Turgor regulation in the salt-tolerant alga Chara longifolia

Chara longifolia is a salt‐tolerant Charophyte which regulates its turgor inresponse to osmotic stress. Membrane depolarization, in creased membrane conductance, and cessation of cytoplasmic streaming (due to increase in cytoplasmic Ca^{2 +} ) precede regulation in response to hypotonic stress. Measurements of these three parameters are presented here with simultaneous turgor measurements. Variability in the occurrence, rate and extent of turgor regulation in individual cells was correlated with magnitude of the stress. Hypertonic stress showed the same slow time course as was found previously, requiring several days for complete regulation. Fifty μ M nifedipine, a Ca^{2 +} channel blocker, inhibited turgor regulation. In the presence of 5 μ M nifedipine, turgor regulation was delayed. An increase in conductance preceded regulation, but membrane depolarization was less and no detectable change in cytoplasmic streaming was observed, requiring modifications to a previously presented model for turgor regulation. There was no significant difference in ⁴⁵Ca^{2 +} influx under control and stress conditions. However, the control flux was insensitive to nifedipine, whereas under stress the flux is inhibited 54% by nifedipine. We suggest that osmotic stress results in a rapid increase in a nifedipine‐sensitive Ca^{2 +} entry mechanism, followed very quickly by a decrease in the control entry mechanism.     

Determination of Solute Permeability in Chara Internodes by a Turgor Minimum Method : Effects of External pH

The analysis of Sha'afi et al. (Sha'afi, Rich, Mickulecky, Solomon 1970 J Gen Physiol 55: 427-450) for determining solute permeability in red blood cells has been modified and applied to turgid plant cells. Following the addition of permeating solute to the external medium, a biphasic response of cell turgor can be measured with the pressure probe in isolated internodes of Chara corallina. After an initial decrease in turgor due to water flow (water phase), turgor increases due to the uptake of the solute (solute phase) until the original turgor is reattained. From the pressure/time course in the neighborhood of the minimum turgor, the permeability of the osmotic solute can be determined. The data obtained by the minimum method for rapidly permeating (ethanol, methanol) and slowly permeating (formamide, dimethylformamide) solutes are similar to those calculated from the half-time of pressure changes during the solute phase and to data obtained by other workers using radioactive tracers. The methods employing the pressure probe were applied to examine the effect of high pH (up to pH 11) on the membrane permeability. There appeared to be no effect of high pH on the permeability coefficients, reflection coefficients, and hydraulic conductivity.     

The role of calcium in turgor regulation in Chara longifolia

The salt-tolerant alga Chara longifolia (Robinson) is capable of regulating its turgor in response to hypotonic stress resulting from a decrease in the osmotic pressure of the medium. This regulatory process takes only 40 min in small cells (length ≤ 10 mm), but requires 3d in large cells (length ≥30mm). Turgor regulation in small cells is comprised of two phases, a fast phase reducing the increased turgor by about 25% in the First 5 min, and a second phase reducing the turgor to near the original value within 40 min. The second phase is inhibited by reducing the concentration of Ca²⁺ in the external medium from 4.6 to 0.01 mol m^?3; the first phase is less affected by the reduction of Ca²⁺. In the first 5 min of stress, the membrane depolarizes in a voltage-dependent fashion, electrical conductance of the membrane increases transiently and cytoplasmic streaming is inhibited. When the external Ca²⁺ concentration is lowered, conductance does not increase and streaming continues unaffected. In a low ionic strength medium, Ca²⁺ is not required in the medium for turgor regulation. To test the hypothesis that there is increased Ca²⁺ entry from the medium during turgor regulation, we measured the influx of ⁴⁵Ca²⁺ into the cell. We found an increased influx of Ca²⁺, from 18 to 36 nmol m^?2 s^?1 during the first 30 to 90 s following osmotic stress. This increase was evident only in cells below about 7 mm in length, and was more marked in smaller cells.     

Influence of Turgor Pressure Manipulation on Plasmalemma Transport of HCO(3) and OH in Chara corallina

A modified version of the osmotic shock technique was used to investigate HCO₃⁻ and OH⁻ transport in the alga Chara corallina. Cell turgor was brought close to zero and then restored. When turgor was reduced to near the plasmolytic point using an osmoticum, little effect was observed on H¹⁴CO₃⁻ assimilation and OH⁻ transport. However, when turgor was recovered in these cells, there was a large reduction in HCO₃⁻ and OH⁻ transport activity. In contrast, when cells were air-dried to zero turgor, and rewetted to restore turgor, no significant effect on OH⁻ transport was observed.     

Unique cellular effect of the herbicide bromoxynil revealed by electrophysiological studies using characean cells

In a previous paper, we proposed that the primary action of the herbicide bromoxynil (BX; 3,5-dibromo-4-hydroxybenzonitrile) is cytosol acidification, based on the fact that bromoxynil induced the inhibition of cytoplasmic streaming and cell death of Chara corallina in acidic external medium (Morimoto and Shimmen in J Plant Res 121:227–233, 2008). In the present study, electrophysiological analysis of the BX effect was carried out in internodal cells of C. corallina. Upon addition of BX, a large and rapid pH-dependent depolarization was induced, supporting our hypothesis. Ioxynil, which belongs to the same group as bromoxynil, also induced a large and rapid membrane depolarization in a pH-dependent manner. On the other hand, four herbicides belonging to other groups of herbicides did not induce such a membrane depolarization. Thus, BX has a unique cellular effect. The decrease in the electro-chemical potential gradient for H⁺ across the plasma membrane appears to result in inhibition of cell growth and disturbance of intracellular homeostasis in the presence of BX.     

Biophysical mechanisms of physiological water exchange with the surroundings by the cells of the <Emphasis Type="Italic">Nitella translucens</Emphasis> and <Emphasis Type="Italic">Chara corallina</Emphasis> plants

In the present study, we discussed the biophysical mechanisms of stationary water exchange with the surroundings by the Nitella translucens and Chara corallina plants. It was postulated that these plants, which subsist under total immersion in a water medium, conduct water exchange within single cells individually. With the application of the equations of mechanistic formalism for membrane transport to our investigations (Kargol and Kargol 2000, Kargol 2001, Kargol 2002, Kargol and Kargol 2003, 2003*), it was demonstrated that individual cells of these plants can simultaneously absorb and remove considerable amounts of water at constant cell volume, i.e. under stationary conditions. Water absorption is osmosis-driven, and its removal is effected by the cell turgor pressure.     

Turgor regulation inValonia macrophysa following acute osmotic shock

Summary The marine algaValonia macrophysa an inhabitant of shallow subtropical waters, is subjected to sudden dilutions of external seawater during rain showers. This study describes the mechanisms involved in turgor pressure regulation following acute hyposmotic shock. Turgor regulation is 88% effective and complete within 4 hr following hyposmotic shocks of up to –10 bar. Loss of vacuolar K⁺, Na⁺ and Cl^– accounts for the decrease in vacuolar osmotic pressure associated with turgor regulation. A novel mechanism of turgor regulation is exhibited byValonia macrophysa given hyposmotic shocks greater than about –4 bar. Such an osmotic shock causes cell wall tension to increase above a critical value of about 6×10⁵ dyne/cm, whereupon the protoplasm ruptures and the cell wall stretches irreversibly at a localized site. The protoplasm rupture is suggested by (1) a large abrupt increase in K⁺ efflux (as measured by⁸⁶Rb⁺), (2) a rapid decrease in turgor pressure as measured with a pressure probe, and (3) sudden depolarization of the vacuole potential. Evidence for an increase in cell wall permeability includes efflux from the vacuole of dextran (mol wt 70,000), which normally has a very low cell wall permeability, and scanning electron micrographs which show a trabeculated scar area in the cell wall. This mechanism of turgor regulation is physiologically important because 98% of the cells regained normal growth rate and turgor following acute osmotic shock.     

Microtubule orientation in globular leaflet cells of <Emphasis Type="Italic">Chara inflata</Emphasis>

Chara inflata has globular leaflet cells and cylindrical internodal cells. The morphology of the leaflet cells is different from that of other Characeae. The orientation of cortical microtubules (MTs) in young leaflet and internodal cells of this species was analyzed by immunofluorescence microscopy. MTs with random orientation were observed in leaflet cells, while those relatively transverse to the cell axis were observed in cylindrical internodal cells. In cylindrical leaflet cells in Chara corallina, transverse MTs were observed. These results imply that C. inflata is a morphological mutant lacking a mechanism for orienting cortical MTs transverse in leaflet cells.     

Control of phosphate transport across the plasma membrane of Chara corallina

This paper examines the control of phosphate uptake into Chara corallina. Influxes of inorganic phosphate (Pi) into isolated single internodal cells were measured with ³²Pi. Pretreatment of cells without Pi for up to 10 d increased Pi influx. However, during this starvation the concentrations of Pi in both the cytoplasm and the vacuole remained quite constant. When cells were pre-treated with 0.1 mM Pi, the subsequent influx of Pi was low. Under these conditions the Pi concentrations in the cytoplasm was almost the same as that of Pi-starved cells, but vacuolar Pi increased with time. Transfer of cells from medium containing 0.1 mM Pi to Pi-free medium induced an increase of Pi influx within 3 d irrespective of the concentration of Pi in the vacuole.During Pi starvation, neither the membrane potential nor the cytoplasmic pH changed. Manipulation of the cytoplasmic pH by weak acids or ammonium decreased the Pi influx slightly.Pi efflux was also measured, using cells loaded with ³²Pi. Addition of a low concentration of Pi in the rinsing medium rapidly and temporarily induced an increase in the efflux.The results show that Pi influx is controlled by factors other than simple feedback from cytoplasmic or vacuolar Pi concentrations or thermodynamic driving forces for H⁺-coupled Pi uptake. It is suggested that uptake of Pi is controlled via the concentration of Pi in the external medium through induction or repression of two types of plasma membrane Pi transporters.Key words: Chara corallina, membrane transport, phosphate influx, phosphate starvation      

Studies on semipermeability and electrical characteristics in membranes of<Emphasis Type="Italic"> Chara</Emphasis> cells fixed with glutaraldehyde

When internodal cells of Chara corallina were incubated in a solution containing 1% glutaraldehyde, an increase in intracellular osmolality was observed, and this indicates that the plasma membrane maintained its semipermeability. The effect on the membrane potential was studied. Although the active component generated by the electrogenic proton pump was lost, the passive component (more negative than –100 mV) was maintained during glutaraldehyde treatment for more than 1–2 h. The membrane resistance increased significantly. It was found that the tonoplasts also maintained their semipermeability during glutaraldehyde treatment.     

Increase in cytoplasmic calcium content in internodal cells of Lamprothamnium upon hypotonic treatment

Abstract Internodal cells of Lamprothamnium succinctum, a brackish water Characeae, regulate turgor pressure in response to changes in external osmotic pressure (turgor regulation). When internodal cells were transferred to a hypotonic medium containing 3.9 mol m^?3 Ca²⁺, the cell osmotic pressure decreased and the original turgor pressure was recovered. During turgor regulation Ca content of the cytoplasm increased significantly. Lowering the external Ca²⁺ concentration from 3.9 to 0.01 mol m^?3 inhibited this increase in cytoplasmic calcium content. In a hypotonic medium containing 0.01 mol m^?3 Ca²⁺, turgor regulation was inhibited as previously reported (Okazaki & Tazawa, 1986a). Thus transient increase in cytoplasmic Ca, probably in the ionized form, induced by hypotonic treatment may play an important role in turgor regulation.     

Mechanism of acquisition of exogenous bicarbonate by internodal cells of Chara corallina

Electrophysiological measurements on internodal cells of the alga, Chara corallina Klein ex Willd., em. R.D.W., showed that the potential across the plasmalemma was sensitive to the level of exogenous HCO ₃ ^- . In alkaline solutions (pH 8) the membrane potential depolarized by 50–75 mV when exogenous HCO ₃ ^- was removed from the bathing medium. In the presence of exogenous HCO ₃ ^- , the membrane potential rapidly hyperpolarized when the cell was given a brief dark treatment; in the light the potential was approx.-240 mV; after the cell had been in the dark for 3–6 min the potential was -330 to -350 mV. In the absence of exogenous HCO ₃ ^- the potential only hyperpolarized slowly and to a much smaller extent when cells were placed in the dark. Upon re-illuminating the cell, the potential further hyperpolarized, transiently, and then rapidly depolarized back towards the light-adapted value. (These responses were only obtained when cells were not perturbed by microelectrode insertion into the vacuole.) Analysis of membrane potential and experiments with the extracellular vibrating electrode indicated a high level of correlation between the light- and dark-induced changes in membrane potential and extracellular currents. However, when experiments were conducted in HCO ₃ ^- -free media that contained 1.0 mM phosphate buffer, pH 8, it was found that the dark-induced hyperpolarization of the membrane potential and the light-dependent extracellular currents could be maintained in the absence of exogenous HCO ₃ ^- . These results are interpreted in terms of two basic models by which internodal cells of C. corallina may acquire exogenous HCO ₃ ^- for photosynthesis. They are consistent with HCO ₃ ^- being transported across the plasmalemma via an electrically neutral HCO ₃ ^- –H⁺ cotransport system. The hyperpolarizing response is thought to be the consequence of the operation of an electrogenic H⁺-translocating ATPase that has a transport stoichiometry of 1 H⁺ per ATP hydrolyzed.Abbreviation CPW/B artificial Chara pond water containing exogenous bicarbonate     

The effect of divalent cations on Na+ tolerance in Charophytes. II: Chara corallina

Abstract The freshwater Charophyte Chora corallina dies when subjected to 70 molm^?3 NaCl if the Ca²⁺ concentration is 0.1 mol m ^?3. This stress is accompanied by a depolarization of the cell to a membrane potential more positive than E_K, a net influx of Na⁺ into the vacuole, and a net loss of K⁺ from the vacuole. Raising the Ca²⁺ concentration to 7 mol m ^?3 in the presence of elevated Na⁺ restores the Na⁺ to Ca²⁺ ratio to 10: 1 as in the control solution, and results in enhanced survival even though turgor is not regulated. Mg²⁺ is not a good substitute for Ca²⁺. It is suggested that the main reason that C. corallina fails to occupy saline habitats is its failure to regulate turgor, not sensitivity to Na ⁺, since the latter is similar to that seen in C. buckellii, which is found in saline habitats.     

Physiological Control of Chloride Transport in Chara corallina: I. EFFECTS OF LOW TEMPERATURE, CELL TURGOR PRESSURE, AND ANIONS

The rate of Cl⁻ transport at the plasma membrane of the freshwater alga Chara corallina is investigated with respect to possible in vivo controls acting in addition to the two well established ones of cytoplasmic Cl⁻ and cytoplasmic pH. In contrast with results from many other plant tissues, halides appear to be the only anions capable of inhibiting Cl⁻ transport, either from the outside or inside surfaces of the plasma membrane. Cell turgor pressure was also investigated. It was found that neither the influx of Cl⁻ nor that of K⁺ or HCO₂⁻ is sensitive to turgor. Internal osmotic pressure is also insensitive to turgor, a situation contrasting with that in closely related brackish water charophytes.     

D2O-induced cell excitation

Summary The effects of deuterium oxide (D₂O) on giant internodal cells of the fresh water algaChara gymnophylla, were investigated. D₂O causes membrane excitation followed by potassium leakage. The primary effect consists of an almost instantaneous membrane depolarization resembling an action potential with incomplete repolarization. A hypothesis was proposed which deals with an osmotic stress effect of D₂O on membrane ion channels followed by the supression of the electrogenic pump activity. The initial changes (potential spike and rapid K⁺ efflux) may represent the previously undetected link between the D₂O-induced temporary arrest of protoplasmic streaming and the early events triggered at the plasma membrane level as the primary site of D₂O action.     

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     

Effect of Sulfhydryl Reagents on the Biophysical Properties of the Plasmalemma of Chara corallina

The administration of the sulfhydryl reagent N-ethyl-maleimide (NEM) to internodal cells of Chara corallina caused alterations in the biophysical properties of the plasmalemma, as measured with electrophysiological and radioactive tracer techniques. The membrane potential depolarized to, or near, the calculated Nernst potential for potassium (E_K) after 30 seconds' exposure to 0.1 millimolar NEM. During this time, the ATP level did not decrease below the control value, and the specific membrane resistance did not increase; only upon further exposure to NEM did the resistance approach the value observed in the dark. In the depolarized state, the membrane potential responded to changes in the external potassium concentration in the manner of a K⁺-electrode, but it retained it's relative insensitivity to external sodium.     

Characteristics of Hg- and Zn-sensitive Water Channels in the Plasma Membrane of Chara Cells*

Hydraulic conductivity (L_p) of the plasma membrane of Chara corallina was inhibited by HgCl₂ maximally by about 95%. The inhibition was reversed by 2-mercaptoethanol, reconfirming the observation obtained by Henzler and Steudle (1995). The results suggest that osmotic water transport through Chara cells occurs mostly via mercury-sensitive water channels containing thiol groups. ZnCl₂ dissolved in APW (pH 5.6) also inhibited L_p by about 80% within 1–2 h, while ZnCl₂ dissolved in Hepes-Tris buffer (pH 7.4) inhibited it by about 90% within several minutes. Inhibition of L_p by ZnCl₂ was also reversed by 2-mercaptoethanol, suggesting that zinc acts also on thiol groups of water channel proteins. Cells from which tonoplast had been removed by ECTA were as sensitive to both HgCl₂ and ZnCl₂ (pH 7.4) as normal cells. This demonstrates that water channels sensitive to thiol reagents really exist in the plasma membrane. On the other hand, ZnCl₂ (pH 5.6) did not inhibit L_p of tonoplast-free cells. This may be accounted for by assuming first that Hg- and Zn-sensitive thiol groups of water channels may exist on the cytoplasmic side, and second that ZnCl₂ in acidic medium may exist in ionized species which can be chelated by EGTA after permeation. The polar water permeability, or the endoosmotic L_p being larger than the exoosmotic one, was not affected by lowering the rate of osmosis by decreasing the osmotic gradient for transcellular osmosis down to 0.02 M sorbitol. The polarity disappeared when osmotic water flow through water channels was completely inhibited by HgCl₂. Thus the polarity is assumed to be intrinsic to water channels in the plasma membrane.     

Turgor regulation in a brackish water charophyte,Lamprothamnium succinctum

Internodal cells of a brackish water charophyte,Lamprothamnium succinctum (A. Br. in Ash.) R.D.W. regulate the turgor pressure in response to changes in both the cellular and the external osmotic pressures. During turgor regulation upon hypotonic treatment, net effluxes of K⁺ and Cl⁻ from the vacuole, membrane depolarization, a transient increase in the electrical membrane conductance and a transient increase in concentration of cytoplasmic Ca²⁺ are induced. Activation of the plasmalemma Ca²⁺ channels and the Ca²⁺-controlled passive effluxes of K⁺ and Cl⁻ through the plasmalemma ion channels are postulated.     

Inversion of extracellular current and axial voltage profile inChara andNitella

Summary Reducing the pH of the bathing solution from 8.2 to pH 6 can induce an inversion of the extracellular current pattern that develops at the surface ofChara corallina internodal cells. A similar result can be obtained on some cells by changing the medium to a pH value of 10. In noninvertingChara cells the currents were strongly reduced when the pH value of the medium was changed between 3 and 11. Simultaneous measurements of theChara transmembrane potential in the acid and alkaline regions revealed that a light-induced electrical potential gradient of approximately 24 mV was present in the axial (or longitudinal) direction. Correlated to the external current pattern inversion was an inversion of this internal longitudinal voltage gradient. Reillumination ofNitella cells, after a period of darkness, often resulted in a complete inversion of the extracellular current pattern. These results are discussed in terms of spatial and temporal control of membrane transport processes, and in particular the control of current loops that pass through these cells.