Elucidation of the Mechanisms Underlying Hypo-osmotically Induced Turgor Pressure Regulation in the Marine Alga Valonia utricularis

Exposure of the giant marine alga Valonia utricularis to acute hypo-osmotic shocks induces a transient increase in turgor pressure and subsequent back-regulation. Separate recording of the electrical properties of tonoplast and plasmalemma together with turgor pressure was performed by using a vacuolar perfusion assembly. Hypo-osmotic turgor pressure regulation was inhibited by external addition of 300 microM of the membrane-permeable ion channel blocker 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB). In the presence of 100 microM NPPB, regulation could only be inhibited by simultaneous external addition of 200 microM 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS), a membrane-impermeable inhibitor of Cl(-) transport. At concentrations of about 100 microM, NPPB seems to selectively inhibit Cl(-) transporters in the tonoplast and K(+) transporters in the plasmalemma, whereas 300 microM NPPB inhibits K(+) and Cl(-) transporters in both membranes. Evidence was achieved by measuring the tonoplast and plasmalemma conductances (G(t) and G(p)) in low-Cl(-) and K(+)-free artificial seawater. Inhibition of turgor pressure regulation by 300 microM NPPB was accompanied by about 85% reduction of G(t) and G(p). Vacuolar addition of sulfate, an inhibitor of tonoplast Cl(-) transporters, together with external addition of DIDS and Ba(2+) (an inhibitor of K(+) transporters) also strongly reduced G(p) and G(t) but did not affect hypo-osmotic turgor pressure regulation. These and many other findings suggest that KCl efflux partly occurs via electrically silent transport systems. Candidates are vacuolar entities that are disconnected from the huge and many-folded central vacuole or that become disconnected upon disproportionate swelling of originally interconnected vacuolar entities upon acute hypo-osmotic challenge.     

Turgor pressure changes trigger characteristic changes in the electrical conductance of the tonoplast and the plasmalemma of the marine alga Valonia utricularis

The giant marine alga Valonia utricularis is capable of regulating its turgor pressure in response to changes in the osmotic pressure of the sea water. The turgor pressure response comprises two phases, a fast, exponential phase arising exclusively from water shifting between the vacuole and the external medium (time constant about 10 min) and a second very slow, almost exponential phase adjusting (but not always) the turgor pressure near to the original value by release or uptake of KCl (time constant about 5 h). The changes in the vacuolar membrane potential as well as in the individual conductances of the tonoplast and plasmalemma accompanying turgor pressure regulation were measured by using the vacuolar perfusion assembly (with integrated microelectrodes, pressure transducers and pressure‐regulating valves) as described by Wang et al. (J. Membrane Biology 157, 311–321, 1997). Measurements on pressure‐clamped cells gave strong evidence that the turgor pressure, but not effects related to water flow (i.e. electro‐osmosis or streaming potential) or changes in the internal osmotic pressure and in the osmotic gradients, triggers the cascade of osmotic and electrical events recorded after disturbance of the osmotic equilibrium. The findings definitely exclude the existence of osmosensors as postulated for other plant cells and bacteria. There was also evidence that turgor pressure signals were primarily sensed by ion transporters in the vacuolar membrane because conductance changes were first recorded in the many‐folded tonoplast and then significantly delayed in the plasmalemma independent of the direction of the osmotic challenge. Consistently, turgor pressure up‐regulation (but not down‐regulation) could be inhibited reversibly by external addition of the K⁺ transport inhibitor Ba²⁺ and/or by the Cl^– transport inhibitor 4,4′‐diisothiocyanatostilbene‐2,2′‐disulfonic acid (DIDS). Extensive studies under iso‐, hyper‐ and hypo‐osmotic conditions revealed that K⁺ and Cl^– contribute predominantly to the plasmalemma conductance. Addition of 0.3 mm NaCN showed further that part of the K⁺ and Cl^– transporters depended on ATP. These transporters are apparently up‐regulated upon hyper‐osmotic, but not hypo‐osmotic challenge. These findings explain the strong increase of the K⁺ influx upon lowering turgor pressure and the less pronounced pressure‐dependence of the Cl^– influx of V. utricularis reported in the literature. The data derived from the blockage experiments under hypo‐osmotic conditions were also equally consistent with the experimental findings that the K⁺ efflux is solely passive and progressively increases with increasing turgor pressure due to an increase of the volumetric elastic modulus of the cell wall. However, despite unravelling some of the sequences and other components involved in turgor pressure regulation of V. utricularis the co‐ordination between the ion transporters in the tonoplast and plasmalemma remains unresolved because of the failure to block the tonoplast transporters by addition of Ba²⁺ and DIDS from the vacuolar side.     

Effects of ABA on 86Rb+ fluxes at plasmalemma and tonoplast of stomatal guard cells

Abscisic acid (ABA) induces a transient stimulation of ⁸⁶Rb⁺ from isolated guard cells of Commelina communis L. When ABA is added after 30–50 min of wash-out in the absence of ABA, when tracer is almost entirely vacuolar, its effects on vacuolar release are measured. When ABA is added early in the wash-out (at 2–4 min), when both cytoplasm and vacuole are labelled, the resulting efflux includes both vacuolar and cytoplasmic contributions. Detailed comparison of rates of efflux in the absence of ABA, and in the presence of ABA added early and late in the wash-out, allows the effects of ABA on plasmalemma and tonoplast fluxes to be assessed. Three effects of ABA can be distinguished: these are stimulation of the ⁸⁶Rb⁺ flux from vacuole to cytoplasm (by twofold to 6.7-fold); stimulation of the plasmalemma efflux, by up to twofold, a smaller factor than that of the tonoplast effect and variable between experiments; and a doubling of the half-time for cytoplasmic exchange in ABA, taken to reflect an increase in cytoplasmic ion content as ions flood out of the vacuole. Concentrations of ABA of 0.1–0.2 µM and 1–10 µM are equally effective in the stimulation of plasmalemma efflux, but the effects on tonoplast fluxes are both delayed and reduced at low external concentrations of ABA. It is argued that the delay reflects the need for a threshold internal ABA to be reached before the initiation of vacuolar release, and the reduction reflects the sensitivity of the extent of activation of tonoplast ion channels to concentration of internal ABA. It is likely that the plasmalemma change is mediated by external ABA, and could be the result of the modulation of the stretch-activated channel suggested previously.     

Characterization of vacuolar polypeptides of barley mesophyll cells by two-dimensional gel electrophoresis and by their affinity to lectins

Vacuoles were isolated from primary leaves of barley (Hordeum vulgare L.) by mechanical breakage of protoplasts, and their polypeptide composition analyzed by two-dimensional gel electrophoresis. Vacuoplasts which consist of the vacuole, a portion of the plasmalemma and of the cytoplasma were prepared from protoplasts by ultracentrifugation. By comparing the vacuolar polypeptide pattern with polypeptide patterns of isolated chloroplasts and of vacuoplasts, vacuolar polypeptides could clearly be distinguished from polypeptides derived from cross-contaminating cell compartments. At least 14 polypeptides of apparent molecular mass between 12 and 76 kilodaltons and an isoelectric point between 4.5 and 7.6 could be attributed to the tonoplast fraction of the vacuole, and 35 polypeptides to the soluble fraction of the vacuole. Several lectins with different specificity were employed to characterize the degree and nature of glycosylation of vacuolar polypeptides. Concanavalin A bound to a large number of polypeptides. Three out of the 14 tonoplast polypeptides exhibited detectable carbohydrate moieties and almost two-thirds of the surveyed soluble polypeptides were glycosylated.Abbreviations IEF isoelectric focussing - kDa kilodalton - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Compartment analysis of plant cells by means of turgor pressure relaxation: I. Theoretical considerations

Summary Turgor pressure relaxation curves for individual plant cells represent an important source of information for the plant physiologist. However, the accurate interpretation of these curves is strongly dependent on the model chosen to describe the plant cell. If the compartmentation of the cell into vacuole and cytoplasm is taken into account, a theoretical analysis shows that pressure relaxation curves can be represented by the sum of two exponential functions. Givena priori assumptions about the exchange area of the tonoplast and its reflection coefficient, the hydraulic conductivities of the plasmalemma and tonoplast can be determined and the proportion of the total cell volume occupied by the cytoplasm is also obtained. Numerical solutions to the flow equations have shown that the biphasic nature of pressure relaxations is maintained even when a permeable tonoplast is assumed. Depending on the magnitude of the reflection coefficient and the permeability of the vacuolar membrane, large errors can arise in the determination of the hydraulic conductivity of the tonoplast. However, under certain conditions, even a highly permeable tonoplast may behave like a nonpermeable membrane during pressure relaxation.     

Control of Volume and Turgor in Stomatal Guard Cells

Water loss from plants is determined by the aperture of stomatal pores in the leaf epidermis, set by the level of vacuolar accumulation of potassium salt, and hence volume and turgor, of a pair of guard cells. Regulation of ion fluxes across the tonoplast, the key to regulation of stomatal aperture, can only be studied by tracer flux measurements. There are two transport systems in the tonoplast. The first is a Ca²⁺-activated channel, inhibited by phenylarsine oxide (PAO), responsible for the release of vacuolar K⁺(Rb⁺) in response to the “drought” hormone, abscisic acid (ABA). This channel is sensitive to pressure, down-regulated at low turgor and up-regulated at high turgor, providing a system for turgor regulation. ABA induces a transient stimulation of vacuolar ion efflux, during which the flux tracks the ion content (volume, turgor), suggesting ABA reduces the set-point of a control system. The second system, which is PAO-insensitive, is responsible for an ion flux from vacuole to cytoplasm associated with inward water flow following a hypo-osmotic transfer. It is suggested that this involves an aquaporin as sensor, and perhaps also as responder; deformation of the aquaporin may render it ion-permeable, or, alternatively, the deformed aquaporin may signal to an associated ion channel, activating it. Treatment with inhibitors of aquaporins, HgCl₂ or silver sulfadiazine, produces a large transient increase in ion release from the vacuole, also PAO-insensitive. It is suggested that this involves the same aquaporin, either rendered directly ion-permeable, or signalling to activate an associated ion channel.     

ULTRASTRUCTURAL STUDIES OF PINUS PINASTER NEEDLES: THE ENDODERMIS

The endodermis in the needles of Pinus pinaster was examined with light and electron microscopy. The endodermis is composed of very long, radially flattened cells, filled with a large central vacuole, which contains spherical dense bodies whose concentration decreases from the ends of the cell to the middle part. They are individually surrounded by a fine granular matrix. The central vacuole is bounded by a thick tonoplast. Other small, clear vacuoles are limited by a thin tonoplast. The parietal cytoplasm contains relatively few ribosomes, long slender chloroplasts, and lipid bodies. The smooth endoplasmic reticulum is highly developed along the tangential walls and frequently connected, or apposed, to the plasma membrane. Numerous primary pit fields are seen in the radial walls which are lignified and in the tangential walls; the latter exhibit a characteristic loosening of the outer layer of the wall. The lipid bodies are connected to endoplasmic reticulum tubules. The role of the endodermis in the active transport of water inside the needle is discussed in reference to previous physiological studies. The chemical composition of the vacuolar dense bodies is as yet unknown.     

Determination of the Individual Electrical and Transport Properties of the Plasmalemma and the Tonoplast of the Giant Marine Alga Ventricaria ventricosa by Means of the Integrated Perfusion/Charge-Pulse Technique: Evidence for a Multifolded Tonoplast

The charge-pulse relaxation spectrum of nonperfused and perfused (turgescent) cells of the giant marine alga Ventricaria ventricosa showed two main exponential decays with time constants of approximately 0.1 msec and 10 msec, respectively, when the cells were bathed in artificial sea water (pH 8). Variation of the external pH did not change the relaxation pattern (in contrast to other giant marine algae). Addition of nystatin (a membrane-impermeable and pore-forming antibiotic) to the vacuolar perfusion solution resulted in the disappearance of the slow exponential, whereas external nystatin decreased dramatically the time constant of the fast one. This indicated (by analogy to corresponding experiments with Valonia utricularis, J. Wang, I. Spiess, C. Ryser, U. Zimmermann, J. Membrane Biol. 157: 311-321, 1997) that the fast relaxation must be assigned to the RC-properties of the plasmalemma and the slow one to those of the tonoplast. Consistent with this, external variation of [K+]o or of [Cl-]o as well as external addition of K+- or Cl--channel/carrier inhibitors (TEA, Ba2+, DIDS) affected only the fast relaxation, but not the slow one. In contrast, addition of these inhibitors to the vacuolar perfusion solution had no measurable effect on the charge-pulse relaxation spectrum. The analysis of the data in terms of the "two membrane model" showed that K+- and (to a smaller extent) Cl--conducting elements dominated the plasmalemma conductance. The analysis of the charge-pulse relaxation spectra also yielded the following area-specific data for the capacitance and the conductance for the plasmalemma and tonoplast (by assuming that both membranes have a planar surface): (plasmalemma) Cp = 0.82 * 10(-2) F m-2, Rp = 1.69 * 10(-2) Omega m2, Gp = 5.9 * 10(4) mS m-2, (tonoplast) Ct = 7. 1 * 10(-2) F m-2, Rt = 14.9 * 10(-2) Omega m2 and Gt = 0.67 * 10(4) mS m-2. The electrical data for the tonoplast show that (in contrast to the literature) the area-specific membrane resistance of the tonoplast of these marine giant algal cells is apparently very high as reported already for V. utricularis. The exceptionally high value of the area-specific capacitance could be explained - among other interpretations - by assuming a 9-fold enlargement of the tonoplast surface. The hypothesis of a multifolded tonoplast was supported by transmission electronmicroscopy of cells fixed under maintenance of turgor pressure and of the electrical parameters of the membranes. This finding indicates that the tonoplast of this species exhibited a sponge-like appearance. Taking this result into account, it can be easily shown that the tonoplast exhibits a high-resistance (1.1 Omega m2). Vacuolar membrane potential measurements (performed in parallel with charge-pulse relaxation studies) showed that the potential difference across the plasmalemma was mainly controlled by the external K+-concentration which suggested that the resting membrane potential of the plasmalemma is largely a K+-diffusion potential. After permeabilization of the tonoplast with nystatin the potential of the intact membrane barrier dropped from about slightly negative or positive (-5.1 to +18 mV, n = 13) to negative values (-15 up to -68 mV; n = 8). This indicated that the cytoplasm of V. ventricosa was apparently negatively charged relative to the external medium. Permeabilization of the plasmalemma by addition of external nystatin resulted generally in an increase in the potential to slightly more positive values (-0.8 to +4.3 mV; n = 5), indicating that the vacuole is positively charged relative to the cytoplasm. These findings apparently end the long-term debate about the electrical properties of V. ventricosa. The results presented here support the findings of Davis (Plant Physiol. 67: 825-831, 1981), but are contrary to the results of Lainson and Field (J. Membrane Biol. 29: 81-94, 1976).     

Separate Determination of the Electrical Properties of the Tonoplast and the Plasmalemma of the Giant-Celled Alga Valonia utricularis: Vacuolar Perfusion of Turgescent Cells with Nystatin and Other Agents

In the giant-celled marine algae Valonia utricularis the turgor-sensing mechanism of the plasmalemma and the role of the tonoplast in turgor regulation is unknown because of the lack of solid data about the individual electrical properties of the plasmalemma and the vacuolar membrane. For this reason, a vacuolar perfusion technique was developed that allowed controlled manipulation of the vacuolar sap under turgescent conditions (up to about 0.3 MPa). Charge-pulse relaxation studies on vacuolarly perfused cells at different turgor pressure values showed that the area-specific resistance of the total membrane barrier (tonoplast and plasmalemma) exhibited a similar dependence on turgor pressure as reported in the literature for nonperfused cells: the resistance assumed a minimum value at the physiological turgor pressure of about 0.1 MPa. The agreement of the data suggested that the perfusion process did not alter the transport properties of the membrane barrier. Addition of 16 μm of the H⁺-carrier FCCP (carbonylcyanide p-trifluoromethoxyphenyhydrazone) to the perfusion solution resulted in a drop of the total membrane potential from +4 mV to −22 mV and in an increase of the area-specific membrane resistance from 6.8 × 10⁻² to 40.6 × 10⁻²Ωm². The time constants of the two exponentials of the charge pulse relaxation spectrum increased significantly. These results are inconsistent with the assumption of a high-conductance state of the tonoplast (R. Lainson and C.P. Field, J. Membrane Biol. 29:81–94, 1976). Depending on the site of addition, the pore-forming antibiotics nystatin and amphotericin B affected either the time constant of the fast or of the slow relaxation (provided that the composition of the perfusion solution and the artificial sea water were replaced by a cytoplasma-analogous medium). When 50 μm of the antibiotics were added externally, the fast relaxation process disappeared. Contrastingly, the slow relaxation process disappeared upon vacuolar addition. The antibiotics cannot penetrate biomembranes rapidly, and therefore, the findings suggested that the fast and slow relaxations originated exclusively from the electrical properties of the plasmalemma and the tonoplast respectively. This interpretation implies that the area-specific resistance of the tonoplast is significantly larger than that of the plasmalemma (consistent with the FCCP data) and that the area-specific capacitance of the tonoplast is unusually high (6.21 × 10⁻² Fm⁻² compared to 0.77 × 10⁻² Fm⁻² of the plasmalemma). Thus, we have to assume that the vacuolar membrane of V. utricularis is highly folded (by a factor of about 9 in relation to the geometric area) and/or contains a fairly high concentration of mobile charges of an unknown electrogenic ion carrier system. Received: 22 October 1996/Revised: 16 January 1997     

Structural Peculiarities Dominate the Turgor Pressure Response of the Marine Alga <Emphasis Type="Italic">Valonia utricularis</Emphasis> upon Osmotic Challenges

The pressure response of (plant) cells to osmotic challenges depends on the reflection coefficient, sigma, of osmotically active solutes; it is less than predicted by the van't Hoff equation if sigma < 1. In Valonia utricularis, sigma is significantly reduced by internal (and, to a lesser extent, by external) unstirred layers, protecting the cytoplasm against vacuolar osmotic fluctuations. As shown by scanning and transmission electron microscopy, diffusion-restricted spaces are formed by innumerable small vacuoles that are interconnected with each other and with the central vacuole. They are embedded in networks of cytoplasmic strands connecting and encircling the organelles. Unstirred layers are also created in the central vacuole by an extensive network of acid mucopolysaccharide filaments (visualized by alcian blue staining). Mucopolysaccharides apparently also affect steady-state turgor by reducing the water activity. When the effective vacuolar osmotic pressure was adjusted to that of the bath by perfusion with an artificial vacuolar sap (AVS), an "offset turgor pressure" of 17 +/- 5 kPa was recorded. Consistent with the ultrastructural data, sigma values less than unity were calculated from the pressure response upon vacuolar addition of KCl or sucrose by perfusion (sigma(iKCl) = 0.63 +/- 0.13; sigma(isuc) = 0.58 +/- 0.17). Dilution of AVS yielded slightly higher sigma(iKCl) values (0.73 +/- 0.35). External addition to the artificial sea water (ASW) indicated that sigma(e) > sigma(i) for these osmotica. However, even in this case, sigma(esuc) (0.86 +/- 0.09) and sigma(ePEG) (0.58 +/- 0.08) were significantly less than sigma(eNaCl) (0.94 +/- 0.05) and sigma(eKCl) (0.91 +/- 0.13), presumably due to unstirred layers within the 4 micro m thick cell wall. Consistent with the low sigma values, a partial replacement of NaCl by osmotically equivalent amounts of sucrose (ASW(suc)), PEG and dextran, respectively, as well as replacement of Cl(-) by the large anion MES(-) induced an 'anomalous' hyposmotic turgor pressure response followed by the usual backregulation of pressure. After a 2-day preincubation in ASW(suc), significantly lower sigma(e) values were obtained both hyperosmotically (sigma(eNaCl) = 0.78 +/- 0.14; sigma(esuc) = 0.72 +/- 0.15) and hyposmotically (sigma(eNaCl) = 0.70 +/- 0.17; sigma(esuc) = 0.63 +/- 0.09), probably due to long-term effects on membrane structure to be elucidated yet. The freshwater alga Chara corallina lacked these apparently closely related structural and biophysical features of Valonia.     

Light-Induced H+ Accumulation in the Vacuole of Nitellopsis obtusa

The effects of light on the pH in the vacuole and the electricpotential difference across the plasmalemma and the tonoplastof Nitellopsis obtusa were investigated by means of conventionaland H⁺-specific glass or antimony microelectrodes. Illuminationis found to bring about a decrease in the pH of the vacuolarsap by 0.1–0.5 units concomitant with a depolarizationof the cell. The light-induced changes of the potential differenceand the vacuolar pH depend in different ways on the pH of theexternal medium (pH_o). At pH_o 9.0 cells exhibit great light-inducedpotential changes (up to 100 mV), but only small pH changesof the vacuolar sap. At neutral or slightly acidic pH_o valuesthe amplitude of the light-induced pH changes in the vacuoleincreases up to 0.3–0.5 pH units, but the amplitudes ofthe potential changes at the plasmalemma are relatively small.At pH_o 9.0 a transient acidification of the medium is observedupon illumination whereas at lower pH values light-induced alkalinizationwas only seen. Transfer of the cells from pH_o 9.0 to pH_o 7.5results in a cell hyperpolarization by 60–80 mV and adecrease of the vacuolar pH by 0.4–0.5 units under lightconditions but has no significant effect on the potential andthe vacuolar pH in the darkness. It is proposed that mechanismsof active H⁺ extrusion from the cytoplasm are located both inthe plasmalemma and the tonoplast. The observed acidificationin the vacuole appears to be determined by a light-induced increaseof the concentration of H⁺ in the cytoplasm. The H⁺ conductionof the plasmalemma seems to increase on illumination. The patternof the light-induced H⁺ fluxes across the tonoplast and theplasmalemma depends crucially on the extent of the light-inducedchanges in the H⁺ conductance and on the electrochemical gradientfor H⁺ at the plasmalemma.     

Studies on the tonoplast action potential ofNitella flexilis

Summary The origins of the two peaks of the action potential inNitella flexilis were analyzed by inserting two microelectrodes. one into the vacuole and the other into the cytoplasm. It was unequivocally demonstrated that the rapid first peak was generated at the plasmalemma and the slow second peak at the tonoplast. MnCl₂ applied in the external medium abolished the second, tonoplast, peak but not the first, plasmalemma, peak, MnCl₂ also inhibited the cessation of the cytoplasmic streaming accompanying the action potential. CaCl₂ added in MnCl₂-containing medium recovered generation of the tonoplast action potential and the streaming cessation. Since it has been established that the cessation of cytoplasmic streaming on membrane excitation is caused by an increase in cytoplasmic free Ca^2– (Williamson, R.E., Ashley, C.C., 1982.Nature (London) 296:647–651: Tominaga, Y., Shimmen, T., Tazawa, M., 1983,Protoplasma 116:75–77), it is suggested that the tonoplast action potential is also induced by an increase in cytoplasmic Ca²⁺ resulting from the plasmalemma excitation. When vacuolar Cl was replaced with SO ₄ ² by vacuolar perfusion, the polarity of the second, slow peak was reversed from vacuolar positive to vacuolar negative with respect to the cytoplasm, supporting the previous report that the tonoplast action potential is caused by increase in Cl permeability (Kikuyama, M., Tazawa, M., 1976.J. Membrane Biol.29:95–110).     

Morphology and ultrastructure ofOlisthodiscus luteus (Raphidophyceae) with special reference to the taxonomy

A flattened discoid flagellate collected from the Seto Inland Sea, Japan, has been examined by light and electron microscopy. This alga agrees well withClisthodiscus luteus Carter. It has two heterodynamic flagella emerging from a furrow on the upward side of the cell that contains six to 13 yellow-green parietal chloroplasts. It does not rotate but smoothly glide while swimming. The cell has a thin periplast lying between the plasmalemma and chloroplasts. Neither lipid bodies nor mucocysts are seen in the periplast. The pyrenoid matrix being free from thylakoids is penetrated by several cytoplasmic canals from various directions. There are no vesicles of periplastidal network in the narrow space between chloroplast envelope and chloroplast ER. The ultrastructural features ofO. luteus are unique, sharing certain characters with the raphidophycean algae but others withPseudopedinella pyriformis, a unique member of the Chrysophyceae.     

Increased Expression of Vacuolar Aquaporin and H+-ATPase Related to Motor Cell Function in Mimosa pudica L

Mature motor cells of Mimosa pudica that exhibit large and rapid turgor variations in response to external stimuli are characterized by two distinct types of vacuoles, one containing large amounts of tannins (tannin vacuole) and one without tannins (colloidal or aqueous vacuole). In these highly specialized cells we measured the abundance of two tonoplast proteins, a putative water-channel protein (aquaporin belonging to the [gamma]-TIPs [tonoplast intrinsic proteins]) and the catalytic A-subunit of H+-ATPase, using either high-pressure freezing or chemical fixation and immunolocalization. [gamma]-TIP aquaporin was detected almost exclusively in the tonoplast of the colloidal vacuole, and the H+-ATPase was also mainly localized in the membrane of the same vacuole. Cortex cells of young pulvini cannot change shape rapidly. Development of the pulvinus into a motor organ was accompanied by a more than 3-fold increase per length unit of membrane in the abundance of both aquaporin and H+-ATPase cross-reacting protein. These results indicate that facilitated water fluxes across the vacuolar membrane and energization of the vacuole play a central role in these motor cells.     

Sodium fluxes in roots of Eleocharis uniglumis, a brackish water species

Abstract Fluxes of sodium across the plasmalemma and tonoplast of the roots of Eleocharis uniglumis have been measured using ²²Na. E. uniglumis (one glumed spike rush) was collected from an estuarine habitat where it was growing in a wide range of salinities (1 mM-50 mM Na). Compartmental analysis was used to determine sodium concentrations in the cytoplasm and the vacuole. Application of the Ussing-Teorell equation revealed the presence of sodium pumps in the plasmalemma and the tonoplast. Active sodium transport into the cytoplasm from the bathing medium was found to occur in most of the external sodium concentrations investigated. There also appeared to be active transport of sodium into the cytoplasm from the vacuole. In contrast to halophytes, high levels of sodium appeared to be accumulated in the cytoplasm of E. uniglumis roots.     

Electrochemical Potential Gradients of H+, K+, Ca2+, and Cl- across the Tonoplast of the Green Alga Eremosphaera Viridis

Using ion-selective microelectrodes, we measured the activity of H+, K+, Ca2+, and Cl- and the electrical potential both in the vacuole and in the cytoplasm of the unicellular green alga Eremosphaera viridis to obtain comparable values of the named parameters from the same object under identical conditions. The cytosol had a pH of 7.3, and activities of the other ions were 130 mM K+, 160 nM Ca2+, and 2.2 mM Cl-. We observed only small and transient light-dependent changes of the cytosolic Ca2+ activity. The vacuolar K+ activity did not differ significantly from the cytosolic one. The Ca2+ activity inside the vacuole was approximately 200 [mu]M, the pH was 5.0, and the Cl- activity was 6.2 mM. The concentrations of K+, Ca2+, and Cl- in cell extracts were measured by induction-coupled plasma spectroscopy and anion chromatography. This confirmed the vacuolar activities for K+ and Cl- obtained with ion-selective microelectrodes and indicated that approximately 60% of the vacuolar Ca2+ was buffered. The tonoplast potential was vanishingly low ([less than or equal to][plus or minus]2 mV). There was no detectable electrochemical potential gradient for K+ across the tonoplast, but there was, however, an obvious electrochemical potential gradient for Cl- (-26 mV), indicating an active accumulation of Cl- inside the vacuole.     

Dismantling of Arabidopsis thaliana mesophyll cell chloroplasts during natural leaf senescence

One of the earliest events in the process of leaf senescence is dismantling of chloroplasts. Mesophyll cell chloroplasts from rosette leaves were studied in Arabidopsis thaliana undergoing natural senescence. The number of chloroplasts decreased by only 17% in fully yellow leaves, and chloroplasts were found to undergo progressive photosynthetic and ultrastructural changes as senescence proceeded. In ultrastructural studies, an intact tonoplast could not be visualized, thus, a 35S-GFP::δ-TIP line with a GFP-labeled tonoplast was used to demonstrate that chloroplasts remain outside of the tonoplast even at late stages of senescence. Chloroplast DNA was measured by real-time PCR at four different chloroplast loci, and a fourfold decrease in chloroplast DNA per chloroplast was noted in yellow senescent leaves when compared to green leaves from plants of the same age. Although chloroplast DNA did decrease, the chloroplast/nuclear gene copy ratio was still 31:1 in yellow leaves. Interestingly, mRNA levels for the four loci differed: psbA and ndhB mRNAs remained abundant late into senescence, while rpoC1 and rbcL mRNAs decreased in parallel to chloroplast DNA. Together, these data demonstrate that, during senescence, chloroplasts remain outside of the vacuole as distinct organelles while the thylakoid membranes are dismantled internally. As thylakoids were dismantled, Rubisco large subunit, Lhcb1, and chloroplast DNA levels declined, but variable levels of mRNA persisted.     

Proton flows across the plasma membrane in microperforated characean internodes: tonoplast injury and involvement of cytoplasmic streaming

Microperforation of characean cell wall with a glass micropipette in the absence of the tonoplast impalement was found to cause rapid alkalinization of the apoplast by 2–3 pH units, which may rigidify the cell wall structure, thus protecting the cell from further injury. A similar but a deeper insertion of a microneedle, associated with piercing the tonoplast and with an action potential generation, led to a considerable delay in the apoplast alkalinization without affecting the amplitude of the eventual increase in pH. The retardation by the mechanically elicited action potential of the incision-mediated pH transients in the apoplast contrasted sharply to the enhancement of these pH transients by the action potential triggered electrically before the microperforation. Hence, the delay of the apoplast alkalinization was not related to basic ionic mechanisms of plant action potentials. Measurements of the vacuolar pH after mechanical elicitation of an action potential indicate that the tonoplast piercing was accompanied by leakage of protons from the vacuole into the cytoplasm, which may strongly acidify the cytoplasm around the wounded area, thus collapsing the driving force for H⁺ influx from the medium into the cytoplasm. The lag period preceding the onset of external alkalinization was found linearly related to the duration of temporal cessation of cytoplasmic streaming. The results suggest that the delayed alkalinization of the apoplast in the region of tonoplast wounding reflects the localized recovery of the proton motive force across the plasmalemma during replacement of the acidic cytoplasm with fresh portions of unimpaired cytoplasm upon restoration of cytoplasmic streaming.     

Effects of Water Stress on the Ultrastructure of Leaf Cells of Sorghum bicolor

The subcellular changes which occurred in sorghum leaves during increasing water stress and subsequent rewatering are described. Stomata were closed, abscisic acid levels were elevated, and the amounts of starch in the bundle sheath chloroplasts were much reduced by - 14 bars leaf water potential. Swelling of the outer chloroplast membrane, and reorganization of the tonoplast to form small vesicles from the large central vacuole, occurred by a leaf water potential of - 37 bars. Complete structural disruption of the tonoplast, as previously described for maize was not found. On rewatering, large amounts of starch reappeared within three hours. These findings strengthen the hypothesis that maintenance of tonoplast integrity is an important factor in the ability of plants to withstand drought.     

Actin-endoplasmic reticulum complexes inDrosera

In epidermal cells ofDrosera tentacles that have been preserved for ultrastructural analysis through high pressure freeze fixation and freeze substitution we describe the frequent occurrence of microfilament (MF)-endoplasmic reticulum (ER) complexes. These are found throughout the cytoplasm where they are observed in close association with the plasmalemma (PL), the tonoplast, nuclei, mitochondria, chloroplasts, and microbodies. The MF component of the complexes is identified as actin based on immunogold labelling with actin antibodies. The actin-ER complexes are prominent in the cortical cytoplasm. In this region a network of predominantly tubular ER occupies an intermediary position in which it associates closely with both the PL and the actin MFs. We suggest that the ER, especially those elements adjacent to the PL in the cortical cytoplasm, stabilizes the actin MFs and provides the necessary anchor against which the forces for cytoplasmic streaming are generated.Abbreviations CF chemical fixation - ER endoplasmic reticulum - FS freeze substitution - HPF high pressure freezing - MF microfilaments - MT microtubules - PL plasmalemma