Further support for the involvement of phytoehrome in stomatal movement

The involvement of phytochrome in stomatal movement in Commelina communis L. is indicated by the following observations: 1) Short irradiation with red or blue light causes opening, of isolated stomata and swelling of guard cell protoplasts. This is reversed by subsequent far red irradiation. 2) In a similar way, stomatal response to prolonged irradiation with red or blue light is decreased by concomitant far red irradiation. 3) Pretreatment with filipin, which interferes with phytochrome binding to membranes, decreases stomatal opening in red and blue light. The stomatal responses to blue and red light are modified by DCMU, N₂, CO_2-enriched atmosphere, and CO_2-free air, which are known to affect, among other processes, chlorophyll fluorescence. Increased chlorophyll fluorescence by DCMU, N₂ and CO₂-enriched atmosphere enhanced stomatal opening in blue light and inhibited it in red light. CO₂-free air, which decreases chlorophyll fluorescence, had the opposite effect.     

Stomatal responses to light in the facultative Crassulacean acid metabolism species, Portulacaria afra

Guard cell responses to light are mediated by guard cell chlorophyll and by a specific blue light photoreceptor. Gas exchange and epidermal peel techniques were employed to investigate these responses in the facultative Crassulacean acid metabolism (CAM) species, Portulacaria afra (L.) Jacq. In P. afra individuals performing C₃ metabolism, red light stimulated an increase in leaf conductance in intact leaves and stomatal opening in isolated epidermal peels, indicating the presence in guard cells of the chlorophyll-mediated response to light. Under a background of continuous red illumination, conductance exhibited transient increases following pulses of blue but not red light, indicating that the specific stomatal response to blue light was also operative. In contrast, in CAM individuals, conductance in gas exchange experiments and stomatal opening in epidermal peel experiments were not stimulated by red light. In CAM plants, conductance did not increase following blue light pulses administered over a range of temperatures, vapor pressure differences (VPD), ambient CO₂ concentrations and background red light intensities. These results indicate that P. afra does possess typical guard cell responses to light when performing C₃ metabolism. The metabolic pathways mediating these responses are either lost or inhibited when CAM is induced.     

Effect of sink size on photosynthesis and carbohydrate content of leaves of three spring wheat varieties

Effects of CO₂ on stomatal movements of Commelina communis L. were studied with plants, epidermal strips and guard cell protoplasts. With plants, the stomatal response induced by a blue light pulse was studied for different ambient CO₂ concentration ranging from CO₂-deprived air to 100 Pa in darkness or under red light. It was observed that the blue light response could be obtained not only under a red light background but also in darkness and CO₂-free air, the two responses being quite similar.
With epidermal strips, the effect of CO₂ on ferricyanide reductase activity at the guard cell plasmalemma was studied by transmission electron microscopy. In the presence of ferric ions, reduced ferricyanide gives an electron dense precipitate of Prussian Blue. In darkness and air, no precipitate was observed. In darkness and CO₂-free air as well as under light and normal air, a precipitate was found along the plasmalemma of the guard cells, indicating a ferricyanide reductase activity. With guard cell protoplasts suspended in a medium either in equilibrium with air or in a CO₂-free medium the H⁺ extrusion induced by a blue light pulse added to a red light background was measured. A low CO₂ content was obtained by adding photosynthetic algae to the suspension of guard cell protoplasts. In a CO₂-free medium the rate of H⁺ extrusion was enhanced.
The results are discussed on the basis of a possible competition for reducing power between CO₂ fixation and a putative blue light dependent redox chain located on the plasma membrane.     

Opinion: Stomatal responses to light and CO2 depend on the mesophyll

The mechanisms by which stomata respond to red light and CO₂ are unknown, but much of the current literature assumes that these mechanisms reside wholly within the guard cells. However, responses of guard cells in isolated epidermes are typically much smaller than those in leaves, and there are several lines of evidence in the literature suggesting that the mesophyll is necessary for these responses in leaves. This paper advances the opinion that although guard cells may have small direct responses to red light and CO₂, most of the stomatal response to these factors in leaves is caused by an unknown signal that originates in the mesophyll.     

A reassessment of the intervention of calmodulin in the regulation of stomatal movement

Commelina cammunis L., a monocotyledonous plant whose stomata are highly sensitive to calcium ions, was used to study calmodulin (CaM) involvement in stomatal movements. CaM was detected and quantified in guard cell and mesophyll cell protoplasts by western blot and by ⁴⁵Ca²⁺-overlays. CaM was found to be 3- to 7-fold more abundant on a per protein basis in guard cell than in mesophyll cell protoplasts. Numerous guard cell proteins that bind CaM in a Ca²⁺-dependent manner were detected by gold-labelled CaM overlays. Using bioassays with epidermal strips, different CaM-antagonists were found to induce a net stimulation of stomatal opening in darkness or under illumination (trifluoperazine > compound 48/80 ∼ fluphenazine > W7 > W5). As CaM is frequently involved in the regulation of phosphorylation processes, the effects of different inhibitors of protein kinases on stomatal movements were studied. In red plus blue light, a promotion of the stomatal aperture was observed in the nanomolar range with K252a and KT5926 and in the micromolar range with KT5720 ≫ ML7 ∼ ML9 ≫ H7 > KN62. Only the inhibitors with a high specificity for Ca²⁺-CaM dependent protein kinases (K252a, KT5926, ML7, ML9) triggered a stomatal opening in darkness and increased stomatal aperture in red plus blue light. Taken together, these data strongly suggest that a Ca²⁺- or a Ca²⁺-CaM-dependent protein kinase plays a central role in the calcium transduction pathway leading to the maintaining of stomatal closure.     

A reassessment of the intervention of calmodulin in the regulation of stomatal movement

Commelina cammunis L., a monocotyledonous plant whose stomata are highly sensitive to calcium ions, was used to study calmodulin (CaM) involvement in stomatal movements. CaM was detected and quantified in guard cell and mesophyll cell protoplasts by western blot and by ⁴⁵Ca²⁺-overlays. CaM was found to be 3- to 7-fold more abundant on a per protein basis in guard cell than in mesophyll cell protoplasts. Numerous guard cell proteins that bind CaM in a Ca²⁺-dependent manner were detected by gold-labelled CaM overlays. Using bioassays with epidermal strips, different CaM-antagonists were found to induce a net stimulation of stomatal opening in darkness or under illumination (trifluoperazine > compound 48/80 ≅ fluphenazine > W7 > W5). As CaM is frequently involved in the regulation of phosphorylation processes, the effects of different inhibitors of protein kinases on stomatal movements were studied. In red plus blue light, a promotion of the stomatal aperture was observed in the nanomolar range with K252a and KT5926 and in the micromolar range with KT5720 ≫ ML7 ≅ ML9 ≫ H7 > KN62. Only the inhibitors with a high specificity for Ca²⁺-CaM dependent protein kinases (K252a, KT5926, ML7, ML9) triggered a stomatal opening in darkness and increased stomatal aperture in red plus blue light. Taken together, these data strongly suggest that a Ca²⁺- or a Ca²⁺-CaM-dependent protein kinase plays a central role in the calcium transduction pathway leading to the maintaining of stomatal closure.     

The cellular basis of guard cell sensing of rising CO2

Numerous studies conducted on both whole plants and isolated epidermes have documented stomatal sensitivity to CO₂. In general, CO₂ concentrations below ambient stimulate stomatal opening, or an inhibition of stomatal closure, while CO₂ concentrations above ambient have the opposite effect. The rise in atmospheric CO₂ concentrations which has occurred since the industrial revolution, and which is predicted to continue, will therefore alter rates of transpirational water loss and CO₂ uptake in terrestrial plants. An understanding of the cellular basis for guard cell CO₂ sensing could allow us to better predict, and perhaps ultimately to manipulate, such vegetation responses to climate change. However, the mechanisms by which guard cells sense and respond to the CO₂ signal remain unknown. It has been hypothesized that cytosolic pH and malate levels, cytosolic Ca²⁺ levels, chloroplastic zeaxanthin levels, or plasma-membrane anion channel regulation by apoplastic malate are involved in guard cell perception and response to CO₂. In this review, these hypotheses are discussed, and the evidence for guard cell acclimation to prevailing CO₂ concentrations is also considered.     

Silencing of NtMPK4 impairs CO-induced stomatal closure, activation of anion channels and cytosolic Casignals in Nicotiana tabacum guard cells

Light-induced stomatal opening in C3 and C4 plants is mediated by two signalling pathways. One pathway is specific for blue light and involves phototropins, while the second pathway depends on photosyntheticaly active radiation (PAR). Here, the role of Nt MPK4 in light-induced stomatal opening was studied, as silencing of this MAP kinase stimulates stomatal opening. Stomata of Nt MPK4-silenced plants do not close in elevated atmospheric CO₂, and show a reduced response to PAR. However, stomatal closure can still be induced by abscisic acid. Measurements using multi-barrelled intracellular micro-electrodes showed that CO₂ activates plasma membrane anion channels in wild-type Nicotiana tabacum guard cells, but not in Nt MPK4-silenced cells. Anion channels were also activated in wild-type guard cells after switching off PAR. In approximately half of these cells, activation of anion channels was accompanied by an increase in the cytosolic free Ca²⁺ concentration. The activity of anion channels was higher in cells showing a parallel increase in cytosolic Ca²⁺ than in those with steady Ca²⁺ levels. Both the darkness-induced anion channel activation and Ca²⁺ signals were repressed in Nt MPK4-silenced guard cells. These data show that CO₂ and darkness can activate anion channels in a Ca²⁺-independent manner, but the anion channel activity is enhanced by parallel increases in the cytosolic Ca²⁺ concentration. Nt MPK4 plays an essential role in CO₂- and darkness-induced activation of guard-cell anion channels, through Ca²⁺-independent as well as Ca²⁺-dependent signalling pathways.     

Direct and indirect effects of light on stomata. I. In Scots pine and Sitka spruce

Abstract. The response of stomatal conductance to broadband blue and red light was measured in whole shoots of Scots pine and Sitka spruce, two species which have low stomatal sensitivity to CO². In Scots pine, blue light was more than three times more effective than red light (on an incident quantum basis) in opening stomata, particularly at low quantum flux densities (<100μmiol m⁻² s⁻¹). However, the apparent quantum yield of net CO² assimilation rate in blue light was only half that in red light. The contrasting effects of red and blue light on conductance and assimilation led to higher intercellular CO² concentrations (C_i) in blue light (up to 100 μmol mol⁻¹ higher) than in red light. Similar results were obtained with Sitka spruce shoots, though differences in the effectiveness of red and blue light were less marked. In both species, both red and blue light increased conductance in normal and CO²-free air, indicating that neither red nor blue light exert effects through changes in C_i or mesophyll assimilation. However, decreases in C_i caused increases in conductance in both red and blue light, suggesting that these direct effects of light are not wholly independent of CO².     

The stomatal response to CO2 is linked to changes in guard cell zeaxanthin*

The mechanisms mediating CO₂ sensing and light–CO₂ interactions in guard cells are unknown. In growth chamber-grown Vicia faba leaves kept under constant light (500 μ mol m^–2 s^–1) and temperature, guard cell zeaxanthin content tracked ambient [CO₂] and stomatal apertures. Increases in [CO₂] from 400 to 1200 cm³ m^–3 decreased zeaxanthin content from 180 to 80 mmol mol^–1 Chl and decreased stomatal apertures by 7·0 μ m. Changes in zeaxanthin and aperture were reversed when [CO₂] was lowered. Guard cell zeaxanthin content was linearly correlated with stomatal apertures. In the dark, the CO₂-induced changes in stomatal aperture were much smaller, and guard cell zeaxanthin content did not change with chamber [CO₂]. Guard cell zeaxanthin also tracked [CO₂] and stomatal aperture in illuminated stomata from epidermal peels. Dithiothreitol (DTT), an inhibitor of zeaxanthin formation, eliminated CO₂-induced zeaxanthin changes in guard cells from illuminated epidermal peels and reduced the stomatal CO₂ response to the level observed in the dark. These data suggest that CO₂-dependent changes in the zeaxanthin content of guard cells could modulate CO₂-dependent changes of stomatal apertures in the light while a zeaxanthin-independent CO₂ sensing mechanism would modulate the CO₂ response in the dark.     

Involvement of intracellular Ca2+ in blue light-dependent proton pumping in guard cell protoplasts from Vicia faba

Recent studies have suggested that Ca²⁺/calmodulin (CaM) or CaM-like proteins may be involved in blue light (BL)-dependent proton pumping in guard cells. As the increase in cytosolic concentration of Ca²⁺ is required for the activation of CaM and CaM-like proteins, the origin of the Ca²⁺ was investigated by measuring BL-dependent proton pumping with various treatments using guard cell protoplasts (GCPs) from Vicia faba . BL-dependent proton pumping was affected neither by Ca²⁺ channel blockers nor by changes of Ca²⁺ concentration in the medium used for the GCPs. Addition of Ca²⁺ ionophores and an agonist to GCPs did not induce proton pumping. However, BL-dependent proton pumping was inhibited by 10 m M caffeine, which releases Ca²⁺ from the intracellular stores, and by 10 μ M 2,5-di-( tert -butyl)-1,4-benzohydroquinone (BHQ) and 10 μ M cyclopiazonic acid (CPA), inhibitors of Ca²⁺-ATPase in the sarcoplasmic and endoplasmic reticulum (ER). By contrast, the inhibitions were not observed by 10 μ M thapsigargin, an inhibitor of animal ER-type Ca²⁺-ATPase. The inhibitions by caffeine and BHQ were reversible. Light-dependent stomatal opening in the epidermis of Vicia was inhibited by caffeine, BHQ, and CPA. From these results, we conclude that the Ca²⁺ thought to be required for BL-dependent proton pumping may originate from intracellular Ca²⁺ stores, most likely from ER in guard cells, and that this origin of Ca²⁺ may generate a stimulus-specific Ca²⁺ signal for stomatal opening.     

Isolation and Characterization of a Cytosolic Phospholipase A2 from Bovine Adrenal Medulla

Abstract: We have recently demonstrated that bovine adrenal medulla contains a soluble phospholipase A₂ (PLA₂), which is localized in the cytosol. In the present study, this PLA₂ was purified 1,097-fold using sequential concanavalin A, hydrophobic interaction, anion exchange, gel filtration, and an additional anion exchange chromatography. The enzyme is activated over the range of 20–1,000 µ M Ca²⁺ and has a pH optimum near 8.0. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the protein has a molecular mass of 26 kDa and an isoelectric point of 4.6 as revealed by isoelectric focusing. The cytosolic PLA₂ is not inhibited by NaCl, and the enzymatic activity is stimulated at low concentrations of Triton X-100 (0.01%) and deoxycholate (1 m M ) but inhibited at higher concentrations (0.1% and 3 m M , respectively) of these detergents. Furthermore, heat treatment (57°C, 5 min) reduced the enzymatic activity by 80%, whereas glycerol (30%) increased the activity. p -Bromophenacylbromide, a frequently used irreversible inhibitor of type II PLA₂, has little effect until 100 µ M , and 2–10 m M dithiothreitol totally inactivated the enzyme. The purified PLA₂ displays a preference for phosphatidylcholine as a substrate but hydrolyzes phospholipid substrates with arachidonic acid or linoleic acid esterified at the sn -2 position to the same extent. It is concluded that the chromaffin cell cytosolic PLA₂, which was isolated and characterized in this study, represents a type of PLA₂ that has not been formerly reported in chromaffin cells. Additional research on the chromaffin cell cytosolic PLA₂ will help to reveal whether the enzyme is important for exocytosis.     

Light perception in guard cells

Abstract. Guard cells perceive light via two photoreceptor systems: a blue-light-dependent photosystem and the guard cell chloroplast. Chloroplasts stimulate stomatal opening by transducing photosynthetic active radiation into proton pumping at the guard cell plasma membrane. In addition, guard cell chloroplasts fix CO₂ photosynthetically. Sugar from guard cell photosynthesis can contribute to the osmotic build-up required for opening. The blue-light-dependent photosystem activates proton pumping at the guard cell plasma membrane and stimulates starch hydrolysis. Available information on the photobiological properties of guard cells makes it possible to describe stomatal function in terms of the cellular components regulating stomatal movements. The blue light response is involved in stomatal opening in the early morning and stomatal responses to sunflecks. The guard cell chloroplast is likely to be involved in stomatal adaptations to sun, shade and to temperature. Interactions between these photosystems, a third photoreceptor in guard cells, phytochrome, and other mechanisms transducing stomatal responses such as VPD and carbon dioxide, provide the cellular basis for stomatal regulation.     

Characterization of the effects of metabolic inhibitors, ATPase inhibitors and a potassium-channel blocker on stomatal opening and closing in isolated epidermis of Commelina communis L.

Abstract. The specific effects of hypoxia and various inhibitors on stomatal opening in the light and closing in the dark were characterized in isolated epidermis from Commelina communis L. Reducing the guard cell metabolism with hypoxia and the uncoupler carbonyl cyanide-m-chloro-phenyl-hydrazone, CCCP, respectively, inhibited both stomatal opening and closing. Stomatal closing was very efficiently blocked by CCCP and this effect could be readily reversed by washing out the inhibitor. The authors were unable to inhibit stomatal opening with ATPase-inhibitors, without also affecting closing. Orthovanadate, up to 2 mol m⁻³, affected neither opening nor closing. Dicyclohexylcarbodiimide, DCCD, and diethylstilbestrol, DES, inhibited opening as well as closing to about 50%. The K⁺ -channel blocker tetraethylammonium chloride, TEA-Cl, inhibited both stomatal opening and closing, as did phenyl acetic acid, PAA, a compound considered to interfere with blue light induced stomatal opening. The results are discussed in the view that the uncontrolled K⁺ leakage from the guard cells is low, that K⁺ efflux during stomatal closing, as well as K⁺ influx during opening, occurs through specific K⁺-channels and that ATP and/or a membrane potential seems to be needed to keep these channels open.     

Photosynthesis affects following night leaf conductance in Vicia faba

Night-time stomatal opening in C₃ plants may result in significant water loss when no carbon gain is possible. The objective of this study was to determine if endogenous patterns of night-time stomatal opening, as reflected in leaf conductance, in Vicia faba are affected by photosynthetic conditions the previous day. Reducing photosynthesis with low light or low CO₂ resulted in reduced night-time stomatal opening the following night, irrespective of the effects on daytime stomatal conductance. Likewise, increasing photosynthesis with enriched CO₂ levels resulted in increased night-time stomatal opening the following night. Reduced night-time stomatal opening was not the result of an inability to regulate stomatal aperture as leaves with reduced night-time stomatal opening were capable of greater night-time opening when exposed to low CO₂. After acclimating plants to long or short days, it was found that night-time leaf conductance was greater in plants acclimated to short days, and associated with greater leaf starch and nitrate accumulation, both of which may affect night-time guard cell osmotic potential. Direct measurement of guard cell contents during endogenous night-time stomatal opening will help identify the mechanism of the effect of daytime photosynthesis on subsequent night-time stomatal regulation.     

Genetic variation of stomatal conductance, blue light sensitivity and zeaxanthin content in guard cells of Pima cotton (Gossypium barbadense)

Pima S‐6 ( Gossypium barbadense L.) is a modern line with high stomatal conductance, while B368 is a primitive cotton with low conductance. The blue light sensitivity of adaxial guard cells, probed as the blue light‐dependent enhancement of the red light‐induced chlorophyll a fluorescence quenching, was investigated in these two cotton lines with contrasting stomatal conductance. Adaxial guard cells isolated from Pima S‐6 cotton plants had a significantly higher carotenoid content and a higher blue light sensitivity than those isolated from B368 plants. In a growth chamber‐grown F₂ population of a cross between these two lines, adaxial stomatal conductances of individual plants segregated over a range exceeding the average conductances of the parents. Carotenoid content and the blue light sensitivity of adaxial guard cells also segregated. The concentrations of xanthophylls and β‐carotene in the adaxial guard cells were poorly correlated with the blue light response, except for zeaxanthin. The co‐segregation of stomatal conductance and blue light sensitivity suggested that the stomatal response to blue light may play a role in the regulation of stomatal conductance in the intact leaf. Zeaxanthin content and blue light sensitivity also co‐segregated, suggesting that both parameters are under genetic control. The co‐segregation of zeaxanthin content, blue light sensitivity and stomatal conductance provides further evidence for a role of zeaxanthin in the blue light photoreception of guard cells.     

Stomatal sensing of the environment

The effects of environmental factors on stomatal behaviour are reviewed and the questions of whether photosynthesis and transpiration eontrol stomata or whether stomata themselves control the rates of these processes is addressed. Light affects stomata directly and indirectly. Light can act directly as an energy source resulting in ATP formation within guard cells via photophosphorylation, or as a stimulus as in the case of the blue light effects which cause guard cell H⁺ extrusion. Light also acts indirectly on stomata by affecting photosynthesis which influences the intercellular leaf CO₂ concentration ( C _i). Carbon dioxide concentrations in contact with the plasma membrane of the guard cell or within the guard cell acts directly on cell processes responsible for stomatal movements. The mechanism by which CO₂ exerts its effect is not fully understood but, at least in part, it is concerned with changing the properties of guard cell plasma membranes which influence ion transport processes. The C _i may remain fairly constant for much of the day for many species which is the result of parallel responses of stomata and photosynthesis to light. Leaf water potential also influences stomatal behaviour. Since leaf water potential is a resultant of water uptake and storage by the plant and transpirational water loss, any factor which affects these processes, such as soil water availability, temperature, atmospheric humidity and air movement, may indirectly affect stomata. Some of these factors, such as temperature and possibly humidity, may affect stomata directly. These direct and indirect effects of environmental factors interact to give a net opening response upon which is superimposed a direct effect of stomatal circadian rhythmic activity.     

Characterization of a Novel Phospholipase A2 Activity in Human Brain

Abstract: Phospholipases A₂ (PLA₂) are a family of enzymes that catalyze the removal of fatty acid residues from phosphoglycerides. The enzyme is postulated to be involved in several human brain disorders, although little is known regarding the status of PLA₂ activity in human CNS. We therefore have characterized some aspects of the PLA₂ activity present in the temporal cortex of human brain. More PLA₂ activity was found in the membrane (particulate) fraction than in the cytosolic fraction. The enzyme could be solubilized from particulate material using 1 M potassium chloride, and was capable of hydrolyzing choline phosphoglyceride (CPG) and ethanolamine phosphoglyceride (EPG), with a preference (approximately eightfold) for EPG over CPG. When the solubilized particulate enzyme was subjected to gel filtration chromatography, PLA₂ activity eluted in a high molecular mass fraction (∼180 kDa). PLA₂ activity was weakly stimulated by dithiothreitol, strongly stimulated by millimolar concentrations of calcium ions, and inhibited by brief heat treatment at 57°C, bromophenacyl bromide, the arachidonic acid derivative AACOCF₃, γ-linolenoyl amide, and N -methyl γ-linolenoyl amide. Thus, whereas the human brain enzyme(s) characterized in our study displays some of the characteristics of previously characterized PLA₂s, it differs in several key features.     

A Soluble Phospholipase of Toxoplasma gondii Associated with Host Cell Penetration

We previously reported that phospholipase increases host cell penetration by Toxoplasma gondii . Here we show that calcium-dependent phospholipase A (PLA) activity is found in the supernatant of sonically disrupted T. gondii . When fractions of disrupted T. gondii were incubated with host cells, the release of fatty acids and lysolipids was detected. Fractions of sonically disrupted T. gondii with PLA activity increased T. gondii host cell penetration in a bioassay. In addition, a protein of approximately 20 kDa was detected by immunoblot of T. gondii antigens with horse antiserum to snake venom, the major antibody of which recognizes PLA₂. Incubation of T. gondii with exogenous PLA₂ resulted in increased solubility of a rhoptry protein. This protein, which we previously characterized as involved with enhanced parasite invasion of host cells and which is recognized by monoclonal antibody Tg49, was detected in increased amounts in supernatant fractions of extracellular parasites treated with PLA₂. Whereas without PLA₂ treatment, it is only slightly soluble under physiological conditions. This raises the possibility that PLA may be implicated in the release of rhoptry proteins.     

Phytochrome effects on K+ fluxes in guard cells of Commelina communis

The effect of phytochrome on K⁺ transport in guard cells of Commelina communis L. was studied following stomatal movement and using the K⁺−channel blockers tetraethylammonium (TEA), Cs⁺ and quinidine. TEA and quinidine prevented stomatal opening and closure in red light, but not when it was supplemented with far-red. This indicates that channels that can be blocked by TEA and quinidine are regulated by phytochrome. Evidence for a phytochrome effect on K⁺ leakage through other membranal compartments was also found. These phytochrome effects are modified by temperature. Elevated temperature decreases the involvement of channels and increases K⁺ transport through other membrane compartments, while low temperature causes channel opening and diminishes K⁺ leakage. The interaction between phytochrome effects and those of temperature is discussed.