Charybdotoxin blocks cation-channels in the vacuolar membrane of suspension cells of Chenopodium rubrum L.

Using the patch-clamp technique, we studied the action of charybdotoxin which blocks Ca(2+)-activated large-conductance K+ channels in animal tissue on the slow-activating (SV), Ca(2+)-activated cation channel in the vacuolar membrane of suspension-cells of Chenopodium rubrum L. The toxin reversibly reduced the vacuolar current with EC50 approximately 20 nM suggesting structural similarities between ion channels in animal and plant membranes.     

Calcium Retrieval from Vacuolar Pools (Characterization of a Vacuolar Calcium Channel)

Voltage patch-clamp experiments at the whole-vacuole and single-channel levels were employed to study the retrieval of Ca2+ from vacuoles into the cytoplasm in sugar beet cell (Beta vulgaris L.) suspension cultures. Channels allowing the movement of Ca2+ out of the vacuole were identified at physiological conditions of pH, vacuolar membrane potential, and vacuole/cytoplasm Ca2+ concentrations. The operation of the channel was voltage dependent and inositol-1,4,5-triphosphate insensitive and displayed high selectivity for Ca2+ ions. These channels bear similarities to the dihydropyridine-sensitive L-type Ca2+ channels from animal cells. Bay K-8644, an agonist, increased the frequency of channel openings, whereas nifedipine, an antagonist, reduced the channel activity. Both effects were elicited only from the vacuolar side of the channel. Channel activities were also inhibited by verapamil, La3+, and cytoplasmic Ca2+ concentrations higher than 1 x 10-6 M. The modulation of the channel currents by cytoplasmic Ca2+ would suggest the role of these channels in triggering the initiation of signal transduction processes in plant cells.     

膜片钳技术的新进展及其在药物高通量筛选中的应用

作为先进的细胞电生理技术,膜片钳一直被奉为研究离子通道的“金标准”。应用膜片钳技术可以证实细胞膜上离子通道的存在并能对其电生理特性、分子结构、药物作用机制等进行深入的研究。基因组学、蛋白质组学研究表明,以离子通道为靶标的药物研究在未来具有很大的发展空间。为了突破由于筛选技术所造成的针对离子通道为靶标的药物研发的瓶颈,近年来,对膜片钳技术进行了改进以适合药物高通量筛选的需求,由此产生了一些新的技术。本文就最近几年膜片钳技术的新进展及其在药物高通量筛选中的应用进行了综述。     

Distinct ion channel classes are expressed on the outer nuclear envelope of T- and B-lymphocyte cell lines

The outer nuclear membrane, endoplasmic reticulum, and mitochondrial membrane ion channels are poorly understood, although they are important in the control of compartmental calcium levels, cell division, and apoptosis. Few direct recordings of these ion channels have been made because of the difficulty of accessing these intracellular membranes. Using patch-clamp techniques on isolated nuclei, we measured distinct ion channel classes on the outer nuclear envelope of T-cell (human Jurkat) and BFL5 cell (murine promyelocyte) lines. We first imaged the nuclear envelopes of both Jurkat and FL5 cells with atomic force microscopy to determine the density of pore proteins. The nuclear pore complex was intact at roughly similar densities in both cell types. In patch-clamp recordings of Jurkat nuclear membranes, Cl channels (105 +/- 5 pS) predominated and inactivated with negative pipette potentials. Nucleotides transiently inhibited the anion channel. In contrast, FL5 nuclear channels were cation selective (52 +/- 2 pS), were inactivated with positive membrane potentials, and were insensitive to GTPgammaS applied to the bath. We hypothesize that T- and B-cell nuclear membrane channels are distinct, and that this is perhaps related to their unique roles in the immune system.     

Calcium-Activated K+ Channels and Calcium-Induced Calcium Release by Slow Vacuolar Ion Channels in Guard Cell Vacuoles Implicated in the Control of Stomatal Closure

Stomatal closing requires the efflux of K+ from the large vacuolar organelle into the cytosol and across the plasma membrane of guard cells. More than 90% of the K+ released from guard cells during stomatal closure originates from the guard cell vacuole. However, the corresponding molecular mechanisms for the release of K+ from guard cell vacuoles have remained unknown. Rises in the cytoplasmic Ca2+ concentration have been shown to trigger ion efflux from guard cells, resulting in stomatal closure. Here, we report a novel type of largely voltage-independent K+-selective ion channel in the vacuolar membrane of guard cells that is activated by physiological increases in the cytoplasmic Ca2+ concentration. These vacuolar K+ (VK) channels had a single channel conductance of 70 pS with 100 mM KCI on both sides of the membrane and were highly selective for K+ over NH4+ and Rb+. Na+, Li+, and Cs+ were not measurably permeant. The Ca2+, voltage, and pH dependences, high selectivity for K+, and high density of VK channels in the vacuolar membrane of guard cells suggest a central role for these K+ channels in the initiation and control of K+ release from the vacuole to the cytoplasm required for stomatal closure. The activation of K+-selective VK channels can shift the vacuolar membrane to more positive potentials on the cytoplasmic side, sufficient to activate previously described slow vacuolar cation channels (SV-type). Analysis of the ionic selectivity of SV channels demonstrated a Ca2+ over K+ selectivity (permeability ratio for Ca2+ to K+ of ~3:1) of these channels in broad bean guard cells and red beet vacuoles, suggesting that SV channels play an important role in Ca2+-induced Ca2+ release from the vacuole during stomatal closure. A model is presented suggesting that the interaction of VK and SV channel activities is crucial in regulating vacuolar K+ and Ca2+ release during stomatal closure. Furthermore, the possibility that the ubiquitous SV channels may represent a general mechanism for Ca2+-induced Ca2+ release from higher plant vacuoles is discussed.     

Using planar lipid-bilayers to study plant ion channels

Ion channels are found in most plant membranes. They catalyse the rapid passive uniport of particular ions with varying selectivity. Planar lipid-bilayer (PLB) techniques have been developed to study the electrical activities of single ion channels in well-defined lipid and aqueous environments. They greatly facilitate both the biophysical and biochemical characterisation of ion channels and complement both conventional impaling electrode and membrane-patch voltage-clamping (patch-clamping) electrophysiological techniques applied in vivo. Bilayers can be formed across the end of patch-clamp pipettes or across apertures in specifically designed chambers. Ion channels in native membranes and purified, genetically altered or synthetic ion channels, proteins and peptides can all be studied in PLBs. The main applications of PLBs are (1) to study ion channels in membranes inaccessible to patch-clamp electrodes, (2) to provide a functional assay system during channel-protein purification and (3) to investigate the relationship between the molecular structure of ion channels and their conductance properties. In the present article we describe the techniques available for reconstitution and analysis of ion channels in PLBs and discuss how the PLB technique has been, and may be, useful to the study of plant ion channels.     

Ionic conductances of squid giant fiber lobe neurons

The cell bodies of the neurons in the giant fiber lobe (GFL) of the squid stellate ganglion give rise to axons that fuse and thereby form the third-order giant axon, whose initial portion functions as the postsynaptic element of the squid giant synapse. We have developed a preparation of dissociated, cultured cells from this lobe and have studied the voltage-dependent conductances using patch-clamp techniques. This system offers a unique opportunity for comparing the properties and regional differentiation of ionic channels in somatic and axonal membranes within the same cell. Some of these cells contain a small inward Na current which resembles that found in axon with respect to tetrodotoxin sensitivity, voltage dependence, and inactivation. More prominent is a macroscopic inward current, carried by Ca2+, which is likely to be the result of at least two kinetically distinct types of channels. These Ca channels differ in their closing kinetics, voltage range and time course of activation, and the extent to which their conductance inactivates. The dominant current in these GFL neurons is outward and is carried by K+. It can be accounted for by a single type of voltage-dependent channel. This conductance resembles the K conductance of the axon, except that it partially inactivates during relatively short depolarizations. Ensemble fluctuation analysis of K currents obtained from excised outside-out patches is consistent with a single type of K channel and yields estimates for the single channel conductance of approximately 13 pS, independently of membrane potential. A preliminary analysis of single channel data supports the conclusion that there is a single type of voltage-dependent, inactivating K channel in the GFL neurons.     

Cytoplasmic chloride regulates cation channels in the vacuolar membrane of plant cells

Summary This study is concerned with the characterization of the ionic currents in the vacuolar membrane (tonoplast) of plant cells. Voltage patch-clamp experiments at the whole vacuole and single channel levels were employed to study the effects of cytoplasmic chloride on the tonoplast inward rectifying currents of sugar beet cultured cells. Whole vacuole experiments showed that removal of cytoplasmic chloride induced a decrease in the level of the inward currents, an effect that was reversed upon returning to control levels of cytoplasmic chloride. Substitution of cytoplasmic chloride by any other anion (organic or inorganic) resulted in a reduction in the level of the inward currents. At a given negative tonoplast potential, the inward currents showed a linear relationship with the concentration of cytoplasmic chloride between 10 and 100 mM, with the slope of these relationships increasing as the potential was made more negative. Single channel experiments showed that reduction of cytoplasmic chloride changed the gating mechanism of the channels without affecting the single channel conductance. Reduction of cytoplasmic chloride caused a decrease in the open probability of the tonoplast cation channels by reducing their mean open time and by inducing the appearance of an additional closed state.This work was supported by the National Science and Engineering Research Council of Canada.     

Sensitivity of the Plant Vacuolar Malate Channel to pH, Ca2+ and Anion-Channel Blockers

The organic anion malate is accumulated in the central vacuole of most plant cells. Malate has several important roles in plant vacuoles, such as the maintenance of charge balance and pH regulation, as an osmolyte involved in the generation of cell turgor, and as a storage form of CO2. Transport of malate across the vacuolar membrane is important for the regulation of cytoplasmic pH and the control of cellular metabolism, particularly in plants showing crassulacean acid metabolism (CAM), in which large fluxes of malate occur during the day/night cycle. By applying the patch-clamp technique, in the whole-vacuole configuration, to isolated vacuoles from leaf mesophyll cells of the CAM plant Kalancho? daigremontiana, we studied the regulation of the vacuolar malate channel by pH and Ca2+, as well as its sensitivity to anion-channel blockers. Malate currents were found to be insensitive to Ca2+ on the cytoplasmic side of the membrane over a range from approximately 10(-8) M to 10(-4) M. In contrast, decreasing cytoplasmic pH below 7.5 had a significant modulatory effect on channel activity, reducing malate currents by 40%, whereas increasing cytoplasmic pH above 7.5 resulted in no change in current. Several known Cl?-channel blockers inhibited the vacuolar malate currents: niflumic acid and indanoyloxyacetic acid (IAA-94) proved to be the most effective inhibitors, exerting half-maximal effects at concentrations of approximately 20 mM, suggesting that the plant vacuolar malate channel may share certain similarities with other classes of known anion channels.     

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

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

Heterogeneity of Volume-sensitive Chloride Channels in Basolateral Membranes of A6 Epithelial Cells in Culture

A new technique allowing single-channel patch-clamp recordings from basolateral membranes of A6 renal epithelial cells in culture was developed. Using this technique we studied the chloride channels activated in these basolateral membranes during hypo-osmotic stress. Four different types of channel were identified and classified according to their current/voltage (I/V) relationships as observed in the on-cell configuration of the patch-clamp technique. Three of these channels had linear I/V relationships with unitary conductances of 12, 30 and 42 pS. The fourth type had an outwardly rectifying I/V curve with inward and outward conductances of 16 and 57 pS respectively. The kinetic properties of each class of channel were studied and kinetic models developed for two of them: the 42 pS channel and the outward rectifier. These models permitted the study of the evolution of the kinetic parameters during hypo-osmotic shock and revealed two different kinetic schemes of channel activation. The results of experiments made on the basolateral membranes were also compared with those of a set of analogous patch-clamp experiments carried out on isolated A6 cells. In these latter, the frequency of successful observations of active channels in a patch was 13%, whereas it was 31% for basolateral membranes. Also, of the four types of channel observed in basolateral membranes, two were never found in isolated cells, only the 12 pS channel and the outward rectifier were present in these isolated cells. Received: 17 April 1996/Revised: 26 June 1996     

HIV-1 nef expression inhibits the activity of a Ca2+-dependent K+ channel involved in the control of the resting potential in CEM lymphocytes

The HIV-1 Nef protein plays an important role in the development of the pathology associated with AIDS. Despite various studies that have dealt with different aspects of Nef function, the complete mechanism by which it alters the physiology of infected cells remains to be established. Nef can associate with cell membranes, therefore supporting the hypothesis that it might interact with membrane proteins as ionic channels and modify their electrical properties. By using the patch-clamp technique, we found that Nef expression determines a 25-mV depolarization of lymphoblastoid CEM cells. Both charybdotoxin (CTX) and the membrane-permeable Ca2+ chelator BAPTA/AM depolarized the membrane of native cells without modifying that of Nef-transfected cells. These data suggested that the resting potential in native CEM cells is settled by a CTX- and Ca2+-sensitive K+ channel (KCa,CTX), whose activity is absent in Nef-expressing cells. This was confirmed by direct measurements of whole-cell KCa,CTX currents. Single-channel recordings on excised patches showed that a KCa,CTX channel of 35 pS with a half-activation near 400 nM Ca2+ was present in both native and Nef-transfected cells. The measurements of free intracellular Ca2+ were not different in the two cell lines, but Nef-transfected cells displayed an increased Ca2+ content in ionomycin-sensitive stores. Taken together, these results indicate that Nef expression alters the resting membrane potential of the T lymphocyte cell line by inhibiting a KCa,CTX channel, possibly by intervening in the regulation of intracellular Ca2+ homeostasis.     

K+ currents through SV-type vacuolar channels are sensitive to elevated luminal sodium levels

Non-selective slow vacuolar (SV) channels mediate uptake of K+ and Na+ into vacuolar compartment. Under salt stress plant cells accumulate Na+ in the vacuole and release vacuolar K+ into the cytoplasm. It is, however, unclear how plants mediate transport of K+ from the vacuole without concomitant efflux of toxic Na+. Here we show by patch-clamp studies on isolated Arabidopsis thaliana cell culture vacuoles that SV channels do not mediate Na+ release from the vacuole as luminal Na+ blocks this channel. Gating of the SV channel is dependent on the K+ gradient across the vacuolar membrane. Under symmetrical K+ concentrations on both sides of the vacuolar membrane, SV channels mediate potassium uptake. When cytoplasmic K+ decreases, SV channels allow K+ release from the vacuole. In contrast to potassium, Na+ can be taken up by SV channels, but not released even in the presence of a 150-fold gradient (lumen to cytoplasm). Accumulation of Na+ in the vacuole shifts the activation potential of SV channels to more positive voltages and prevents gradient-driven efflux of K+. Similar to sodium, under physiological conditions, vacuolar Ca2+ is not released from vacuoles via SV channels. We suggest that a major Arabidopsis SV channel is equipped with a positively charged intrinsic gate located at the luminal side, which prevents release of Na+ and Ca2+, but permits efflux of K+. This property of the SV channel guarantees that K+ can shuttle across the vacuolar membrane while maintaining Na+ and Ca2+ stored in this organelle.     

蚕豆气孔运动中水通道和离子通道的作用和地位的探讨

 用不同浓度HgCl2、LaCl3和TEACl (Tetraethylammonium chloride)处理蚕豆(Vicia faba)叶片下表皮条,发现HgCl2能显著抑制气孔开闭,Ca2+通道阻塞剂LaCl3或K+通道阻塞剂TEACl处理也都有一定程度的抑制。三者的作用效果HgCl2>>LaCl3>TEACl。用HgCl2+LaCl3、HgCl2+TEACl或HgCl2+LaCl3+TEACl处理,则气孔开闭运动几乎完全被抑制。表明：蚕豆气孔运动中,保卫细胞胀缩主要是水通道直接参与保卫细胞与叶肉细胞间水流的调节引起的,离子通道起间接次要作用,二者共同引起保卫细胞体积变化而导致气孔开闭。     

A novel Cl- inward-rectifying current in the plasma membrane of the calcifying marine phytoplankton Coccolithus pelagicus

We investigated the membrane properties and dominant ionic conductances in the plasma membrane of the calcifying marine phytoplankton Coccolithus pelagicus using the patch-clamp technique. Whole-cell recordings obtained from decalcified cells revealed a dominant anion conductance in response to membrane hyperpolarization. Ion substitution showed that the anion channels were selective for Cl(-) and Br(-) over other anions, and the sensitivity to the stilbene derivative 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid, ethacrynic acid, and Zn(2+) revealed a pharmacological profile typical of many plant and animal anion channels. Voltage activation and kinetic characteristics of the C. pelagicus Cl(-) channel are consistent with a novel function in plants as the inward rectifier that tightly regulates membrane potential. Membrane depolarization gave rise to nonselective cation currents and in some cases evoked action potential currents. We propose that these major ion conductances play an essential role in membrane voltage regulation that relates to the unique transport physiology of these calcifying phytoplankton.     

Characterization of an anion-permeable channel from sugar beet vacuoles: effect of inhibitors

The vacuole occupies 25-95% of the plant cell volume and plays an essential role in maintaining cytoplasmic homeostasis of nutrients and ions. Recent patch-clamp studies identified ion channels and electrogenic pumps as pathways for the movement of ions and metabolites across the vacuolar membrane (tonoplast). At high cytoplasmic Ca²⁺ (>10^-6 M) and negative potentials (inside the vacuole) non-selective channels of the `slow-vacuolar (SV)-type' were activated resulting in anion release or cation influx. In the present study these vacuolar channels were characterized pharmacologically by ion channel inhibitors. The cation-transport inhibitors Ba<sup>2+</sup>, TEA<sup>+</sup> and amiloride caused only partial and reversible block of the `SV-type'channels, whereas anion-transport inhibitors strongly affected the vacuolar channels. Pyridoxalphosphate and the dimethylaminecarboxylate derivates anthracene-9-carboxylic acid and C 144 reversibly blocked the channels up to 70% and Zncl₂ up to 95%. DIDS and SITS inhibited this channel irreversibly up to 95%. The block developed under a variety of experimental conditions using solutions containing combinations of permanent cations and anions. The DIDS binding site is located on the cytoplasmic surface of the tonoplast, as intravacuolar DIDS did not block the channels. DIDS concentrations in the micromolar range, efficient in blocking 70—80% of the `SV-type' channels did not significantly affect ATP-induced or pyrophosphate-induced proton-pumps. Stilbene derivatives may therefore be useful tools for studies on the substrate binding site on this vacuolar channel and for channel isolation.     

The patch clamp is more useful than anyone had expected

The patch clamp was developed into its present form by Neher and Sakmann for recording the currents through individual ionic channels in excitable membranes. Recent advances now allow the patch-clamp technique to be used to record from cell-free membrane patches and from entire small cells. The technique has been used extensively for recordings from single channels that have provided new insights into their functioning; it is also being applied to a surprising variety of other physiological problems.     

Ca2+ channels from brain microsomal membranes reconstituted in patch-clamped bilayers

Single Ca2+ channels from brain microsomal membranes were reconstituted in bilayers made at the tips of patch-clamp micropipettes. The single-channel conductance was defined to be 107 pS in 50 mM Ca2+. The channel activity was stimulated by nucleotides and inositol 1,4,5-trisphosphate (Ins-P3), and was inhibited by ruthenium red. Na+ added asymmetrically to the membrane bilayer induced an increase in the Ca2+-channel activity. The described characteristics of these Ca2+ channels suggest that they may be responsible for the Ca2+ transport across the membranes of the endoplasmic reticulum system triggering and modulating various neurosecretory and excitatory processes in nerve cells.     

Vacuolar calcium channels

The central vacuole is the largest Ca2+ store in a mature plant cell. Ca2+ release from this store contributes to Ca2+-mediated intracellular signalling in a variety of physiological responses. However, the routes for vacuolar Ca2+ release are not well characterized. To date, at least two voltage-dependent and two ligand-gated Ca2+-permeable channels have been reported in plant vacuoles. However, the so-called VVCa (vacuolar voltage-gated Ca2+) channel most probably is not a separate channel but is identical to another voltage-dependent channel-the so-called SV (slow vacuolar) channel. Studies in the last few years have added a new dimension to our knowledge of SV channel-mediated ion transport and the mechanisms of its regulation by multiple natural factors. Recently, the SV channel was identified as the product of the TPC1 gene in Arabidopsis. In contrast, the TPC1 channel from other species was thought to be localized in the plasma membrane. A re-evaluation of this work under the assumption that the TPC1 channel is generally a vacuolar channel provides interesting insights into the physiological function of the TPC1/SV channel. Considerably less is known about vacuolar Ca2+ channels that are supposed to be activated by inositol 1,4,5-trisphosphate or cADP ribose. The major problems are controversial reports about functional characteristics, and a remarkable lack of homologues of animal ligand-gated Ca2+ channels in higher plants. To help understand Ca2+-mediated intracellular signalling in plant cells, a critical update of existing experimental evidence for vacuolar Ca2+ channels is presented.     

Glutamate receptors in plants

Ionotropic glutamate receptors function in animals as glutamate-gated non-selective cation channels. Numerous glutamate receptor-like (GLR) genes have been identified in plant genomes, and plant GLRs are predicted, on the basis of sequence homology, to retain ligand-binding and ion channel activity. Non-selective cation channels are ubiquitous in plant membranes and may function in nutrient uptake, signalling and intra-plant transport. However, there is little evidence for amino acid gating of plant ion channels. Recent evidence suggests that plant GLRs do encode non-selective cation channels, but that these channels are not gated by amino acids. The functional properties of these proteins and their roles in plant physiology remain a mystery. The problems surrounding characterization and assignation of function to plant GLRs are discussed in this Botanical Briefing, and potential roles for GLR proteins as non-selective cation channels involved in metabolic signalling are described.