Time dependent K+ currents through plasmalemma of laticifer protoplasts from Hevea brasiliensis

The purpose of our work was to investigate the functioning of K⁺ channels in protoplasts of laticifers of Hevea brasiliensis Muell. Arg., anastomosed into a network devoid of large central vacuoles, after tapping stress. Physiological functions such as proton pump activity and uptake of sucrose (a rubber precursor) were maintained, when the voltage-clamp method was used in vivo to record the whole-cell K⁺ current during the stress response.
A time-dependent inward current was induced in 50 m M KCl and rapidly inactivated (about 100 ms). The activation potential of this inward K⁺ channel was not closely dependent on E_k. This would be coherent with the 'valve model' of Schroeder and Fang (1991, Proc. Natl. Acad. Sci. USA 88: 11583–11587) involving the activation of a H⁺-pump accounting for the K⁺ uptake observed in laticiferous cells under stress. The activation half-time of outward currents was clearly voltage dependent: from about 350 to 60 ms for 125 and 155 mV, respectively. Time-dependent outward current sensitivity to 5 m M BaCl₂ or CaCl₂ or to 5 μ M Erythrosin B showed that the K⁺ channels could be Ca²⁺-dependent. Because of the positive values of the activation potential of the outward current, the possibility opens that an action potential exists, these cells being specialized for stress response.     

Potassium ion channels in the plasmalemma

The potassium ion is an indispensible cytosolic component of living cells and a key osmolyte of plant cells, crossing the plasmalemma to drive physiological processes like cell growth and motor cell activity. K⁺ transport across the plasmalemma may be passive through channels, driven by the electrochemical gradient, K⁺ equilibrium potential (E_K) – membrane potential (V_m), or secondary active by coupling through a carrier to the inward driving force of H⁺ or Na⁺. Known K⁺ channels are permeable to monovalent cations, a permeability order being K⁺ > Rb⁺ > NH₄⁺ > Na⁺≥ Li⁺ > Cs⁺. The macroscopic K⁺ currents across a cell or protoplast surface commonly show rectification, i.e. a V^m-dependent conductance which in turn, may be controlled by the cytosolic activity of Ca²⁺, of K⁺, of H⁺, or by the K⁺ driving force. Analysis by the patch clamp technique reveals that plant K⁺ channels are similar to animal channels in their single channel conductance (4 to 100 pS), but different in that a given channel population slowly activates and may not inactivate at all. Single-channel kinetics reveal a broad range of open times (ms to s) and closed times (up to 100 s). Further progress in elucidating plant K⁺ channels will critically depend on molecular cloning, and the availability of channel-specific (phyto)toxins.     

Fast-activating cation channel in barley mesophyll vacuoles. Inhibition by calcium

In contrast to the vacuolar ion channels which are gated open by an increase of cytosolic Ca²⁺ the vacuolar ion currents at resting cytosolic Ca²⁺are poorly explored. Therefore, this study was performed to investigate the properties of the so-called fast-activating vacuolar (FV) current which dominates the electrical characteristics of the tonoplast at physiological free Ca²⁺ concentrations. Patch—clamp measurements were performed on whole barley ( Hordeum vulgare ) mesophyll vacuoles and on excised tonoplast patches. Single ion channels were identified, which, based on their selectivity, activation kinetics, Ca²⁺- and voltage-dependence, carry the whole-vacuole FV current. Reversal potential determinations indicated a K⁺ overs C⁻ permeability ratio of about 30. Both inward and outward whole-vacuole currents as well as the activity of single FV channels were inhibited by an increase of cytosolic Ca²⁺, with a K_d≈ 6 µM. At physiological vacuolar Ca²⁺ activities, the FV channel is an outward-rectifying potassium channel. The FV channel was activated in less than a few milliseconds both by negative and positive potential steps, having a minimal activity that is 40 mV negative of the K⁺ equilibrium potential. It is proposed that transport of K⁺ through this cation channel controls the electrical potential difference across the tonoplast.     

Potassium channels in barley: cloning, functional characterization and expression analyses in relation to leaf growth and development

It is not known how the uptake and retention of the key osmolyte K⁺ in cells are mediated in growing leaf tissue. In the present study on the growing leaf 3 of barley, we have cloned the full-length coding sequence of three genes which encode putative K⁺ channels ( HvAKT1 , HvAKT2 , HvKCO1 / HvTPK1 ), and of one gene which encodes a putative K⁺ transporter ( HvHAK4 ). The functionality of the gene products of HvAKT1 and HvAKT2 was tested through expression in Xenopus laevis oocytes. Both are inward-rectifying K⁺ channels which are inhibited by Cs⁺. Function of HvAKT1 in oocytes requires co-expression of a calcineurin-interacting protein kinase ( At CIPK23) and a calcineurin B-like protein (AtCBL9) from Arabidopsis , showing cross-species complementation of function. In planta , HvAKT1 is expressed primarily in roots, but is also expressed in leaf tissue. HvAKT2 is expressed particularly in leaf tissue, and HvHAK4 is expressed particularly in growing leaf tissue. Within leaves, HvAKT1 and HvAKT2 are expressed predominantly in mesophyll. Expression of genes changes little in response to low external K⁺ or salinity, despite major changes in K⁺ concentrations and osmolality of cells. Possible contributions of HvAKT1 , HvAKT2 , HvKCO1 and HvHAK4 to regulation of K⁺ relations of growing barley leaf cells are discussed.     

Mechanisms of potassium absorption by higher plant roots

Potassium, as a plant macronutrient, is accumulated in plant cells from relatively dilute soil solutions and is indispensable for many vital processes. Studies characterising potassium uptake by roots stretch back over many decades. However, it is only with the introduction of modern electrophysiological and molecular techniques that investigations have been possible at a molecular level. Such approaches have confirmed the existence of discrete high and low affinity uptake systems at the root plasma membrane and have greatly enhanced our understanding of the underlying molecular nature of these uptake systems.
High affinity K⁺ uptake from micromolar external K⁺ levels is coupled to H⁺ transport as demonstrated independently by patch clamping of single root protoplasts and by studying the transport system after expression in Xenopus oocytes . The measured coupling ratio between the two ions is 1:1 and is sufficient to account for an accumulation ratio in excess of 10⁶, a value which encompasses experimental observations on K⁺ accumulation.
Low affinity K⁺ uptake activates at relatively high external K⁺ levels in the millimolar range and is 'passive' i.e. down the electrochemical gradient for potassium. In two higher plant species single cell inward potassium currents have been identified which are associated with low affinity potassium uptake. Furthermore, specific ion channels which underlie these potassium influxes and form a major constituent of the low affinity potassium uptake pathway have been identified and characterised.     

Net Glutamate Release from Astrocytes Is Not Induced by Extracellular Potassium Concentrations Attainable in Brain

Abstract: Elevated extracellular potassium concentration ([K⁺]_e) has been shown to induce reversal of glial Na⁺-dependent glutamate uptake in whole-cell patch clamp preparations. It is uncertain, however, whether elevated [K⁺]_e similarly induces a net glutamate efflux from intact cells with a physiological intracellular milieu. To answer this question, astrocyte cultures prepared from rat and mouse cortices were incubated in medium with elevated [K⁺]_e (by equimolar substitution of K⁺ for Na⁺), and glutamate accumulation was measured by HPLC. With [K⁺]_e elevations to 60 m M , medium glutamate concentrations did not increase during incubation periods of 5–120 min. By contrast, 45 min of combined inhibition of glycolytic and oxidative ATP production increased medium glutamate concentrations 50–100-fold. Similar results were obtained in both rat and mouse cultures. Studies were also performed using astrocytes loaded with the nonmetabolized glutamate tracer d -aspartate, and parallel results were obtained; no increase in medium d -aspartate content resulted from [K⁺]_e elevation up to 90 m M , whereas a large increase occurred during inhibition of energy metabolism. These results suggest that a net efflux of glutamate from intact astrocytes is not induced by any [K⁺]_e attainable in brain.     

Effect of temperature on plasma membrane and tonoplast ion channels in Arabidopsis thaliana

The temperature dependence of the activity of ion channels was investigated, by means of the patch-clamp technique in the 'whole-cell' configuration, using protoplasts and vacuoles isolated form Arabidopsis thaliana L. cultured cells. The effect of temperature changes in the range 11–22°C was tested on the hyperpolarization and depolarization-activated K⁺ currents in the plasma membrane and on the hyperpolarization-activated K⁻ currents in the tonoplast (vacuolar membrane). All 3 kinds of currents were unaffected by increasing temperature up to 15°C and were activated between 15 and 20°C.     

Ethylene-induced putrescine accumulation modulates K+ partitioning between roots and shoots in barley seedlings

We investigated the cause and effect relationships among ethylene, polyamines, and K⁺ in barley ( Hordeum vulgare L. cv. Amagi) seedlings. Application of 1-aminocyclopropane-1-carboxylic acid (ACC), a precursor of ethylene, to the growth medium caused a decrease in K⁺ concentration in roots and an increase in shoots. Addition of ACC induced putrescine accumulation in roots, while spermidine and spermine levels remained unchanged. Exogenous supply of putrescine led to putrescine accumulation and reduced K⁺ concentration. Application of Co²⁺, an inhibitor of ethylene biosynthesis, together with ACC, inhibited putrescine accumulation with a decrease in K⁺ concentration in roots. ACC-treated roots showed K⁺ uptake capacity equivalent to that of control roots, implying that the majority of K⁺ is translocated to shoots. These results suggest that ethylene regulates K⁺ partitioning between roots and shoots through the level of accumulation of putrescine in barley seedlings.     

Elevated Levels of Glucose and L-Fucose Reduce 22Na+ Uptake and Whole Cell Na+ Current in Cultured Neuroblastoma Cells

Abstract: Na⁺ flux was studied in cultured neuroblastoma cells grown in medium containing increased glucose or L - fucose concentrations. Chronic exposure of neuroblastoma cells to 30 m M glucose or 30 m M L-fucose caused a decrease in ouabain-sensitive and veratridine-stimulated ²²Na⁺ uptake compared with cells cultured in unsupplemented medium. The Na⁺ current, determined by using whole-cell configuration of the patch clamp, was also decreased in these cells. Tetrodotoxin (3 μ M ), which blocked whole cell Na⁺ currents, also blocked veratridine-stimulated ²²Na⁺ accumulation. Culturing cells in medium containing 30 m M fructose as an osmotic control had no effect on Na⁺ flux. Specific [³H] saxitoxin binding was not affected by 30 m M glucose or 30 m M L-fucose compared with cells grown in unsupplemented medium, suggesting that the number of Na⁺ channels was not decreased. These studies suggest that exposing cultured neuronal cells to conditions that occur in the diabetic milieu alters Na⁺ transport and Na⁺-channel activity.     

Depolarization and Activation of Dihydropyridine-Sensitive Ca2+ Channels Stimulate Inositol Phosphate Accumulation in Photoreceptor-Enriched Chick Retinal Cell Cultures

Abstract: Elevated concentrations of extracellular K⁺ increased inositol phosphate accumulation in primary cultures of chick retinal photoreceptors and multipolar neurons. K⁺-evoked stimulation of inositol phosphate accumulation was greater in photoreceptor-enriched cell cultures than in cultures where multipolar neurons were the predominant cell type. Destroying multipolar neurons, but not photoreceptors, with kainic acid and N -methyl- d -aspartate did not reduce the K⁺-evoked stimulation of inositol phosphate accumulation. Both of these observations indicate that the observed effects occur in photoreceptor cells. The K⁺-evoked stimulation of inositol phosphate accumulation was blocked by omitting Ca²⁺ from the incubation medium or by adding the dihydropyridine-sensitive Ca²⁺-channel antagonists, nitrendipine and nifedipine. Bay K 8644, a dihydropyridine agonist, stimulated inositol phosphate accumulation and enhanced the effect of K⁺. ω-Conotoxin GVIA, an inhibitor of N-type Ca²⁺ channels, had no significant effect on K⁺-stimulated inositol phosphate accumulation. Pretreatment with pertussis toxin neither blocked K⁺-evoked inositol phosphate accumulation nor altered the inhibitory effect of nifedipine. K⁺-evoked inositol phosphate accumulation appears to reflect activation of phosphatidylinositol-specific phospholipase C, as it is inhibited by U-73122. These results indicate that Ca²⁺ influx through voltage-gated, dihydropyridine-sensitive channels activates phospholipase C in photoreceptor inner segments and/or synaptic terminals.     

A calcium influx precedes organogenesis in Graptopetalum

Abstract. An account is given of an investigation of net ionic currents and specific ion fluxes occuring during the initiation of organogenesis in detached leaves of Graptopetalum paraguayense E. Walther, in which a dramatic change in growth polarity is cytomorphologically evident 3–5 d after leaf detachment from the plant. Using the vibrating probe, it was possible to identify a peak of ionic current which is focused over the area of the leaf base where organogenesis is initiated. This net current is largest during the initial 12h after leaf detachment. With ion-selective microelectrodes capable of measuring H⁺, K⁺ and Ca²⁺ ion fluxes simultaneously in the same region of the leaf base, H⁺ and K⁺ fluxes remain relatively steady during the initial 24 h after detachment, while a large lanthanum-sensitive Ca²⁺ influx decreases by 50% from 2 to 12h. By 24h, Ca²⁺ transport is dominated by an efflux. We present evidence from a quantitative comparison of the ion current data collected using these two techniques, that Ca²⁺, H⁺ and K⁺ transport accounts for the major electrogenic ion fluxes during 2 and 12 but not 24 h after leaf detachment. The possibility is addressed that these ion currents, which precede organogenesis, and in particular the predominant Ca²⁺ flux, play a role in the establishment of growth polarity in higher plant tissues.     

Protein Phosphatase-1 Regulates Outward K+ Currents in Sensory Neurons of Aplysia californica

Abstract: The peptide neurotransmitter Phe-Met-Arg-PheNH₂ (FMRFamide) increases outward K⁺ currents and promotes dephosphorylation of many phosphoproteins in Aplysia sensory neurons. We examined FMRFamide-induced current responses in sensory neurons injected with thiophosphorylated protein phosphate inhibitor-1 and inhibitor-2 (I-1 and I-2), two structurally different vertebrate protein phosphatase-1 (PP1) inhibitors to define a role for PP1 in the physiological actions of FMRFamide. Thiophosphorylated I-1 and I-2 both reduced the amplitude of outward currents elicited by FMRFamide by 50–60% and were as effective as microcystin-LR, which inhibited both PP1 and protein phosphatase-2A in Aplysia neuronal extracts. These data suggested that of the two major neuronal protein serine/threonine phosphatases, FMRFamide utilized primarily PP1 to open serotonin-sensitive K⁺ (S-K⁺) channels. Earlier studies showed that a membrane-associated phosphatase regulated S-K⁺ channels in cell-free patches from sensory neurons. Utilizing its unique substrate specificity and inhibitor sensitivity, we have characterized PP1 as the principal protein phosphatase associated with neuronal plasma membranes. Two protein phosphatase activities (apparent M_r values of 170,000 and 38,000) extracted from crude membrane preparations from the Aplysia nervous system were shown to be isoforms of PP1. These biochemical and physiological studies suggest that PP1 is preferentially associated with neuronal membranes and that its activity may be required for the induction of outward K⁺ currents in the Aplysia sensory neurons by FMRFamide.     

Growth, contents of K+ and kinetics of K+(86Rb) uptake in barley cultured at different low supply rates of potassium

Plants of barley ( Hordeum vulgare L. cv. Salve) were grown with 6.5–35% relative increase of K⁺ supply per day (RKR) using a special computer-controlled culture unit. After a few days on the culture solution the plants adapted their relative growth rate (RGR) to the rate of nutrient supply. The roots of the plants remained in a low salt status irrespective of the rate of nutrient supply, whereas the concentration of K⁺ in shoots increased with RKR. Both V_max and K_m for K⁺(⁸⁶Rb) influx increased with RKR. It is concluded that with a continuous and stable K⁺ stress, the K⁺ uptake system is adjusted to provide an effective K⁺ uptake at each given RKR. Allosteric regulation of K⁺ influx does not occur and efflux of K⁺ is very small.     

Influence of exogenously supplied potassium and sodium salts on the abscisic acid-induced proline accumulation in barley leaf segments

A stimulation of the abscisic acid (ABA)-induced increase in proline was observed in leaf segments of barley ( Hordeum vulgare L. cv. Georgie) if K⁺ or Na⁺ were supplied in the external medium as salts of monovalent anions such as NO₃, Br, Cr and I, but not when sulphate or phosphate were used. To a lesser extent, the effect was evident also with RbCl, but it did not occur when chlorides of Li⁺. Cs⁺, NH₄⁺, Mg:⁺ and Ca²⁺ were used. Both KC1 and NaCl in the concentration range 2–100 m M influence the ABA-dependent proline accumulation to the same extent; the increase induced was about 100% at 10 m M , and reached a maximum between 60 and 100 m M. The effect is not due to the osmotic activity of the salts and does not seem to depend on changes in K⁺ and Na⁺ levels within the leaf tissue, but it is somehow linked to their external concentration. The existence of a specific interaction between ABA and K⁺ or Na⁺, possibly at the cell membrane level, is proposed.     

Potassium ion uptake by swelling Commelina communis guard cell protoplasts

Commelina communis L. guard cell protoplasts were induced to swell under low CO₂ conditions in the light while incubated in media containing KCl. Precise measurements of changes in the volume of the protoplasts were made including estimates of protoplast non-osmotic volume by Boyle-van't Hoff analysis. The amount of K⁺ which accumulated during the treatment was measured. The observed changes in osmotic volume could be accounted for by the uptake of K⁺ which appeared to be balanced by an anion or anions with an effective mean charge of – 1.63. The K⁺ flux rates occurring in guard cell protoplasts were sufficient to explain guard cell turgor regulation in vivo.     

Screening plants for salt tolerance by measuring K+ flux: a case study for barley

Development of salt-tolerant genotypes is central both to remediation of salinity-affected land and to meet increasing global food demand, which has been driving expansion of cropping into marginal areas. The bottleneck of any breeding programme is the lack of a reliable screening technique. This study tested the hypothesis that the ability of plants to retain K⁺ under saline conditions is central to their salt tolerance. Using seven barley cultivars contrasting in salt tolerance (CM72, Numar, ZUG293, ZUG95, Franklin, Gairdner, ZUG403), a comprehensive study was undertaken of whole-plant (growth rate, biomass, net CO₂ assimilation, chlorophyll fluorescence, root and leaf elemental and water content) and cellular (net fluxes of H⁺, K⁺, Na⁺ and Ca²⁺) responses to various concentrations of NaCl (20–320 m m ). Na⁺ selective microelectrodes were found to be unsuitable for screening purposes because of non-ideal selectivity of the commercially available Na⁺ LIX. At the same time, our results show very strong negative correlation between the magnitude of K⁺ efflux from the root and salt tolerance of a particular cultivar. K⁺ efflux from the mature root zone of intact 3-day-old seedlings following 40 min pretreatment with 80 m m NaCl was found to be a reliable screening indicator for salinity tolerance in barley. As a faster and more cost-effective alternative to microelectrode measurements, a procedure was developed enabling rapid screening of large numbers of seedlings, based on amount of K⁺ leaked from plant roots after exposure to NaCl.     

Hypoxia-Induced Catecholamine Release and Intracellular Ca2+ Increase via Suppression of K+ Channels in Cultured Rat Adrenal Chromaffin Cells

Abstract: Hypoxia (5% O₂) enhanced catecholamine release in cultured rat adrenal chromaffin cells. Also, the intracellular free Ca²⁺ concentration ([Ca²⁺]_i) increased within 3 min in ∼50% of the chromaffin cells under hypoxic stimulation. The increase depended on the presence of extracellular Ca²⁺. Nifedipine and ω-conotoxin decreased the population of the cells that showed the hypoxia-induced [Ca²⁺]_i increase, showing that the Ca²⁺ influx was attributable to L- and N-type voltage-dependent Ca²⁺ channels. The membrane potential was depolarized during the perfusion with the hypoxic solution and returned to the basal level following the change to the normoxic solution (20% O₂). Membrane resistance increased twofold under the hypoxic condition. The current-voltage relationship showed a hypoxia-induced decrease in the outward K⁺ current. Among the K⁺ channel openers tested, cromakalim and levcromakalim, both of which interact with ATP-sensitive K⁺ channels, inhibited the hypoxia-induced [Ca²⁺]_i increase and catecholamine release. The inhibitory effects of cromakalim and levcromakalim were reversed by glibenclamide and tolbutamide, potent blockers of ATP-sensitive K⁺ channels. These results suggest that some fractions of adrenal chromaffin cells are reactive to hypoxia and that K⁺ channels sensitive to cromakalim and glibenclamide might have a crucial role in hypoxia-induced responses. Adrenal chromaffin cells could thus be a useful model for the study of oxygen-sensing mechanisms.     

Paradoxical effect of ethanol on potassium channel currents and cell survival in cerebellar granule neurons

Transient exposure to ethanol (EtOH) results in a massive neurodegeneration in the developing brain leading to behavioral and cognitive deficits observed in fetal alcohol syndrome. There is now compelling evidence that K⁺ channels play an important role in the control of programmed cell death. The aim of the present work was to investigate the involvement of K⁺ channels in the EtOH-induced cerebellar granule cell death and/or survival. At low and high concentrations, EtOH evoked membrane depolarization and hyperpolarization, respectively. Bath perfusion of EtOH (10 mM) depressed the I _A (transient K⁺ current) potassium current whereas EtOH (400 mM) provoked a marked potentiation of the specific I _K (delayed rectifier K⁺ current) current. Pipette dialysis with GTPγS or GDPβS did not modify the effects of EtOH (400 mM) on both membrane potential and I _K current. In contrast, the reversible depolarization and slowly recovering inhibition of I _A induced by EtOH (10 mM) became irreversible in the presence of GTPγS. EtOH (400 mM) induced prodeath responses whereas EtOH (10 mM) and K⁺ channel blockers promoted cell survival. Altogether, these results indicate that in cerebellar granule cells, EtOH mediates a dual effect on K⁺ currents partly involved in the control of granule cell death.     

Few cultured rat primary sensory neurons express a tolbutamide-sensitive K+ current

The response of dorsal root ganglion (DRG) neurons to metabolic inhibition is known to involve calcium-activated K⁺ channels; in most neuronal types ATP-sensitive K⁺ channels (K_ATP) also contribute, but this is not yet established in the DRG. We have investigated the presence of a K_ATP current using whole-cell recordings from rat DRG neurons, classifying the neurons functionally by their "current signature" (Petruska et al, J Neurophysiol 84: 2365–2379, 2000). We clearly identified a K_ATP current in only 1 out of 62 neurons, probably a nociceptor. The current was activated by cyanide (2 mM NaCN) and was sensitive to 100 μM tolbutamide; the relation between reversal potential and external K⁺ concentration indicated it was a K⁺ current. In a further two neurons, cyanide activated a K⁺ current that was only partially blocked by tolbutamide, which may also be an atypical K_ATP current. We conclude that K_ATP channels are expressed in normal DRG, but in very few neurons and only in nociceptors.     

Antibodies Against Rat Brain Vesicle-Associated Membrane Protein (Synaptobrevin) Prevent Inhibition of Acetylcholine Release by Tetanus Toxin or Botulinum Neurotoxin Type B

Abstract: The Shaw-type K⁺ channel K_v3.1 was stably transfected in human embryonic kidney cells. Voltage dependence of activation, K⁺ permeability, sensitivity to external tetraethylammonium, and unitary conductance were similar to K_v 3.1 channels expressed transiently in Xenopus oocytes. K_v 3.1 channels appear to be regulated because the protein kinase C activator phorbol 12,13-dibutyrate decreased K_v 3.1 currents. Based on these results, we find that the stable expression of voltage-gated K⁺ channels in human embryonic kidney cells appears to be well suited for analysis of both biophysical and biochemical regulatory processes.