Dark/Light modulation of ribulose bisphosphate carboxylase activity in plants from different photosynthetic categories

Ribulose bisphosphate carboxylase/oxygenase (RuBPCase) from several plants had substantially greater activity in extracts from lightexposed leaves than dark leaves, even when the extracts were incubated in vitro with saturating HCO₃⁻ and Mg²⁺ concentrations. This occurred in Glycine max, Lycopersicon esculentum, Nicotiana tabacum, Panicum bisulcatum, and P. hylaeicum (C₃); P. maximum (C₄ phosphoenolpyruvate carboxykinase); P. milioides (C₃/C₄); and Bromelia pinguin and Ananas comosus (Crassulacean acid metabolism). Little or no difference between light and dark leaf extracts of RuBPCase was observed in Triticum aestivum (C₃); P. miliaceum (C₄ NAD malic enzyme); Zea mays and Sorghum bicolor (C₄ NADP malic enzyme); Moricandia arvensis (C₃/C₄); and Hydrilla verticillata (submersed aquatic macrophyte). It is concluded that, in many plants, especially Crassulacean acid metabolism and C₃ species, a large fraction of ribulose-1,5-bisphosphate carboxylase/oxygenase in the dark is in an inactivatable state that cannot respond to CO₂ and Mg²⁺ activation, but which can be converted to an activatable state upon exposure of the leaf to light.     

Light stimulation of proline synthesis in water-stressed barley leaves

The effect of light on [¹⁴C]glutamate conversion to free proline during water stress was studied in attached barley (Hordeum vulgare L.) leaves which had been trimmed to 10 cm in length. Plants at the three-leaf stage were stressed by flooding the rooting medium with polyethylene glycol 6000 (osmotic potential-19 bars) for up to 3 d. During this time the free proline content of 10-cm second leaves rose from about 0.02 to 2 mol/leaf while free glutamate content remained steady at about 0.6 mol/leaf. In stressed leaves, the amount of [¹⁴C]glutamate converted to proline in a 3-h period of light or darkness was taken to reflect the in-vivo rate of proline biosynthesis because the following conditions were met: (a) free-glutamate levels were not significantly different in light and darkness; (b) both tracer [¹⁴C]-glutamate and [¹⁴C]proline were rapidly absorbed; (c) rates of [¹⁴C]proline oxidation and incorporation into protein were very slow. As leaf water potential fell, more [¹⁴C]glutamate was converted to proline in both light and darkness, but at any given water potential in the range-12 to-20 bars, illuminated leaves converted twice as much [¹⁴C]glutamate to proline.     

Light modulation of enzyme activity: activation of the light effect mediators by reduction and modulation of enzyme activity by thiol-disulfide exchange

Light and dark modulation experiments with pea (Pisum sativum L.) chloroplast stromal fractions pretreated with dithiothreitol (to reduce protein disulfide bonds) or with 5,5′-dithiobis(2-nitrobenzoic acid) (DTNB) (to block sulfhydryl groups) suggest that light modulation involves thiol-disulfide exchange on the modulatable stromal enzyme protein. Light-dependent reduction of DTNB involves a photosynthetic electron transport chain component located on the reducing side of photosystem I prior to ferredoxin; DTNB may be acting as a light effect mediator substitute. The thylakoid-bound light effect mediator system, then, in its light-activated reduced form probably catalyzes thiol-disulfide exchange reactions on stromal enzymes.     

Involvement of CO2 fixation products in the light-dark modulation of nitrate reductase activity in barley leaves

Nitrate reductase (NR, NADH:nitrate oxidoreductase, EC 1.6.6.1) activity from leaves of barley (Hordeum vulgare L. cv. Hassan) is rapidly and reversibly inactivated during a light-dark transition. A hyperbolic correlation exists between in vivo rates of CO₂ fixation and extractable NR activity from the leaves, and feeding hexose and hexosephosphate protects against the dark-inactivation; indicating that carbon-assimilation products are regulatory factors of NR activity mediating both the light-dark modulation and its dependence upon CO₂ fixation. To corroborate this point, the effect of inhibiting CO₂ fixation on NR activity in barley leaves has been analyzed. Glycolaldehyde (50 mM), an inhibitor of the regeneration phase of the Calvin cycle, was fed through the transpiration stream and inhibited CO₂ fixation by more than 80% at the same time as it produced a parallel inhibition of NR light-activation. Feeding mannose (10 mM), inhibited CO₂ fixation by 35% but did not affect NR activity in illuminated leaves and completely protected against dark-inactivation. Interestingly, feeding inorganic phosphate, P_i, (10 mM) alone or together with mannose also protected NR activity against dark-inactivation. The mannose effect could be interpreted in terms of accumulation of mannose 6-phosphate, an analog of glucose 6-phosphate. After feeding either 10 mM glucose or dihydroxyacetone phosphate, NR activity from darkened leaves was significantly higher than that of darkened control leaves fed with water (P< 0.03). These treatments, as well as P_i feeding, also produce some increase in extractable NR activity from illuminated leaves. The results indicate that factors increasing the levels of hexose- and triose-phosphate have positive effects on NR activation, supporting the contention that the NR activation system is sensitive to carbon-assimilation products.     

Isolation and characterisation of developing chloroplasts from light-grown barley leaves

Developing chloroplasts were isolated from the basal region of green barley ( Hordeum vulgare L. cv. Menuet) leaves and their ultrastructure and biochemical composition were compared to those of mature chloroplasts from the tip of the same leaves, using two methods of purification on sucrose and Percoll gradients.
When examined and compared to mature chloroplasts, the developing chloroplasts showed well-developed grana stacks, but these last organelles were 2-fold smaller and contained lower amounts of chlorohylls and polar lipids. Only traces of trans -3-hexadecenoic acid could be detected in phosphatidylglycerol of developing plastids. The protein content of these plastids was higher than in mature plastids and showed an increased proportion of polypeptides linked to P-700 chlorophyll α-protein. The photosynthetic activity of these plastids was about 2-fold lower and their photosystem 1/photosystem II ratio higher than in mature chloroplasts.     

Hormone-mediated enzyme activity in source leaves

The initial step in carbon allocation occurs in leaves and is the chemical partitioning of carbon between sucrose and starch. Sucorse phosphate synthase is one of the enzymes belived to regulate rate of sucrose synthesis. In this study, the effects of indoleacetic acid, gibberellic acid, and abscisic acid on the activity of this enzyme were investigated in source leaves of mature sugar beets. Preliminary evidence is presented that, concurrent with a modification of sucrose uptake rates, i.e., phloem loading, these plant growth substances modify the activity of sucrose phosphate synthase resulting in altered partitioning of carbon between sucrose and starch.This work was supported by National Science Foundation grant #PCM 82-39139. New Jersey Agricultural Experiment Station Paper No. 3-15192-1-85.     

The photochemical activities and electron carriers of developing barley leaves

The development of photochemical activities in isolated barley plastids during illumination of dark-grown plants has been studied and compared with the behaviour of plastocyanin, cytochromes f, b-559_LP, b-563 and b-559_HP and pigments P546 (C550) and P700. Electron-transport activity dependent on Photosystem 1 and cyclic photophosphorylation dependent on N-methylphenazonium methosulphate (phenazine methosulphate) were very active relative to the chlorophyll content after only a few minutes of illumination of etiolated leaves, and then rapidly declined during the first few hours of greening. By contrast, Photosystem 2 activity (measured with ferricyanide as electron acceptor) and non-cyclic photophosphorylation were not detectable during the first 2½h of greening, but then increased in total amount in parallel with chlorophyll. The behaviour of the electron carriers suggested their association with either Photosystem 1 or 2 respectively. In the first group were plastocyanin, cytochrome f and cytochrome b-563, whose concentrations in the leaf did not change during greening, and cytochrome b-559_LP whose concentration fell to one-half its original value, and in the second group were cytochrome b-559_HP and pigment P546, the concentrations of which closely followed the activities of Photosystem 2. Pigment P700 could not be detected during the first hour, during which time some other form of chlorophyll may take its place in the reaction centre of Photosystem 1. The plastids started to develop grana at about the time that Photosystem 2 activity became detectable.     

Circadian rhythmicity of nitrate reductase activity in barley leaves

Nitrate reductase (EC 1.6.6.1) activity showed circadian rhythmicity in the first leaf of 8–11 days old barley ( Hordeum vulgare L. cv. Herta) plants. Circadian rhythms were found using both the in vitro and in vivo method for testing the enzyme activity. When the light intensity was reduced from 65 to 20 W m⁻², the amplitude was smaller and the oscillations were damped sooner. In continuous darkness nitrate reductase activity decreased in a two step process. Three different light qualities were tested which all gave the same results.     

Acetyl-CoA-carboxylase activity in normally developing wheat leaves

In order to investigate the role of acetyl CoA carboxylase (ACC) in the regulation of fatty-acid biosynthesis in chloroplasts, the activities and relative amounts of the enzyme have been measured in the tissue of wheat (Triticum aestivum L.) leaves undergoing development and cellular differentiation. The total activity in the first leaves of 5- to 7-d-old plants was similar but decreased to less than half in 9-d-old plants. The activity of ACC in the cells of the first leaf of 7-d-old plants doubled when cell age increased from 24 to 48 h, remained relatively constant for a further 24 h and then declined. The amount of ACC in cells increased 15-fold during the first 36 h of cell enlargement. Cells more than 36 h old contained about two-thirds the maximum amount of ACC found in younger cells. The most rapid phase of fatty-acyl accumulation in lipids was in cells aged between 60 and 84 h. Tenfold changes in the activity of ACC were observed when the assay conditions with respect to ATP, ADP, Mg²⁺ and pH were changed to correspond to the physiological conditions in chloroplasts during light/dark transitions. This observation and the magnitude of the changes in the optimum activity and amount of ACC in leaf cells undergoing development are consistent with a role for ACC in the regulation of the flow of carbon from acetyl CoA to fatty acids in chloroplasts.Abbreviation ACC acetyl CoA carboxylase     

Differences in fructose-2,6-bisphosphate metabolism between sections of developing barley leaves

In order to study the regulation of carbohydrate metabolism in leaf tissue the activity of fructose-6-phosphate,2-kinase was determined in individual sections of developing primary leaves of barley. Activity was about 25-fold higher in the leaf tip than in the leaf sheath when measured on a fresh weight basis. There was a gradual increase in enzyme activity from the leaf base to the leaf tip. The higher activity of fructose-6-phosphate,2-kinase in the apical parts of the leaf was associated with higher levels of fructose-2,6-bisphosphate. This was especially pronounced when isolated leaf segments were treated with vanadate and kept in darkness. As compared to the kinase, little difference was observed in the fructose-2,6-bisphospatase activity among leaf sections. The significance of these patterns for regulation of carbohydrate metabolism in different tissues is discussed.     

Air ion effects on RNAse activity in green barley leaves

Previously we reported that green barley leaves floated on the surface of a solution of EDTA and exposed to light undergo severe chlorosis. Such bleaching was substantially reduced by (+) or (–) small air ions. EDTA bleached leaves contained more RNA than did the controls. In the present work we found that (+) and (–) air ions markedly increased the RNAse activity of leaves floated on water in the presence or absence of light. EDTA in solution diminished RNAse activity and air ions do not affect this process. In the light there was a loss of RNAse protein; air ions do not influence the reaction. Even larger decreases in RNAse protein develop if EDTA is added to the water and here again air ions were without effect. RNA fractionation of leaves prior to exposure to water or light yielded a typical curve with four peaks representing: RNA, RNA-DNA, Ribosomal-DNA and Messenger-RNA. After 24 hours in water and light the peaks were much lower and were shifted to the right. Air ions did not effect the alternation in profiles. After 12 hours EDTA solution in the light produced 14 peaks instead of four. This profile disruption was eliminated by treatment with (+) or (–) air ions.

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Zusammenfassung Wir haben früher berichtet, dass grüne Gerstenblätter, die auf der Oberfläche einer EDTA-Lösung treiben, bei Belichtung eine schwere Chlorose aufweisen. Dieser Bleichungseffekt ist in Anwesenheit von (+) und (–) kleinen Luftionen erheblich vermindert. EDTA gebleichte Blätter enthalten mehr RNA als Kontrollen. Wir fanden in dieser Arbeit, dass (+) und (–) Luftionen die RNAse-Aktivität treibender Blätter auf Wasser mit und ohne Belichtung stark erhöhen. EDTA-Lösung verminderte die RNAse-Aktivität und darauf hatten Luftionen keinen Einfluss. Bei Lichtexponierung fiel der Anteil an RNAse-Protein; Luftionen beeinflussten diese Reaktion nicht. Der RNAse-Proteinanteil fiel weiter ab, wenn EDTA zugegeben wurde; auch darauf hatten Luftionen keinen Einfluss. Die RNA-Fraktionierung der Blätter vor dem Exponieren auf Wasser und im Licht ergab eine typische Kurve mit 4 Gipfeln (RNA, RNA — DNA, Ribosomen-DNA und Messenger-RNA). Nach 24 Stunden im Wasser und Licht waren die Gipfel flacher und rechtsverschoben, unabhängig von der Einwirkung von Luftionen. EDTA-Lösung und Licht bewirkten nach 12 Stunden 14 Gipfel anstatt 4. Diese Auflösung des Profils wurde durch Einwirkung von (+) und (–) Luftionen unterbunden.

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Resume On a rapporté dans un précédent mémoire que les feuilles vertes d'orge flottant à la surface d'une solution aqueuse de EDTA présentent des symptômes importants de chlorose dès qu'elles sont exposées à la lumière. Ces symptômes sont nettement moindres lorsqu'on introduit de petits ions (+) ou (–) dans l'air ambiant. Les feuilles chlorosées par EDTA contiennent plus de RNA que les feuilles de contrôle. Dans le présent travail, on démontre que les ions (+) et (–) de l'air augmentent de façon marquée la réduction du RNA dans les feuilles flottant sur l'eau et cela avec ou sans lumière. Une solution de EDTA diminue le phénomène et l'ionisation de l'air est sans effet. Par suite de l'exposition à la lumière, la proportion de la proteine issue de la dite réduction diminue et la présence d'ions dans l'air est sans effet. La proportion de la dite proteine diminue encore si l'on ajoute du EDTA et l'ionisation n'a également pas de répercussions sur ce phénomène. Lors de la distillation fractionnée du RNA tiré des feuilles avant leur traitement par l'eau et la lumière, on obtient une courbe typique avec 4 maximums correspondant à RNA, RNA-DNA, DNA ribosomal et RNA Messenger. Après 24 heures de traitement à l'eau et à la lumière, les pointes sont moins prononcées et déplacées vers la droite et cela quelle que soit l'ionisation de l'air. Un traitement de 12 heures à la solution de EDTA et à la lumière a eu pour effet de produire 14 maximums le long de la courbe au lieu de 4. Cette modification de la courbe a été supprimée par une ionisation positive ou négative de l'air ambiant.

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This work was supported by: (1) a grant (5 RO 1 AP00002-12) from the Air Pollution Control Office, Environmental Protection Agency, Department of Health, Education and Welfare and (2) the Bureau of Medicine and Surgery of the United States Navy.     

Dark chilling increases glucose-6-phosphate dehydrogenase activity in soybean leaves

Available evidence suggests that the stress‐induced increase in the activity of glucose‐6‐phosphate dehydrogenase (G6PDH, EC 1.1.1.49), the key regulatory enzyme of the oxidative pentose phosphate pathway, might often be related to the presence of plant water deficit. The response of G6PDH to dark chilling in chilling sensitive plant species is still unknown. In this communication we report on this response and its dependence on the presence of chill‐induced drought stress. A chilling sensitive soybean (Glycine max L. Merr.) genotype was exposed to dark chilling of the entire plant (whole‐chilled) or only the shoots and leaves (shoot‐chilled). The development of chill‐induced drought stress upon illumination was quantified by measurement of proline and relative water content (RWC). Chill‐induced drought stress (decrease in RWC and increase in proline content) developed with time in whole‐chilled plants, but not in shoot‐chilled plants. The response of the above‐mentioned treatments on G6PDH activity in fully expanded leaves was assessed. In parallel, the effects on CO₂ assimilation, PSII activity and chloroplast fructose‐1,6‐bisphosphatase (FBPase EC 3.1.3.11) and ribulose‐1,5‐bisphosphate carboxylase/oxygenase (Rubisco EC 4.1.1.39) activity were quantified. A decrease in CO₂ assimilation rate, FBPase activity and ribulose‐1,5‐bisphosphate (RuBP) content was observed in whole‐chilled but not in shoot‐chilled plants. However, in shoot‐chilled plants regulation of diurnal PSII activity was altered. The increase in the activation state of NADP‐dependent malate dehydrogenase (NADP‐MDH EC 1.1.1.82) in shoot‐chilled plants suggests an increase in stromal redox state. Although the two different dark chilling treatments resulted in distinct physiological and biochemical effects, both induced an increase in foliar G6PDH activity, suggesting an important role of this enzyme during and following dark chilling stress, irrespective of the presence of chill‐induced drought stress.     

Diurnal variations of nitrate reductase activity and stability in barley leaves

Diurnal variations of nitrate reductase (NR) activity and stability have been studied in leaves of barley seedlings ( Hordeum vulgare L. cv. Herta) grown in an 8 h light/16 h darkness regime. Stability (decay) of NR was tested both in the extracts and in the plants. In the morning, when the plants were transferred to light, NR activity increased rapidly during the first hour and then remained constant. After the photoperiod, activity decreased rapidly during the first hour of darkness and then remained fairly constant during the rest of the dark period. The high NR activity during the photoperiod was associated with low NR stability both in the extracts and in the plants. On the other hand the low NR activity during the dark period was associated with high stability in the extracts and in the plants.     

β-d-glucosidase activity in developing leaves of Nicotiana tabacum

Tobacco (Nicotiana tabacum L. cv. Burley 21) leaves were assayed for β-d-glucosidase activity, using esculin as substrate. The enzymatically produced esculetin was silylated and quantitatively measured by GLC, using a tritium foil electron-capture detector. In field-grown plants, the activity in mid-stalk leaves increased with plant maturation; conversely, the activity in the top leaves decreased.     

Light/Dark Modulation: Regulation of Chloroplast Metabolism in a New Light

Light-dark modulation of chloroplast enzymes is achieved by covalent redox-modification of protein thiols/disulfides mediated by ferredoxin/thioredoxin reductase and thioredoxins. Light-dependent electron flow leads to reduction of particular chloroplast proteins, while photosynthetically evolved oxygen effects their continuous reoxidation. The oxidized and the reduced forms, respectively, differ greatly in their catalytic properties. The rate of reduction of each target enzyme is specifically fine-controlled by metabolites. By this combined mode of producing a defined ratio of active to inactive enzyme during steady-state each of the enzymes is adjusted to the immediate requirements of the chloroplast. Upon changes of the metabolic situation the system can respond in a flexible manner as is known from comparable regulatory mechanisms such as protein phosphorylation/dephosphorylation in animals and bacteria. From sequence comparisons between various light-dark modulated chloroplast enzymes and their non-regulated counterparts from other organelles or non-photosynthetic organisms, the presence of extra-peptides in the otherwise highly homologous sequences has been estabüshed for the chloroplast enzymes. However, no general pattern in the primary structure of those extra-sequences can be recognized. By the acquisition of “regulatory peptides” during evolution a new type of metabolic control was created in a compartment uniquely occurring in organisms performing oxygenic photosynthesis.     

Light activation of NADP malic enzyme in leaves of maize: marginal increase in activity,but marked change in regulatory properties of enzyme

This article reports the characteristics of light activation of NADP-malic enzyme (NADP-ME, EC 1.1.1.40) in leaf discs of maize (Zea mays cv. VMH 404) for the first time. The leaf discs were illuminated in the presence of 2 mmol/L bicarbonate, as light activation increases in the presence of bicarbonate. Upon illumination, the Vmax of NADP-ME increased by about 30%. Although small, the increase was consistent and significant. The changes in regulatory properties of NADP-ME were quite pronounced. The extent of light activation was similar when substrate (malate) concentration was either 4 mmol/L (saturating) or 0.01 mmol/L (limiting). There was only a marginal change in the Km for malate, but there was marked change in the response of NADP-ME to activators or inhibitors. The Ki for pyruvate and oxalate increased by 100 and 67% respectively, while the Ka for the citrate and succinate increased by 36 and 32% respectively. These results suggest that the NADP-ME becomes less sensitive to feedback inhibition on illumination. The light-induced change seems to be due, at least partially, to the reduction of dithiols, as incubation of leaf extracts with DTE dampened light activation of NADP-ME. We conclude that the properties of NADP-ME do change on illumination. Although there was only a marginal increase in the activity of the enzyme on illumination of leaf discs, the changes in regulatory properties of NADP-ME were marked.     

Light/Dark profiles of sucrose phosphate synthase, sucrose synthase, and Acid invertase in leaves of sugar beets

The activity of sucrose phosphate synthase, sucrose synthase, and acid invertase was monitored in 1- to 2-month-old sugar beet (Beta vulgaris L.) leaves. Sugar beet leaves achieve full laminar length in 13 days. Therefore, leaves were harvested at 2-day intervals for 15 days. Sucrose phosphate synthase activity was not detectable for 6 days in the dark-grown leaves. Once activity was measurable, sucrose phosphate synthase activity never exceeded half that observed in the light-grown leaves. After 8 days in the dark, leaves which were illuminated for 30 minutes showed no significant change in sucrose phosphate synthase activity. Leaves illuminated for 24 hours after 8 days in darkness, however, recovered sucrose phosphate synthase activity to 80% of that of normally grown leaves. Sucrose synthase and acid invertase activity in the light-grown leaves both increased for the first 7 days and then decreased as the leaves matured. In contrast, the activity of sucrose synthase oscillated throughout the growth period in the dark-grown leaves. Acid invertase activity in the dark-grown leaves seemed to be the same as the activity found in the light-grown leaves.     

Demonstration of in vitro starch branching enzyme activity for a 51/50-kDa polypeptide isolated from developing barley (Hordeum vulgare) caryopses

Starch branching enzyme (SBE, EC 2.4.1.18) activity was followed in developing barley ( Hordeum vulgare L. cv. Golf) caryopses during a period of one month after anthesis. Caryopses with the highest specific activity, and corresponding to a fresh weight of around 60 mg per caryopsis, were homogenized and the soluble extract used for branching enzyme purification by FPLC chromatography. Four branching enzyme activity fractions were resolved. From one of these fractions, which exhibited high activity in both the phosphorylation stimulation and amylose branching assays, a branching enzyme preparation containing two related polypeptides of 51 and 50 kDa was obtained. Native polyacrylamide gel electrophoresis and gel filtration showed that the 51/50-kDa polypeptide is monomeric. A combination of phosphorylation stimulation and amylose branching gel assays, SDS-PAGE, and TLC was used to demonstrate the branching activity of the 51/50-kDa polypeptide. The activity was further confirmed by spectroscopic analyses of iodine-glucan complexes. SBEs from four different plant species were compared using the phosphorylation stimulation gel assay.     

Photeolytic activation of a lipolytic enzyme activity in potato leaves

Potato (Solanum tuberosum L.) leaves were shown to contain a lipolytic enzyme activity which is stimulated by treatment with purified trypsin, pronase, and to a lesser degree by chymotrypsin. This protease-stimulated activity was stable over a wide range of pH values. Lipolytic enzyme activity also appeared to be regulated by pH, with a pronounced stimulation at pH 6.0 ± 0.5 and a subsequent inactivation at pH 8.0–9.0. This pH stimulation was slightly by ethylene diamine tetracetic acid (EDTA), and was inhibited by Ca²⁺. Although leupeptin slightly inhibited the pH stimulation, two other protease inhibitors, phenylmethylsulfonyl fluoride (PMSF) and soybean trypsin inhibitor showed no effect. While some of the lipolytic enzyme activitiesn potato leaves (those detected by 1-acyl-2-[6-[(7-nitro-2,1,3 benzoxadiazol-4-yl) amino]-caproyl] phosphatidylcholine (C₆-NBD-PC) hydrolysis) are stimulated by protease or pH treatment, others (those detected by 4-methylumbelliferyl laurate (4MUL) hydrolysis) are inactivated by them. The possible physiological significance of this apparent proteolytic activation is discussed.     

Xanthophyll cycle activity in detached barley leaves senescing under dark and light

Senescence-induced changes in the xanthophyll cycle activity and chlorophyll (Chl) fluorescence parameters were compared in detached barley (Hordeum vulgare L.) leaf segments kept for 6 d in darkness or under continuous white light (90 mol m^–2 s^–1). Before detachment of the leaf segments, the plants were grown at periodic regime [12 h light (90 mol m^–2 s^–1)/12 h dark]. The de-epoxidation state of the xanthophyll cycle pigments (DEPS) in the leaf samples was determined immediately (the actual DEPS), after 1 h of dark-adaptation (the residual DEPS), and during 14 min of a high-irradiance (HI) exposure (500 mol m^–2 s^–1) (HI-induced DEPS). In the light-senescing segments, senescence was delayed pronouncedly compared to dark-senescing ones as the Chl content, the photosystem 2 photochemistry, and electron transport processes were highly maintained. Further, the actual DEPS increased, probably due to the increased mean photon dose. The HI-induced increase in the DEPS was stimulated in the light-senescing segments, whereas it was slowed down in the dark-senescing ones. However, after the 14 min HI-exposure of the dark-senescing segments the HI-induced DEPS was not markedly lower than in the mature leaves, which indicated the maintenance of the xanthophyll cycle operation.