Photosynthetic recovery in the resurrection plant Selaginella lepidophylla after wetting

Summary Photosynthetic recovery (PR) in a southwest Texas, USA population of Selaginella lepidophylla (Hook and Grev.) (Selaginellaceae), a poikilohydric spikemoss, was examined in the laboratory. Infrared CO₂ gas analysis and ribulose 1,5-bisphosphate (RuBP) carboxylase activity measurements indicated that optimal temperature for PR was near 25°C in terms of: (1) rapidity of net CO₂ uptake after hydration (5.4 h), (2) maximum net photosynthetic rate at 2000 E·m^-2·s^-1 (2.44 mg CO₂·g(DWT)^-1·h^-1), and (3) maximum net CO₂ assimilation per 30 h hydration event (43.8 mg CO₂·g(DWT)^-1·30 h^-1). The PR was much slower at both 15° and 35° C, with lower photosynthetic rates and net carbon gains per hydration event. High respiratory costs were incurred at 45°C and no net photosynthesis was observed. Increases in RuBP carboxylase activity and chlorophyll content during 24 h hydration were also greatest near 25°C. Dry plants had 60% of the enzyme activity of fully recovered (24 h hydration) plants, indicating enzyme conservation. Actinomycin D and cycloheximide did not appear to inhibit PR, but chloramphenicol appeared to totally inhibit RuBP carboxylase activity increases over levels conserved in dry plants. Therefore, rapid PR in S. lepidophylla was achieved by both rapid increase in RuBP carboxylase activity, possibly via de novo synthesis, and conservation of the photosynthetic enzyme. Both mechanisms are essential to maximize assimilation in S. lepidophylla in an environment where hydrated periods are rare and of short duration.     

Enzyme Dynamics of the Resurrection Plant Selaginella lepidophylla (Hook. & Grev.) Spring during Rehydration

The activities of 10 enzymes involved in carbohydrate metabolism were measured in both desiccated and rehydrated fronds of the desiccation-tolerant pteridophyte Selaginella lepidophylla (Hook. & Grev.) Spring. Enzyme conservation was defined as the ratio of desiccated to hydrated frond enzyme activity. The mean level of conservation was 74%, with nine of the 10 enzymes showing significant activity increases (P<0.05) during hydration. The mean of photosynthetic enzyme conservation was significantly lower (P=0.05) than the mean for glycolytic and respiratory enzymes combined. Chloramphenicol inhibited the normal activity increase in ribulose bisphosphate carboxylase and (NADPH)triose-P dehydrogenase but not pyruvate kinase upon rehydration. Cycloheximide did not affect the normal activity increase for these three enzymes. It is concluded that substantial enzyme conservation is beneficial for rapid resumption of metabolic activity in resurrection plants.     

Reduced photoinhibition with stem curling in the resurrection plant Selaginella lepidophylla

Summary Selaginella lepidophylla, the resurrection plant, curls dramatically during desiccation and the hypothesis that curling may help limit bright light-induced damage during desiccation and rehydration was tested under laboratory conditions. Restraint of curling during desiccation at 25° C and a constant irradiance of 2000 mol m^–2 s^]t-1 significantly decreased PSII and whole-chain electron transport and the F_v/F_m fluorescence yield ratio following rehydration relative to unrestrained plants. Normal curling during desiccation at 37.5°C and 200 mol m^–2 s^–1 irradiance did not fully protect against photoinhibition or chlorophyll photooxidation indicating that some light-induced damage occurred early in the desiccation process before substantial curling. Photosystem I electron transport was less inhibited by high-temperature, high-irradiance desiccation than either PSII or whole-chain electron transport and PSI was not significantly affected by restraint of curling during desiccation at 25°C and high irradiance. Previous curling also helped prevent photoinhibition of PSII electron transport and loss of whole-plant photosynthetic capacity as the plants uncurled during rehydration at high light. These results demonstrate that high-temperature desiccation exacerbated photoinhibition, PSI was less photoinhibited than PSII or whole-chain electron transport, and stem curling ameliorated bright light-induced damage helping to make rapid recovery of photosynthetic competence possible when the plants are next wetted.     

Photoprotection Conferred by Changes in Photosynthetic Protein Levels and Organization during Dehydration of a Homoiochlorophyllous Resurrection Plant

During desiccation, homoiochlorophyllous resurrection plants retain most of their photosynthetic apparatus, allowing them to resume photosynthetic activity quickly upon water availability. These plants rely on various mechanisms to prevent the formation of reactive oxygen species and/or protect their tissues from the damage they inflict. In this work, we addressed the issue of how homoiochlorophyllous resurrection plants deal with the problem of excessive excitation/electron pressures during dehydration using Craterostigma pumilum as a model plant. To investigate the alterations in the supramolecular organization of photosynthetic protein complexes, we examined cryoimmobilized, freeze-fractured leaf tissues using (cryo)scanning electron microscopy. These examinations revealed rearrangements of photosystem II (PSII) complexes, including a lowered density during moderate dehydration, consistent with a lower level of PSII proteins, as shown by biochemical analyses. The latter also showed a considerable decrease in the level of cytochrome f early during dehydration, suggesting that initial regulation of the inhibition of electron transport is achieved via the cytochrome b₆f complex. Upon further dehydration, PSII complexes are observed to arrange into rows and semicrystalline arrays, which correlates with the significant accumulation of sucrose and the appearance of inverted hexagonal lipid phases within the membranes. As opposed to PSII and cytochrome f, the light-harvesting antenna complexes of PSII remain stable throughout the course of dehydration. Altogether, these results, along with photosynthetic activity measurements, suggest that the protection of retained photosynthetic components is achieved, at least in part, via the structural rearrangements of PSII and (likely) light-harvesting antenna complexes into a photochemically quenched state.Desiccation tolerance, the ability to survive absolute water contents down to approximately 0.1 g water g⁻¹ dry weight, is a trait found in some bacteria, algae, fungi, as well as animals and plants. In the plant kingdom, desiccation tolerance is common in ferns, mosses, and most seeds and pollen of flowering plants (angiosperms). Resurrection plants, a diverse group of approximately 300 angiosperm species, possess this trait also in their vegetative tissues. These plants are able to withstand prolonged periods of dehydration and to recover within hours to a few days once water is available. A major and interesting aspect in the study of desiccation tolerance in resurrection plants is how they protect themselves against oxidative damage during dehydration, which is often accompanied by conditions of high irradiance (for review, see Bartels and Hussain, 2011; Farrant and Moore, 2011; Morse et al., 2011).A decrease in water content quickly results in lowered leaf stomatal conductance and, consequently, decreased uptake of CO₂. This hinders and ultimately blocks the Calvin cycle. The light-driven reactions, however, typically continue well after the onset of water deficiency, with intact chlorophyll-protein complexes absorbing light energy. The imbalance between the light reactions and the downward biochemical pathways results in a lack of electron sinks and in the system becoming overenergized. This, in turn, leads to enhanced generation of reactive oxygen species (ROS), which inflict damage onto photosynthetic components as well as onto other chloroplast and cellular constituents. At times, the damage may be severe and lead to irreversible impairment and finally plant death (Dinakar et al., 2012).Resurrection plants minimize such potential ROS damage by shutting down photosynthesis during early stages of dehydration (Farrant, 2000; Farrant et al., 2007). There are two mechanisms whereby this is achieved. In poikilochlorophyllous resurrection plants, chlorophyll, along with photosynthetic protein complexes, are degraded, and thylakoids, the membranes that host the photosynthetic pigment-protein complexes, are dismantled. This straightforward mechanism prevents the formation of ROS, yet it comes at the cost of resynthesizing photosynthetic components de novo upon rehydration. On the other hand, homoiochlorophyllous species retain most of their photosynthetic complement and so must rely on other means to protect themselves from oxidative damage in the desiccated state. Some of these, such as leaf folding or curling, which minimize the exposure of inner leaves and/or of adaxial (upper) leaf surfaces to the light, and the accumulation of anthocyanins in leaf surfaces, which act as sunscreens, and the presence of reflective hairs and waxy cuticles, reduce the overall absorption of radiation and thus protect against photodamage (Sherwin and Farrant, 1998; Farrant, 2000; Bartels and Hussain, 2011; Morse et al., 2011). ROS that are generated are dealt with by antioxidants, ROS scavengers, and in some cases also by anthocyanins and other polyphenols (Moore et al., 2005; Kytridis and Manetas, 2006; Farrant et al., 2007). Nevertheless, all of these mechanisms are insufficient to completely prevent and/or detoxify all ROS that are formed, necessitating additional means to prevent or deal with possible damage that ROS may inflict during dehydration and while desiccated (Dinakar et al., 2012).The major photoprotective mechanism in plants and algae is nonphotochemical quenching (NPQ), in which excess light energy absorbed at the antennae of PSII is dissipated as heat. NPQ has been shown to be active in desiccation-tolerant bryophytes and pteridiophytes (Eickmeier et al., 1993; Oliver, 1996), in homoiochlorophyllous angiosperms (Alamillo and Bartels, 2001; Georgieva et al., 2009; Dinakar and Bartels, 2012; Huang et al., 2012), and during the initial stages of drying in poikilochlorophyllous angiosperms (Beckett et al., 2012). Photoinhibition, when damage to PSII (mainly to its D1 subunit) exceeds the repair capacity, typically under conditions of light stress, is also observed in homoiochlorophyllous resurrection plants (e.g. Georgieva and Maslenkova, 2006). Other ways to avoid ROS-induced damage include the rerouting of reducing equivalents to alternative electron sinks, such as the water-water cycle and/or photorespiration, as well as structural rearrangements of PSII and light-harvesting antenna (LHCII) complexes into energy-dissipating states (for review, see Dekker and Boekema, 2005; Yamamoto et al., 2014). These latter processes, in particular the ones pertaining to possible changes in PSII-LHCII macrostructure, have not yet been characterized in homoiochlorophyllous resurrection plants.To gain insight into the ways homoiochlorophyllous resurrection plants cope with dehydration while retaining most of their photosynthetic apparatus, we combined microscopic, spectroscopic, and biochemical approaches. Investigation of the supramolecular organization of photosynthetic complexes was carried out using cryoscanning electron microscopy (cryo-SEM) of high-pressure frozen, freeze-fractured leaf samples; to our knowledge, this combination of procedures has not been utilized previously to investigate thylakoid membranes within plant tissues.The studies reveal that during dehydration, the density of PSII in grana membranes gradually decreases. Notably, in the dehydrated state, in which photosynthetic activity is halted, PSII complexes are also observed to be arranged into rows and two-dimensional arrays. These arrangements are proposed to represent quenched PSII complexes that likely minimize the generation of ROS during desiccation. Furthermore, we observe inverted hexagonal (H_II) phases in this dry state, and these two structural rearrangements are correlated with the massive accumulation of Suc. Biochemical studies of thylakoid membrane fractions support the finding that the relative level of PSII proteins decreases during dehydration. These analyses also reveal that the level of the cytochrome f subunit of the cytochrome b₆f complex decreases quite dramatically and early during dehydration. This provides evidence for an additional level of regulation that inhibits/shuts down the photosynthetic light reactions during desiccation.     

Trehalose 6-phosphate synthase from Selaginella lepidophylla: purification and properties

A protein of 440 kDa with trehalose 6-phosphate synthase activity was purified with only one purification step by immobilized metal affinity chromatography, from fully hydrated Selaginella lepidophylla plants. The enzyme was purified 50-fold with a yield of 89% and a specific activity of 7.05 U/mg protein. This complex showed two additional aggregation states of 660 and 230 kDa. The three complexes contained 50, 67, and 115 kDa polypeptides with pI of 4.83, 4.69, and 4.55. The reaction was highly specific for glucose 6-phosphate and UDP-glucose. The optimum pH was 7.0 and the enzyme was stable from pH 5.0 to 10. The enzyme was activated by low concentrations of Ca2+, Mg2+, K+, and Na+ and by fructose 6-phosphate, fructose, and glucose. Proline had an inhibitory effect, while sucrose and trehalose up to 0.4M did not have any effect on the activity. Neither the substrates nor final product had an inhibitory effect.     

Isolation and partial characterization of trehalose 6-phosphate synthase aggregates from Selaginella lepidophylla plants

Trehalose 6-phosphate synthase was purified from Selaginella lepidophylla plants and three aggregates of the enzyme were found by molecular exclusion chromatography, ion exchange chromatography and electrophoresis. Molecular exclusion chromatography showed four activity peaks with molecular weights of 624, 434, 224 and 115 kDa. Ion exchange chromatography allowed three fractions to be separated with TPS activity which eluted at 0.35, 0.7 and 1 M KCl. Native PAGE of each pool had three protein bands with apparent M(r) 660, 440 and 200 kDa. Western blot results showed that anti-TPS antibody interacted with 115 and 67 kDa polypeptides; these polypeptides share peptide sequences as indicated by internal sequence data. The effects of pH and temperature on enzyme stability and activity were studied. For fractions eluted at 0.35 and 1.0 M KCl, the optimum pH is 5.5, while an optimum pH of 7.5 for 0.7 M fraction was found. The three fractions eluted from ion exchange chromatography were stable in a pH 5-11 range. Optimal temperatures were 25, 45 and 55 degrees C for 0.7, 0.35 and 1.0 M fractions, respectively. The 0.7 M KCl fraction showed highest stability in a temperature range of 25-60 degrees C, whereas the 0.35 M KCl fraction had the lowest in the same temperature range.     

Dynamics of Endogenous Phytohormones during Desiccation and Recovery of the Resurrection Plant Species Haberlea rhodopensis

Drought is one of the most significant threats to world agriculture and hampers the supply of food and energy. The mechanisms of drought responses can be studied using resurrection plants that are able to survive extreme dehydration. As plant hormones function in an intensive cross-talk, playing important regulatory roles in the perception and response to unfavorable environments, the dynamics of phytohormones was followed in the resurrection plant Haberlea rhodopensis Friv. during desiccation and subsequent recovery. Analysis of both leaves and roots revealed that jasmonic acid, along with and even earlier than abscisic acid, serves as a signal triggering the response of the resurrection plants to desiccation. The steady high levels of salicylic acid could be considered an integral part of the specific set of parameters that prime H. rhodopensis desiccation tolerance. The dynamic changes of cytokinins and auxins suggest that these hormones actively participate in the dehydration response and development of desiccation tolerance in the resurrection plants. Our data contribute to the elucidation of a global complex picture of the resurrection plant’s ability to withstand desiccation, which might be successfully utilized in crop improvement.     

A Selaginella lepidophylla trehalose-6-phosphate synthase complements growth and stress-tolerance defects in a yeast tps1 mutant

The accumulation of the disaccharide trehalose in anhydrobiotic organisms allows them to survive severe environmental stress. A plant cDNA, SlTPS1, encoding a 109-kD protein, was isolated from the resurrection plant Selaginella lepidophylla, which accumulates high levels of trehalose. Protein-sequence comparison showed that SlTPS1 shares high similarity to trehalose-6-phosphate synthase genes from prokaryotes and eukaryotes. SlTPS1 mRNA was constitutively expressed in S. lepidophylla. DNA gel-blot analysis indicated that SlTPS1 is present as a single-copy gene. Transformation of a Saccharomyces cerevisiae tps1Delta mutant disrupted in the ScTPS1 gene with S. lepidophylla SlTPS1 restored growth on fermentable sugars and the synthesis of trehalose at high levels. Moreover, the SlTPS1 gene introduced into the tps1Delta mutant was able to complement both deficiencies: sensitivity to sublethal heat treatment at 39 degrees C and induced thermotolerance at 50 degrees C. The osmosensitive phenotype of the yeast tps1Delta mutant grown in NaCl and sorbitol was also restored by the SlTPS1 gene. Thus, SlTPS1 protein is a functional plant homolog capable of sustaining trehalose biosynthesis and could play a major role in stress tolerance in S. lepidophylla.     

Conservation of Cell Order in Desiccated Mesophyll of Selaginella lepidophylla ([Hook and Grev.] Spring)

Understanding of the basis of desiccation tolerance in matureplant tissues that survive extreme dehydration requires knowledgeof the degree of cellular order in the dry state. Generally,aqueous fixatives have been used in ultrastructural studiesof such material, and these are known to be inadequate in thepreservation of dry material. Cryopreservation provides a moreassured level of fixation fidelity than aqueous fixatives, particularlywith dry material. Using freeze substitution and electron microscopy,we examined the ultrastructure of dry mesophyll cells ofSelaginellalepidophylla ([Hook and Grev.] Spring). In this material thecells were condensed and had highly folded walls. The plasmalemmawas bounded on both sides by layers of granular material, andthe membrane was in close and continuous apposition to the walls.The conformation and position of organelles and their structureappeared to be influenced by being compacted within the shrunkencells, but the ultrastructural integrity of all organelles andcellular membranes, including mitochondria, chloroplasts andvacuoles, was maintained in the dry state. These cells had numeroussmall vacuoles clustered in aggregates, and the tonoplast membranesappeared to be coated on the internal side by a fine granularlayer. The vacuoles contained osmiophilic material of varyingdegrees of condensation and had embedment holes suggesting thepresence of salt crystals within the vacuoles. The general conclusionsfrom these studies are that a critical level of cell order ismaintained in the dry state in these desiccation-tolerant plants,and a high degree of effective packing and shape fitting ofcellular constituents with the compaction forces of dehydrationunderlies this conservation of cell order. Freeze substitution; Selaginella lepidophylla ([Hook and Grev.] Spring); ultrastructure; membrane structure; desiccation tolerance; resurrection plants     

复苏植物旋蒴苣苔C2结构域小蛋白BhC2DP1参与植物对ABA的反应

为揭示植物抗旱的调控机理, 对复苏植物旋蒴苣苔(Boea hygrometrica)的一个编码C2结构域小蛋白的基因BhC2DP1进行研究。Real-time PCR和Pro_BhC2DP1:GUS报告基因检测显示, 该基因只在干旱早期和外源Ca²⁺处理0.5小时时受诱导表达; 分别施加Ca²⁺螯合剂EGTA和逆境激素ABA均抑制该基因表达, 但二者同时处理则显著诱导其表达, 表明ABA对该基因转录水平的调控是Ca²⁺依赖型的。过表达BhC2DP1的拟南芥(Arabidopsis thaliana)对ABA的敏感性增强, EGTA处理可消除其与野生型的差异, 表明Ca²⁺是BhC2DP1蛋白参与ABA反应所必需的。综上所述, ABA和Ca²⁺信号途径的精细调控可能是决定干旱诱导旋蒴苣苔中BhC2DP1基因表达时间、丰度和功能的重要机制。     

植物蛋白质合成延伸因子

蛋白质的生物合成是一个需要许多大分子如起动因子、延伸因子、终止因子、核糖体、信使RNA、氨酰合成酶和tR NA协同作用的复杂的生理生化过程。植物蛋白质合成延伸因子eEF1和eEF2通过在核糖体上催化氨基酸链的延伸而推动、控制蛋白质的合成。文章介绍植物蛋白质生物合成延伸因子的研究进展     

Protein Synthesis in Plant Microsomal System

An active microsomal system from 48-h germinating seeds of Vigna sinensis (L.) Savi has now been developed. It can incorporate amino acids into protein under both in vitro and in vivo conditions, provided dithiothreitol (a protective reagent for SH groups) and phenylthiourea (an inhibitor of phenol oxidase) are present in the buffer system for extraction; and provided the assay mixture contains added dithiothreitol. The system consists of microsomes or ribosomes, tRNA or pH 5 fraction and 20 natural amino acids, ATP and an ATP-generating system and GTP with requirement for Mg ions. The cell fractions possess aminoacyl-RNA synthetase activity as indicated by the aminoacylhydroxamate formation. Microsomal synthesis is stimulated by exogenous tRNA from Escheriehia coli or rat liver and sensitive to various inhibitors such as cyclo-heximide, chloramphenicol, fusidic acid. The ribosomal transfer reaction has absolute dependence on the microsomal wash, on the crude enzyme from the same participate source, and on a synthetic messenger. It is greatly suppressed by fusidic acid and by cycloheximide.     

Desiccation Tolerance Studied in the Resurrection Plant Craterostigma plantagineum

This review will focus on the acquisition of desiccation tolerancein the resurrection plant Craterostigma plantagineum. Molecularaspects of desiccation tolerance in this plant will be comparedwith the response of non-tolerant plants to dehydration. Uniquefeatures of C. plantagineum are described like the CDT-1 (Craterostigmadesiccation tolerance gene-1) gene and the carbohydrate metabolism.Abundant proteins which are associated with the desiccationtolerance phenomenon are the late embryogenesis abundant (=LEA)proteins. These proteins are very hydrophilic and occur in severalother species which have acquired desiccation tolerance.     

Chlorophyll fluorescence in the resurrection plant Selaginella lepidophylla (Hook. & Grev.) Spring during high-light and desiccation stress,and evidence for zeaxanthin-associated photoprotection

The function of photosystem (PS)II during desiccation and exposure to high photon flux density (PFD) was investigated via analysis of chlorophyll fluorescence in the desert resurrection plant Selaginella lepidophylla (Hook. and Grev.) Spring. Exposure of hydrated, physiologically competent stems to 2000 mol · m^–2 · s^–1 PFD caused significant reductions in both intrinsic fluorescence yield (F_O) and photochemical efficiency of PSII (F_V/F_M) but recovery to pre-exposure values was rapid under low PFD. Desiccation under low PFD also affected fluorescence characteristics. Both F_V/F_M and photochemical fluorescence quenching remained high until about 40% relative water content and both then decreased rapidly as plants approached 0% relative water content. In contrast, the maximum fluorescence yield (F_M) decreased and non-photochemical fluorescence quenching increased early during desiccation. In plants dried at high PFD, the decrease in F_V/F_M was accentuated and F_O was reduced, however, fluorescence characteristics returned to near pre-exposure values after 24-h of rehydration and recovery at low PFD. Pretreatment of stems with dithiothreitol, an inhibitor of zeaxanthin synthesis, accelerated the decline in F_V/F_M and significantly increased F_O relative to controls at 925 mol · m^–2 · s^–1 PFD, and the differences persisted over a 3-h low-PFD recovery period. Pretreatment with dithiothreitol also significantly decreased non-photochemical fluorescence quenching, increased the reduction state of Q_A, the primary electron acceptor of PSII, and prevented the synthesis of zeaxanthin relative to controls when stems were exposed to PFDs in excess of 250 mol · m^–2 · s^–1. These results indicate that a zeaxanthin-associated mechanism of photoprotection exists in this desert pteridophyte that may help to prevent photoinhibitory damage in the fully hydrated state and which may play an additional role in protecting PSII as thylakoid membranes undergo water loss.Abbreviations and Symbols DTT dithiothreitol - EPS epoxidation state - F_O yield of instantaneous fluorescence at open PSII centers - F_M maximum yield of fluorescence at closed PSII centers induced by saturating light - F_M F_M determined during actinic illumination - F_V yield of variable fluorescence (F_M-F_O) - F_V/F_M photochemical efficiency of PSII - q_P photochemical fluorescence quenching - q_NP non-photochemical fluorescence quenching of Schreiber et al. (1986) - NPQ non-photochemical fluorescence quenching from the Stern-Volmer equation - PFD photon flux density - RWC relative water content This paper is based on research done while W.G.E. was on leave of absence at Duke University during the fall of 1990. We would like to thank Dan Yakir, John Skillman, Steve Grace, and Suchandra Balachandran and many others at Duke University for their help and input with this research. Dr. Barbara Demmig-Adams provided zeaxanthin for standard-curve purposes.     

Plant Chromatin Replicated in the Absence of Protein Synthesis

The aim of the present work is to detect possible differencesin the chromatin of plants replicated in the absence of proteinsynthesis. The kinetics of nuclease digestion in Allium cepa L., evaluatedafter making the cells permeable, was faster for the chromatinof meristem cells replicated in the presence of 1.0 µgml^–1 cycloheximide than in control cells. In order to have a synchronous population in the meristems,cells were labelled as binucleate by a short treatment with5.0 mM caffeine. Treated cells failed to increase both theircontent in dense chromatin and intranuclear histones. Thesefacts suggest that chromatin replicated in the presence of cycloheximidedid not incorporate histones and was unable to be integratedinto dense chromatin patches. Key words: Allium cepa L., Chromatin replication, Protein synthesis     

A Protein Phosphorylation Threshold for Functional Stacking of Plant Photosynthetic Membranes

Phosphorylation of photosystem II (PSII) proteins affects macroscopic structure of thylakoid photosynthetic membranes in chloroplasts of the model plant Arabidopsis. In this study, light-scattering spectroscopy revealed that stacking of thylakoids isolated from wild type Arabidopsis and the mutant lacking STN7 protein kinase was highly influenced by cation (Mg⁺⁺) concentrations. The stacking of thylakoids from the stn8 and stn7stn8 mutants, deficient in STN8 kinase and consequently in light-dependent phosphorylation of PSII, was increased even in the absence of Mg⁺⁺. Additional PSII protein phosphorylation in wild type plants exposed to high light enhanced Mg⁺⁺-dependence of thylakoid stacking. Protein phosphorylation in the plant leaves was analyzed during day, night and prolonged darkness using three independent techniques: immunoblotting with anti-phosphothreonine antibodies; Diamond ProQ phosphoprotein staining; and quantitative mass spectrometry of peptides released from the thylakoid membranes by trypsin. All assays revealed dark/night-induced increase in phosphorylation of the 43 kDa chlorophyll-binding protein CP43, which compensated for decrease in phosphorylation of the other PSII proteins in wild type and stn7, but not in the stn8 and stn7stn8 mutants. Quantitative mass spectrometry determined that every PSII in wild type and stn7 contained on average 2.5±0.1 or 1.4±0.1 phosphoryl groups during day or night, correspondingly, while less than every second PSII had a phosphoryl group in stn8 and stn7stn8. It is postulated that functional cation-dependent stacking of plant thylakoid membranes requires at least one phosphoryl group per PSII, and increased phosphorylation of PSII in plants exposed to high light enhances stacking dynamics of the photosynthetic membranes.