H+ tolerance of Chara Internodal Cells and Apparent Net Influx of H+ in Weakly Acidic Solutions: Implication of the Net Flux of H+ as a Minor Component among the Total Net Flux of Ions across the Intact Cell Membrane of Chara

Precise measurements of the net flux of protons in Chara internodalcells were made with a recently designed high-resolution pH-meter.Survival of intact Chara internodal cells in artificial pondwater (APW) that contained HC1 at various concentrations wasalso examined. The apparent net flux of H⁺ was inward and muchsmaller than that reported so far. In APW at pH 4.005, a valuehigher than the extracellular pH expected from the values ofH⁺ efflux reported to date, all of the intact Chara internodalcells died within a day. With reference to the data on the circadianflow of ions in the pulvinus of Phaseolus [Kiyosawa (1979) PlantCell Physiol. 20: 1621–1634, Hosokawa and Kiyosawa (1983)Plant Cell Physiol. 24: 1065–1072] and ionic regulationin Chara L-cells [Kiyosawa and Okihara (1988) Plant Cell Physiol.29: 9–19], a discussion is presented of the prossiblyminor contribution of the net flux of H⁺ in the generation ofthe electrical membrane potential. Regulation of the net fluxof H⁺ in weakly acidic APW is also discussed. (Received September 4, 1989; Accepted January 25, 1990)     

A New Turgor/Membrane Potential Probe Simultaneously Measures Turgor and Electrical Membrane Potential

Abstract: A new combined turgor/membrane potential probe (T-EP probe) monitored cell turgor and membrane potential simultaneously in single giant cells. The new probe consisted of a silicone oil-filled micropipette (oil-microelectrode), which conducted electric current. Measurements of turgor and hydraulic conductivity were performed as with the conventional cell pressure probe besides the membrane potential. In internodal cells of Chara corallina, steady state turgor (0.5-0.7 MPa) and resting potentials (-200 to ?220 mV) in APW, and hydraulic conductivity (0.07 to 0.21 × 10～⁵ m s^?1 MPa^?1) were measured with the new probe, and cells exhibited healthy cytoplasmic streaming for at least 24 h during measurements. When internodal cells of Chara corallina were treated with 30, 20, 10, and 5 mM KCI, turgor responded immediately to all concentrations, and the osmotic changes in the medium were measured. Action potentials, which brought the membrane potential to a steady depolarization that measured the concentration difference of K⁺ in the medium, were induced in a concentration — dependent delay and occurred only 30, 20, and 10 mM of KCl. When the solution was changed back to APW, the repolarization of membrane potential consisted of a quick and a following slow phase. During the quick phase, which took place immediately and lasted 1 to 3 min, the plasma membrane remained activated. The membrane was gradually deactivated in the slow phase, and entirely deactivated when the membrane potential recovered to the resting potential in APW. Although the activated plasma membrane was permeable to K⁺, no major ion channels were activated on the tonoplast, and therefore, internodal cells of Chara corallina did not regulate turgor when osmotic potential changed in the surrounding medium.     

Ion Efflux during a Single Action Potential of Nitella axilliformis in Medium Lacking Ca2-

Ion efflux during excitation of Nitella axilliformis was measuredconductometrically. In medium lacking Ca²⁺ but with 0.1 mM MgCl₂,the duration of the action potential and the total efflux weremuch larger than those in APW, while the efflux rate, givenas the total efflux divided by the duration, was about halfof that in APW. (Received September 4, 1986; Accepted November 25, 1986)     

Electromotive force of Nitella membrane during excitation

Excitation of the Nitella membrane is analysed by assuming themembrane to be an electromotive force in series with a resistance,both being variables of time and of membrane potential. Duringstep depolarization beyond a threshold, conductance and electromotiveforce increase transiently, finally reaching their respectivesteady state levels. The conductance increase peak is attainedearlier than the peak for electromotive force increase. Wheneverelectromotive force increases beyond the level of clamped membranepotential, the ionic current flows inward. This is consideredto be the origin of the apparent negative resistance characteristicof the excitable membrane. Anodal break response and spontaneousfiring of Nitella membrane are also caused by transient increasesin electromotive force and conductance irrespective of whetherthe membrane potential is being held at its resting level. Thetransient increase in electromotive force reflects changes,like a phase transition, occurring during excitation. (Received May 6, 1968; )     

Studies on cessation of cytoplasmic streaming under K+-induced depolarization inNitella axilliformis

Internodal cells ofNitella axilliformis had a membrane potential of about−120mV and showed active cytoplasmic streaming with a rate of about 90 μm/sec in artificial pond water (APW) at 25C. When APW was replaced with 50 mM KCl solution, the membrane potential depolarized accompanying an action potential, and the cytoplasmic streaming stopped. Soon after this quick cessation, the streaming started again, but its velocity remained very low for at least 60 min. Removal of KCl from the external medium led to repolarization of the membrane and accelerated recovery of the streaming. The change in the concentration of free Ca²⁺ in the cytoplasm ([Ca²⁺]_c) was monitored by light emission from aequorin which had previously been injected into the cytoplasm. Upon application of KCl to the external medium, the light emission, i.e., [Ca²⁺]_c, quickly increased. It then decreased exponentially and reached the original low level within 100 sec. The cause of the long-lasting inhibition of cytoplasmic streaming observed even when [Ca²⁺]_c had returned to its low resting level is discussed based on the mechanism proposed for action potential-induced cessation of cytoplasmic streaming; inactivation of myosin by Ca²⁺-dependent phosphorylation or formation of cross bridge between actin filaments and myosin.     

Conduction Velocity and Blockage of Action Potential in Chara Internodal Cells

Conduction velocity of the action potential in Chara brauniiinternodal cells was 0.21 ?0.05 cms in moist air and 1.5?0.9cms in artificial pond water (APW). The action potential waspropagated at an almost constant velocity along the cell inmoist air except within 0.3 cm from an end of the cell, whereasin APW, the velocity increased to 5.7 ? 2.3 cms within 1.8 cmfrom the end of the cell. When part of the cell was put in moistair and the other part was immersed in APW, conduction of theaction potential in moist air decreased in velocity and sometimesstopped in the vicinity of the boundary between moist air andAPW. Some cells from the plants collected in late autumn towinter generated an action potential which could not propagatein moist air. In these cells, an increase in the threshold andpartial cessation of protoplasmic streaming were observed. ¹Present address: Department of Physiology, Tohoku UniversitySchool of Dentistry, Seiryo-machi, Sendai 980 ²Present address: Biology Laboratory, Kyoritsu Women's University,Hachioji, Tokyo 193, Japan. (Received March 10, 1987; Accepted July 6, 1987)     

Electrophysiological Evidence for an Electrogenic Proton Pump and the Proton Symport of Glucose in the Marine Fungus Dendryphiella salina

The marine hyphomycete Dendryphiella salina (Suth.) Nicot &Pugh has a resting membrane potential of –250 mV (insidenegative). The respiratory inhibitors sodium azide and FCCPinduced a rapid but reversible depolarization of the membraneof at least 180 mV; sodium azide also caused alkalinizationof the medium. Vanadate brought about significant depolarizationbut this was not always reversible. EDTA induced depolarizationthough to a lesser extent. DIDS and SITS caused a depolarizationof around 30–70 mV which was readily reversible, N-ethylmaleimideirreversibly depolarized the membrane by 180–200 mV. Ouabainhad no effect. When external concentrations of H⁺ , K⁺ , Na⁺or Cl^– were changed singly, only changes in H⁺ affectedmembrane potential, with shifts decreasing with increasing pH.Glucose and 3-O-methyl glucose depolarized the membrane in aconcentration-dependent manner which was enhanced by starvationof the hyphae. Recovery occurred in the presence of the hexose.Glucose caused an alkalinization of the medium, with time characteristicssimilar to the membrane potential changes. It is concluded thatthere is an electrogenic proton pump and a proton—glucosesymporter in D. salina. The retention of proton-based transportsystems suggests a terrestrial origin for the fungus. Key words: Marine fungi, Dendryphiella salina, membrane potential, electrogenic proton pump, proton symport, hexose     

Pharmacological and biophysical isolation of K+ currents encoded by ether-a-go-go-related genes in murine hepatic portal vein smooth muscle cells

Previous studies have shown that murine portal vein myocytes express ether-à-go-go related genes (ERGs) and exhibit distinctive currents when recorded under symmetrical K⁺ conditions. The aim of the present study was to characterize ERG channel currents evoked from a negative holding potential under conditions more pertinent to a physiological scenario to assess the possible functional impact of this conductance. Currents were recorded with ruptured or perforated patch variants of the whole cell technique from a holding potential of –60 mV. Application of three structurally distinct and selective ERG channel blockers, E-4031, dofetilide, and the peptide toxin BeKM-1, all inhibited a significant proportion of the outward current and abolished inward currents with distinctive "hooked" kinetics recorded on repolarization. Dofetilide-sensitive currents at negative potentials evoked by depolarization to +40 mV had a voltage-dependent time to peak and rate of decay characteristic of ERG channels. Application of the novel ERG channel activator PD-118057 (1–10 µM) markedly enhanced the hooked inward currents evoked by membrane depolarization and hyperpolarized the resting membrane potential recorded by current clamp and the perforated patch configuration by 20 mV. In contrast, ERG channel blockade by dofetilide (1 µM) depolarized the resting membrane potential by 8 mV. These data are the first record of ERG channel currents in smooth muscle cells under quasi-physiological conditions that suggest that ERG channels contribute to the resting membrane potential in these cells. vascular smooth muscle; voltage-dependent K⁺ current; membrane excitability     

Electrophysiological characterization of murine HL-5 atrial cardiomyocytes

HL-5 cells are cultured murine atrial cardiomyocytes and have been used in studies to address important cellular and molecular questions. However, electrophysiological features of HL-5 cells have not been characterized. In this study, we examined such properties using whole cell patch-clamp techniques. Membrane capacitance of the HL-5 cells was from 8 to 62 pF. The resting membrane potential was –57.8 ± 1.4 mV (n = 51). Intracellular injection of depolarizing currents evoked action potentials (APs) with variable morphologies in 71% of the patched cells. Interestingly, the incidence of successful, current-induced APs positively correlated with the hyperpolarizing degrees of resting membrane potentials (r = 0.99, P < 0.001). Only a few of the patched cells (4 of 51, 7.8%) exhibited spontaneous APs. The muscarinic agonist carbachol activated the acetylcholine-activated K⁺ current and significantly shortened the duration of APs. Immunostaining confirmed the presence of the muscarinic receptor type 2 in HL-5 cells. The hyperpolarization-activated cation current (I_f) was detected in 39% of the patched cells. The voltage to activate 50% of I_f channels was –73.4 ± 1.2 mV (n = 12). Voltage-gated Na⁺, Ca²⁺, and K⁺ currents were observed in the HL-5 cells with variable incidences. Compared with the adult mouse cardiomyocytes, the HL-5 cells had prolonged APs and small outward K⁺ currents. Our data indicate that HL-5 cells display significant electrophysiological heterogeneity of morphological appearance of APs and expression of functional ion channels. Compared with adult murine cardiomyocytes, HL-5 cells show an immature phenotype of cardiac AP morphology. action potential; ion channel; muscarinic receptor     

Acute hypoxia selectively inhibits KCNA5 channels in pulmonary artery smooth muscle cells

Acute hypoxia causes pulmonary vasoconstriction in part by inhibiting voltage-gated K⁺ (Kv) channel activity in pulmonary artery smooth muscle cells (PASMC). The hypoxia-mediated decrease in Kv currents [I_K(V)] is selective to PASMC; hypoxia has little effect on I_K(V) in mesenteric artery smooth muscle cells (MASMC). Functional Kv channels are homo- and/or heterotetramers of pore-forming -subunits and regulatory -subunits. KCNA5 is a Kv channel -subunit that forms functional Kv channels in PASMC and regulates resting membrane potential. We have shown that acute hypoxia selectively inhibits I_K(V) through KCNA5 channels in PASMC. Overexpression of the human KCNA5 gene increased I_K(V) and caused membrane hyperpolarization in HEK-293, COS-7, and rat MASMC and PASMC. Acute hypoxia did not affect I_K(V) in KCNA5-transfected HEK-293 and COS-7 cells. However, overexpression of KCNA5 in PASMC conferred its sensitivity to hypoxia. Reduction of PO₂ from 145 to 35 mmHg reduced I_K(V) by 40% in rat PASMC transfected with human KCNA5 but had no effect on I_K(V) in KCNA5-transfected rat MASMC (or HEK and COS cells). These results indicate that KCNA5 is an important Kv channel that regulates resting membrane potential and that acute hypoxia selectively reduces KCNA5 channel activity in PASMC relative to MASMC and other cell types. Because Kv channels (including KCNA5) are ubiquitously expressed in PASMC and MASMC, the observation from this study indicates that a hypoxia-sensitive mechanism essential for inhibiting KCNA5 channel activity is exclusively present in PASMC. The divergent effect of hypoxia on I_K(V) in PASMC and MASMC also may be due to different expression levels of KCNA5 channels. membrane potential; potassium channels; vascular smooth muscle     

The Influence of Temperature on a K+-Channel and on a Carrier-Type Transporter in Nitella

Fisahn, J. and Hansen, U-P. 1986. The influence of temperatureon a K⁺ -channel and on a carrier type transporter in Nilella—J.exp. Bot. 37. 440–460. In Nitella, the effects of temperature on membrane potentialand on resistance consist of several components. The evaluationof their associated time-constants measured in linear(ized)temperature responses at a resting potential of–120 mVprovides an approach to their identification. For changes slowerthan c. 1 s, the temperature effect on membrane potential andresistance does not originate from temperature action on theinvolved transporter, but is mediated by signals from temperaturesensitive metabolic processes. In the case of potential, theseprocesses seem to be identical to those which also mediate thelight effect: pH-regulation, and two direct signals from photosynthesis,as indicated by the similarities of the related time-constants( respectively). The temperature effect on resistance displays only one time-constant of 40 sinmost experiments. The related process is unknown. The non-coincidenceof the time-constants of the effect on potential and on resistanceimplies the involvement of a carrier-type transporter (H+-pumpor cotransporter) in the effect on potential, and of a K+channelin the effect on resistance. The K+-channel is identified bythe reversal potential of the effect on membrane potential measuredin cells depolarized or hyperpolarized by an injected electricalcurrent Under these conditions the temperature effect on resistancedominates the effect on potential. Key words: H⁺-pump, K⁺-channel, kinetic analysis, Nitella, oscillation, pH-regulation, reversal, potential, temperature, time-constants     

N-Ethylmaleimide Blocks the H+ Pump in the Plasma Membrane of Chara corallina Internodal Cells

The sulfhydryl (SH) modifying reagent N-ethylmaleimide (NEM)was applied to the internodal cells of Chara corallina to studythe role of SH residues in the activity of the plasma membraneH⁺ pump. NEM (1 µM) caused a marked depolarizing shiftof the resting potential by 6410mV (n=7) together with depressionof the conductance peak at around —200 mV, indicatinga marked depression of the H⁺ pump activity. This effect ofNEM was partly reversible, the membrane repolarized and theconductance peak was restored after extracellular washing. TheH⁺ pump inhibitor, dicyclohexylcarbodiimide (DCCD), caused noadditive membrane depolarization and/or depression of the H⁺pump conductance, in the presence of NEM. This suggests thatNEM blocks the H⁺ pump and that SH residues play a pivotal rolein maintaining the H⁺ pump activity in Chara corallina. (Received April 10, 1993; Accepted July 29, 1993)     

Abscisic Acid-Induced Membrane Potential Changes in Barley Aleurone Protoplasts: a Possible Relevance for the Regulation of rab Gene Expression

The effect of ABA on the membrane potential of barley (Hordeumvulgare cv. Himalaya) aleurone protoplasts was studied by measuringthe distribution of the lipophilic cation tetraphenylphosphonium(TPP⁺). The resting membrane potential (E_m) according to ourmeasurements with TPP⁺ is about –53 mV and is in agreementwith membrane potential values as measured with intracellularmicroelectrodes (about –55 mV). The TPP⁺-measurementscould demonstrate a clear dependence of the resting E_m on theexternal pH (pH_e). Stimulation of the protoplasts with ABA induced a transienthyperpolarization of the membrane to –62 mV as measuredwith TPP⁺. The hyperpolarization was ABA-concentration dependent. Inhibition of the H⁺-ATPases with the specific proton pump inhibitorsdiethylstilbestrol (DES) or Micanozole effectively preventedhyperpolarization. This indicates that the hyperpolarizationis consistent with the activation of plasma membrane H⁺-ATPases.The K⁺-inward rectifier inhibitor BaCl₂ was able to prolongthe hyperpolarization. This result suggests that the hyperpolarizationcauses the opening of K⁺-channels. The ABA-induced proton-pump activation may be involved in ABA-inducedgene-expression, as DES was able to inhibit this gene expression.BaCl₂ did only show a slight inhibitory effect on ABA-inducedgene-expression. (Received January 4, 1994; Accepted April 12, 1994)     

Effects of temperature on slow and fast inactivation of rat skeletal muscle Na+ channels

Patch-clampstudies of mammalian skeletal muscleNa⁺ channels are commonly done atsubphysiological temperatures, usually room temperature. However, atsubphysiological temperatures, mostNa⁺ channels are inactivated atthe cell resting potential. This study examined the effects oftemperature on fast and slow inactivation ofNa⁺ channels to determine iftemperature changed the fraction of Na⁺ channels that were excitableat resting potential. The loose patch voltage clamp recordedNa⁺ currents(I_Na) in vitroat 19, 25, 31, and 37°C from the sarcolemma of rat type IIbfast-twitch omohyoid skeletal muscle fibers. Temperature affected thefraction of Na⁺ channels that wereexcitable at the resting potential. At 19°C, only 30% of channelswere excitable at the resting potential. In contrast, at 37°C, 93%of Na⁺ channels were excitable atthe resting potential. Temperature did not alter the resting potentialor the voltage dependencies of activation or fast inactivation.I_Na available atthe resting potential increased with temperature because thesteady-state voltage dependence of slow inactivation shifted in adepolarizing direction with increasing temperature. The membranepotential at which half of the Na⁺channels were in the slow inactivated state was shifted by +16 mV at37°C compared with 19°C. Consequently, the low availability ofexcitable Na⁺ channels atsubphysiological temperatures resulted from channels being in the slow,inactivated state at the resting potential.

     

Is Calmodulin Involved in Electrophysiology of Chara corallina?

The role of calmodulin in Chara was investigated using the antipsychoticdrug trifluoperazine (TFP), which is known to bind to the calmodulin/Ca⁺⁺complex preventing it from carrying out its normal functions. At low concentration (4.0 µM), TFP had profound and irreversibleeffects on the electrophysiology of Chara plasmalemma. The restingp.d. depolarized and the membrane conductance decreased suggestingan inhibition of the proton pump. After several hours of exposurethe membrane became leaky, as cells deteriorated. The excitation was also affected by TFP. Spontaneous repetitivefiring was observed. The excitation increased in duration andthe action potential peak depolarized to + 20 mV. The cytoplasmic streaming was unaffected by TFP; the streamingrate at the resting potential remained unchanged when TFP wasadded to the medium, stoppage occurred at the time of excitationand the streaming slowly resumed. Key words: Calmodulin, Chara corallina, Proton pump, Cytoplasmic streaming, Current, voltage characteristics     

Membrane Potentials in Excitable Cells of Aldrovanda vesiculosa Trap-Lobes

The resting membrane potential in excitable cells of Aldrovandatrap-lobes is composed of diffusion and electrogenic potentials.The diffusion potential, about –100 mV in artificial pondwater, was determined from the external K⁺ and Na⁺ concentrations.The permeability ratio, P_Na/P_K of the membrane was estimatedto be about 0.3. The electrogenic potential hyperpolarized themembrane to about –140 mV. The peak value of the actionpotential increased by +26 mV with a tenfold increase in theexternal Ca²⁺ concentration. The action potential was blockedby an application of the Ca²⁺ chelater or the Ca channel blocker,LaCl₃. Cells showed additional Ca²⁺ influx (7.8 pmole/cm² impulse)during membrane excitation. These facts suggest that the transientincrease in Ca²⁺ influx causes the action potential presentin cells of Aldrovanda trap-lobes. ¹ Present address: Jerry Lewis Neuromuscular Research Center,School of Medicine, University of California Los Angeles, LosAngeles, CA90024, U.S.A. ² Present address: Biological Laboratory, Kyoritsu Women's University,Hachioji 193, Japan. (Received September 21, 1983; Accepted September 7, 1984)     

The effect of external pH on the membrane potential of Nitella and its linkage to metabolism

The membrane potential of Nitella is highly sensitive to externalpH in the neutral region (pH 5.5 to 8) in the light. We foundthat the sensitivity usually was reduced by darkness, metabolicinhibitors (DCMU, DNP) or cooling. Under some circumstancesthe high pH-sensitivity of the membrane potential was observedeven in the dark. However, even in this case, it was reducedby DNP or cooling. These results indicate that the externalpH-dependence of the membrane potential of Nitella is closelylinked to metabolism. (Received May 8, 1973; )     

Changes in Cell Length During Action Potentials in Chara

Changes in cell length during excitation in Chara were recordedsimultaneously with extracellular action potentials. Cells stimulatedin artificial pond water (APW) gave a diphasic change in celllength ; that is, a transient shortening followed by a delayedextension. When a cell was stimulated 1–3 min after aprevious shortening, the extension phase was not evident, andthe amplitude of the shortening was always larger than the previousone. Cells stimulated in moist air gave shortenings with muchlarger amplitudes and much greater durations compared with thosein APW. From such marked differences in both amplitude and durationbetween the two types of shortening it is suggested that theshortening might be caused mainly by an osmotic water movementduring excitation. Net water loss during a single action potentialwas calculated from the cell shortening to be 1.076 nl cm^–2per impulse or 59800 pmol cm^–2 per impulse, which couldbe caused by a local enhancement of ionic concentration justoutside the plasmalemma of about 0.74 mN.     

Phytochrome and calcium ions are involved in light-induced membrane depolarization in Nitella

Isolated internodes of Nitella (N. opaca, N. flexilis) and Nitellopsis spec. were punctured with single microelectrodes and their membrane potentials were recorded continuously during various light treatments. In red light the initial response was always a depolarization. This depolarization began with a lag-time of 0.4-3.5s and reached a steady state within 1–2 min of continuous illumination. Repolarization began within several seconds after turning off the light. The magnitude of the red-light-induced depolarization increased with the Ca²⁺-concentration of the medium. The largest depolarizations were recorded in 5 m mol l^-1 Ca²⁺. Ca²⁺ could not be replaced in this function by Na⁺, Mg²⁺, La³⁺ or mannitol. Far-red light alone had no effect on the resting membrane potential. Far-red light applied immediately after red light accelerated the repolarization of the membrane potential. Far-red light applied simultaneously with red light reduced the amount of depolarization and increased the rate of repolarization. The results indicate that phytochrome and Ca²⁺ are involved in the light-induced depolarization of the membrane. They are consistent with the hypothesis that phytochrome may act by triggering a Ca²⁺-influx at the plasma membrane.Abbreviations APW artificial pond water - Pfr far-red absorbing form of phytochrome - DCMU 3-(3,4-Dichlorphenyl)-1,1-dimethylurea     

氮、硅限制对赤潮藻扁面角毛藻休眠孢子形成的影响

休眠孢子的形成对于赤潮藻种群的保存、延续以及分布扩散等均具有重要的意义。通过单因子营养限制研究氮、硅对赤潮藻扁面角毛藻 (Chaetoceros compressus )休眠孢子形成的影响, 结果表明: 培养基中氮的初始浓度对休眠孢子的出现时间有一定影响。氮的初始浓度越低, 休眠孢子出现的时间越早; 反之, 氮的初始浓度越高, 休眠孢子出现的时间越晚。氮缺乏是硅藻形成休眠孢子的必需条件之一, 当培养基中氮含量低于10 mmol.L^-1时, 扁面角毛藻可以形成休眠孢子。氮缺乏诱发的休眠孢子的形成需要大量的硅, 当培养基中硅含量低于23 mmol.L^-1时, 即使氮缺乏, 扁面角毛藻也几乎不再继续形成休眠孢子。这说明硅藻休眠孢子的形成不仅受氮浓度的影响, 还与硅浓度有关。