Syringomycin, a bacterial phytotoxin, closes stomata

The effects of the bacterial phytotoxin, syringomycin, on stomata were investigated using detached leaves of Xanthium strumarium and isolated epidermes of Vicia faba. Syringomycin is known to cause K⁺ efflux in fungal and higher plant cells. Doses of syringomycin as low as 0.3 unit per square centimeter (about 0.88 pmole per square centimeter) resulted in measurable stomatal closure when applied through the transpiration stream of detached leaves; higher doses produced larger reductions in stomatal conductance. Stomatal apertures of isolated epidermes were also reduced by low concentrations (3.2 units per milliliter; 10⁻⁸ molar) of syringomycin. The effects of syringomycin were similar to those of ABA. Both compounds closed stomata at a similar rate and at similar concentrations. In addition, neither compound significantly affected the relationship between photosynthesis and intercellular CO₂ based on data taken after stomatal conductance had stabilized following the treatment. It is possible that syringomycin and ABA activate the same K⁺ export system in guard cells, and syringomycin may be a valuable tool for studying the molecular basis of ABA effects on guard cells.     

Effect of Phenolic Compounds on ABA-induced Changes in K+ Concentration of Guard Cells and in Epidermal Diffusive Resistance

The study of the structure-activity relationship of phenoliccompounds in reversing the ABA-effect on stomata led us to investigatethe changes in K⁺ concentrations in guard cells and in the epidermaldiffusive resistance of leaves, after treatment with ABA andphenolics. The amount of potassium localized in guard cells usually correspondsto stomatal aperture in different treatments. Umbelliferone,however, permits stomatal opening without retention of potassiumin the guard cells, which is an exception. The effect of phenolicsin retaining K⁺ in epidermal peels is matched by recorded epidermaldiffusive resistance changes in the leaves.Although flavonoidsand some other phenolics behave differently showing recoveryin epidermal peels with K⁺ in guard cells, epidermal diffusiveresistance is not recovered. Key words: Epidermal diffusive resistance, K⁺, ABA, phenolics, stomata     

Effects of external potassium supply on stomatal closure induced by abscisic acid

Abstract Epidermal strips of Commelina communis with ‘isolated’ stomata were incubated on Trizma-maleate buffer containing 0-500 mM KCL, with or without 10^?4 M ABA, for 2.5 h. The resulting stomatal apertures indicate that there is no absolute requirement for live epidermal and subsidiary cells for ABA-mediated closure. This implies that ABA has a direct effect on influx or efflux of K⁺ into or out of the guard cells rather than on uptake of K⁺ by the subsidiary cells. The possible in vivo role of subsidiary cells in stomatal closure is discussed.     

Stomatal morphology and physiology explain varied sensitivity to abscisic acid across vascular plant lineages

Abscisic acid (ABA) can induce rapid stomatal closure in seed plants, but the action of this hormone on the stomata of fern and lycophyte species remains equivocal. Here, ABA-induced stomatal closure, signaling components, guard cell K⁺ and Ca²⁺ fluxes, vacuolar and actin cytoskeleton dynamics, and the permeability coefficient of guard cell protoplasts (P_f) were analyzed in species spanning the diversity of vascular land plants including 11 seed plants, 6 ferns, and 1 lycophyte. We found that all 11 seed plants exhibited ABA-induced stomatal closure, but the fern and lycophyte species did not. ABA-induced hydrogen peroxide elevation was observed in all species, but the signaling pathway downstream of nitric oxide production, including ion channel activation, was only observed in seed plants. In the angiosperm faba bean (Vicia faba), ABA application caused large vacuolar compartments to disaggregate, actin filaments to disintegrate into short fragments and P_f to increase. None of these changes was observed in the guard cells of the fern Matteuccia struthiopteris and lycophyte Selaginella moellendorffii treated with ABA, but a hypertonic osmotic solution did induce stomatal closure in fern and the lycophyte. Our results suggest that there is a major difference in the regulation of stomata between the fern and lycophyte plants and the seed plants. Importantly, these findings have uncovered the physiological and biophysical mechanisms that may have been responsible for the evolution of a stomatal response to ABA in the earliest seed plants.

Physiological and biophysical evidence for insensitivity of stomata to abscisic acid in ferns and lycophytes supports stomatal responsiveness to abscisic acid evolved after the divergence of ferns.     

Light quality and osmoregulation in vicia guard cells : evidence for involvement of three metabolic pathways

Osmoregulation in opening stomata of epidermal peels from Vicia faba L. leaves was investigated under a variety of experimental conditions. The K⁺ content of stomatal guard cells and the starch content of guard cell chloroplasts were examined with cobaltinitrite and iodine-potassium iodide stains, respectively; stomatal apertures were measured microscopically. Red light (50 micromoles per square meter per second) irradiation caused a net increase of 3.1 micrometers in aperture and a decrease of −0.4 megapascals in guard cell osmotic potential over a 5 hour incubation, but histochemical observations showed no increase in guard cell K⁺ content or starch degradation in guard cell chloroplasts. At 10 micromoles per square meter per second, blue light caused a net 6.8 micrometer increase in aperture over 5 hours and there was a substantial decrease in starch content of chloroplasts but no increase in guard cell K⁺ content. At 25 micromoles per square meter per second of blue light, apertures increased faster (net gain of 5.7 micrometers after 1 hour) and starch content decreased. About 80% of guard cells had a higher K⁺ content after 1 hour of incubation but that fraction decreased to 10% after 5 hours. In the absence of KCl in the incubation medium, stomata opened slowly in response to 25 micomoles per square meter per second of blue light, without any K⁺ gain or starch loss. In dual beam experiments, stomata irradiated with 50 micomoles per square meter per second of red light for 3 hours opened without detectable starch loss or K⁺ gain; addition of 25 micomoles per square meter per second of blue light caused a further net gain of 4.4 micometers in aperture accompanied by substantial K⁺ uptake and starch loss. Comparison of K⁺ content in guard cells of opened stomata in epidermal peels with those induced to open in leaf discs showed a substantially higher K⁺ content in the intact tissue than in isolated peels. These results are not consistent with K⁺ (and its counterions) as the universal osmoticum in guard cells of open stomata under all conditions; rather, the data point to sugars arising from photosynthesis and from starch degradation as additional osmotica. Biochemical confirmation of these findings would indicate that osmoregulation during stomatal opening is the result of three key metabolic processes: ion transport, photosynthesis, and sugar metabolism.     

Synergistic effect of light and fusicoccin on stomatal opening : epidermal peel and patch clamp experiments

Upon incubation of epidermal peels of Commelina communis in 1 millimolar KCl, a synergistic effect of light and low fusicoccin (FC) concentrations on stomatal opening is observed. In 1 millimolar KCl, stomata remain closed even in the light. However, addition of 0.1 micromolar FC results in opening up to 12 micrometers. The same FC concentration stimulates less than 5 micrometers of opening in darkness. The synergistic effect (a) decreases with increasing FC or KCl concentrations; (b) is dark-reversible; (c) like stomatal opening in high KCl concentrations (120 millimolar) is partially inhibited by the K⁺ channel blocker, tetraethyl-ammonium⁺ (20 millimolar). In whole-cell patch-clamp experiments with guard cell protoplasts of Vicia faba, FC (1 or 10 micromolar) stimulates an increase in outward current that is essentially voltage independent between - 100 and +60 millivolts, and occurs even when the membrane potential is held at a voltage (−60 millivolts) at which K⁺ channels are inactivated. These results are indicative of FC activation of a H⁺ pump. FC effects on the magnitude of inward and outward K⁺ currents are not observed. Epidermal peel and patch clamp data are both consistent with the hypothesis that the plasma membrane H⁺ ATPase of guard cells is a primary locus for the FC effect on stomatal apertures.     

The effect of Cl- upon the sensitivity of starch-containing and starch-deficient stomata and guard cell protoplasts towards potassium ions,fusicoccin and abscisic acid

Chloride ions are necessary to compensate for the positively charged potassium ions imported into guard cells of Allium cepa L. during stomatal opening. Therefore an external Cl^- supply of intact Allium plants is important. But high levels of chloride have been found to reduce the sensitivity of the starch-lacking stomata and isolated guard cell protoplasts (GCPs) from Allium to potassium ions, fusicoccin and abscisic acid. Furthermore, with high levels of chloride, malate anions disappear from the guard cells of Allium, a finding which contrasts with situation in Vicia where the stomatal sensitivity to K⁺ ions, fusicoccin and ABA is not influenced by Cl^- ions and malate levels are unaffected. It is suggested that the absence of malate as a proton yielding primer inhibits the mechanism of H⁺/K⁺ exchange in Allium.Abbreviations ABA abscisic acid - FC fusicoccin - GCPs guard cell protoplasts     

Stomatal opening quantitatively related to potassium transport: evidence from electron probe analysis

When stomata of Vicia faba opened (from a stomatal aperture of about 2 micrometers to one of 12 micrometers) the solute content of the guard cells increased by 4.8 × 10⁻¹² osmoles per stoma. During the same time an average of 4.0 × 10⁻¹² gram equivalents of K⁺ were transported into each pair of guard cells. This amount of K⁺, if associated with dibasic anions, is sufficient to produce the changes in guard cell volume and osmotic pressure associated with stomatal opening. Analysis of Cl, P, and S showed that these elements were not transported in significant amounts during stomatal opening. This finding suggests that the anions balancing K⁺ were predominantly organic. K⁺ was specifically required because no other elements, likely to be present as cations, were found to accumulate in appreciable quantities in guard cells of open stomata.     

Potassium channel currents in intact stomatal guard cells: rapid enhancement by abscisic acid

Evidence of a role for abscisic acid (ABA) in signalling conditions of water stress and promoting stomatal closure is convincing, but past studies have left few clues as to its molecular mechanism(s) of action; arguments centred on changes in H⁺-pump activity and membrane potential, especially, remain ambiguous without the fundamental support of a rigorous electrophysiological analysis. The present study explores the response to ABA of K⁺ channels at the membrane of intact guard cells ofVicia faba L. Membrane potentials were recorded before and during exposures to ABA, and whole-cell currents were measured at intervals throughout to quantitate the steady-state and time-dependent characteristics of the K⁺ channels. On adding 10 M ABA in the presence of 0.1, 3 or 10 mM extracellular K⁺, the free-running membrane potential (V _m) shifted negative-going (–)4–7 mV in the first 5 min of exposure, with no consistent effect thereafter. Voltage-clamp measurements, however, revealed that the K⁺-channel current rose to between 1.84- and 3.41-fold of the controls in the steady-state with a mean halftime of 1.1 ± 0.1 min. Comparable changes in current return via the leak were also evident and accounted for the minimal response inV _m. Calculated atV _m, the K⁺ currents translated to an average 2.65-fold rise in K⁺ efflux with ABA. Abscisic acid was not observed to alter either K⁺-current activation or deactivation.These results are consistent with an ABA-evoked mobilization of K⁺ channels or channel conductance, rather than a direct effect of the phytohormone on K⁺-channel gating. The data discount notions that large swings in membrane voltage are a prerequisite to controlling guard-cell K⁺ flux. Instead, thev highlight a rise in membranecapacity for K⁺ flux, dependent on concerted modulations of K⁺-channel and leak currents, and sufficiently rapid to account generally for the onset of K⁺ loss from guard cells and stomatal closure in ABA.     

The trafficking protein SYP121 of Arabidopsis connects programmed stomatal closure and K⁺ channel activity with vegetative growth

The vesicle‐trafficking protein SYP121 (SYR1/PEN1) was originally identified in association with ion channel control at the plasma membrane of stomatal guard cells, although stomata of the Arabidopsis syp121 loss‐of‐function mutant close normally in ABA and high Ca²⁺. We have now uncovered a set of stomatal phenotypes in the syp121 mutant that reduce CO₂ assimilation, slow vegetative growth and increase water use efficiency in the whole plant, conditional upon high light intensities and low relative humidity. Stomatal opening and the rise in stomatal transpiration of the mutant was delayed in the light and following Ca²⁺‐evoked closure, consistent with a constitutive form of so‐called programmed stomatal closure. Delayed reopening was observed in the syp121, but not in the syp122 mutant lacking the homologous gene product; the delay was rescued by complementation with wild‐type SYP121 and was phenocopied in wild‐type plants in the presence of the vesicle‐trafficking inhibitor Brefeldin A. K⁺ channel current that normally mediates K⁺ uptake for stomatal opening was suppressed in the syp121 mutant and, following closure, its recovery was slowed compared to guard cells of wild‐type plants. Evoked stomatal closure was accompanied by internalisation of GFP‐tagged KAT1 K⁺ channels in both wild‐type and syp121 mutant guard cells, but their subsequently recycling was slowed in the mutant. Our findings indicate that SYP121 facilitates stomatal reopening and they suggest that K⁺ channel traffic and recycling to the plasma membrane underpins the stress memory phenomenon of programmed closure in stomata. Additionally, they underline the significance of vesicle traffic for whole‐plant water use and biomass production, tying SYP121 function to guard cell membrane transport and stomatal control.     

Phosphatidic Acid Inhibits Blue Light-Induced Stomatal Opening via Inhibition of Protein Phosphatase 1

Stomata open in response to blue light under a background of red light. The plant hormone abscisic acid (ABA) inhibits blue light-dependent stomatal opening, an effect essential for promoting stomatal closure in the daytime to prevent water loss. However, the mechanisms and molecular targets of this inhibition in the blue light signaling pathway remain unknown. Here, we report that phosphatidic acid (PA), a phospholipid second messenger produced by ABA in guard cells, inhibits protein phosphatase 1 (PP1), a positive regulator of blue light signaling, and PA plays a role in stimulating stomatal closure in Vicia faba. Biochemical analysis revealed that PA directly inhibited the phosphatase activity of the catalytic subunit of V. faba PP1 (PP1c) in vitro. PA inhibited blue light-dependent stomatal opening but did not affect red light- or fusicoccin-induced stomatal opening. PA also inhibited blue light-dependent H⁺ pumping and phosphorylation of the plasma membrane H⁺-ATPase. However, PA did not inhibit the autophosphorylation of phototropins, blue light receptors for stomatal opening. Furthermore, 1-butanol, a selective inhibitor of phospholipase D, which produces PA via hydrolysis of phospholipids, diminished the ABA-induced inhibition of blue light-dependent stomatal opening and H⁺ pumping. We also show that hydrogen peroxide and nitric oxide, which are intermediates in ABA signaling, inhibited the blue light responses of stomata and that 1-butanol diminished these inhibitions. From these results, we conclude that PA inhibits blue light signaling in guard cells by PP1c inhibition, accelerating stomatal closure, and that PP1 is a cross talk point between blue light and ABA signaling pathways in guard cells.Stomatal guard cells in the epidermis of aerial plants regulate gas exchange between leaves and the atmosphere, allowing the uptake of CO₂ for photosynthesis and the loss of water by transpiration. Guard cells integrate a wide variety of stimuli such as light, humidity, temperature, CO₂, and plant hormones to prevent excessive water loss and optimize plant growth under changing environmental conditions (Vavasseur and Raghavendra, 2005; Shimazaki et al., 2007). Among them, blue light and abscisic acid (ABA) represent key factors that promote stomatal opening and closure, respectively (Assmann and Shimazaki, 1999; Hetherington, 2001; Schroeder et al., 2001; Roelfsema and Hedrich, 2005). Blue light induces H⁺ pumping by activation of the plasma membrane H⁺-ATPase, which causes membrane hyperpolarization and drives K⁺ uptake into guard cells via inward-rectifying K⁺ channels (Assmann et al., 1985; Shimazaki et al., 1986; Schroeder et al., 1987). By contrast, ABA activates the anion channels, thereby causing membrane depolarization and promoting K⁺ efflux from guard cells via outward-rectifying K⁺ channels (Schroeder et al., 1987). There is cross talk between the opening and closure systems, and ABA inhibits blue light-induced activation of the H⁺-ATPase (Shimazaki et al., 1986; Goh et al., 1996; Roelfsema et al., 1998). Such inhibition of H⁺-ATPase by ABA is crucial to maintain the plasma membrane depolarization and supports efficient stomatal closure of open stomata. For example, when H⁺-ATPase is kept in the active state, as was found in the open stomata2 mutants, plants lost the stomatal closure response to ABA, which brought about the wilty phenotype even under well-watered conditions (Merlot et al., 2002, 2007). Although the regulation of the stomatal opening system by ABA is important for plant survival, the mechanism by which ABA inhibits the activation of H⁺-ATPase by blue light is largely unknown.Blue light is required for the activation of phototropins, plant-specific Ser/Thr autophosphorylating kinases, and the activated phototropins transmit the signal to the plasma membrane H⁺-ATPase for its activation (Kinoshita et al., 2001; Christie, 2007). Activation of the H⁺-ATPase is caused by the phosphorylation of a Thr residue in the C terminus with subsequent binding of a 14-3-3 protein to the Thr residue (Kinoshita and Shimazaki, 1999; Emi et al., 2001). Since phototropins are Ser/Thr protein kinases, it might be possible that phototropins directly phosphorylate the H⁺-ATPase. However, this has been shown not to be the case. Recently, we demonstrated that protein phosphatase 1 (PP1), a major member of the PPP family of Ser/Thr protein phosphatases, mediates the signaling between phototropins and H⁺-ATPase in guard cells (Takemiya et al., 2006). Therefore, ABA is likely to inhibit the signaling molecule(s), including phototropins, PP1, H⁺-ATPase, and other unidentified components.In guard cells, ABA induces the production of phosphatidic acid (PA), and PA has been implicated in stimulating stomatal closure and inhibiting light-induced stomatal opening (Jacob et al., 1999; Zhang et al., 2004a; Mishra et al., 2006). PA has also been shown to interact with the catalytic subunit of human PP1 (PP1c) and decreases its phosphatase activity (Kishikawa et al., 1999; Jones and Hannun, 2002). It is thus conceivable that PA also functions as an inhibitor of plant PP1c and suppresses the blue light signaling of guard cells.In this study, we investigated the effect of PA on blue light responses of stomata from Vicia faba. We found that PA inhibited the phosphatase activity of PP1c in vitro, suppressed blue light-dependent H⁺ pumping and phosphorylation of H⁺-ATPase, and did not affect the autophosphorylation of phototropins in guard cells.     

Isotachophoretic Analysis of Ions in Guard Cells of Vicia faba

Isotachophoretic analysis of ions was performed on guard cells of Vicia faba cv. Ryosai Issun with either open or closed stomata. In guard cells of open stomata, K⁺ and malic acid concentrations were 5–7 and 5–10 times higher, respectively, than in guard cells of closed stomata. The content of citric acid (plus isocitric acid) also increased during stomatal opening, but the increment was smaller than that of malic acid. Sodium ions, phosphoric and glyceric acids were present in low concentrations but did not increase during the opening. Other cations and anions could not be measured because of low concentrations. Malic acid provided 68–79% of the counter anions for the potassium taken up by guard cells during stomatal opening.     

The mechanism of stomatal movement in Allium cepa L.

In the guard cells of Allium cepa leaves, no starch was found either when the stomata were open or closed. The lack of other soluble polysaccharides that could be hydrolyzed during the opening reaction of the stomata (Schnabl, Planta 1977, in press) leads to the question, how is the osmotic effect, which is the basis of the stomatal movement, achieved in Allium? It is shown in this paper, by histochemical and microprobe analyses, that in Allium — as in other plant species—the K⁺ concentration of the guard cells increases during stomatal opening. The charges of the K⁺ ions in the guard cells seem to be fully compensated by imported Cl^- ions. This could mean that if starch is present in the guard cells, as in the majority of plant species, its major role in the mechanism of stomatal movement is to deliver the cuunteranions for the imported K⁺ ions.     

Stomatal Responses to Water Deficits and Abscisic Acid in Leaves of Sunflower Plants (Helianthus annuus L.) Grown under Different Conditions

The decrease in diffusive conductance of a leaf exposed to waterstress or to exogenous abscisic acid (ABA) was smaller in leavesof sunflower plants (Helianthus annuus L. cv. NK285) that hadbeen grown in a phytotron in humid air than in leaves of sunflowersgrown outdoors. Stomata of the phytotron-grown plants were slowerto close after detachment of a leaf than those of the outdoorplants. When stomata closed rapidly, as they did in detachedleaves and after treatment with ABA, the extent of closure wasvaried over the leaf's surface, in particular in the case ofphytotron-grown plants, and the extent of the heterogeneitywas greater in the phytotrongrown plants than in the outdoorplants. When stomata closed gradually, for example, under conditionsof limited moisture in the soil, closure occurred uniformlyover leaves of plants of both types. The smaller decrease indiffusive conductance of leaves from phytotron-grown plantsafter treatment with ABA resulted from the presence of patcheson the surface in which stomata remained open. The smaller decreaseof diffusive conductance in the phytotron-grown plants underconditions of limited moisture in the soil resulted from theuniformly lower responsiveness of stomata on a leaf to the decreasein water potential. When estimates are made of the intercellularconcentration of CO₂ (Ci) from gas-exchange measurements, heterogeneityin stomatal closure should be monitored when stomata close rapidly,in particular in plants grown in humid air, because heterogeneousstomatal closure can lead to overestimates of Ci. (Received April 18, 1994; Accepted May 25, 1995)     

Early ABA Signaling Events in Guard Cells

The plant hormone abscisic acid (ABA) regulates a wide variety of plant physiological and developmental processes, particularly responses to environmental stress, such as drought. In response to water deficiency, plants redistribute foliar ABA and/or upregulate ABA synthesis in roots, leading to roughly a 30-fold increase in ABA concentration in the apoplast of stomatal guard cells. The elevated ABA triggers a chain of events in guard cells, causing stomatal closure and thus preventing water loss. Although the molecular nature of ABA receptor(s) remains unknown, considerable progress in the identification and characterization of its downstream signaling elements has been made by using combined physiological, biochemical, biophysical, molecular, and genetic approaches. The measurable events associated with ABA-induced stomatal closure in guard cells include, sequentially, the production of reactive oxygen species (ROS), increases in cytosolic free Ca²⁺ levels ([Ca²⁺]_i), activation of anion channels, membrane potential depolarization, cytosolic alkalinization, inhibition of K⁺ influx channels, and promotion of K⁺ efflux channels. This review provides an overview of the cellular and molecular mechanisms underlying these ABA-evoked signaling events, with particular emphasis on how ABA triggers an “electronic circuitry” involving these ionic components.     

Effects of Internal K+ and ABA on the Voltage- and Time-dependence of the Outward K+-rectifier in Vicia Guard Cells

One of the main effects of abscisic acid (ABA) is to induce net loss of potassium salts from guard cells enabling the stomata to close. K⁺ is released from the vacuole into the cytosol and then to the extracellular space. The effects of increasing cytosolic K⁺ on the voltage- and time-dependence of the outwardly rectifying K⁺-current (I _K,out) in guard cell protoplasts (GCP) was examined in the whole-cell configuration of the patch-clamp technique. The same quantitative analysis was performed in the presence of ABA at different internal K⁺ concentrations ([K⁺] _i ). Varying [K⁺] _i in the patch pipette from 100 to 270 mm increased the magnitude of I _K,out in a nonlinear manner and caused a negative shift in the midpoint (V _0.5) of its steady-state activation curve. External addition of ABA (10–20 μm) also increased the magnitude of I _K,out at all [K⁺] _i , but caused a shift in V _0.5 of the steady-state activation curve only in those GCP loaded with 150 mm internal K⁺ or less. Indeed, V _0.5 did not shift upon addition of ABA when the [K⁺] _i was above 150 mm and up to 270 mm, i.e., the shift in V _0.5 caused by ABA depended on the [K⁺] _i . Both increase in [K⁺] _i and external addition of ABA, decreased (by ≈ 20%) the activation time constant (τ _n ) of I _K,out. The small decrease in τ _n , in both cases, was found to be independent of the membrane voltage. The results indicate that ABA mimics the effect of increasing cytoplasmic K⁺, and suggest that ABA may increase I _K,out and alter V _0.5 of its steady-state activation curve via an enhancement in cytosolic K⁺. This report describes for the first time the effects of [K⁺] _i on the voltage- and time-dependence of I _K,out in guard cells. It also provides an explanation for the quantitative (total membrane current) and qualitative (current kinetics) differences found between intact guard cells and their protoplasts. Received: 1 December 1995/Revised: 8 May 1996     

Changes in K+, Cl− and P contents in stomata of Zea mays leaves exposed to different light and CO2 levels

Maize plants (Zea mays L. hybrid INRA 508) were placed under controlled conditions of light and CO₂ partial pressure. The K⁺, Cl^? and P contents were then determined by X-ray microanalysis in the bulbous end of guard cells and in the center of subsidiary cells. The results were interpreted in connection with the stomatal conductance at the time of sampling. In normal air, the K⁺ and Cl^? contents in guard cells only rose from a light threshold of about 300 μmol m^?2 s^?1 at which stomata were already largely open. At 600 μmol m^?2 s^?1, the K⁺ and Cl^? levels in guard cells attained values that were 3- and 8-fold greater, respectively, than the values observed in darkness. The K⁺ and Cl^? contents in the subsidiary cells remained quite constant irrespective of the light conditions. CO₂-free air in darkness induced a significant K⁺ influx towards guard and subsidiary cells. Under light and in CO₂-free air, the K⁺ and Cl^? contents dramatically increased in the guard cells, but slightly decreased in the subsidiary cells. Thus, when subjected to strong light in CO₂-free air, the K⁺ and Cl^? contents in the subsidiary cells were approximately equal to those measured in normal air conditions. In the guard cells, stomatal opening was associated with a marked shift of the Cl^?/K⁺ ratio – from 0.3 for closed stomata to ca 1 for fully open stomata. This could imply a slow change in the nature of the principal counterion accompanying K⁺ during stomatal opening. The content of P in guard cells appeared, in contrast to that of K⁺ and Cl^?, to be practically independent of stomatal aperture.     

New fava bean guard cell signaling mutant impaired in ABA-induced stomatal closure

We isolated a mutant from Vicia faba L. cv. House Ryousai. Itwilts easily under strong light and high temperature conditions,suggesting that its stomatal movement may be disturbed. We determinedresponses of mutant guard cells to some environmental stimuli.Mutant guard cells demonstrated an impaired ability to respondto ABA in 0.1 mM CaCl₂ and stomata did not close in thepresence of up to 1 mM ABA, whereas wild-type stomata closedwhen exposed to 10 µM ABA. Elevating external Ca²⁺caused a similar degree of stomatal closure in the wild typeand the mutant. A high concentration of CO₂ (700 µlliter^–1) induced stomatal closure in the wild type, butnot in the mutant. On the basis of these results, we proposethe working hypothesis that the mutation occurs in the regiondownstream of CO₂ and ABA sensing and in the region upstreamof Ca²⁺ elevation. The mutant is named fia (fava bean impairedin ABA-induced stomatal closure). ³ Corresponding author: E-mail, smoiwai{at}agri.kagoshima-u.ac.jp;Fax, +81-99-285-8556.     

Cytosolic acidification precedes nitric oxide removal during inhibition of ABA-induced stomatal closure by fusicoccin

The role of nitric oxide (NO) and the relationship between NO and cytosolic pH during inhibition of ABA effect by fusicoccin (FC) in guard cells of Vicia faba were analyzed. ABA induced NO generation and stomatal closure, but FC inhibited the effects of ABA. Treatment with 2-(4-carboxyphenyl)-4,4,5,5-tetra-methylimidazoline-1-oxyl-3-oxide (cPTIO) and N^G-nitro-L-Arg-methyl ester (L-NAME) mimicked the effects of FC. These data suggest that inhibition of ABA effect by FC is possibly related to the decreasing in the NO level. Furthermore, like cPTIO, FC not only suppressed stomatal closure and NO level in guard cells treated with NO donor sodium nitroprusside (SNP), but also reopened stomata, which had been closed by ABA, and reduced the level of NO in guard cells that had been produced by ABA, indicating that FC caused NO removal. Butyric acid simulated the effects of FC on the stomatal aperture and increased NO levels in guard cells treated with SNP and had been closed by ABA, and both FC and butyric acid surely reduced cytosolic pH, which demonstrates that cytosolic acidification mediates FC-induced NO removal. Taken together, our results show that FC induces NO removal and reduces NO level via cytosolic acidification in guard cells, thus inhibiting ABA effect.