Influence of photoinhibition on electron transport and photophosphorylation of isolated chloroplasts

The effects of a photoinhibition treatment (PIT) on electron transport and photophosphorylation reactions were measured in chloroplasts isolated from triazine-resistant and susceptible Chenopodium album plants grown under high and low irradiance. Electron transport dependent on photosystem I (PSI) alone was much less affected by PIT than that dependent on both photosystem II (PSII) and PSI. There was a smaller difference in susceptibility to PIT between the photophosphorylation activitity dependent on PSI alone and that dependent on both PSII and PSI. Because in all cases photophosphorylation activity decreased faster upon PIT than the rate of electron transport, we conclude that photoinhibition causes a gradual uncoupling of electron transport with phosphorylation. Since the extent of the light-induced proton gradient across the thylakoid membrane decreased upon PIT, it is suggested that photoinhibiton causes a proton leakiness of the membrane. We have found no significant differences to PIT of the various reactions measured in chloroplasts isolated from triazine-resistant and susceptible plants. We have also not observed any significant differences to PIT of the photophosphorylation reactions in chloroplasts of plants grown under low irradiance, compared with those grown under high irradiance. However, the electron transport reactions in chloroplasts from plants grown under low irradiance appeared to be somewhat less sensitive to PIT than those grown under high irradiance.     

Miltiparticle computer simulation of photosynthetic electron transport in the thylakoid membrane

Further developing the method for direct multiparticle modeling of electron transport in the thylakoid membrane, here we examine the influence of the shape of the reaction volume on the kinetics of the interaction of the mobile carrier with the membrane complex. Applied to cyclic electron transport around photosystem I, with account of the distribution of complexes in the membrane and restricted diffusion of the reactants, the model demonstrates that the biphasic character of the dark reduction of P700⁺ is quite naturally explained by the spatial heterogeneity of the system.     

Regulation of photosynthetic electron transport and photophosphorylation in intact chloroplasts and leaves of Spinacia oleracea L.

Oxygen ist reduced by the electron transport chain of chloroplasts during CO₂ reduction. The rate of electron flow to oxygen is low. Since antimycin A inhibited CO₂-dependent oxygen evolution, it is concluded that cyclic photophosphorylation contributes ATP to photosynthesis in chloroplasts which cannot satisfy the ATP requirement of CO₂ reduction by electron flow to NADP and to oxygen. Inhibition of photosynthesis by antimycin A was more significant at high than at low light intensities suggesting that cyclic photophosphorylation contributes to photosynthesis particularly at high intensities. Cyclic electron flow in intact chloroplasts is under the control of electron acceptors. At low light intensities or under far-red illumination it is decreased by substrates which accept electrons from photosystem I such as oxaloacetate, nitrite or oxygen. Obviously, the cyclic electron transport pathway is sensitive to electron drainage. In the absence of electron acceptors, cyclic electron flow is supported by far-red illumination and inhibited by red light. The inhibition by light exciting photosystem II demonstrated that the cyclic electron transport pathway is accessible to electrons from photosystem II. Inhibition can be relieved by oxygen which appears to prevent over-reduction of electron carriers of the cyclic pathway and thus has an important regulatory function. The data show that cyclic electron transport is under delicate redox control. Inhibition is caused both by excessive oxidation and by over-reduction of electron carriers of the pathway.     

Modification of excitation energy distribution to photosystem I by protein phosphorylation and cation depletion during thylakoid biogenesis in wheat

The effects of protein phosphorylation and cation depletion on the electron transport rate and fluorescence emission characteristics of photosystem I at two stages of chloroplast development in light-grown wheat leaves are examined. The light-harvesting chlorophyll a/b protein complex associated with photosystem I (LHC I) was absent from the thylakoids at the early stage of development, but that associated with photosystem II (LHC II) was present. Protein phosphorylation produced an increase in the light-limited rate of photosystem I electron transport at the early stage of development when chlorophyll b was preferentially excited, indicating that LHC I is not required for transfer of excitation energy from phosphorylated LHC II to the core complex of photosystem I. However, no enhancement of photosystem I fluorescence at 77 K was observed at this stage of development, demonstrating that a strict relationship between excitation energy density in photosystem I pigment matrices and the long-wavelength fluorescence emission from photosystem I at 77 K does not exist. Depletion of Mg²⁺ from the thylakoids produced a stimulation of photosystem I electron transport at both stages of development, but a large enhancement of the photosystem I fluorescence emission was observed only in the thylakoids containing LHC I. It is suggested that the enhancement of PS I electron transport by Mg²⁺-depletion and phosphorylation of LHC II is associated with an enhancement of fluorescence at 77 K from LHC I and not from the core complex of PS I.     

Stress-induced degradation of the photosynthetic apparatus is accompanied by changes in thylakoid protein turnover and phosphorylation

Development of chlorosis and loss of PSII were compared in young spinach plants suffering under a combined magnesium and sulphur deficiency. Loss of chlorophyll could be detected already after the first week of deficiency and preceded any permanent functional inhibition of PSII as detected by changes in the chlorophyll fluorescence parameter F_v/F_m. A substantial decrease in F_v/F_m was observed only after the second week of deficiency. After 4 weeks, the plants had lost about 70% of their original chlorophyll content, but fluorescence data indicated that 80% of the existing PSII centers were still capable of initiating photosynthetic electron transport. The degradation of the photosynthetic apparatus without loss of PSII activity was due to changes in protein turnover, especially of the PSII D1 reaction center protein. Already by day 7 of deficiency, a 1.4-fold increase in D1 protein synthesis was observed measured as incorporation of ¹⁴C-leucine. Immunological determination by western-blotting did not reveal a change in D1 protein content. Thus, D1 protein was also degraded more rapidly. The increased turnover was high enough to prevent any loss or inhibition of PSII. After 3 weeks, D1 protein synthesis on a chlorophyll basis was further increased by a factor of 2. However, this was not enough to prevent a net loss of D1 protein of about 70%. Immunological determination revealed that together with the D1 protein also other polypeptides of PSII became degraded. This process prevented a large accumulation of photo-inactivated PSII centers. However, it initiated the breakdown of the other thylakoid proteins, especially of LHCII, resulting in the observed chlorosis. Together with the change in protein turnover and stability, a characteristic change in thylakoid protein phosphorylation was observed. In the deficient plants steady state phosphorylation of both LHCII and PSII proteins was increased in the dark. In the light phosphorylation of PSII proteins was stimulated and after 3 weeks of deficiency was even higher in the deficient leaves than in the control plants. In contrast, the phosphorylation level of LHCII decreased in the light and could hardly be detected after 3 weeks of deficiency. Phosphorylation of the reaction center polypeptides presumably increased their stability against proteolytic attack, whereas phosphorylated LHCII seems to be the substrate for proteolysis.     

Radiation inactivation analysis of thylakoid protein kinase systems in light and in darkness

Chloroplast thylakoid contains several membrane-bound protein kinases that phosphorylate thylakoid polypeptides for the regulation of photosynthesis. Thylakoid protein phosphorylation is activated when the plastoquinone pool is reduced either by light-dependent electron flow through photosystem 2 (PS2) or by adding exogenous reductants such as durohydroquinone in the dark. The major phosphorylated proteins on thylakoid are components of light-harvesting complex 2 (LHC2) and a PS2 associated 9 kDa phosphoprotein. Radiation inactivation technique was employed to determine the functional masses of various kinases for protein phosphorylation in thylakoids. Under the photosynthetically active radiation (PAR), the apparent functional masses of thylakoid protein kinase systems (TPKXs) for catalyzing phosphorylation of LHC2 27 and 25 kDa polypeptides were 540±50 and 454±35 kDa as well as it was 448±23 kDa for PS2 9 kDa protein phosphorylation. Furthermore, the functional sizes of dark-regulated TPKXs for 25 and 9 kDa proteins were 318±25 and 160±8 kDa. The 9 kDa protein phosphorylation was independent of LHC2 polypeptides phosphorylation with regard to its TPKX functional mass. Target size analysis of protein phosphorylation mentioned above indicates that thylakoid contains a group of distinct protein kinase systems. A working model is accordingly proposed to interpret the interaction between these protein kinase systems.     

Effect of copper deficiency on photosynthetic electron transport in wheat plants

Copper deficiency in wheat ( Triticum aestivum L. cv. Nazareno Stramppeli) markedly affects photosynthetic activity. Flag leaves of copper-deficient plants showed a 50% reduction of the photosynthetic rate expressed as mg CO₂ dm⁻²h⁻¹. The activities of PSI and PSII, determined for isolated chloroplasts, as well as fluorescence measurements on intact leaves of copper-deficient plants, indicated a low activity of photosynthetic electron transport. Ribulose bisphosphate carboxylase/oxygenase (Rubisco) activity was not affected by copper deficiency but copper deficiency affected the chloroplast ultrastructure, especially at the level of grana, where a disorganization of thylakoids is evident.     

Role of thylakoid protein kinases in photosynthetic acclimation

Photosynthetic organisms are able to adjust to changes in light quality through state transition, a process which leads to a balancing of the light excitation energy between the antennae systems of photosystem II and photosystem I. A genetic approach has been used in Chlamydomonas with the aim of elucidating the signaling chain involved in state transitions. This has led to the identification of a small family of Ser-Thr protein kinases associated with the thylakoid membrane and conserved in algae and land plants. These kinases appear to be involved both in short and long term adaptations to changes in the light environment.     

Control of electron transfer by protein dynamics in photosynthetic reaction centers

Abstract

Trehalose and glycerol are low molecular mass sugars/polyols that have found widespread use in the protection of native protein states, in both short- and long-term storage of biological materials, and as a means of understanding protein dynamics. These myriad uses are often attributed to their ability to form an amorphous glassy matrix. In glycerol, the glass is formed only at cryogenic temperatures, while in trehalose, the glass is formed at room temperature, but only upon dehydration of the sample. While much work has been carried out to elucidate a mechanistic view of how each of these matrices interact with proteins to provide stability, rarely have the effects of these two independent systems been directly compared to each other. This review aims to compile decades of research on how different glassy matrices affect two types of photosynthetic proteins: (i) the Type II bacterial reaction center from Rhodobacter sphaeroides and (ii) the Type I Photosystem I reaction center from cyanobacteria. By comparing aggregate data on electron transfer, protein structure, and protein dynamics, it appears that the effects of these two distinct matrices are remarkably similar. Both seem to cause a “tightening” of the solvation shell when in a glassy state, resulting in severely restricted conformational mobility of the protein and associated water molecules. Thus, trehalose appears to be able to mimic, at room temperature, nearly all of the effects on protein dynamics observed in low temperature glycerol glasses.     

Studies on thylakoid phosphorylation and noncyclic electron transport

The effect of thylakoid phosphorylation on noncyclic electron transport in spinach chloroplasts was investigated by measuring both the reduction of nicotinamide adenine dinucleotide phosphate (NADP) and the steady-state redox level of the primary electron acceptor quinone of photosystem II (Q) during electron flow to NADP. These data are compared with the theoretical predictions for an electron transport model which relates both the redox levels of Q and the photosystem II optical cross section to the overall velocity of noncyclic electron flow. It is demonstrated that transfer of 15-20% of the photosystem II antenna to photosystem I may stimulate electron flow to NADP only if Q is less than 60-70% oxidized (this condition exists with our thylakoids, even at extremely low absorption fluxes, when the illumination is not specifically enriched in photosystem I absorbed wavelengths); in phosphorylated thylakoids the steady-state redox level Q is substantially shifted to a more oxidized one (measurements of this parameter using light of different wavelengths quantitatively support the idea that thylakoid phosphorylation leads to increased photosystem I and decreased photosystem II cross sections); thylakoid phosphorylation leads to stimulated noncyclic electron flow to NADP only when the increased photosystem I antenna is able to bring about large increases in the steady-state level of oxidized Q.     

Effects of calmodulin and calmodulin binding protein BP-10 on phosphorylation of thylakoid membrane protein

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The coupling factor of photophosphorylation and the electric properties of the thylakoid membrane

The rate of ATP synthesis of illuminated chloroplasts is correlated with the electric conductance of their inner membranes. In agreement with previous studies it is shown that ATP synthesis is paralleled by an increased conductance of the thylakoid membrane. This conductance together with the ability to form ATP is abolished if chloroplasts are treated with an antibody against the coupling factor CF₁. It is not influenced by the fragmented monovalent antibody. This parallels the lack of influence of the fragmented antibody on ATP synthesis in contrast to its influence on hydrolysis and exchange reactions. We conclude that there are different sites for the interaction of the coupling factor with adenine nucleotides.Extraction of the coupling factor is shown to increase the membrane conductance by more than two orders of magnitude. Reincorporation of the crude coupling factor partially restores the net conductance of the membrane (increase in resistance by a factor of 2.5), while a higher degree of restoration was observed for ATP synthesis and the proton conductivity of the membrane. We conclude that the extraction procedure opens different conductive channels in the membrane; a proton specific one, possibly associated with the binding protein for the coupling factor, plus other channels for “non-protons” which in contrast to the proton channel cannot be plugged by reincorporation of the coupling factor.     

Redox-controlled thylakoid protein phosphorylation. News and views

Thylakoid protein phosphorylation regulates state transition and PSII protein turnover under light-dependent redox control via a signal transduction system. The redox-dependent activation/deactivation of the membrane-bound protein kinase(s), mostly localized in the grana partitions, differs for the various phosphoproteins. Reduction of the plastoquinone pool may be sufficient to activate phosphorylation of few of these proteins. Phosphorylation of LHCII, requires the presence of the cytochrome bf complex in an 'activating mode' characterized by the reduction of its high potential path components and ability to interact with a reduced plastoquinol without oxidizing it. Activation and maintenance of this kinase activity is considered to involve alternate interactions with a cytochrome bf in its activating mode and with the substrate PSII(LHCII). The segregation of the thylakoid components into grana and stroma partitions appears to be mandatory for the kinase activation process. The protein substrate specificity and kinetics differs for various kinases. The thylakoid redox-controlled kinase(s) have not yet been isolated. Preparations highly enriched in kinase activity capable to phosphorylate LHCII and PSII core proteins, contain two kinase active bands, resolved by denaturing electrophoresis and renaturation, and having apparent molecular masses of about 53 and 66 kDa. The roughly estimated abundance of these putative kinase(s) in the grana partitions may be compatible with a ratio of kinase(s): PSII(LHCII) dimers:cytochrome bf dimers in the range of 1:60:30 and a ratio of kinase:phosphorylation sites of about 1:2000. Only about 10–20% of these sites are phosphorylated during state transition. The low turnover rate of the LHCII kinase(s) (< 5) may be due to hindrance of the required random lateral migration within the grana domain rich in tightly packed PSII(LHCII) and cytochrome bf complexes.     

Correlation between thylakoid protein phosphorylation and molecular organization of the photosynthetic apparatus in a dynamic system

In-vitro thylakoid protein phosphorylation has been studied in synchronized cells of Scenedesmus obliquus at the 8- and 16-h of the life cycle, stages which are characterized by the maximum and minimum photosynthetic activities, respectively. The stage of maximum photosynthetic activity (8-h) is characterized by the highest protein phosphorylation in vitro and in vivo, by the largest proportion of the heavy subfraction of thylakoids, and by maximum oligomerization of the light-harvesting chlorophyll a/b-protein complex, altogether creating the highest energy charge of the thylakoid membranes. Protein phosphorylation in vitro decreases the amount of the heavy subfraction and increases the amount of oligomerization of the antenna of photosystem I (PSI) (increase of chlorophyll b in the light fraction). Concomittantly, PSII units become smaller (longer time for the rise in fluorescence induction) and photosynthetic efficiency increases (decrease of fluorescence yield). In-vivo protein phosphorylation is controlled mainly endogenously during the 8-h of the life cycle but is exogenously modulated by light to optimize the photosynthetic activity by redistribution of pigment-protein complexes. In-vitro protein phosphorylation seems to restore partially the conditions prevalent in vivo and lost during the preparation of membranes. The effect is greater in 16-h cells which have less-stable membranes. The regulatory mechanism between membrane stabilization and oligomerization on the one hand and redistribution of the light-harvesting chlorophyll a/b-protein complex from PSII to PSI on the other hand remains unexplained. We have confirmed that the mechanism of protein phosphorylation is regulated via plastohydroquinone, but experiments with the plastohydroquinone analogue 2,3,5,6-tetramethyl-p-benzoquinone demonstrated that plastohydroquinone is not solely responsible for the differences in protein phosphorylation of 8- and 16-h thylakoids. The inhibitory effect of ADP and the distinct rates of kinase reaction indicate that the adenylate energy charge and changes in the organization of the photosynthetic apparatus also contribute to the observed differences in protein phosphorylation. Phosphorylation in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea indicated that the 32-kDa phosphoprotein and the herbicide-binding Q_B protein may be the same. These experiments also indicated that 3-(3,4-dichlorophenyl)-1,1-dimethylurea-binding reduces kinase activity directly and not only by inhibiting electron transport.Abbreviations DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - LHCP light-harvesting chlorophyll a/b-protein complex - PSI, II photosystem I, II - TMQ 2,3,5,6-tetramethyl-p-benzoquinone Dedicated to Professor Dr. W. Nultsch on the occasion of his 60th brithday     

The effect of the dark interval in intermittent light on thylakoid development: photosynthetic unit formation and light harvesting protein accumulation

Etiolated bean plants were grown in intermittent light with dark intervals of shorter or longer duration, to modulate the rate of chlorophyll accumulation, relative to that of the other thylakoid components formed. We thus produced conditions under which chlorophyll becomes more or less a limiting factor. We then tested whether LHC complexes can be incorporated in the thylakoid. It was found that an equal amount of chlorophyll, formed under the same total irradiation received, may be used for the stabilization of few and large-in-size PS units containing LHC components (short dark-interval intermittent light), or for the stabilization of many and small-in-size PS units with no LHC components (long dark-interval intermittent light). The size of the PS units diminishes as the dark-interval duration is increased, with no further change after 98 minutes. The PSII/cytf ratio remains constant throughout development in intermittent light and equal to that of mature chloroplasts (PSII/cytf = 1) except in the case of very long dark-interval regimes, where about half PSII units per cytf are present. The PSII/PSI ratio was found to be correlated with the PSII unit size (the larger the size, the lower the ratio). The number of PSI units operating on the same electron transfer chain varied depending on the size of the PSII unit (the larger the PSII unit size, the more the PSI units per chain). The results suggest that it is not the chlorophyll content per se which regulates the stabilization of LHC in developing thylakoids and consequently the size of the PS units, but rather the rate by which it is accumulated, relative to that of the other thylakoid components.Abbreviations Chl Chlorophyll - CL Continuous light - CPa the reaction center complex of PSII - CPI the reaction center complex of PSI - CPIa Chlorophyll protein complex containing the CPI and the light harvesting complex of PSI - fr w fresh weight - LDC Light dark cycles - LHC-I Light-harvesting complex of PSI - LHC-II Light harvesting complex of PSII - PS photosystem - PSI photosystem I - PSII photosystem II     

The role of plastidic cytochrome c in algal electron transport and photophosphorylation

By an improved isolation procedure chloroplasts could be obtained from the alga Bumilleriopsis filiformis (Xanthophyceae) which exhibited high electron transport rates tightly coupled to ATP formation. Uncouplers both stimulate electron transport and inhibit photophosphorylation. These chloroplasts retain almost all soluble cytochrome c-553 besides a membrane-bound cytochrome c-554.5 (=f-554.5). Sonification or iron deficiency removed the soluble cytochrome only with a concurrent decrease of electron transport from water to methyl viologen or to NADP and decreased non-cyclic and cyclic photophosphorylation. However, photosynthetic control and the $\text{P}\text{2e}$ ratios remain unaltered.In Bumilleriopsis, which apparently has no plastocyanin, the soluble cytochrome c-553 seemingly links electron transport between the bound cytochrome c and P-700.     

Electrostatic control of chloroplast coupling factor binding to thylakoid membranes as indicated by cation effects on electron transport and reconstitution of photophosphorylation

1. Increase in electron transport rate and the decay rate of the 518 nm absorption change, induced by EDTA treatment, is prevented by cations. The order of effectiveness is C³⁺ > C²⁺ > C⁺.2. In this respect methyl viologen is an effective divalent cation in addition to its action as an electron acceptor.3. Complete cation irreversible EDTA-induced uncoupling occurs in the dark in 2 min. Light greatly stimulates the rate of uncoupling by EDTA. It is concluded that the uncoupling is due to release of coupling factor I from the thylakoid membrane.4. Binding of purified coupling factor I to coupling factor I-depleted thylakoids can be achieved with any cation. The order of effectiveness is C³⁺ > C²⁺ > C⁺, reconstituted thylakoids are active in photophosphorylation regardless of the cation used for coupling factor I binding.5. The marked difference in the concentration requirements for cation effects on 9-aminoacridine fluorescence yield and for prevention of uncoupling by EDTA indicate that coupling factor I and its binding site have a lower surface charge density than the net surface charge density of the thylakoid membrane.6. It is concluded that coupling factor I binding only occurs when negative charges on coupling factor I and its binding site are electrostatically screened by cations.7. Previously reported examples of uncoupling by low ionic conditions are discussed in relation to the basic concepts of diffuse electrical layer theory.     

The use of polyclonal antibodies to identify peptides exposed on the stroma side of the spinach thylakoid

We have raised polyclonal antibodies against an oxygen-evolving photosystem II preparation. Western Blot analysis of the whole serum revaals antibodies specific for at least 15 Coomassie visible bands ranging from 59 to 11 kDa. These antibodies are specific for proteins located on both sides of the membrane. Included are antibodies specific for Tris-removable peptides (33, 25 and 18 kda), which are thought to be exposed on the lumen surface of the PS II complex. Since the whole serum agglutinates thylakoids, antibodies specific for the stroma side of the PS II complex are also present. A sub-population of antibodies can be isolated by allowing the antibodies in whole serum to bind to EDTA-treated thylakoid membranes. The antibodies which specifically bind are cross-reactive with peptides with Mr of 59, 57, 34, 28, 27, 26, and 23 kDa. Our data indicate that these peptides have antigenic determinants exposed on the stroma side of the thylakoid membrane.     

Polyribosome loading of spinach mRNAs for photosystem I subunits is controlled by photosynthetic electron transport

In light-, but not in dark-grown spinach seedlings, the mRNAs for the nuclear-encoded photosystem I subunits D, F and L are associated with polyribosomes and this association is prevented by the application of 3-(3',4'-dichlorophenyl)-1,1'-dimethyl urea (DCMU), an inhibitor of the photosynthetic electron transport. To identify the cis-elements which are responsible for this regulation, we generated a series of chimeric PsaD constructs and tested them in transgenic tobacco. The spinach PsaD 5'-untranslated region is sufficient to confer light- and photosynthesis-dependent polyribosome association onto the uidA reporter gene, while the tobacco PsaD 5'-untranslated region directs constitutive polyribosome association. These results are discussed with regard to signals from photosynthetic electron flow which control processes in the cytoplasm.     

Regulation of the photosynthetic apparatus under fluctuating growth light

Safe and efficient conversion of solar energy to metabolic energy by plants is based on tightly inter-regulated transfer of excitation energy, electrons and protons in the photosynthetic machinery according to the availability of light energy, as well as the needs and restrictions of metabolism itself. Plants have mechanisms to enhance the capture of energy when light is limited for growth and development. Also, when energy is in excess, the photosynthetic machinery slows down the electron transfer reactions in order to prevent the production of reactive oxygen species and the consequent damage of the photosynthetic machinery. In this opinion paper, we present a partially hypothetical scheme describing how the photosynthetic machinery controls the flow of energy and electrons in order to enable the maintenance of photosynthetic activity in nature under continual fluctuations in white light intensity. We discuss the roles of light-harvesting II protein phosphorylation, thermal dissipation of excess energy and the control of electron transfer by cytochrome b₆f, and the role of dynamically regulated turnover of photosystem II in the maintenance of the photosynthetic machinery. We present a new hypothesis suggesting that most of the regulation in the thylakoid membrane occurs in order to prevent oxidative damage of photosystem I.