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.     

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.     

Effect of ionophore A23187 upon membrane function and ion movement in human and toad erythrocytes

Summary Addition of 0.1–0.3 m A23187, a divalent cation ionophore, to human erythrocytes suspended in a 1.0mm ⁴⁵Ca²⁺-containing buffer results in a small ( two fold) increase in [Ca²⁺] _i , a significant decrease in osmotic fragility, and a decrease in intracellular K⁺ (100 mmoles/liter of cells to 70 mmoles/liter cells) without significant alteration of intracellular [Na⁺]. This decrease in [K⁺] _i is associated with a significant decrease in packed cell volume and correlates directly with the observed alteration is osmotic fragility. Increasing extracellular K⁺ to 125mm prevents the A23187-induced changes in osmotic fragility, K⁺ content and cell volume, but does not prevent the ionophore-induced uptake of⁴⁵Ca²⁺. Addition of 0.1–0.3 m A23187 to toad erythrocytes leads to an increase in⁴⁵Ca²⁺ uptake comparable to that observed in human erythrocytes, but does not alter osmotic fragility, cell volume or K⁺ content. Higher concentrations of ionophore (3.0–10.0 m) cause a 30- to 50-fold increase in⁴⁵Ca²⁺ uptake and concomitant change in K⁺ content, cell volume and osmotic fragility. These changes in cell properties can be prevented by increasing extracellular [K⁺] to 90mm. The difference in sensitivity of the two cell types to A23187 is attributed to the presence of additional intracellular calcium pools within toad erythrocytes that prevent an increase in cytoplasmic Ca²⁺ until Ca²⁺ uptake is increased substantially at the higher concentrations of A23187.     

The effect of abscisic acid on the uptake of potassium and chloride into Avena coleoptile sections

Summary The effect of abscisic acid (ABA) on uptake of potassium (⁸⁶Bb⁺ or ⁴²K⁺) by Avena sativa L. coleoptile sections was investigated. ABA lowered the potassium uptake rate within 30 min after its application and inhibition reached a maximum (ca. 75%) after 2 h. The inhibition of K⁺ uptake increased with ABA concentration over a range of 0.03 to 10 g/ml ABA. At a higher K⁺ concentration (20 mM) the percentage inhibition decreased. The percentage inhibition of K⁺ uptake by ABA remained constant with external K⁺ varied from 0.04 to 1.0 mM. After a loading period in 20 mM K⁺ (⁸⁶Rb⁺), apparent efflux of potassium was only slightly increased by ABA. Experiments in which growth was greatly reduced by mannitol or by omission of indole-3-acetic acid from the medium indicated there was no simple quantitative correspondence between ABA inhibition of coleoptile elongation and ABA inhibition of K⁺ uptake. Chloride uptake was also inhibited by ABA but to a smaller degree than was K⁺ uptake. No specificity for counterions was observed for K⁺ uptake. Uptake of 3,0-methylglucose and proline were inhibited by ABA to a much smaller extent (14 and 11%) than that of K⁺, a result which suggests that ABA acts on specific ion uptake mechanisms.     

Osmotic measurements on stomatal cells ofCommelina communis L.

Summary Observations of aperture changes as sucrose is added to the solution bathing epidermal strips ofCommelina communis L. allow calculation of the osmotic changes required to open or close the stomatal pore, for comparison with changes in potassium content. With isolated guard cells, in strips in which all cells other than guard cells have been killed, the internal osmotic changes required are 83 mosmol kg^–1 m^–1 below 10m aperture, 129 mosmol kg^–1 m^–1 in the range 10–15 m, and 180 mosmol kg^–1 m^–1 above 15 m. For opening against subsidiary cell turgor in addition to guard cell turgor, in intact strips with live subsidiary and epidermal cells, these figures should each be increased by about 33 mosmol kg^–1 m^–1. A change in subsidiary cell turgor is magnified in its effects on the water relations of the guard cell by a factor greater than 3.7 for equal changes in the water potential of the two cells, or greater than 4.7 at constant volume of the guard cell.     

The chemiosmotic model of stomatal opening revisited

Stomata are light‐activated biological valves in the otherwise gas‐impermeable epidermis of aerial organs of higher plants. Stomata often regulate rates of photosynthesis and transpiration in ways that optimize whole‐plant carbon gain against water loss. Each stoma is flanked by a pair of opposing guard cells. Stomatal opening occurs by light‐activated increases in the turgor pressure of guard cells, which causes them to change shape so that the stomatal pore between them widens. These increases in turgor pressure oppose increases in cellular osmotic pressure that result from uptake of K⁺. K⁺ uptake occurs by a chemiosmotic mechanism in response to light‐activated extrusion of H⁺ outward across the plasma membrane of the guard cell. The initial changes in cellular membrane potential lead to the opening of inward‐rectifying K⁺ channels, after which K⁺ is taken up along its electrochemical gradient. Changes in membrane potential resulting from K⁺ uptake may be balanced by accumulation of Cl^?ions by guard cells and/or by synthesis of malic acid within each cell. Malic acid also acts to buffer increases in cytosolic pH caused by H⁺ extrusion. This review describes how the application of patch‐clamp technology to guard cell protoplasts has enabled investigators to elucidate the mechanisms by which H⁺ is extruded from guard cells, the types of ion channels present in the guard cell plasma membrane, how those ion channels are regulated, and the signal transduction processes that trigger stomatal opening and closing.     

Vanadate inhibition of stomatal opening in epidermal peels of Commelina communis

An H⁺ ATPase at the plasma-membrane of guard cells is thought to establish an electrochemical gradient that drives K⁺ and Cl^– uptake, resulting in osmotic swelling of the guard cells and stomatal opening. There are, however, conflicting results regarding the effectiveness of the plasma-membrane H⁺-ATPase inhibitor, vanadate, in inhibiting both H⁺ extrusion from guard cells and stomatal opening. We found that 1 mM vanadate inhibited light-stimulated stomatal opening in epidermal peels of Commelina communis L. only at KCl concentrations lower than 50 mM. When impermeant n-methylglucamine and HCl (pH 7.2) were substituted for KCl, vanadate inhibition was still not observed at total salt concentrations50 mM. In contrast, in the absence of Cl^–, when V₂O₅ was used to buffer KOH, vanadate inhibition of stomatal opening occurred at K⁺ concentrations as high as 70 mM. Partial vanadate inhibition was observed in the presence of the impermeant anion, iminodiacetic acid (100 mM KHN(CH₂CO₂H)₂). These results indicate that high concentrations of permeant anions prevent vanadate uptake and consequently prevent its inhibitory effect. In support of this hypothesis, an inhibitor of anion uptake, anthracene-9-carboxylic acid, partially prevented vanadate inhibition of stomatal opening. Other anion-uptake inhibitors (1 mM 4,4-diisothiocyanatostilbene-2,2-disulfonic acid, 1 mM 4-acetamido-4-isothiocyanostilbene-2,2-disulfonic acid, 200 M Zn²⁺) were not effective. Decreased vanadate inhibition at high Cl^–/vanadate ratios may result from competition between vanadate and Cl^– for uptake. Unlike metabolic inhibitors, vanadate did not affect the extent of stomatal closure stimulated by darkness, further indicating that the observed action of vanadate represents a specific inhibition of the guard-cell H⁺ ATPase.Abbreviations DIDS 4,4-diisothiocyanatostilbene-2,2-disulfonic acid - FC fusicoccin - SITS 4-acetamido-4-isothiocyanostilbene-2,2-disulfonic acid We thank Drs. R.T. Leonard (University of California, Riverside, USA) and K.A, Rubinson (Yellow Springs, Oh., USA) for helpful comments on the research, Janet Sherwood (Harvard University) for excellent plant care, and Angela Ciamarra, Anne Gershenson, Gustavo Lara (Harvard University) and Orit Tal (Hebrew University) for valuable technical assistance. This research was supported by a grant from the National Science Foundation (DCB-8904041) to S.M.A.     

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.     

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.     

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.     

[3H]Histamine uptake and release by astrocytes from rat brain: Effects of sodium deprivation,high potassium,and potassium channel blockers

Histamine transport has been characterized in cultured astroglial cells of rat brain. The kinetics of [³H]-histamine uptake yielded a K_m of 0.19±0.03 M and a V_max of 3.12±0.75 pmol×mg protein^–1×min^–1. Transport system revealed high affinity for histamine and an approximately ten times higher capacity than that shown in cultured glial cells of chick embryonic brain. Ouabain which interferes with utilization of ATP to generate ion gradients, and the replacement of Na⁺ with choline inhibited the initial rate of uptake showing a strong Na⁺-dependency and suggesting the presence of a tightly coupled sodium/histamine symporter. Dissipation of K⁺-gradient (in>out) by high K⁺ or by K⁺-channel blockers, BaCl₂, (100 M), quinine (100 M) or Sparteine (20 M) produced also remarkable inhibitions in the uptake of [³H]-histamine. Impromidine, a structural histamine-analogue could inhibit the uptake non-competitively in a range of concentrations of 1 to 10 M with a K_i value of 2.8 M, indicating the specificity of the uptake. [³H]histamine uptake measurements carried out by using a suspension of dissociated hypothalamic cells, of rat brain showed a strong gliotoxin-sensitivity and yielded a Km of 0.33±0.08 M; and a V_max of 2.65±0.35 pmoles×mg protein^–1×min^–1. The uptake could be reversed by incubating the cells in histamine-free Krebs medium. The [³H]histamine efflux was sensitive to Na⁺ omission, ouabain treatment and high K⁺ or K⁺ channel blockers, resulting in marked elevations in the efflux. Data indicate that glial uptake of histamine is a high affinity, Na⁺-dependent and electrogenic, driven by an inward-oriented sodium ion gradient and an outward-oriented potassium ion gradient and functions as part of histamine inactivation, at least in a shunt mechanism.Abbreviations used HA histamine - [³H]HA [2.5-³H]-histamine - dl--aAA dl-alpha-aminoadipic acid - (Na⁺+K⁺) ATP-ase sodium and potassium activated adenosine triphosphatase - SAH S-Adenosyl-d-Homocysteine - HNMT histamine-N-methyltransferase     

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.     

Close coupling between extrusion of H+ and uptake of K+ by barley roots

Extrusion of H⁺ by intact barley (Hordeum vulgare L.) roots was automatically titrated. Simultaneously, uptake of K⁺ into the roots, transport of K⁺ through the roots, and (as a residual term) accumulation of K⁺ within the root tissue were determined. When no monovalent cation was present in the medium the steady rate of H⁺ release was close to zero. Addition of K⁺ stimulated H⁺ extrusion within less than 1 min. The stimulation of H⁺ release was apparently limited only by the movement of K⁺ through the apoplast of the roots. The steady rate of H⁺ extrusion depended on the availability of external K⁺ and saturated at a K⁺ concentration of about 100 mol· dm^-3. Half-maximum rates of net K⁺ uptake and H⁺ extrusion were reached at a K⁺ concentration of about 10 mol·dm^-3. With (slowly absorbable) sulfate as the only anion present, the stoichoimetry between H⁺ release and net K⁺ uptake was one. In conclusion, the uptake of K⁺ across the plasmalemma of the cells of the root cortex is electrically coupled to H⁺ extrusion.     

Cloning and functional characterization of the high-affinity K<Superscript>+</Superscript> transporter HAK1 of pepper

High-affinity K⁺ uptake in plants plays a crucial role in K⁺ nutrition and different systems have been postulated to contribute to the high-affinity K⁺ uptake. The results presented here with pepper (Capsicum annum) demonstrate that a HAK1-type transporter greatly contributes to the high-affinity K⁺ uptake observed in roots. Pepper plants starved of K⁺ for 3 d showed high-affinity K⁺ uptake (K _m of 6 M K⁺) that was very sensitive to NH and their roots expressed a high-affinity K⁺ transporter, CaHAK1, which clusters in group I of the KT/HAK/KUP family of transporters. When expressed in yeast (Saccharomyces cerevisiae), CaHAK1 mediated high-affinity K⁺ and Rb⁺ uptake with K _m values of 3.3 and 1.9 M, respectively. Rb⁺ uptake was competitively inhibited by micromolar concentrations of NH and Cs⁺, and by millimolar concentrations of Na⁺.     

Organic Acid Changes in the Epidermis of Vicia faba and Their Implication in Stomatal Movement

Considerable evidence indicates that the increase in guard cell turgor resulting in stomatal opening is brought about by active K⁺ uptake into guard cells. Only a small increase in inorganic anions appears to accompany the increase in K⁺. A plausible explanation is that organic acids are produced within guard cells and act as counterions, whereas the H⁺ produced are exchanged for K⁺.     

Stimulation of human cheek cell Na+/H+ antiporter activity by saliva and salivary electrolytes: amplification by nigericin

Proton-dependent, ethylisopropylamiloride (EIPA)-sensitive Na⁺ uptake (Na⁺/H⁺ antiporter) studies were performed to examine if saliva, and ionophores which alter cellular electrolyte balance, could influence the activity of the cheek cell Na⁺/H⁺ antiporter. Using the standard conditions of 1 mmol/1 Na⁺, and a 65:1 (inside:outside) proton gradient in the assay, the uniport ionophores valinomycin (K⁺) and gramicidin (Na⁺) increased EIPA-sensitive Na⁺ uptake by 177% (p < 0.01) and 227% (p < 0.01), respectively. The dual antiporter ionophore nigericin (K⁺-H⁺) increased EIPA-sensitive Na⁺ uptake by 654% (p < 0.01), with maximal Na⁺ uptake achieved by 1 min and at an ionophore concentration of 50 mol/l, with an EC ₅₀ value 6.4 mol/l. Preincubation of cheek cells with saliva or the low molecular weight (MW) components of saliva (saliva activating factors, SAF) for 2 h at 37°C, also significantly stimulated EIPA-sensitive Na⁺ uptake. This stimulation could be mimicked by pre-incubation with 25 mmol/l KCl or K⁺-phosphate buffer. Pre-incubating cheek cells with SAF and the inclusion of 20 mol/1 nigericin in the assay, produced maximum EIPA-sensitive Na⁺ uptake. After pre-incubation with water, 25 mmol/1 K⁺-phosphate or SAF, with nigericin in all assays, the initial rate of proton-gradient dependent, EIPA-sensitive Na⁺ uptake was saturable with respect to external Na⁺ with K_m values of 0.9, 1.7, and 1.8 mmol/l, and V _max values of 13.4, 25.8, and 31.1 nmol/mg protein/30 sec, respectively. With 20 mol/1 nigericin in the assay, Na⁺ uptake was inhibited by either increasing the [K⁺]_o in the assay, with an ID ₅₀ of 3 mmol/l. These results indicate that nigericin can facilitate K⁺ _i exchange for H⁺ _o and the attending re-acidification of the cheek cell amplifies IINa+ uptake via the Na⁺/H⁺ antiporter. The degree of stimulation of proton-dependent, EIPA-sensitive Na⁺ uptake is therefore dependent, in part, on the intracellular K⁺ _i.     

Ion content and aperture in “isolated” guard cells ofCommelina communis L.

Summary Isolated guard cells ofCommelina communis L., in epidermal strips in which all cells other than guard cells have been killed by treatment at low pH, will open to a degree dependent on the K (Rb)/Cl(Br) concentration in the bathing medium. Estimates of the changes with aperture of the ion concentrations in the guard cells were made by measurement of⁸⁶Rb uptake from RbCl, of⁸²Br uptake from K⁸²Br, and of potassium activity with a potassium-sensitive microelectrode. The osmotic effects of such changes were compared with the previous estimates of the osmotic changes required to change the aperture. The results suggest that a substantial fraction of the osmotic pressure of isolated guard cells is contributed by solutes other than KCl (or other potassium salts), and that, even in stomata opened by incubation on KCl solutions, a substantial fraction of the increase in osmotic pressure associated with opening is contributed by solutes other than KCl.     

Sodium dependency of GABA uptake into glial cells in bullfrog sympathetic ganglia

The kinetics of sodium dependency of GABA uptake by satellite glial cells was studied in bullfrog sympathetic ganglia. GABA uptake followed simple Michaelis-Menten kinetics at all sodium concentrations tested. Increasing external sodium concentration increased bothK _m andV _max for GABA uptake, with an increase in theV _max/K _m ratio. The initial rate of uptake as a function of the sodium concentration exhibited sigmoid shape at 100 M GABA. Hill number was estimated to be 2.0. Removal of external potassium ion or 10 M ouabain reduced GABA uptake time-dependently. The effect of ouabain was potentiated by 100 M veratrine. These results suggest that at least two sodium ions are involved with the transport of one GABA molecule and that sodium concentration gradient across the plasma membrane is the main driving force for the transport of GABA. The essential sodium gradient may be maintained by Na⁺, K⁺-ATPase acting as an ion pump.     

Potassium modulation of methionine uptake in astrocytes in vitro

Methionine participates in a large variety of metabolic pathways in brain, and its transport may play an important regulatory role. The properties of methionine uptake were examined in a preparation of neonatal rat brain astrocytes. Uptake is linear for 15 minutes, up to 2.5 M. At steady state conditions, methionine is concentrated 30–50-fold. Measured methionine homoexchange accounts for a significant fraction of uptake at concentrations greater than 10 M. We recently reported that methionine uptake is decreased by elevations in extracellular K⁺. Potassium induced efflux cannot account for this apparent effect; and thus for concentrations less than 2.5M, and for short times of incubation, measured rates of methionine uptake represent unidirectional flux. At extracellular concentrations of K⁺ equal to 6.9 mM, the apparentV _max of methionine transport is 182 pmol/min/mg protein, and theK _m is 1.3 M. Where K⁺ is shifted to 11.9 mM, theK _m remains unchanged, and theV _max is reduced by half.     

Roles of heterotrimeric G proteins in guard cell ion channel regulation

Stomata are formed by pairs of surrounding guard cells and perform important roles in photosynthesis, transpiration and innate immunity of terrestrial plants. Ionic solutes in the cytosol of guard cells are important for cell turgor and volume change. Consequently, trans-membrane flux of ions such as K⁺, Cl⁻, and malate2⁻ through K⁺ channels and anion channels of guard cells are a direct driving force for turgor change, while the opening of calcium permeable channels can serve as a trigger of cytosolic free calcium concentration elevations or oscillations, which play second messenger roles. In plants, heterotrimeric G proteins have fewer members than in animals, but they are well investigated and found to regulate these channels and to play fundamental roles in guard cell function. This mini-review focuses on the recent understanding of G-protein regulation of ion channels on the plasma membrane of guard cells and their participation in stomatal movements.Key words: guard cell, heterotrimeric G protein, ion channel, arabidopsis thaliana, stomata, plasma membrane, patch clampHeterotrimeric G proteins, composed of Gα, Gβ and Gγ subunits, are key elements of cellular signal transduction networks. In plant species, fewer members of G proteins are present than in animals. For example, only one Gα subunit (GPA1), one Gβ subunit (AGB1) and two Gγ subunits (AGG1 and AGG2) are reported in Arabidopsis while 23 Gα, 5 Gβ and 12 Gγ subunits have been identified in human.¹ All three kinds of subunits are expressed in guard cells. Ubiquitous expression of GPA1 throughout plant was ascertained by northern and promoter::GUS analyses and RT-PCR results also indicate guard cell expression.^2–4 AGB1 is ubiquitously expressed throughout the plant and its promoter::GUS transgenic lines show strong expression in guard cells.^5–7 For Gγ subunits, RNA blots show AGG1 and AGG2 expression throughout the plant, however, reporter gene analysis shows guard cell expression of AGG2 but not AGG1.^7–9 The guard cell expression of G protein subunits implies the function of G protein in guard cell signaling and stomatal movement regulation.Stomata are microscopic pores in the epidermis of terrestrial plants, which serve as the mouths of plants for gas change since through them CO₂ enters leaves for photosynthesis and water vapor is lost as transpiration.^10–13 In addition, stomatal movements induced by pathogen and pathogen/microbe-associated molecular patterns (PAMPs or MAMPs) are a component of the plant innate immunity system.^14–16 Biotic and abiotic stresses (e.g. water deficiency, cold, pathogens) and their induced phytohormone changes (e.g. abscisic acid [ABA], ethylene) have been widely investigated in stomatal movement regulation, and stomatal apertures are directly regulated by volume change of the surrounding guard cell pairs. The accumulation/release of ionic solutes through ion channels on the guard-cell plasma membrane together with malate production/metabolism induces water influx/efflux driving increase/decrease of cell turgor and volume which co-operates with the radial reinforcement of the guard cell walls to widen/shrink stomatal aperture.^10,17 Given that mature guard cells lack plasmodesmata with neighboring cells, all ion uptake and efflux must pass through ion channels and ion transporters on the plasma membrane.In Arabidopsis guard cells, the model cell type for cell signaling of the model plant species, all three kinds of ion channels (K⁺ channels, anion channels and Ca²⁺-permeable channels) have been investigated and found to be regulated by heterotrimeric G proteins.^10,17 Their ion channel activities can be measured in intact guard cells, guard cell protoplasts, or cell membrane patches using the patch clamp technique.^15,18,19 Patch clamping can be used to measure ion fluxes in whole cells or even through a single ion channel.^20,21 The patch clamp technique under the whole-cell recording configuration can measure the currents through hyperpolarization-activated inward K⁺ channels which account for K⁺ accumulation during stomatal opening, and the depolarizationactivated outward K⁺ channels which, together with R-type and S-type anion channels, mediate solute removal during stomatal closure. Besides these ionic fluxes which directly elicit changes in turgor, Ca²⁺-permeable channels which participate in Ca²⁺ signaling are also regulated by G proteins. For better visualization of the currents through K⁺, anion and Ca²⁺permeable channels, real current traces and their idealized current/voltage relationships are indicated in Figure 1. The G-protein regulation of inward and outward K⁺ channels, S-type anion channels, and Ca²⁺-permeable channels and their significance for stomatal movements will be discussed below, and the genes encoding them which have been explored up to now also will be discussed.Open in a separate windowFigure 1Current traces and idealized current/voltage relationships of wild type guard cell plasma membrane ion channels involved in G-protein regulation (A–C), ABA inhibition of whole-cell inward K⁺ currents. (A) indicates inward K⁺ currents of wild type guard cell protoplasts in response to hyperpolarizing voltages under control conditions [Scale bar is shown in (B)]; (B) indicates inward K+ currents of wild type guard cell protoplasts with ABA treatment; (C) indicates the idealized current/voltage relationship of inward K⁺ currents for control (gray) and ABA treatments (black). (D–F), ABA activation of slow anion currents. (D) indicates anion currents of wild type under control condition and (E) shows current after ABA treatment; (F) indicates the idealized current/voltage relationship of anion currents for control (gray) and ABA treatments (black). (G–I), ABA activation of currents through Ca²⁺-permeable channels. (G) indicates currents through Ca²⁺-permeable channels of wild type under control condition and (H) shows current after ABA treatments; (I) indicates the idealized current/voltage relationship of currents through Ca²⁺-permeable channels for control (gray) and ABA treatments (black).