-sensitive anion channel activity to the induction of electrical activity in single isolated rat pancreatic beta-cells by glucose, 2-ketoisocaproate and tolbutamide. In cells equilibrated in the absence of glucose, the membrane potential was -71 mV and G(input) 3.66 nS. Addition of 8 mM glucose resulted in depolarisation, electrical activity and a reduction in G(input), reflecting an inhibition of K(ATP) channels. Cells equilibrated in 4 mM glucose had a membrane potential of -59 mV and a G(input) of 0.88 nS. In this case, a rise in glucose concentration to 8-20 mM again resulted in depolarisation and electrical activity, but caused a small increase in G(input). 2-Ketoisocaproate also evoked electrical activity and an increase in G(input), whereas electrical activity elicited by addition of tolbutamide was accompanied by reduced G(input). Increasing the concentration of glucose from 4 to 8-20 mM generated a noisy inward current at -70 mV, reflecting activation of the volume-sensitive anion channel. The mean amplitude of this current was glucose-dependent within the range 4-20 mM. Addition of 2-ketoisocaproate or a 15% hypotonic solution elicited similar increases in inward current. In contrast, addition of tolbutamide failed to induce the inward current. It is concluded that K(ATP) channel activity is most sensitive to glucose within the range 0-4 mM. At higher glucose concentrations effective in generating electrical activity, activation of the volume-sensitive anion channel could contribute towards the nutrient-induced increase in G(input).     

Fatty Acids Induce Chloride Permeation in Rat Liver Mitochondria by Activation of the Inner Membrane Anion Channel (IMAC)

The inner membrane of freshly isolated mammalian mitochondria is poorly permeable to Cl(-). Low, nonlytic concentrations (< or =30 microM) of long-chain fatty acids or their branched-chain derivatives increase permeation of Cl(-) as indicated from rapid large-scale swelling of mitochondria suspended in slightly alkaline KCl medium (supplemented with valinomycin). Myristic, palmitic, or 5-doxylstearic acid are powerful inducers of Cl(-) permeation, whereas lauric, phytanic, stearic, or 16-doxylstearic acid stimulate Cl(-) permeation in a lesser extent. Fatty acid-induced Cl(-) permeation across the inner membrane correlates well with the property of nonesterified fatty acids to release endogenous Mg(2+) from mitochondria. Myristic acid stimulates anion permeation in a selective manner, similar as was described for A23187, an activator of the inner membrane anion channel (IMAC). Myristic acid-induced Cl(-) permeation is blocked by low concentrations of tributyltin chloride (IC(50) approximately 1.5 nmol/mg protein). Moreover, myristic acid activates a transmembrane ion current in patch-clamped mitoplasts (mitochondria with the outer membrane removed) exposed to alkaline KCl medium. This current is best ascribed to the opening of an ion channel with a single-channel conductance of 108 pS. We propose that long-chain fatty acids can activate IMAC by withdrawal of Mg(2+) from intrinsic binding sites.     

Identification and modulation of a voltage-dependent anion channel in the plasma membrane of guard cells by high-affinity ligands.

Guard cell anion channels (GCAC1) catalyze the release of anions across the plasma membrane during regulated volume decrease and also seem to be involved in the targeting of the plant growth hormones auxins. We have analyzed the modulation and inhibition of these voltage-dependent anion channels by different anion channel blockers. Ethacrynic acid, a structural correlate of an auxin, caused a shift in activation potential and simultaneously a transient increase in the peak current amplitude, whereas other blockers shifted and blocked the voltage-dependent activity of the channel. Comparison of dose-response curves for shift and block imposed by the inhibitor, indicate two different sites within the channel which interact with the ligand. The capability to inhibit GCAC1 increases in a dose-dependent manner in the sequence: probenecid less than A-9-C less than ethacrynic acid less than niflumic acid less than IAA-94 less than NPPB. All inhibitors reversibly blocked the anion channel from the extracellular side. Channel block on the level of single anion channels is characterized by a reduction of long open transitions into flickering bursts, indicating an interaction with the open mouth of the channel. IAA-23, a structural analog of IAA-94, was used to enrich ligand-binding polypeptides from the plasma membrane of guard cells by IAA-23 affinity chromatography. From this protein fraction a 60 kDa polypeptide crossreacted specifically with polyclonal antibodies raised against anion channels isolated from kidney membranes. In contrast to guard cells, mesophyll plasma membranes were deficient in voltage-dependent anion channels and lacked crossreactivity with the antibody.     

An S-Type Anion Channel SLAC1 Is Involved in Cryptogein-Induced Ion Fluxes and Modulates Hypersensitive Responses in Tobacco BY-2 Cells

Pharmacological evidence suggests that anion channel-mediated plasma membrane anion effluxes are crucial in early defense signaling to induce immune responses and hypersensitive cell death in plants. However, their molecular bases and regulation remain largely unknown. We overexpressed Arabidopsis SLAC1, an S-type anion channel involved in stomatal closure, in cultured tobacco BY-2 cells and analyzed the effect on cryptogein-induced defense responses including fluxes of Cl⁻ and other ions, production of reactive oxygen species (ROS), gene expression and hypersensitive responses. The SLAC1-GFP fusion protein was localized at the plasma membrane in BY-2 cells. Overexpression of SLAC1 enhanced cryptogein-induced Cl⁻ efflux and extracellular alkalinization as well as rapid/transient and slow/prolonged phases of NADPH oxidase-mediated ROS production, which was suppressed by an anion channel inhibitor, DIDS. The overexpressor also showed enhanced sensitivity to cryptogein to induce downstream immune responses, including the induction of defense marker genes and the hypersensitive cell death. These results suggest that SLAC1 expressed in BY-2 cells mediates cryptogein-induced plasma membrane Cl⁻ efflux to positively modulate the elicitor-triggered activation of other ion fluxes, ROS as well as a wide range of defense signaling pathways. These findings shed light on the possible involvement of the SLAC/SLAH family anion channels in cryptogein signaling to trigger the plasma membrane ion channel cascade in the plant defense signal transduction network.     

Ion currents involved in early Nod factor response in Medicago sativa root hairs: a discontinuous single-electrode voltage-clamp study

Nod factor [NodRm-IV(Ac,S)], isolated from the bacterium Rhizobium meliloti, induces a well-known depolarization in Medicago sativa (cv Sitel) root hairs. Analysis of this membrane response using the discontinuous single-electrode voltage-clamp technique (dSEVC) shows that anion channel, K+ channel and H+-ATPase pump currents are involved in young growing root hairs. The early Nod-factor-induced depolarization is due to increase of the inward ion current and inhibition of the H+ pump. It involved an instantaneous inward anion current (IIAC) and/or a time-dependent inward K+ current (IRKC). These two ion currents are then down-regulated while the H+ pump is stimulated, allowing long-term rectification of the membrane potential (Em). Our results support the idea that the regulation of inward current plays a primary role in the Nod-factor-induced electrical response, the nature of the ions carried by these currents depending on the activated anion and/or K+ channels at the plasma membrane.     

Developmental regulation of a novel outwardly rectifying mechanosensitive anion channel in Caenorhabditis elegans

The nematode Caenorhabditis elegans offers unique experimental advantages for defining the molecular basis of anion channel function and regulation. However, the relative inaccessibility of somatic cells in adult animals greatly limits direct electrophysiological studies of channel activity. We developed methods to routinely isolate and patch clamp C. elegans embryo cells and oocytes and to culture and patch clamp neurons and muscle cells. Dissociated embryonic cells express a robust outwardly rectifying anion current that is activated by membrane stretch and depolarization. This current, termed I(Cl,mec), is inhibited by anion and mechanosensitive channel inhibitors. I(Cl,mec) has broad anion selectivity and the channel has a unitary conductance of 5-7 picosiemens. I(Cl,mec) is not detectable in whole-cell or isolated patch recordings from oocytes, cultured muscle cells, and cultured neurons but is expressed in single cell and later embryos. Channel density is high, and the current is observed in >80% of membrane patches. Macroscopic currents of 40-120 pA at +100 mV are typically observed in inside-out membrane patches formed using low resistance patch pipettes. Isolated membrane patches of early embryonic cells therefore contain 60-200 I(Cl,mec) channels. The apparent activation of I(Cl,mec) shortly after fertilization and its down-regulation in terminally differentiated cells suggests that the channel may play important roles in embryogenesis and/or cytokinesis.     

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.