Studies on Electrogenesis under High K+ Concentrations in Internodal Cells of Chara corallina

+ concentration ([K⁺]_o) on the membrane potential (E_m) of Chara corallina was studied. E_m more negative than -100 mV was maintained even at 100 mM [K⁺]_o. Addition of Ca²⁺ to the external medium further increased this tendency. However, E_m responded sensitively to the increase in [K⁺]_o, when the electrogenic proton pump of the plasma membrane was inhibited by treating cells with dicyclohexylcarbodiimide, an inhibitor of proton pump. Analysis using equivalent circuit model of the plasma membrane suggested that the electrogenic proton pump was activated by the increase in [K⁺]_o. In the presence of 100 mM K⁺, action potentials were generated by electric stimuli. The ionic mechanism of generation of action potentials in the presence of K⁺ at high concentration was discussed. Received 3 October 2000/ Accepted in revised form 6 January 2001     

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)     

Cortical Microtubule Organization and Internodal Cell Maturation in Chara corallina

The arrangement of cortical microtubules, as documented by immunofluorescence and immunogold-silver enhancement, changes during the growth and maturation of giant internodal cells of Chara corallina, a process taking approximately 45 days. Transverse microtubules are found throughout growth along with a subset of distinctly non-transverse microtubules. During the second half of the growing period, when relative growth rates are diminishing, these non-transverse microtubules become more abundant but a few days prior to growth cessation, they are mostly absent. At about the time of growth cessation the microtubules, while retaining their locally parallel alignment, begin to show increasing deviation from the transverse axis. Eventually, a mosaic of locally parallel yet variably oriented fields of microtubules forms. Many days after growth stops, microtubules become shorter and less numerous and lose parallel alignment, leading to the formation of a random MT pattern.     

The Influence of Ca2+ and K+ on H14CO3-Influx in Internodal Cells of Chara corallina

The influences of Ca²⁺-free solutions and increasing K⁺ concentrationson the H¹⁴CO^–₃ influx capacity of Chara corallina wereinvestigated. It was found that contact with Ca^2–freesolutions resulted in a gradual reduction in the H¹⁴CO^–₃influx capacity of these cells. Recovery of this influx capacity,following the return of Ca²⁺ to the experimental solution, followeda ‘mirror-image’ of the time course of decay. Potassium concentrations above a certain critical value (2 mM)induced a rapid reduction in H¹⁴CO^–₃ influx capacity.Normal activity was recovered within 60–90 min followingthe return to 0.2 mMK⁺ solutions. It was also shown that 10mM K⁺ can be used to determine the relative contribution of¹⁴C supplied by diffusion of ¹⁴CO₂ and transport of H¹⁴CO^–₃.The Ca²⁺ and K⁺ results are discussed in relation to the effectsof these treatments on the electrical properties of the plasmalemma.     

Effects of Lanthanum on Calcium and Magnesium Contents and Cytoplasmic Streaming of Internodal Cells of Chara corallina

Biological and environmental effects of lanthanide series of elements have received much attention recently due to their wide applications. In this study, effects of La³⁺ treatments on calcium and magnesium concentrations as well as cytoplasmic streaming of internodal cells of Chara corallina were investigated. At all treatment concentrations (10, 100, and 1,000 μM), La³⁺ significantly decreased calcium concentrations in the cell-wall fractions after 5-h treatments. Calcium concentrations in the cell contents and magnesium concentrations in the cell-wall fractions were reduced by 100 and 1,000 μM La³⁺ treatments. However, cytoplasmic streaming as an indicator of [Ca²⁺]_cyt was only inhibited at the highest La³⁺ concentration (1,000 μM). The results suggest that La³⁺ may affect cellular calcium homeostasis by actions other than as a simple Ca²⁺ antagonist. La³⁺ could partially compensate for calcium deficiency at certain concentrations.     

Intercellular Transport and Photosynthetic Differentiation in Chara corallina

Intercellular transport of ¹⁴C-labelled photoassimilates, bothin isolated upper shoots and in isolated internode-branchletcomplexes of Chara corallina, was measured. The isolated uppershoots were composed of a primary apex, two mature internodes,and three branchlet whorls. A 10 min loading of the isolatedupper shoot with H¹⁴CO₃^– resulted in a greater accumulationof ¹⁴C in the apical complex and branchlets than in the internodes,while a subsequent 50 min chase with unlabelled solution inthe light resulted in a greater accumulation of ¹⁴C in internodesthan in other parts of the shoot. In the isolated internode-branchlet complex, when the apex wasnot detached, the amount of ¹⁴C transported from branchletsto internodes was about fives times that transported from internodesto branchlets. Removal of the apex resulted in a decrease intransport from branchlets to internodes and an increase in transportin the opposite direction. In an attempt to explain the mechanism of the polar transportof photosynthetically fixed carbon between branchlets and internodes,photosynthetic activities of both types of cells were investigated.Detached branchlets have higher photosynthetic ¹⁴C-fixationactivities than those of internodes. Chlorophyll contents, measuredin terms of surface area, in internodes and branchlets werealmost identical. The ribulose-l,5-bisphosphate carboxylase(RuBPCase) activity of branchlets was 1.6 times that of internodes,and the rate of ferricyanide-dependent evolution of oxygen inbranchlets was 1.4 times that in internodes. Key words: Chara, internode, branchlet, polar transport, photosynthesis     

Entry of Methylammonium and Ammonium Ions into Chara Internodal Cells

Low concentrations of ammonia and methylamine greatly affectmembrane transport by, and the electrical properties of, cellsof Chara corallina (=C. australis). In the presence of theseamines, influx of Cl^– and efflux of K⁺ increase and alarge depolarizing current flows through the cell membrane. Measurements with [¹⁴C]methylamine show that methylamine isabsorbed rapidly over a wide pH range, and that the absorptionisotherm is complex. Methylamine influx is not affected by presenceor absence of Cl^–, K⁺, or Na⁺, but is decreased by additionof . The depolarizing current is associated with a small increase in membrane conductance, except at highpH, and both these effects are reversible. The current showssaturation with increasing amine concentration; when methylamineis 10–12 times more concentrated than ammonia, it producesa current of the same magnitude. The results show that the amines enter the cells as cations( or CH₃) except where external pH is high, and that a specific, selective electrogenicporter is involved. There is no need to invoke active transport,as there is no evidence that internal amine concentrations exceedthe equilibrium (Nernst) concentrations.     

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)     

The Uptake of Sugars by Chara corallina

The influx of several monosaccharides into Chara corallina wasstudied under varying conditions of temperature, in the presenceof inhibitors, and by the use of competition experiments. Itwas found that the mechanism of transport was stereospecific,and the complex interactions between the sugars were characteristicof a carrier-mediated system. There is reason to believe thatthe carrier involved in this system has a narrower range ofaffinities than is usually attributed to a sugar carrier, forglucose and fructose appear to have different sites of entry,though each can influence the uptake of the other. In additionthe carrier system is situated in the plasmalemma and maintainedby metabolic energy.     

Jumping Transmission of Action Potential between Separately Placed Internodal Cells of Chora corallina

We report here a new type of cell-to-cell communication. Wenoticed that a characean cell can transmit its action potentialsto one or more cells which lie parallel to it separately inartificial pond water without any special connection betweenthe cells. Two experimental facts proved this transmission notchemical but electrical. No transmission was observed firstwhen an Ag-AgCl wire was placed between two cells, and secondwhen the whole length of the first cell was stimulated so thatnon-propagated action potential was induced. The results showthat the traveling electrical field strength might be the fundamentalfactor in the jumping transmission. (Received November 10, 1989; Accepted December 22, 1989)     

Autonomous Local Area Control over Membrane Transport in Chara Internodal Cells

Internodal cells of Chara were separated with a Plexiglas divider into two segments and the vibrating probe was used to investigate the extracellular current profiles that formed along these two surfaces. Treating one segment of the Chara cell with K⁺ concentrations greater than 2 millimolar caused a dramatic reduction in the extracellular current pattern in this compartment. Concentrations of 5, 10, and 20 millimolar K⁺ were used to establish that a normal current profile could be maintained along the cell surface in the control compartment, whereas the extracellular current profile was strongly reduced along the entire cell surface that was located in the second, high-K⁺ compartment. Simultaneous measurements of the membrane potential in the two segments of the divided Chara cell established that, in the presence of elevated K⁺ concentrations, a longitudinal voltage gradient of up to 60 millivolts was maintained. Experiments in which the pH value in one compartment was either decreased (pH 6.0) or increased (pH 11) gave rise to a reduced extracellular current profile along this segment of the cell, whereas the pattern in the control segment remained unaltered. These results are discussed in terms of the cellular spatial control system that must function to regulate the regions of outward and inward current, and the concept of autonomous local area (domain) control is presented.     

Analysis of Rapid Light-Induced Potential Change in Cells of Chara corallina

Perfused Chara cells were used to measure the rapid light-inducedpotential change (rapid LPC) caused by activation of a K⁺ channelin the plasma membrane through photosynthesis in the presenceof various photosynthetic inhibitors. The rapid LPC was inhibitedby DCMU but recovered on addition of phenazinemethosulfate (PMS)in the presence of DCMU. Carbonylcyanide m-chlorophenylhydrazone(CCCP) stimulated the rapid LPC. DCCD partially inhibited therapid LPC with a partial inhibition of oxygen evolution. Itis concluded that both cyclic and noncyclic electron flows arecoupled with the rapid LPC. To understand the mechanism of K⁺ channel activation by photosyntheticelectron flow, the rapid LPC was measured under continuous internalperfusion. It was suggested that a diffusible substance wasnot released from chloroplasts, since vigorous continuous perfusiondid not inhibit the rapid LPC. The suggestion that the rapid LPC is caused by changes in surfacecharge density of chloroplasts was supported by the fact thatthe rapid LPC was inhibited by increasing the ionic strengthof the perfusion medium. (Received February 28, 1986; Accepted April 30, 1986)     

Fluorescence and Photosynthetic Activity of Chloroplasts in Acid and Alkaline Zones of Chara corallina

Continuous profiles of local pH near the cell surface of Chara corallinawere recorded during uniform longitudinal movement of an internodal cell relative to a stationary pH microelectrode. Under illumination, the pH profile consisted of alternating acid and alkaline bands with a pH difference of up to 3 pH units. After darkening, the bands disappeared and pH became uniformly distributed along the cell length. Chlorophyll fluorescence of chloroplasts was measured by microfluorometry at different locations within one cell, and significant differences were observed in close relation to light-dependent pH banding. The chlorophyll fluorescence yield was lower in zones of low external pH than in alkaline zones both under actinic and saturating light. The fluorescence parameters Fand F" _m and the quantum yield of photosystem II (PSII) displayed variations along the cell length in accordance with pH changes in unstirred layers of the medium. The results show that PSII photochemical efficiency and the rate of noncyclic electron transport are higher in the chloroplasts of acid zones (zones of H⁺extrusion from the cell) than in alkaline zones. The dependence of photosynthetic electron transport on local pH near the cell surface may result from different contents of CO₂in acid and alkaline regions. The acid zones are enriched with CO₂that readily permeates through the membrane providing the substrate for the Calvin cycle. Conversely, a poorly permeating form, HCO^– ₃is predominant in alkaline zones, which may restrict the dark reactions and photosynthetic electron flow.     

Metabolic Conversion of Amino Acids Loaded in the Vacuole of Chara australis Internodal Cells

Vacuoles of internodal cells of Chara australis (or Chara corallina) were loaded with a 10 millimolar amount of various amino acids by a perfusion method and incubated under continuous light. After 20 to 24 hours, the cell sap was collected, and free amino acids in it and the rest of the cell (cytoplasm) were analyzed. The only amino acid metabolized completely was alanine. About 40 to 80% of the aspartic acid, glutamine, serine, and glycine were metabolized, whereas less than 30% of the threonine, asparagine, isoasparagine, isoleucine, phenylalanine, γ-aminobutyric acid, lysine, and arginine were metabolized. The figure for glutamic acid fluctuated between 10 and 100%. The main metabolites of alanine were glutamine, glycine and ammonia, which accumulated in the vacuole. Alanine utilization was not affected by l-methionine-d,l-sulfoximine or azaserine, but was strongly inhibited by aminooxyacetate. The cell extract contained enough alanine aminotransferase activity to account for the rate of alanine metabolism.     

Tonoplast Anion Channel Activity Modulation by pH in Chara corallina

The patch-clamp technique was used to investigate regulation of anion channel activity in the tonoplast of Chara corallina in response to changing proton and calcium concentrations on both sides of the membrane. These channels are known to be Ca²⁺-dependent, with conductances in the range of 37 to 48 pS at pH 7.4. By using low pH at the vacuolar side (either pH_vac 5.3 or 6.0) and a cytosolic pH (pH_cyt) varying in a range of 4.3 to 9.0, anion channel activity and single-channel conductance could be reversibly modulated. In addition, Ca²⁺-sensitivity of the channels was markedly influenced by pH changes. At pH_cyt values of 7.2 and 7.4 the half-maximal concentration (EC ₅₀) for calcium activation was 100–200 μm, whereas an EC ₅₀ of about 5 μm was found at a pH_cyt of 6.0. This suggests an improved binding of Ca²⁺ ions to the channel protein at more acidic cytoplasm. At low pH_cyt, anion channel activity and mean open times were voltage-dependent. At pipette potentials (V _p) of +100 mV, channel activity was approximately 15-fold higher than activity at negative pipette potentials and the mean open time of the channel increased. In contrast, at pH_cyt 7.2, anion channel activity and the opening behavior seemed to be independent of the applied V _p. The kinetics of the channel could be further controlled by the Ca²⁺ concentration at the cytosolic membrane side: the mean open time significantly increased in the presence of a high cytosolic Ca²⁺ concentration. These results show that tonoplast anion channels are maintained in a highly active state in a narrow pH range, below the resting pH_cyt. A putative physiological role of the pH-dependent modulation of these anion channels is discussed. Received: 14 March 2001/Revised: 16 July 2001     

The Formation of Alkaline and Acid Regions at the Surface of Chara corallina Cells

The magnitude of previously reported pH changes at the surfaceof Chara corallina cells has been measured with specially constructedpH electrodes. An experimental system was designed to reducethe dissipation of pH gradients by convection. When cells areilluminated their surfaces become partitioned into alkalineregions (pH 8.5–9.5) with sharp peaks and acid regions(pH about 5.5) which are more uniform. In the dark these regionsrapidly disappear and the pH of the cell surface becomes uniform(about pH 6.0). With cells initially free of any deposits ofCaCO₃, alkaline regions may appear temporarily, and may migratealong the cell surface. The presence of CaCO₃ stabilizes theregions. It is proposed that alkalinization results from HCO₃^–uptake, CO₂ fixation, and subsequent localized OH- efflux. Alkalinizationis prevented by photosynthetic inhibitors. The nature and magnitude of the HCO₃^–/OH- exchange processis discussed, and the possible role of H⁺ and OH- fluxes incontrolling the ionic and electrical properties of Characeancells is emphasized.     

Generation of action potentials in Chara corallina by turgor pressure changes

A depolarisation of the membrane potential difference (about-170 mV) of Chara corallina is observed in response to changes in cell turgor pressure using the pressure probe technique. The depolarisation occurs in phase with the pressure pulse (0.2 s duration) and is independent of the direction of the applied pressure gradient. This latter finding is in contradiction to results predicted on the basis of electro-kinetic phenomena. Pressure induced electrical leakages were ruled out by measuring the depolarisation in response to pressure in individual segments of the internode which were electrically isolated from one another. The changes in potential were recorded by external electrodes and an internal electrode which was positioned close to the micropipette of the pressure probe inserted through one of the electrically isolated nodes. The depolarisation in response to increasing positive or negative pressure gradients in the intact node region and in the intact middle segments was comparable to that monitored in the node region containing the pressure probe. Action potentials were initiated when the pressure gradients exceeded at least 2 bar. The action potentials were elicited at random in one of the two compartments adjacent to the node regions, but were never found to be initiated in the node regions themselves. The pressure-induced action potentials are explained in terms of an electro-mechanical compression (or expansion) of a local membrane area and discussed in their relevance to the propagation of pressure signals in response to water and salt stress in higher plants.Abbreviations PD potential difference     

Quantitative Analysis of Intercellularly-Transported Photoassimilates in Chara corallina

Using a thin-layer chromatographic technique, we have identifiedthe photoassimilates that are transported intercellularly frombranchlets to internodes in Chara corallina. An internode-branchletcomplex having a primary apex was used in these experiments.After feeding 1 mol m³ NaH¹⁴CO₃ to a branchlet for 10 min, the¹⁴C-labelled photoassimilates (¹⁴C-photoassimilates) found inthe sol endoplasm of the branchlet were composed of sucrose,amino acids, malate, and sugarphosphates. The composition ofthe ¹⁴C-photoassimilates transported from the source branchletto the sink internode in 10 min was the same as that in thesol endoplasm of the source branchlet. From the proportion ofeach ¹⁴C-photoassimilate in both the source branchlet and thesink internode, it was deduced that the main photoassimilatesinvolved in the intercellular transport were sucrose and aminoacids. We found previously that polar transport of photoassimilatesoccurs from a branchlet to an internode with an apex. Determinationof the amount of sucrose, amino acids, glucose-6-phosphate,and malate in both branchlet and internode with or without anapex revealed that there were gradients in the concentrationsof sucrose, serine, and glutamic acid between the sol endoplasmof the two cells. The levels were higher in the branchlet andlower in the internode and the gradients decreased when theapex was detached. Therefore, it is concluded that sucrose andthese amino acids are the compounds involved in the polar intercellulartransport. Key words: Chara corallina, intercellular transport, photoassimilates, ¹⁴C