Modelling of pattern formation and oscillations in pH and transmembrane potential near the cell membrane of Chara corallina

A mathematical model of potencial-dependent proton transfer across the membrane of Chara corallina cells is considered. To construct the model, partial differential equations describing the system dynamics in time and in space were used. The variables of the model are the proton concentration and membrane potential. The model describes the experimentally observed inhomogeneous distribution of transmembrane potential and pH along the membrane and oscillations of the potential and pH in time. A mechanism of the distribution of pH and membrane potential along the Chara corallina cell is suggested.     

Spatial organization of transport domains and subdomain formation in the plasma membrane of Chara corallina

Pattern formation mechanisms in developing organisms determine cellular differentiation and function. However, the components that interact during the manifestation of a spatial pattern are in general unknown. Characean algae represent a model system to study pattern formation. These algae develop alternating acid and alkaline transport domains that influence the pattern of growth. In the present study, it will be demonstrated that a diffusion mechanism is implicated in acid and alkaline domain formation and this growth pattern. Experiments on the characean growth pattern were performed that resulted in pronounced, however, unpredictable modifications in the original pattern. A major component involved in this pattern-forming mechanism emerged from the nonlinear kinetics of the H⁺-ATPase that is located in the plasma membrane of these algae. Based on these kinetics, a mathematical model was developed and numerically analyzed. As a result, the contribution of a diffusional component to the characean acid/alkaline pattern appeared most likely.This work was supported by the Deutsche Forschungsgemeinschaft (grant #571 1/1) to JF.     

Effects of Cations on the Cytoplasmic pH of Chara corallina

Smith, F. A. and Gibson, J.–L. 1985. Effects of cationson the cytoplasmic pH of Chara corallina.—J.exp. Bot.36: 1331–1340 Removal of external Ca²⁺ from cells of Chara corallina lowersthe cytoplasmic pH, as determined by the intracellular distributionof the weak acid 5,5–dimethyloxazolidine2–,4–dione(DM0), when the external pH is below about 60. This effect isreversed, at least partially, by addition of the following cationsto Ca²⁺-free solutions: tetraethylammonium (TEA⁺) and Na⁺ at5 or 10 mol m^-3, Li⁺ and Cs⁺ (10 mol m^-3), or Mg²⁺, Mn²⁺ andLa³⁺ (02 or 05 mol m^-3). Under the same conditions, increasesin pH sometimes, but not always, occur in the presence of 10mol m^-3 K⁺ or Rb⁺ The results are discussed in relation to the major transportprocesses that determine pH and the electric potential differenceacross the plasma membrane, namely fluxes of H⁺ and of K⁺. Thesimplest explanation of the effects of the various cations testedin this study is that they primarily affect pHi_c via changesin influx of H⁺ but direct effects on the H⁺ pump or on K⁺ fluxesmay also be involved Key words: Chara corallina, cytoplasmic pH, cations, H⁺transport     

Measurements of the Cytoplasmic pH of Chara corallina using Double-barrelled pH Micro-electrodes

A range of polymeric compounds was examined for their suitabilityas pressure-stabilizing agents in liquid membrane pH micro-electrodesfor intracellular use in plant cells. Of the compounds tested,mixtures of liquid proton sensor and nitrocellulose were foundto be superior to epoxy resins, polyvinylchloride and ethylcellulose. The electrical resistance of silicone rubber mixtureswas too high for micro-electrodes with tip diameters of 1.0µm. Double-barrelled micro-electrodes containing nitrocellulosemaintained excellent pH sensitivity for up to 1.0 impalementsof charophyte cells. Measurements of cytoplasmic pH were madein both internodal and whorl cells of Chora corallina over arange of experimental conditions. The response of cytoplasmicpH to rapid changes in external pH or illumination occurredover several minutes. The advantages of the use of double-barrelledpH micro-electrodes over other methods of intracellular pH measurementsuch as the distribution of weak acids (DMO), ³¹P-NMR and single-barrelledmicro-electrodes is discussed. Key words: pH micro-electrodes, cytoplasmic pH, charophytes     

Effect of Temperature and External pH on the Cytoplasmic pH of Chara corallina

Cytoplasmic pH (pH_c) in Chara corallina was measured (from [¹⁴C]stribution)as a function of external pH (pH₀)and temperature. With pH₀near 7, pH_c at 25?C is 7.80; pH_cincreases by 0.005 pH units?C^–1 temperature decrease, i.e. pH_c at 5 ?C is 7.90. WithpH? near 5.5, the increase in pH_c with decreasing temperatureis 0.015 units ?C^–1 between 25 and 15?C, but 0.005 units?C^–1 between 15 and 5?C. This implies a more precise regulationof pH_c with variations in pH_o at 5 or 15 ?C compared with 25?C. The observed dp H_c/dT is generally smaller than the –0.017units ?C^–1 needed to maintain a constant H⁺/OH^–1,or a constant fractional ionization of histidine in protein,with variation in temperature. It is closer to that needed tomaintain the fractional ionization of phosphorylated compoundsor of CO₂–HCO₃^– The value of dpH_c/dT has importantimplications for several regulatory aspects of cell metabolism.These include (all as a function of temperature) the rates ofenzyme reactions, the _H+ at the plasmalemma(and hence the energy available for cotransport processes),and the mechanism for pH_c regulation by the control of bidirectionalH⁺ fluxes at the plasmalemma.     

Involvement of membrane potential in alkaline band formation by internodal cells of Chara corallina

Internodal cells of Chara corallina form alkaline bands on their surface upon illumination via photosynthesis. In the present study, the effect of KCl on alkaline band formation was analyzed. When the extracellular KCl concentration was increased, alkaline band formation was extensively inhibited. Electrophysiological analysis unequivocally showed the need for inner negative membrane potential for alkaline band formation.     

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     

Regulation of the Cytoplasmic pH of Chara corallina: Response to Changes in External pH

Effects of external pH (pH_o) on the cytoplasmic pH (pH_c) ofChara corallina have been measured with the weak acid 5, 5-dimethyloxazolidine-2,4-dione (DMO) following standardized pretreatment of cells insolutions at pHo 4.5, 6.3 and 8.3. Irrespective of pH_c duringpretreatment, pH_o responded to pHo during the experimental periodsof 150–180 min or (in one experiment) 90–110 min.There were increases or decreases of about 0.5 in pHo when cellswere transferred from pH_o 4.5 to 8.3 or vice versa. In the darkpH_c was 0.2–0.3 units lower than the corresponding valuein the light. The results are discussed in relation to the factorsinvolved in the regulation of pH_c in C. corallina, which maybegin to break down below about pH_o4.5, as indicated by relativelylarge decreases in pH_c at low pH_o. Key words: Chara corallina, Cytoplasmic pH, External pH, DMO     

Fracture mechanics of the cell wall of Chara corallina

Previous mechanical studies using algae have concentrated on cell extension and growth using creep-type experiments, but there appears to be no published study of their failure properties. The mechanical strength of single large internode cell walls (up to 2 mm diameter and 100 mm in length) of the charophyte (giant alga) Chara corallina was determined by dissecting cells to give sheets of cell wall, which were then notched and fractured under tension. Tensile tests, using a range of notch sizes, were conducted on cell walls of varying age and maturity to establish their notch sensitivity and to investigate the propagation of cracks in plant cell walls. The thickness and stiffness of the walls increased with age whereas their strength was little affected. The strength of unnotched walls was estimated as 47 ± 13 MPa, comparable to that of some grasses but an order of magnitude higher than that published for model bacterial cellulose composite walls. The strength was notch-sensitive and the critical stress intensity factor K _1c was estimated to be 0.63 ± 0.19 MNm^−3/2, comparable to published values for grasses. Received: 4 April 2000 / Accepted: 21 July 2000     

Protein phosphorylation regulates actomyosin-driven vesicle movement in cell extracts isolated from the green algae,Chara corallina

In Characean cells endoplasmic streaming stops upon membrane depolarization accompanied by Ca(2+) entry. We investigated the mechanism of this cessation of endoplasmic streaming by reconstituting the vesicle movement in vitro. In a living cell of Chara corallina, there are a number of vesicles moving along actin cables. Vesicles in the endoplasm squeezed out of the cell into a medium containing Mg-ATP showed directional movements under a dark field microscope. When the extracted endoplasm was treated with 20 nM okadaic acid, vesicles showed only movements like the Brownian motion. When it was treated with 50 nM staurosporine, directional movements of vesicles were activated. These movements were analyzed by image processing of videomicroscopic records. Vesicle movements along F-actin filaments were also observed by merging both images of the same field by dark field microscopy and fluorescence microscopy, indicating that myosin on the vesicle surface was responsible for vesicle movements. We also examined the effects of okadaic acid and staurosporine on in vitro sliding of F-actin on Chara myosin. When Chara myosin was treated with 20 nM okadaic acid in the cell extract, the number of sliding F-actin filaments was greatly reduced. In contrast, it increased when Chara myosin was treated with 50 nM staurosporine. In addition, Chara myosin treated with protein kinase C greatly diminished its motility. These results suggest that inactivation of Chara myosin via its phosphorylation is responsible for cessation of endoplasmic streaming.     

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      

Excitation-induced dynamics of external pH pattern in Chara corallina cells and its dependence on external calcium concentration.

The influence of cell excitation and external calcium level on the dynamics of light-induced pH bands along the length of Chara corallina cells is studied in the present paper. Generation of an action potential (AP) transiently quenched these pH patterns, which was more pronounced at 0.05-0.1 mM Ca2+ than at higher concentrations of Ca2+ (0.6-2 mM) in the medium. After transient smoothing of the pH bands, some alkaline peaks reemerged at slightly shifted positions in media with low Ca2+ concentrations, while at high Ca2+ concentrations, the alkaline spots reappeared exactly at their initial positions. This Ca2+ dependency has been revealed by both digital imaging and pH microelectrodes. The stabilizing effect of external Ca2+ on the locations of recovering alkaline peaks is supposedly due to formation of a physically heterogeneous environment around the cell owing to precipitation of CaCO3 in the alkaline zones at high Ca2+ during illumination. The elevation of local pH by dissolving CaCO3 facilitates the reappearance of alkaline spots at their initial locations after temporal suppression caused by cell excitation. At low Ca2+ concentrations, when the solubility product of CaCO3 is not attained, the alkaline peaks are not stabilized by CaCO3 dissolution and may appear at random locations.     

FT-IR study of the Chara corallina cell wall under deformation

Fourier-transform infrared (FT-IR) microspectroscopy was used to investigate both the chemical composition of, and the effects of an applied strain on, the structure of the Chara corallina cell wall. The inner layers of the cell wall are known to have a transverse cellulose orientation with a gradient through the thickness to longitudinal orientation in the older layers. In both the native state and following the removal of various biopolymers by a sequential extraction infrared dichroism was used to examine the orientation of different biopolymers in cell-wall samples subjected to longitudinal strain. In the Chara system, cellulose microfibrils were found to be aligned predominantly transverse to the long axis of the cell and became orientated increasingly transversely as longitudinal strain increased. Simultaneously, the pectic polysaccharide matrix underwent molecular orientation parallel to the direction of strain. Following extraction in CDTA, microfibrils were orientated transversely to the strain direction, and again the degree of transverse orientation increased with increasing strain. However, the pectic polysaccharides of the matrix were not detected in the dichroic difference spectra. After a full sequential extraction, the cellulose microfibrils, now with greatly reduced crystallinity, were detected in a longitudinal direction and they became orientated increasingly parallel to the direction of strain as it increased.     

Control of Intracellular pH in Chara corallina during Uptake of Weak Acid

Butyric acid was used to acidify the cytoplasm of cells of Characorallina in order to study the mechanisms that regulate intracellularpH. Butyric acid was found to enter the cell rapidly, predominantlyas the undissociated acid, and to dissociate in the cytoplasmto yield high concentrations of the butyrate anion. A rapidreduction in cytoplasmic pH was followed by partial recovery.The reductions in cytoplasmic pH resulting from butyrate accumulationwere small compared to the proton load calculated from the cytoplasmicbuffering capacity and intracellular dissociation of butyricacid. The cytoplasmic and vacuolar buffering capacities, calculatedfrom titration of cell extracts, were 17.9 and 0.5 mol m^–3per pH unit respectively. It was concluded that pH control in Chara during weak acid accumulationwas mainly due to membrane transport (active efflux) of protons.The factors which might determine the rate and extent of protonefflux, such as the energy supply and the availability of ionsfor charge balance, were examined. Butyrate strongly inhibitedphotosynthesis and caused a slight reduction in the rate ofrespiration. The mechanism of inhibition of photosynthesis isdiscussed in relation to the reported effects of weak acidson isolated chloroplasts. Key words: Cytoplasmic pH, weak acids, Chara     

Through pore diameter in the cell wall of Chara corallina.

Determination of pore size of the cell wall of Chara corallina has been made by using the polyethylene glycol (PEG) series as the hydrophilic probing molecules. In these experiments, the polydispersity of commercial preparation of PEGs was allowed for. The mass share (gamma(p)) of polyethylene glycol preparation fractions penetrating through the pores was determined using a cellular 'ghost', i.e. fragments of internodal cell walls filled with a 25% solution of non-penetrating PEG 6000 and tied up at the ends. In water, such a 'ghost' developed a hydrostatic pressure close to the cell turgor which persisted for several days. The determination of gamma(p), for polydisperse polyethylene glycols with different average molecular mass (M) was calculated from the degree of pressure restoration after water was replaced by a 5-10% polymer solution. Pressure was recorded using a dynamometer, which measures, in the quasi-isometric mode, the force necessary for the partial compression of the 'ghost' in its small fragment. By utilizing the data on the distribution of PEG 1000, 1450, 2000, and 3350 fractions over molecular mass (M), it was found that gamma(p), for these polyethylene glycols corresponded to the upper limit of ML=800-1100 D (hydrodynamic radius of molecules, r(h)=0.85-1.05 nm). Thus, the effective diameter of the pores in the cell wall of Chara did not exceed 2.1 nm.     

Biophysical and Biochemical Regulation of Cytoplasmic pH in Chara corallina during Acid Loads

The contribution of membrane transport to regulation of cytoplasmicpH in Chara corallina has been measured during proton-loadingby uptake of butyric acid. In the short-term (i.e. up to 20min) uptake of butyric acid is not affected by removal of externalK⁺, Na⁺ or Cl^– but over longer periods uptake is decreased(by 20–50% in different experiments) in the absence ofexternal Na⁺ or, sometimes, K⁺. Influxes of both Na⁺ and K⁺increase temporarily after addition of butyrate, Na⁺ immediatelyand K⁺ after a lag. Effects on Cl^– influx are small butCl^– efflux increases enormously after a short lag. Anapproximate comparison of internal butyrate with changes inthe concentration of K⁺, Na⁺, and Cl^– suggests that initially(i.e. for a few min) cytoplasmic pH is determined by bufferingand possibly by some decarboxylation of organic acids (biochemicalpH regulation), and that biophysical pH regulation involvingefflux of H⁺ balanced by influxes of K⁺, Na⁺ and especiallyefflux of Cl^– progressively becomes dominant. When butyric acid is washed out of the cells, cytoplasmic pHis restored completely or partially (depending on the butyrateconcentration used) and this is independent of the presenceor absence of external Cl^–. Where Cl^– is present,its influx is relatively small. It is suggested that cytoplasmicpH is then controlled biochemically, involving the synthesisof an (unidentified) organic acid and the accumulation of acidicanions in place of butyurate lost from the cell. During thesecond application of butyrate, net Cl^– efflux is small:it is suggested that control of cytoplasmic pH then involvesdecarboxylation of the organic acid anions. The questions of the source of Cl^– lost from the cell(cytoplasm or vacuole) and of possible cytoplasmic swellingassociated with the accumulation of butyrate are discussed. Key words: Chara corallina, butyric acid, cytoplasmic pH, membrane transport     

Identifying cytoplasmic input to the cell wall of growing Chara corallina

Plants enlarge mostly because the walls of certain cells enlarge, with accompanying input of wall constituents and other factors from the cytoplasm. However, the enlargement can occur without input, suggesting an uncertain relationship between cytoplasmic input and plant growth. Therefore, the role of the input was investigated by quantitatively comparing growth in isolated walls (no input) with that in living cells (input occurring). Cell walls were isolated from growing internodes of Chara corallina and filled with pressurized oil to control turgor pressure while elongation was monitored. Turgor pressure in living cells was similarly controlled and monitored by adding/removing cell solution. Temperature was varied in some experiments. At all pressures and temperatures, isolated walls displayed turgor-driven growth indistinguishable in every respect from that in living cells, except the rate decelerated in the isolated walls while the living cells grew rapidly. The growth in the isolated walls was highly responsive to temperature, in contrast to the elastic extension that has been shown to be insensitive to similar temperatures. Consequently, strong intermolecular bonds were responsible for growth and weak bonds for elastic extension. Boiling the walls gave the same results, indicating that enzyme activities were not controlling these bonds. However, pectin added to isolated walls reversed their growth deceleration and returned the rate to that in the living cells. The pectin was similar to that normally produced by the cytoplasm and deposited in the wall, suggesting that continued cytoplasmic input of pectin may play a role in sustaining turgor-driven growth in Chara.     

Turgor pressure moves polysaccharides into growing cell walls of Chara corallina

BACKGROUND AND AIMS: Plant growth involves pressure-driven cell enlargement generally accompanied by deposition of new cell wall. New polysaccharides are secreted by the plasma membrane but their subsequent entry into the wall is obscure. Therefore, polysaccharides and gold colloids of various sizes were presented to the inner wall face as though they were secreted by the plasma membrane. METHODS: Primary cell walls were isolated from growing internodes of Chara corallina and one end was attached to a glass capillary. Solutions of dextran or suspensions of gold colloids were pushed into the lumen by oil in the capillary. The oil did not enter the wall, and the solution or suspension was pressed against the inner wall face, pressurized at various 'artificial' P (turgor pressure), and polymer or colloid movement through the wall was monitored. KEY RESULTS: Interstices in the wall matrix had a diameter of about 4.6 nm measured at high P with gold colloids. Small solute (0.8 nm) readily moved through these interstices unaffected by P. Dextrans of 3.5 nm diameter moved faster at higher P while dextran of 9 nm scarcely entered unless high P was present. Dextran of 11 nm did not enter unless P was above a threshold, and dextran of 27 nm did not enter at P as high as 0.5 MPa. The walls filtered the dextrans, which became concentrated against the inner wall face, and most polymer movement occurred after P stabilized and bulk flow ended. CONCLUSIONS: P created a steep gradient in concentration and mechanical force at the inner wall face that moved large polymers into small wall openings apparently by starting a polymer end or deforming the polymer mechanically at the inner wall face. This movement occurred at P generally accepted to extend the walls for growth.