Light and stomatal metabolism : I. Possible involvement of light modulation of enzymes in stomatal movement

New evidence is provided regarding the direct effect of light on stomatal opening in the epidermis of the pea (Pisum sativum L. var Little Marvel) leaf. Light modulates the activity of a number of key enzymes involved in stomatal metabolism. When isolated epidermal strips are illuminated, phosphoenolpyruvate carboxylase, NADP-malate dehydrogenase, and NADP-isocitrate dehydrogenase are activated; and aspartate aminotransferase is inactivated. Sulfhydryl compounds, dithiothreitol and glutathione, enhance stomatal opening in epidermal strips both in light or darkness while the sulfhydryl reagent N-ethylmaleimide inhibits, indicating the possible involvement of sulfhydryl groups in stomatal movements. Further, light treatment increases measureable thiol levels in the epidermis about 3-fold. These results suggest that light modulation of enzymes in the epidermis may play a significant role in the mechanism of stomatal movement.     

Stomatal Opening in Isolated Epidermal Strips of Vicia faba. I. Response to Light and to CO(2)-free Air

This paper reports a consistent and large opening response to light + CO₂-free air in living stomata of isolated epidermal strips of Vicia faba. The response was compared to that of non-isolated stomata in leaf discs floating on water; stomatal apertures, guard cell solute potentials and starch contents were similar in the 2 situations. To obtain such stomatal behavior, it was necessary to float epidermal strips on dilute KCl solutions. This suggests that solute uptake is necessary for stomatal opening.

The demonstration of normal stomatal behavior in isolated epidermal strips provides a very useful system in which to investigate the mechanism of stomatal opening. It was possible to show independent responses in stomatal aperture to light and to CO₂-free air.

     

Calcium Effects on Stomatal Movement in Commelina communis L. : Use of EGTA to Modulate Stomatal Response to Light, KCl and CO(2)

Stomatal movements depend on both ion influx and efflux; attainment of steady state apertures reflects modulation of either or both processes. The role of Ca²⁺ in those two processes was investigated in isolated epidermal strips of Commelina communis, using the Ca²⁺ chelator EGTA to reduce apoplastic [Ca²⁺]. The results suggest that a certain concentration of Ca²⁺ is an absolute requirement for salt efflux and stomatal closure. EGTA (2 millimolar) increased KCl-dependent stomatal opening in darkness and completely inhibited the dark-induced closure of initially open stomata. Closure was inhibited even in a KCl-free medium. Thus, maintenance of stomata in the open state does not necessarily depend on continued K⁺ influx but on the inhibition of salt efflux. Opening in the dark was stimulated by IAA in a concentration-dependent manner, up to 15.4 micrometer without reaching saturation, while the response to EGTA leveled off at 9.2 micrometer. IAA did not inhibit stomatal closure to the extent it stimulated opening. The response to IAA is thus consistent with a primary stimulation of opening, while EGTA can be considered a specific inhibitor of stomatal closing since it inhibits closure to a much larger degree than it stimulates opening. CO₂ causes concentration-dependent reduction in the steady state stomatal aperture. EGTA completely reversed CO₂-induced closing of open stomata but only partially prevented the inhibition of opening.     

Tentoxin Suppresses Stomatal Opening by Inhibiting Photophosphorylation

Tentoxin and, to a lesser extent, dihydrotentoxin (both at 10mmol m^–3) reduce stomatal opening in epidermal stripsof Commelina communis in the light but not in darkness. Thiseffect was significantly greater in normal air than in CO₂-freeair. Fusicoccin overcame the tentoxin effect. However, tentoxindid not inhibit stomatal opening in the light in epidermal stripsof Paphiopedilum harrisianum, a species which lacks guard cellchloroplasts. It is concluded that tentoxin exerts its actionon stomata not by an ionophorous effect in the plasmalemma ofguard cells but by the inhibition of photophosphorylation intheir chloroplasts. The effects of DCMU and tentoxin on guardcells are discussed in terms of their effects on chloroplastsand the extent to which energy is supplied from this organelleduring stomatal opening in the light. The results indicate thatneither photophosphorylation nor non-cyclic electron transportin guard cell chloroplasts are essential for stomatal opening. Key words: Commelina, epidermal strips, Paphiopedilum, photophosphorylation, stomata, tentoxin     

Ion-Stimulated Stomatal Opening Induced by Preillumination in Epidermal Strips of Commelina communis

The effects of preillumination were investigated on ion-stimulated stomatal opening of epidermal strips isolated from Commelina communis L. leaves, which are dark-starved 24 hours or more. The rate and the extent of ion-stimulated stomatal openings were increased by preexposure of epidermal strips to light. The evidences are interpreted as indicating that the energy induced by preillumination can be conserved in guard cells for considerable time periods and then used for a delayed stomatal opening in the presence of higher concentration of potassium or sodium ions. Action spectrum showed two peaks, one in blue and one in the red light region. The ratio of the blue peak to the red peak is 1.2; which is the smallest reported value in action spectra of stomatal movements. 3-(4-chlorophenyl)-1,-1-Dimethylurea suppressed the ion-stimulated stomatal opening induced by the preillumination. We conclude that the photosynthetic electron transport system, containing photosystem II, in guard cell chloroplasts is a basic system of energy acquirement for stomatal opening.     

Stomatal opening in isolated epidermis of Commelina benghalensis L. heterophasic response to KCl concentration

The pattern of stomatal opening in epidermal strips detached from leaves of Commelina benghalensis was examined. Two different phases could be distinguished in the stomatal response to KCl, one at low concentrations of KCl (up to 60 mM) and the other at high KCl concentrations (above 100 mM). The stomatal opening at low KCl concentrations was stimulated remarkably by light or fusicoccin and was suppressed by abscisic acid. At higher KCl concentrations, the stimulation by light or FC as well as the inhibition by ABA was limited. Both phases of stomatal response to KCl were sensitive to carbonyl cyanide-m-chlorophenyl hydrazone. The results suggest that illumination or FC favours selectively stomatal opening only at low KCl concentrations. The ionic participation in the stomatal opening is similar to the heterophasic uptake of ions by plant cells/roots.Abbreviations FC fusicoccin - ABA abscisic acid - CCCP carbonyl cyanide-m-chlorophenyl hydrazone     

Energy Supply for Stomatal Opening in Epidermal Strips of Commelina benghalensis

The influence of light or darkness on stomatal opening in epidermal strips of Commelina benghalensis was evaluated in the presence or absence of O₂ and/or metabolic inhibitors. Opening was restricted in nitrogen and was promoted by NADH and acids of the tricarboxylic acid cycle (succinate and α-ketoglutarate) in CO₂-free air in light as well as in darkness. The enhancement by light of stomatal opening was prevalent under nitrogen or in the presence of the respiratory inhibitors (sodium azide and oligomycin). Respiratory inhibitors decreased the opening in light or darkness under CO₂-free air but exhibited no effect under nitrogen, whereas phosphorylation uncouplers were inhibitory in light or darkness under both CO₂-free air and nitrogen. The results suggest that oxidative phosphorylation is a basic source of energy for stomatal opening, although photophosphorylation could be an energy source.     

Stomatal movement and potassium transport in epidermal strips of Zea mays: The effect of CO2

Summary The correlation between stomatal action and potassium movement in the epidermis of Zea mays was examined in isolated epidermal strips floated on distilled water. Stomatal opening in the isolated epidermis is reversible in response to alternate periods of light or darkness, and is always correlated with a shift in the potassium content of the guard cells. K accumulates in guard cells during stomatal opening, and moves from the guard cells into the subsidiary cells during rapid stomatal closure. When epidermal strips are illuminated in normal air, as against CO₂-free air, the stomata do not open and there is a virtually complete depletion of K from the stomatal apparatus. In darkness CO₂-containing air inhibits stomatal opening and K accumulation in guard cells, but does not lead to a depletion of K from the stomata as observed in the light.     

Stomatal Opening in Isolated Epidermal Strips of Vicia faba. II. Responses to KCl Concentration and the Role of Potassium Absorption

The stimulation by KCl of stomatal opening in isolated epidermal strips of Vicia faba was examined. In dark + normal air the opening response was maximal at 100 mm KCl while in light + CO₂-free air it was maximal at about 10 mm KCl. CO₂-free air was more influential than light in reducing the KCl concentration required for maximal opening. K⁺ was essential while Cl⁻ seemed to be of secondary importance in these processes.     

Potassium Deficiency-induced Changes in Stomatal Behavior, Leaf Water Potentials, and Root System Permeability in Beta vulgaris L

Studies of the water relations of potassium deficient sugarbeet plants (Beta vulgaris L.) revealed two factors for stomatal closure. One component of stomatal closure was reversible by floating leaf discs on distilled water to relieve the water deficit in the leaves; the other component was reversible in the light by floating the leaf discs on KCl solution for 1 hour or more. Potassium-activated stomatal opening in the light was observed when the guard cells were surrounded by their normal environment of epidermal and mesophyll cells, just as observed by previous workers for epidermal strips. Leaf water potentials, like stomatal apertures, appear to be strongly related to leaf potassium concentration. Potassium-deficient plants have a greatly decreased root permeability to water, and the implications of this effect on stomatal aperture and leaf water potential are discussed. In contrast, petiole permeability to water is unaffected by potassium treatment.     

Action Spectra for Guard Cell Rb Uptake and Stomatal Opening in Vivia faba

Abaxial epidermal strips, containing guard cells as the only viable cells, were prepared from leaves of Vicia faba following a period in darkness, and floated, under CO₂-free air, on 2 mm RbCl + 0.1 mm CaCl₂ labeled with ⁸⁶Rb⁺. Under white light (high pressure mercury vapor lamp), stomatal opening in these strips approached its maximum at less than 0.02 calorie per square centimeter per minute. Under light of different wavelengths, 20 nanometers apart, and at a low quantum flux density of 7 × 10¹⁴ quanta per square centimeter per second, Rb⁺ uptake and stomatal opening were activated only in the blue and long ultraviolet regions, with a peak at 420 to 460 nanometers. The action spectrum suggests that the underlying process is not photosynthesis. At higher quantum flux density (38 × 10¹⁴ quanta per square centimeter per second), uptake and opening also responded to red (600-680 nanometers) and somewhat to green light, with a minimum at 540 to 560 nanometers, indicating a possible involvement of the photosynthetic process. This light-induced opening appeared not to be mediated by a lowering of CO₂ concentration, since CO₂-free air was used in all treatments and controls. Stomatal opening paralleled Rb⁺ uptake in all cases. This constitutes further evidence for the potassium transport hypothesis of stomatal movement.     

Effects of sulfite on phosphoenolpyruvate carboxylase and nicotinamide adenine dinucleotide phosphate-dependent malate dehydrogenase in epidermal peels in two cultivars of pea

We have identified a differential response of stomatal conductance to sulfur dioxide in two cultivars of pea ( Pisum sativum L. cvs P715 and Nugget). The response to sulfite exposure of PEPC activities present in epidermal peels obtained from the two cultivars was qualitatively in agreement with the results obtained for stomatal conductance. With epidermal tissue isolated from the more sensitive cultivar, we have investigated the effect of light and sulfite on guard cell phosphoenolpyruvate carboxylase (E.E. 4.1.1.31.) and NADP-dependent malate dehydrogenase (E.C. 1.1.1.82), two enzymes of the malate biosynthetic pathway. No difference was found between the substrate-saturated activity of phosphoenolpyruvate carboxylase in epidermal tissue incubated in the light or in the dark under the same conditions. Substratesaturated NADP-dependent malate dehydrogenase activity increased nearly 3-fold during a 60 min incubation in the light. Incubations of epidermal tissue in the light in the presence of sulfite resulted in a decrease in the activity of both enzymes. Our results suggest that the inhibition of these two enzymes of the malate biosynthetic pathway may be one cause of sulfur dioxide-mediated stomatal closure.     

Blue light-promoted stomatal opening in abaxial epidermis of Commelina benghalensis is maximal at low calcium

The requirement for calcium in blue light-promoted stomatal opening, in comparison with that in red light, was studied in epidermal strips of Commelina benghalensis L. Blue light promoted stomatal opening in the presence of a low level of calcium, whereas in red light opening was relatively tolerant to calcium. Stomatal opening under blue light was restricted by external calcium (above 5 μ M ) or abscisic acid. When present in the incubation medium, EGTA increased the extent of stomatal opening under blue light. Verapamil (a calcium-channel blocker) and trifluoperazine (TFP, a calmodulin antagonist) reduced the stimulation of stomatal opening by blue light. Lanthanum, an external calcium-channel antagonist, had no significant effect on stomatal opening under either blue or red light. These observations indicate that blue light-promoted stomatal opening preferentially occurs at low levels of calcium, and modulation by calmodulin is strongly suggested. We conclude that a fine-tuning of the calcium level within guard cells is essential during the transduction of the blue light signal.     

Effects of phaseic Acid and dihydrophaseic Acid on stomata and the photosynthetic apparatus

Plant extracts containing phaseic acid (PA), as well as solutions of purified PA and dihydrophaseic acid (DPA) were applied to leaves, isolated mesophyll cells, and isolated epidermal strips. In Commelina communis, stomatal closure began 4 minutes after the addition of either 20 micromolar (±)-abscisic acid or 10 micromolar PA. Stomata closed less rapidly after treatment with 10 micromolar PA than after treatment with 10 micromolar (±)-abscisic acid in Amaranthus powelli, Hordeum vulgare, Xanthium strumarium, and Zea mays and did not respond at all to PA in Vicia faba. DPA (10 micromolar) did not cause stomatal closure in any species.     

Light modulation of phosphofructokinase in pea leaf chloroplasts

Chloroplastic phosphofructokinase, phosphorylase, phosphoglucomutase, and phosphoglucoisomerase in peas are light inactivated. The effect of light on phosphofructokinase is mimicked by dithiothreitol. DCMU, arsenite, and sulfite inhibit light modulation of the enzyme. No effect of light inactivation on the K_m (fructose-6-P) or pH optima of phosphofructokinase was observed.     

Effect of Potassium Levels on the Stomatal Behavior of the Hemi-Parasite Striga hermonthica

The hemi-parasite Striga hermonthica, exhibits an anomalous pattern of stomatal response, stomata remaining open in darkness and when subjected to water stress. This suggests irregularity in stomatal response due to malfunction of the stomatal mechanism. To test this suggestion guard cells were isolated from the effects of surrounding cells, by incubating epidermal strips at low pH. These stomata responded rapidly to low CO₂ concentrations, darkness, and ABA. Thus, a paradox exists between stomatal behavior observed in whole leaves and that in isolated guard cells. However, when incubated in the presence of high potassium concentrations (>200 millimolar KCl) stomatal responses in epidermal strips resembled those found in whole leaves, with enhanced opening and reduced closing responses. It is suggested that the anomalous behavior of stomata in Striga and other leafy hemiparasites can be explained by the modulatory effects of high potassium concentrations which accumulate in the leaves as a consequence of high transpiration rates and the lack of a retranslocation system.     

Acid-Induced Stomatal Opening in Vicia faba L. and the Role of Guard Cell Wall Elasticity

When epidermal peels of Vicia faba L. were treated with solutions of varying pH, stomatal aperture was significantly increased at pH 4.0, 3.0, and 2.7 in darkness, but not in light. This effect was independent of the presence of KCl in the medium. Using a short-term plasmolytic method, estimates were made of the osmotic pressure (II_i) and the volumetric elastic modulus of guard cells, the aperture of which varied due to pretreatments at different pH, in darkness or light. In darkness, the lower pH pretreatments induced an increase in II_i and a decrease in volumetric elastic modulus. In comparison to the response in unbuffered solutions, 10 and 25 millimolar Mes buffer at pH 6.5 significantly reduced the degree of stomatal opening induced by light or by fusicoccin. These results indicate that acid-induced stomatal opening is, at least partially, due to an increase in guard cell wall elasticity which occurs in association with changes in II_i. It is suggested that the observed inhibitory effect of Mes buffer on stomatal opening may be due to a reduction in the degree of acidification of the guard cell wall and a consequent decrease of cell wall elasticity.     

Light Modulation of Enzyme Activity in Chloroplasts: Generation of Membrane-bound Vicinal-Dithiol Groups by Photosynthetic Electron Transport

Inhibitor experiments indicate that photosynthetic electron transport is required for light activation of the pea (Pisum sativum) leaf chloroplast enzymes NADP-linked glyceraldehyde-3-phosphate dehydrogenase, NADP-linked malic dehydrogenase, ribulose-5-phosphate kinase and sedoheptulose-1,7-diphosphate phosphatase, and for inactivation of glucose-6-phosphate dehydrogenase. Modulation of the activity of the dehydrogenases and kinase apparently involves a component preceding ferredoxin in the photosynthetic electron transport chain; activation of the phosphatase involves an electron transport component at the level of ferredoxin. Modulation of enzyme activity can be obtained in a broken chloroplast system consisting of membrane fragments and stromal extract. The capacity for light regulation in this system is reduced or eliminated when the membrane fraction is exposed to arsenite in the light or to sulfite in light or dark. Light-generated vicinal-dithiols seem therefore to be involved in modulation of the activity of the enzymes included in this study.     

Promotion of Stomatal Opening by Indoleacetic Acid and Ethrel in Epidermal Strips of Vicia faba L

Indole-3-acetic acid (IAA), at concentrations of 0.01 to 1.0 millimolar, and ethephon (0.3% v/v Ethrel) promote stomatal opening when applied to epidermal peels of Vicia faba L. in light or dark. The effect of ethylene is seen by 30 minutes and maximal opening (over two times that of untreated controls) occurs after only 60 to 90 minutes in the light. Stomatal opening by IAA and Ethrel in both light and dark is prevented by 0.14 millimolar AgCl. It is suggested that the effect of added IAA, but not that of light, is linked to ethylene production. The possible role of ethylene in stomatal opening during fungal infection is discussed. The stomates of Vicia faba provide a new system to study the effects of ethylene on certain membrane-regulated processes.     

Endogenous Diurnal and Nocturnal Activity of Guard Cells as Indicated by Stomatal Aperture and Protoplasmic Streaming

The hourly stomatal apertures on epidermal strips of Antirrhinum majus, Rheum rhaponticum, Vicia faba, and Zebrina pendula fixed by Lloyd's technique were compared with the number of stomata found to contain streaming at the same time. With all four species there was an indication of an endogenously controlled rhythm in stomatal opening with both increases and decreases in aperture and streaming during daytime hours in either the light or dark. A similar endogenously activated rhythm was also found at night in Rheum and Vicia. Some relationships exist between changes in stomatal aperture and streaming. Streaming in guard cells may only be a byproduct of metabolism, but as such, it serves the useful purpose as a mixer of chemical activity.