Effects of host-specific toxins on electropotentials of plant cells

Host-specific toxins from Helminthosporium victoriae (HV) and Periconia circinata (PC) caused gradual decreases in the negative electropotentials of single cells of susceptible but not of resistant plants. When tissues were held in a standard nutrient solution, the decrease (depolarization) induced by HV toxin was approximately 50 mv/hr; the decrease induced by PC toxin was even more gradual. Changes in ion efflux were detected before changes in electropotential. In contrast, toxin from H. carbonum caused a rapid but transient increase in negative electropotential of cells. Carbonyl cyanide m-chlorophenylhydrazone, which (like other metabolic inhibitors) blocks electrogenic pumps, caused cell electropotentials to decrease by approximately 50 mv within a few minutes. This suggests that HV and PC toxins do not have direct effects on electrogenic pumps, but do affect passive efflux of ions, or electrically neutral ion exchange systems, across the plasma membrane.     

Influence of Phenolic Acids on Ion Uptake: IV. Depolarization of Membrane Potentials

The membrane potentials of aged, excised barley (Hordeum vulgare L.) root cells were rapidly depolarized by the addition of salicylic acid (o-hydroxybenzoic acid) to the buffered medium bathing root segments. Initial values for membrane potentials were restored very slowly (within 100 minutes) by replacing the phenolic solution by phenolic-free buffer. Several other naturally occurring benzoic and cinnamic acids depolarized cell membrane potentials. The cinnamic acids consistently caused a greater depolarization than the correspondingly substituted benzoic acids. A strong positive correlation was found between the depolarization values (ΔE) for the benzoic acids and their lipid solubilities. This study supports the hypothesis that the inhibition of ion uptake brought about by naturally occurring phenolic acids is caused by a generalized increase in membrane permeability to inorganic ions.     

Effect of cyanide on the plasmalemma potential of mnium

By centrifuging Mnium cuspidatum leaf cells, the cytoplasm can be distinguished from the vacuole and a microelectrode tip can be located unambiguously in the cytoplasm. The site of the electrogenic pump is clearly demonstrated to reside in the plasmalemma as shown by depolarization of the cell electropotential induced by CN⁻.     

The electrical response of Phaseolus vulgaris roots to abrupt exposure to hydroquinone

Previous reports have suggested the primary mode of action of the allelochemical hydroquinone involves disruption of root cell membrane transport. Here we report the effects of hydroquinone on common bean (Phaseolus vulgaris) plants. Growth of leaves, roots and stems were all inhibited by 14 day exposure to 0.01 mM or 0.25 mM hydroquinone. Chlorophyll fluorescence (Fv/Fm) was inhibited by 0.25 mM hydroquinone. The membrane potential of P. vulgaris root cortex cells briefly hyperpolarized and subsequently slowly transiently depolarized upon abrupt exposure to a range of hydroquinone concentrations. Both the hyperpolarization and depolarization were concentration dependent but appeared saturable. Root cells exposed to 0.03 mM hydroquinone hyperpolarized 3.4 mV (+/− 0.6 s.e.) 3 minutes after the start of exposure then depolarized 36.7 mV (+/− 3.9) with no effect evident after 24 hours. Individual recordings showed a response to as little as 0.001 mM hydroquinone. Exposure of P. vulgaris root cells to arbutin, a nontoxic monoglucoside of hydroquinone, produced a similar but much smaller (approximately 25%) electrical response. Exposure of root cells of Antennaria microphylla, a known allelopathic source (donor plant) of hydroquinone, also produced a much smaller hyperpolarization and depolarization response. It is concluded that the electrical response to hydroquinone by P. vulgaris root cells and the changes in membrane transport they represent are not sufficiently large or long lasting enough to disrupt mineral and water uptake leading to plant injury. The possibility, however, that these events are related to initiation of signal transduction events leading to cell death is discussed.Key words: allelopathy, hydroquinone, membrane potential, depolarization, hyperpolarization, Phaseolus vulgaris, Antennaria microphylla     

Effects of fusaric Acid on tomato root hair membrane potentials and ATP levels

Using standard microelectrode techniques, we measured the effects of fusaric acid (FA) on the membrane potential of tomato (Lycopersicon esculentum Mill. cv New Yorker 870) incipient root hair cells. At pH 5.3, FA caused a hyerpolarization, the magnitude of which increased with FA concentrations from 0.05 to 0.50 millimolar. A depolarization followed, the rate and magnitude of which increased with the concentration of FA and exposure to FA. Partial repolarizations occurred after exposures to 1.0 millimolar FA for less than 8 to 10 minutes, after longer exposures to lower FA concentrations, or after longer exposures to 1.0 millimolar FA in a less concentrated nutrient solution. The amount of ATP in tomato root tips decreased by about 85% after incubation for 80 min in 1.0 millimolar FA.

At pH 7.2 and 8.2, the depolarization caused by an 8-minute exposure to 1.0 millimolar FA was immediate and much more rapid than at pH 5.2 and 6.3, but its magnitude was not as great. At pH 6.3, 7.2, and 8.2, the depolarization was at least partially reversible. The data are consistent with FA having at least three effects that elicited changes in tomato root cell electrical potential differences between the cell's interior and the external solution.

     

Effects of diclofop and diclofop-methyl on membrane potentials in roots of intact oat, maize, and pea seedlings

Growth and electrophysiological studies in roots of intact diclofop-methyl susceptible and resistant seedlings were conducted to test the hypothesis that the herbicide acts primarily as a proton ionophore. The ester formulation of diclofop, at 0.2 micromolar, completely inhibited root growth in herbicide-susceptible oat (Avena sativa L.) after a 96 hour treatment, but induced only a delayed transient depolarization of the membrane potential in oat root cortical cells. Root growth in susceptible maize (Zea mays L.) seedlings was dramatically reduced by exposure to 0.8 micromolar diclofop-methyl, while the same diclofop-methyl exposure hyperpolarized the membrane potential within 48 hours after treatment. Furthermore, exposure of maize roots to the protonophore, carbonyl cyanide m-chlorophenylhydrazone (CCCP) (50 nanomolar), inhibited growth by only 31%, 96 hours after treatment, while the same CCCP exposure depolarized the resting potential by an average of 32 millivolts. Thus, the protonophore hypothesis cannot account for a differential membrane response to phytotoxic levels of diclofop-methyl in two susceptible species. From the results of others, much of the evidence to support the protonophore hypothesis was obtained using high concentrations of diclofop acid (100 micromolar). At a similar concentration, we also report a rapid (3 minute) diclofop-induced depolarization of the membrane potential in roots of susceptible oat and maize, moderately tolerant barley (Hordeum vulgare L.), and resistant pea (Pisum sativum L.) seedlings. Moreover, 100 micromolar diclofop acid inhibited growth in excised cultured pea roots. In contrast, 100 micromolar diclofop-methyl did not inhibit root growth. Since the membrane response to 100 micromolar diclofop acid does not correspond to differential herbicide sensitivity under field conditions, results obtained with very high levels of diclofop acid are probably physiologically irrelevant. The results of this study suggest that the effect of diclofop-methyl on the membrane potentials of susceptible species is probably unrelated to the primary inhibitory effect of the herbicide on plant growth.     

Effect of benzoic acid hydroxyl- and methoxy-ring substituents on cucumber (Cucumis sativus L.) root membrane potential

Abstract

The allelopathic effect of some benzoic acid (BA) OH- and OCH₃-ring substituents was studied on cucumber root transmembrane potential difference (Vm). Most of the methoxy-BAs induced a rapid Vm depolarization, followed by a Vm hyperpolarization, with the only exception for p-anisic acid (pA). On the other hand, salicylic acid (SA) and 3,4-dimethoxybenzoic acid (DHB) strongly depolarized Vm. A positive correlation was found between Vm hyperpolarization and lipophilicity of methoxylated BAs, whereas a positive correlation was found between lipophilicity and Vm depolarization of hydroxylated BAs. The influence of BAs on K⁺ was studied by means of specific blocking with Cs⁺ indicating a possible direct interaction of SA, gallic acid (GA), vanillic acid (VA) and 3,4-dimethoxybenzoic acid (DMB). Interference of BAs with the Vm hyperpolarizing effect of root perfusion with the fungal toxin fusicoccin were also observed.     

Effect of Salinity upon Cell Membrane Potential in the Marine Halophyte, Salicornia bigelovii Torr

The electrophysiology of root cells of the marine halophyte, Salicornia bigelovii Torr., has been investigated. Cellular concentrations of K⁺, Cl⁻, and Na⁺ and resulting cell membrane potentials were determined as functions of time and exposure to dilutions of artificial seawater. Treatment of these data by the Nernst criterion suggests that Cl⁻ is actively transported into these root cells, but that active transport need not be invoked to explain the accumulation of Na⁺ at all salinities investigated nor for K⁺ at moderate to high salinities. In low environmental salinity, the cell electropotential of Salicornia root cells was found to respond to inhibitors in a fashion similar to that observed in glycophytes; in high environmental salinity, root cell membrane potential appears to be insensitive to bathing salinity and m-chlorocarbonylcyanide phenylhydrazone induces membrane hyperpolarization, in contrast to the response of glycophytes to such treatments. The fact that measured membrane potentials exceed diffusion potentials for Na⁺, K⁺, and Cl⁻ and the observation of a rapid depolarization by CO in the dark suggests an electrogenic component in Salicornia root cell membrane potentials.     

Electrical Membrane Properties of Leaves, Roots, and Single Root Cap Cells of Susceptible Avena sativa: Effect of Victorin C

The effect of the purified host-selective toxin victorin C, a cyclized penta peptide, was compared to that of CCCP and vanadate on membrane functions of susceptible leaves, roots, and single root cap cells of Avena sativa with conventional electrophysiology. The plasmalemma depolarized irreversibly by about 80 millivolts and to below the diffusion potential within 1 hour. Concentrations as low as 12.5 picomolar were effective in the susceptible but not the resistant cultivar. Electrical membrane potential difference changes were independent of pH and could not be prevented by fusicoccin or Ca²⁺. Membranes began to depolarize after a lag phase that never was shorter than 6.5 minutes, even with concentrations as high as 1.25 micromolar. Membrane depolarization was accompanied by a distinct decrease in specific membrane resistance from 4.5 to 1.0 ohm times square meter on average. These changes were followed by K⁺ and Cl⁻ efflux and extracellular alkalinization. ATP level and O₂ uptake did not decrease within 2 hours. It is concluded that the victorin-induced deleterious membrane alterations are not caused by direct interaction with the plasmalemma H⁺-ATPase, K⁺ channels, lipid structure, nor energy metabolism, but they seem to be triggered by a cascade of events leading to an unspecific increase in membrane permeability.     

Anomalous Effect of Permeant Ion Concentration on Peak Open Probability of Cardiac Na+ Channels

Human heart Na⁺ channels were expressed transiently in both mammalian cells and Xenopus oocytes, and Na⁺ currents measured using 150 mM intracellular Na⁺. Decreasing extracellular permeant ion concentration decreases outward Na⁺ current at positive voltages while increasing the driving force for the current. This anomalous effect of permeant ion concentration, especially obvious in a mutant (F1485Q) in which fast inactivation is partially abolished, is due to an alteration of open probability. The effect is only observed when a highly permeant cation (Na⁺, Li⁺, or hydrazinium) is substituted for a relatively impermeant cation (K⁺, Rb⁺, Cs⁺, N -methylglucamine, Tris, choline, or tetramethylammonium). With high concentrations of extracellular permeant cations, the peak open probability of Na⁺ channels increases with depolarization and then saturates at positive voltages. By contrast, with low concentrations of permeant ions, the open probability reaches a maximum at approximately 0 mV and then decreases with further depolarization. There is little effect of permeant ion concentration on activation kinetics at depolarized voltages. Furthermore, the lowered open probability caused by a brief depolarization to +60 mV recovers within 5 ms upon repolarization to −140 mV, indicative of a gating process with rapid kinetics. Tail currents at reduced temperatures reveal the rapid onset of this gating process during a large depolarization. A large depolarization may drive a permeant cation out of a site within the extracellular mouth of the pore, reducing the efficiency with which the channel opens.     

Relation between Membrane Potential Changes and Tension in Barnacle Muscle Fibers

Constant current pulses have been applied to single muscle fibers of the barnacle, Balanus nubilus Darwin, with an axial metal electrode. The membrane potential change, which took place over a large part of the muscle fiber, was measured with a similar electrode. Depolarizing pulses, if the voltage was greater than threshold, produced tension. The size of the tension was a function of the magnitude and the duration of the depolarizing pulses. The latency between the onset of depolarization and tension can be only in part attributable to mechanical factors. AC stimulation produced tension, but 5 to 10 seconds were required for the steady-state level of the tension to be reached. Muscles were depolarized in elevated K and studied after the contracture had terminated. If not too depolarized, further depolarization produced tension. Termination of hyperpolarizing pulses also produced tension, which decayed quite slowly. Hyperpolarizing pulses reduced, or abolished, any preexisting tension. Thus, it appears that at certain values of the membrane potential tension is set up, but there is also a slow process of accommodation present.     

Transmembrane electropotential in barley roots as related to cell type, cell location, and cutting and aging effects

Transmembrane electropotential difference (PD) was measured in whole roots of barley (Hordeum vulgare L. cvs. Compana and Himalaya). Seedlings were grown 4 to 5 days in aerated 0.5 mm CaSO(4) or a nutrient solution. Measurements of PD were made with roots bathed in CaSO(4), KCl + CaSO(4), or the nutrient solution. The following results were found. (a) There was a radial PD gradient with epidermal cells being 10 to 58 millivolts less negative than cells in the third layer of the cortex (outside to inside). There was no longitudinal PD gradient in the region 0.5 to 4 cm from the root tip, nor was there any difference between the PD of young root hairs and other epidermal cells. (b) Cell PD in excised whole roots was not detectably different from that found in roots attached to the shoot, and was unchanged for 2 hours from excision. (c) In 1-centimeter sections of root, cell PD at the freshly cut surface was depolarized by 90 millivolts from that in the intact root; cells farther than 1 millimeter from the cut surface were not depolarized. The PD of cells at the cut surface became more negative upon aging the segment in 0.5 mm CaSO(4), eventually becoming greater by -25 millivolts than that in cells of intact roots. Cells in segments to which the root tips were attached had less negative PDs after aging than those in subapical segments, indicating a possible hormonal effect. PDs in aged, excised segments are not equivalent to those in intact roots. (d) Creeping of cytoplasm over electrode tips inserted into the vacuole gave measurements of vacuole-to-cytoplasm PD of + 9 millivolts in 0.5 mm CaSO(4) and + 35 millivolts in 1 mm KCl + 0.5 mm CaSO(4). Most of the cell PD was across the plasmalemma. (e) The reducing sugar content of roots in CaSO(4) solution was greater than that of roots in the nutrient solution in which ion uptake, particularly K(+) occurred.     

Prolonged membrane potential depolarization in cingulate pyramidal cells after digit amputation in adult rats

The anterior cingulate cortex (ACC) plays an important role in higher brain functions including learning, memory, and persistent pain. Long-term potentiation of excitatory synaptic transmission has been observed in the ACC after digit amputation, which might contribute to plastic changes associated with the phantom pain. Here we report a long-lasting membrane potential depolarization in ACC neurons of adult rats after digit amputation in vivo. Shortly after digit amputation of the hind paw, the membrane potential of intracellularly recorded ACC neurons quickly depolarized from ~-70 mV to ~-15 mV and then slowly repolarized. The duration of this amputation-induced depolarization was about 40 min. Intracellular staining revealed that these neurons were pyramidal neurons in the ACC. The depolarization is activity-dependent, since peripheral application of lidocaine significantly reduced it. Furthermore, the depolarization was significantly reduced by a NMDA receptor antagonist MK-801. Our results provide direct in vivo electrophysiological evidence that ACC pyramidal cells undergo rapid and prolonged depolarization after digit amputation, and the amputation-induced depolarization in ACC neurons might be associated with the synaptic mechanisms for phantom pain.     

Electropotential in excised pea epicotyls

In contrast to intact etiolated pea seedling tissue (Pisum sativum L.), excised segments immersed in a complete nutrient solution show marked increases in ion content, largely of K⁺ and NO₃⁻, over a 72-hour period. During this time there is increase in cell electropotential difference, PD. During the initial 6 to 8 hours there is a lag in ion uptake; cell PD, however, increases rapidly from approximately −50 to −100 mv then increases more slowly. The increase in PD precedes and thus may be a prerequisite for the rapid ion accumulation phase. Cell PD increases in either water or nutrient solution but eventually reaches higher levels in the latter. Following water pretreatment of sufficient duration K⁺ accumulation shows no lag period. The lag phase noted here appears dissimilar to that of storage tissues.     

Sequential depolarization of root cortical and stelar cells induced by an acute salt shock - implications for Na(+) and K(+) transport into xylem vessels

Early events in NaCl-induced root ion and water transport were investigated in maize (Zea mays L) roots using a range of microelectrode and imaging techniques. Addition of 100 mm NaCl to the bath resulted in an exponential drop in root xylem pressure, rapid depolarization of trans-root potential and a transient drop in xylem K(+) activity (A(K+) ) within ～1 min after stress onset. At this time, no detectable amounts of Na(+) were released into the xylem vessels. The observed drop in A(K+) was unexpected, given the fact that application of the physiologically relevant concentrations of Na(+) to isolated stele has caused rapid plasma membrane depolarization and a subsequent K(+) efflux from the stelar tissues. This controversy was explained by the difference in kinetics of NaCl-induced depolarization between cortical and stelar cells. As root cortical cells are first to be depolarized and lose K(+) to the environment, this is associated with some K(+) shift from the stelar symplast to the cortex, resulting in K(+) being transiently removed from the xylem. Once Na(+) is loaded into the xylem (between 1 and 5 min of root exposure to NaCl), stelar cells become more depolarized, and a gradual recovery in A(K+) occurs.     

Hesperidin depolarizes the pacemaker potentials through 5-HT4 receptor in murine small intestinal interstitial cells of Cajal

ABSTRACT

Hesperidin, a citrus flavonoid, can exert numerous beneficial effects on human health. Interstitial cells of Cajal (ICC) are pacemaker cells in the gastrointestinal (GI) tract. In the present study, we investigated potential effects of hesperidin on pacemaker potential of ICC in murine small intestine and GI motility. A whole-cell patch-clamp configuration was used to record pacemaker potential in ICC, and GI motility was investigated in vivo by recording gastric emptying (GE) and intestinal transit rate (ITR). Hesperidin depolarized pacemaker potentials of ICC in a dose-dependent manner. Pre-treatment with methoctramine or 4-DAMP did not inhibit hesperidin-induced pacemaker potential depolarization. Neither a 5-HT₃ receptor antagonist (Y25130) nor a 5-HT₇ receptor antagonist (SB269970) reduced the effect of hesperidin on ICC pacemaker potential, whereas the 5-HT₄ receptor antagonist RS39604 was found to inhibit this effect. In the presence of GDP–β–S, hesperidin-induced pacemaker potential depolarization was inhibited. Moreover, in the presence of U73122 and calphostin C, hesperidin did not depolarize pacemaker potentials. Furthermore, hesperidin accelerated GE and ITR in vivo. These results imply that hesperidin depolarized ICC pacemaker potential via 5-HT₄ receptors, G protein, and PLC/PKC dependent pathways and that it increased GI motility. Therefore, hesperidin may be a promising novel drug to regulate GI motility.     

Purification and properties of soluble cytoplasmic toxin from the mosquito pathogen Bacillus sphaericus strain 1593

Soluble cytoplasmic toxin from broken Bacillus sphaericus 1593 sporulating cells was partially purified by ammonium sulfate precipitation, ion exchange, and gel filtration chromatography. Purification was monitored by electrophoresis. The toxin remained active after incubation in the presence of several enzymes and in buffers from pH 6 to 10, but was destroyed by Pronase and subtilisin, and by heating to 80°C for 30 min. Results indicate that the B. sphaericus 1593 cytoplasm contains a single proteinaceous toxin with a molecular weight of 100,000 daltons.     

Voltage-sensitive chloride ion channels in Anopheles gambiae Sua-1B cells

In this study, we performed electrophysiological analysis of Anopheles gambiae Sua-1B cells having “neuron-like” morphologies using the patch clamp method. The recorded cells (n = 79) had processes resembling axons/dendrites, with 63 % unipolar, 22 % bipolar, and 15 % multipolar. While no inward currents were observed following step depolarizations (holding potential = ?80 mV), a slowly activating outward current was observed in 96 % of the cells, especially at depolarized potentials. The amplitude of the current was attenuated nearly 70 % by reducing extracellular Cl^? ion concentration, or by incubating with 100 μM DIDS, a known voltage-sensitive chloride channel blocker, suggesting that the current was mediated by chloride ions. No qualitative difference was found between recordings made with Cs⁺ ions in the intracellular pipette solution (inhibits K⁺ currents) and those made with normal physiological solution, indicating a deficiency of potassium channels. Additionally, recordings made with Ca²⁺-free extracellular bath solution eliminated the slowly activating outward current. A subset of cells (n = 3) lacked this current, but had outward currents with voltage-dependent properties similar to those of volume-regulated chloride channels. Taken together, our results suggest that the voltage-sensitive currents observed in the majority of Sua-1B cells are mediated primarily by chloride channels of the calcium-dependent subtype.     

Effects of Inhibitors on the Light-Induced Changes in Electric Potential in Pulvinar Motor Cells of Phaseolus vulgaris L.

To analyze the mechanism of the light-induced changes in electricpotential in motor cells of the pulvinus of Phaseolus vulgarisL., inhibitors were applied to the pulvinus by the xylem perfusionmethod. The membrane potential was –60 to –80 mV,which indicated that the polarization was less than that ofcells of a pulvinus in air. A pulse (30 s) of blue light (BL)induced transient depolarization of the membrane in the motorcells. Red light (RL) caused hyperpolarization of the membrane.The magnitude of BL pulse-induced transient depolarization wasgreater under the hyperpolarized state caused by the RL. The membrane was depolarized to –30 to –40 mV onperfusion with the respiratory inhibitor NaN₃ (1 mM) and a pulseof BL or irradiation with RL did not cause any change in thepotential in the depolarized state. Hyperpolarization of themembrane by RL was inhibited by perfusion with DCMU (50 µM),an inhibitor of electron transport in photosynthesis. However,the magnitude of the depolarization induced by the pulse ofBL was not affected. Perfusion with a proton ionophore CCCP(100µM) depolarized the membrane and no change in thepotential was induced by a pulse of BL or by RL in the depolarizedstate. The extent of the BL pulse-induced depolarization of the membranewas proportional to the magnitude of the membrane potentialat the time of which the pulse of BL was applied. It is suggestedthat the active component of the membrane potential was inhibitedby the pulse of BL. The experimental results further supportthe hypothesis that BL inhibits the activity of the proton ATPaseand, thus, causes loss of the electrogenic component of themembrane potential of the pulvinar motor cells. (Received June 22, 1992; Accepted August 24, 1992)     

Glutamate Oxaloacetate Transaminase in Pea Root Nodules : Participation in a Malate/Aspartate Shuttle between Plant and Bacteroid

Glutamate oxaloacetate transaminase (l-glutamate: oxaloacetate aminotransferase, EC 2.6.1.1 [GOT]), a key enzyme in the flow of carbon between the organic acid and amino acid pools in pea (Pisum sativum L.) root nodules, was studied. By ion exchange chromatography, the presence of two forms of GOT in the cytoplasm of pea root nodule cells was established. The major root nodule form was present in only a small quantity in the cytoplasm of root cells. Fractionation of root nodule cell extracts demonstrated that the increase in the GOT activity during nodule development was due to the increase of the activity in the cytoplasm of the plant cells, and not to an increase in activity in the plastids or in the mitochondria. The kinetic properties of the different cytoplasmic forms of GOT were studied. Some of the K_m values differed, but calculations indicated that not the kinetic properties but a high concentration of the major root nodule form caused the observed increase in GOT activity in the pea root nodules. It was found that the reactions of the malate/aspartate shuttle are catalyzed by intact bacteroids, and that these reactions can support nitrogen fixation. It is proposed that the main function of the nodule-stimulated cytoplasmic form of GOT is participation in this shuttle.