Heterogeneity in photosystem I. Evidence from cation-induced decrease in Photosystem I electron transport

The rate of electron transfer through Photosystem I (reduced 2,6-dichlorophenol indophenol (DCIPH₂ → methylviologen) in a low-salt thylakoid suspension is inhibited by Mg²⁺ both under light-limited and the light-saturated conditions, the magnitude of inhibition being the same. The 2,6-dichlorophenol indophenol (DCIP) concentration dependence of the light-saturated rate in the presence and in the absence of Mg²⁺ shows that the overall rate constant of the photoreaction is not altered by Mg²⁺. With N,N,N′,N′-tetramethyl-p-phenylenediamine or 2,3,5,6-tetramethylphenylenediamine as electron donor only the light-limited rate, not the light-saturated rate, is inhibited by Mg²⁺ and the magnitude of inhibition is the same as with DCIP as donor. The results are interpreted in terms of heterogeneous Photosystem I, consisting of two types, PS I-A and PS I-B, where PS I-A is involved in cation-regulation of excitation energy distribution and becomes unavailable for DCIPH₂ → methyl viologen photoelectron transfer in the presence of Mg²⁺.     

High salt stress in coupled and uncoupled thylakoid membranes: A comparative study

The effect of high salt concentration on photosystem II (PS II) electron transport rates and chlorophyll a fluorescence induction kinetics was investigated in coupled and uncoupled spinach thylakoid membranes. With increase in salt concentration, the rates of electron transport mediated by PS II and the F _v/F _m ratio were affected more in uncoupled thylakoids as compared to coupled thylakoid membranes. The uncoupled thylakoid membranes seemed to behave like coupled thylakoid membranes at high NaCl concentration (∼1 M). On increasing the salt concentration, the uncoupler was found to be less effective and Na⁺ probably worked as a coupling enhancer or uncoupling suppressor. We suggest that positive charge of Na⁺ mimics the function of positive charge of H⁺ in the thylakoid lumen in causing coupled state. The function of NaCl (monovalent cation) could be carried out by even lower concentration of Ca²⁺ (divalent cation) or Al³⁺ (trivalent cation). We conclude that this function of NaCl as coupling enhancer is not specific, and in general a positive charge is required for causing coupling in uncoupled thylakoid membranes. Published in Russian in Biokhimiya, 2009, Vol. 74, No. 6, pp. 761–767.     

Calcium and magnesium effect on divalent cation deficientHydrilla verticillata thylakoid electron transport activity

The role of divalent cations like magnesium (Mg²⁺) and calcium (Ca²⁺) was irrvestigated on energy distribution process ofHydrilla verticillata thylakoids. Effect of these cations was tested on relative quantum yield of photosystem (PS) II catalyzed electron transport activity, room and liquid nitrogen temperature fluorescence emission properties and thylakoid light scattering characteristics. The electron transport activity was found to be stimulated in the presence of these cations in a light intensity independent manner. The concentration of cation required for maximum stimulation was nearly 10–12 mM. Comparatively, Ca²⁺ was more effective than Mg²⁺. Cation induced stimulation in electron transport activity was not accompanied by increase in chlorophylla fluorescence intensity either at room (25°C) or liquid nitrogen (77°K) temperatures. Furthermore, 540 nm absorption and 90° light scattering properties of thylakoids remained insensitive towards divalent cations. These facts together suggest that divalent cations inHydrilla thylakoids are not effective in supporting the excitation distribution between the interacting photosystem complexes.     

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.     

Low growth temperature-induced increase in light saturated photosystem I electron transport is cation dependent

Thylakoid membranes isolated from cold tolerant, herbaceous monocots and dicots grown at 5°C exhibit a 1.5-fold to 2.7-fold increase in light saturated rates of photosystem I (PSI) electron transport compared to thylakoids isolated from the same plant species grown at 20°C. This was observed only when either water or reduced dichlorophenolindophenol was used as an electron donor. The apparent quantum yield for PSI electron transport was not affected by growth temperature. The higher light saturated rates of PSI electron transport in 5°C thylakoids had an absolute requirement for the presence of Na⁺ and Mg⁺². The accessibility of reduced dichlorophenolindophenol to the donor site was not affected by growth temperature since 5°C and 20°C thylakoids exhibited no significant difference in the concentration of this electron donor required for half-maximal PSI activity. The cation dependent higher rates of light saturated PSI activity were also observed when rye thylakoids were developed under intermittent light conditions at 5°C. Thus, this cation effect on PSI activity appeared to be independent of light harvesting complex I and II. The extent of the in vitro reversibility of this cation effect appeared to be limited by an inherent decay process for PSI electron transport. The rate of decay for PSI activity was greatest when thylakoids were isolated in the absence of NaCl and MgCl₂. We conclude that exposure of plants to low growth temperatures induces a reorganization of thylakoid membranes which increases the light saturated rates of PSI electron transport with no change in the apparent quantum efficiency for this reaction. Cations are required to stabilize this reorganization.     

Growth and development of winter rye at cold-hardening temperatures results in thylakoid membranes with increased sensitivity to low concentrations of osmoticum

Chloroplasts developed at cold-hardening (5°C) and non-hardening temperatures (20°C) were compared with respect to the stability of photosynthetic electron transport activities, the capacity to produce and maintain a H⁺ gradient and the capacity fat photophosphorylation as a function of resuspension in the presence or absence of osmoticum. The results for electron transport indicate that whole chain, photosystem I and pfaotosystem II activities in non-hardened chloroplast thyalkoids were unaffected by resuspension in the presence of high or low osmoticum. In contrast, the same electron transport activities in cold-hardened chloroplast thylakoids exhibited a 3- to 4-fold decrease in activity when resuspended in the presence of low osmoticum. Impairment of electron transport through photosystem II of cold-hardened thylakoids resuspended in the presence of low osmoticum was supported by room temperature fluorescence induction kinetics. Since the presence of Mn²⁺ partially overcame this inhibition, it is concluded that this osmotically-induced inhibition of PSII activity in cold-hardened chloroplast thylakoids may, in part, be due to damage to the H₂O-splitting side of photosystem II. Both the initial rate and the maximum capacity for cyclic photophosphorylation were significantly inhibited in cold-hardened as compared to non-hardened thylakoids upon resuspension in the presence of low concentrations of osmoticum. This was correlated with an inability of the cold-hardened chloroplast thylakoids to maintain a significant transrnembrane H⁺ gradient. The results indicate that cold-hardened thylakoid membranes required an osmotic concentration (0.8 M) twice as high as non-hardened thylakoids (0.4 M) to produce the same initial rate of H⁺ uptake. In addition, the capacity to produce a proton gradient in cold-hardened thylakoids was less stable than that in non-hardened thylakoids regardless of the osmotic concentration tested. It is concluded that development of rye thylakoid membranes at low temperature results in a differential sensitivity to low osmoticum and thus extreme caution should be exercised when comparing the structure and function of isolated thylakoids developed under contrasting thermal regimes.     

The effects of cations and trypsin on extraction of chlorophyll-protein complexes by octyl glucoside

The extraction of chlorophyll-protein (CP) complexes from thylakoids by the detergent octyl glucoside is strongly affected by pretreatment of the thylakoids with trypsin or cations. In these experiments, washed thylakoids were incubated in the presence of 0.5 μm to 5 mm Mg²⁺, pelleted, and extracted with octyl glucoside (30 mm). Increasing amounts of Mg²⁺ depressed extractability of all CP complexes, but especially the chlorophyll a + b-containing light-harvesting complex (LHC). This cation effect is observed with other cations which promote thylakoid stacking (5 mm Mn²⁺ or Ca²⁺, 50 mm Na⁺). However, the effect is not merely due to stacking, since low concentrations of Mg²⁺ (0.5 μmto 0.5 mm) have a marked effect on extractability but have no effect on light scattering (OD 550 nm), an indicator of stacking. Furthermore, trypsin treatment of thylakoids stacked with 5 mm Mg²⁺ caused a significant reversal of stacking, but had little effect on extractability. Trypsin treatment of unstacked membranes resulted in increased extractability of all CP complexes, but especially of the LHC. Cation-treated membranes are also significantly different from those “stacked” at pH 4.5. While the latter do show decreased extractability, there is no change in the chlorophyll $\text{a}\text{b}$ ratio of the extract, and the membranes cannot be “unstacked” with trypsin. We conclude that octyl glucoside extractability reflects the lateral interaction of CP complexes with each other and with other components in the same plane of the membrane. It is clear that divalent cations have several effects on thylakoid membranes, not all of which are due to their ability to promote stacking.     

The stacking of chloroplast thylakoids: Evidence for segregation of charged groups into nonstacked regions

Small particles derived from the digitonin treatment of chloroplast thylakoid membranes in either the stacked (grana-containing) or unstacked condition, as determined by cation concentration, have been used to study the aggregation of thylakoid membranes. At pH values above 5, the small particles from stacked chloroplasts do not aggregate in the presence of Mg²⁺ or other screening cations at concentrations sufficient to cause the restacking of thylakoids from low-salt chloroplasts. However, the small particles from stacked chloroplasts are aggregated either by lowering the pH to 4.6 or adding the binding cation La³⁺. In contrast, the small particles obtained on digitonin treatment of unstacked chloroplasts were aggregated by cations at neutral pH. Large particles (mainly grana) derived from digitonin treatment of stacked chloroplasts could not be unstacked by transfer to media of low cation concentration. It is concluded that the nonappressed regions of the chloroplast thylakoid membranes under stacking conditions carry higher than average negative surface charge densities under physiological pH conditions. Transfer of chloroplasts to media of low cation concentration causes a time-dependent lateral redistribution of charge between the appressed and nonappressed regions, but this redistribution is prevented by prior digitonin treatment of stacked chloroplasts.     

The role of trace metals in photosynthetic electron transport in O2-evolving organisms

Iron is the quantitatively most important trace metal involved in thylakoid reactions of all oxygenic organisms since linear (= non-cyclic) electron flow from H₂O to NADP⁺ involves PS II (2–3 Fe), cytochrome b₆-f (5 Fe), PS I (12 Fe), and ferredoxin (2 Fe); (replaceable by metal-free flavodoxin in certain cyanobacteria and algae under iron deficiency). Cytochrome c₆ (1 Fe) is the only redox catalyst linking the cytochrome b₆-f complex to PS I in most algae; in many cyanobacteria and Chlorophyta cytochrome c₆ and the copper-containing plastocyanin are alternatives, with the availability of iron and copper regulating their relative expression, while higher plants only have plastocyanin. Iron, copper and zinc occur in enzymes that remove active oxygen species and that are in part bound to the thylakoid membrane. These enzymes are ascorbate peroxidase (Fe) and iron-(cyanobacteria, and most al gae) and copper-zinc- (some algae; higher plants) superoxide dismutase. Iron-containing NAD(P)H-PQ oxidoreductase in thylakoids of cyanobacteria and many eukaryotes may be involved in cyclic electron transport around PS I and in chlororespiration. Manganese is second to iron in its quantitative role in the thylakoids, with four Mn (and 1 Ca) per PS II involved in O₂ evolution. The roles of the transition metals in redox catalysts can in broad terms be related to their redox chemistry and to their availability to organisms at the time when the pathways evolved. The quantitative roles of these trace metals varies genotypically (e.g. the greater need for iron in thylakoid reactions of cyanobacteria and rhodophytes than in other O₂-evolvers as a result of their lower PS II:PS I ratio) and phenotypically (e.g. as a result of variations in PS II:PS I ratio with the spectral quality of incident radiation).     

Quantitative separation of spinach thylakoids into Photosystem II-enriched inside-out vesicles and Photosystem I-enriched right-side-out vesicles

Yeda press disruption of thylakoids in the presence of magnesium followed by aqueous polymer two-phase partitioning fractionated the total thylakoid membrane material into two distinctly different fractions. One fraction comprised approx. 60% of the material on a chlorophyll basis and contained inside-out vesicles while the other fraction (40%) contained right-side-out vesicles. The sidedness of the vesicles was determined from the direction of their light-induced proton translocation. The inside-out vesicles showed a pronounced Photosystem (PS) II enrichment as judged by their high PS II and low PS I activities. Moreover, they showed a high ratio between the PS II reaction centre chlorophyll-protein complex and the PS I reaction centre chlorophyll-protein complex (CP I). The chlorophyll $\text{a}\text{b}$ ratio was as low as 2.3 compared to 3.2 for the starting material. In contrast, the right-side-out vesicles showed a pronounced PS I enrichment. Their chlorophyll $\text{a}\text{b}$ ratio was 4.3–4.9. The tight stacking induced by Mg²⁺ allows a quantitative formation of inside-out vesicles from the appressed thylakoid regions while mainly non-appressed thylakoids turn right-side-out. The possibility of fractionating all of the thylakoid material into two sub-populations with markedly different composition with respect to PS I and PS II argues against a close physical association between the two photosystems and in favour of their spatial separation in the plane of the membrane. This fractionation procedure, which can be completed within 1 h and gives high yields of both PS II inside-out thylakoids and PS I right-side-out thylakoids, should be very useful for facilitating and improving studies on both the transverse and lateral organization of the thylakoid membrane.     

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.     

Electron microscopic structure and oxygen evolution activity of thylakoids from Avicennia marina prepared under different osmotic and ionic conditions

Abstract Stacking of thylakoid membranes in vitro was assessed using electron microscopy. Grana stacks of spinach thylakoids formed when 5 mol m^?3 MgCl₂ was present, but no stacking of thylakoids from the mangrove Avicennia marina occurred in the presence of 10 mol m^?3? MgCl₂. Isolation of mangrove thylakoids with a high osmotic strength medium did not induce grana formation if the medium consisted only of sorbitol or glycinebetaine. Addition of cations to the high osmotic strength medium did induce some loose-grana formation, with divalent cations being more effective than monovalent cations. Glycinebetaine was a better osmoticum than sorbitol for grana formation provided divalent cations had been added. Oxygen evolution activity of the preparations was influenced by the amount of membrane stacking, with the preparations with the greatest amount of stacked membrane having the highest activity. Isolation with sorbitol or glycinebetaine based media did not alter this pattern, nor did assay in sorbitol or glycinebetaine. Mangrove thylakoids have a requirement for both a high osmotic strength and divalent cations for grana formation in vitro which may be related to the low water potential of the plant environment in vivo.     

Effects of magnesium and chloride ions on light-induced electron transport in membrane fragments from a blue-green alga

The effects of magnesium and chloride ions on photosynthetic electron transport were investigated in membrane fragments of a blue-green alga, Nostoc muscorum (Strain 7119), noted for their stability and high rates of electron transport from water or reduced dichlorophenolindophenol to NADP⁺. Magnesium ions were required not only for light-induced electron transport from water to NADP⁺ but also for protection in the dark of the integrity of the water-photooxidizing system (Photosystem II). Membrane fragments suspended in the dark in a medium lacking Mg²⁺ lost the capacity to photoreduce NADP⁺ with water on subsequent illumination. Chloride ions could substitute, but less effectively, for each of these two effects of magnesium ions. By contrast, the photoreduction of NADP⁺ by DCIPH₂ was independent of Mg²⁺ (or Cl^?) for the protection of the electron transport system in the dark or during the light reaction proper. Furthermore, high concentrations of MgCl₂ produced a strong inhibition of NADP⁺ photoreduction with DCIPH₂ without significantly affecting the rate of NADP⁺ photoreduction with water. The implications of these findings for the differential involvement of Photosystem I and Photosystem II in the photoreduction of NADP⁺ with different electron donors are discussed.     

Inhibition of Photosystem II Precedes Thylakoid Membrane Lipid Peroxidation in Bisulfite-Treated Leaves of Phaseolus vulgaris

Exposure of leaves to SO₂ or bisulfite is known to induce peroxidation of thylakoid lipids and to inhibit photosynthetic electron transport. In the present study, we have examined the temporal relationship between bisulfite-induced thylakoid lipid peroxidation and inhibition of electron transport in an attempt to clarify the primary mechanism of SO₂ phytotoxicity. Primary leaves of bean (Phaseolus vulgaris L. cv Kinghorn) were floated on a solution of NaHSO₃, and the effects of this treatment on photosynthetic electron transport were determined in vivo by measurements of chlorophyll a fluorescence induction and in vitro by biochemical measurements of the light reactions using isolated thylakoids. Lipid peroxidation in treated leaves was followed by monitoring ethane emission from leaf segments and by measuring changes in fatty acid composition and lipid fluidity in isolated thylakoids. A 1 hour treatment with bisulfite inhibited photosystem II (PSII) activity by 70% without modifying Photosystem I, and this inhibitory effect was not light-dependent. By contrast, lipid peroxidation was not detectable until after the inhibition of PSII and was strongly light dependent. This temporal separation of events together with the differential effect of light suggests that bisulfite-induced inhibition of PSII is not a secondary effect of lipid peroxidation and that bisulfite acts directly on one or more components of PSII.     

Temperature and Light Dependence of Photosynthetic Activities in Wheat Seedlings Grown in the Presence of DCMU [3-(3,4-Dichlorophenyl)-1,1-Dimethylurea]

Photosynthetic electron transfer was studied in thylakoids isolated from control and DCMU-grown wheat (Triticum aestivum L.) seedlings. When exposed to high temperature (HT) and high iradiance (HI), thylakoids showed large variations in the photosynthetic electron transport activities and thylakoid membrane proteins. A drastic reduction in the rate of whole electron transport chain (H₂O MV) was envisaged in control thylakoids when exposed to HT and HI. Such reduction was mainly due to the loss of photosystem 2, PS2 (H₂O DCBQ) activity. The thylakoids isolated from seedlings grown in the presence of DCMU showed greater resistance to HT and HI treatment. The artificial exogenous electron donors MnCl₂, DPC, and NH₂OH failed to restore the HI induced loss of PS2 activity in both control and DCMU thylakoids. In contrast, addition of DPC and NH₂OH significantly restored the HT induced loss of PS2 activity in control thylakoids and partially in DCMU thylakoids. Similar results were obtained when F_v/F_m was evaluated by chlorophyll fluorescence measurements. The marked loss of PS2 activity in control thylakoids was evidently due to the loss of 33, 23, and 17 kDa extrinsic polypeptides and 28-25 kDa LHCP polypeptides.     

The interaction between bicarbonate and the herbicide ioxynil in the thylakoid membrane and the effects of amino acid modification on bicarbonate action

Bicarbonate depletion of chloroplast thylakoids reduces the affinity of the herbicide, ioxynil, to its binding site in Photosystem (PS) II. This herbicide is found to be a relatively more efficient inhibitor of the Hill reaction when HCO^?₃ is added to CO₂-depleted thylakoids in subsaturating rather than in saturating concentrations. The reason for this dependence of the inhibitor efficiency on the HCO^?₃ concentration is that the inactive HCO^?₃-deficient PS II reaction chains bind less ioxynil than the active PS II electron-transport chains that have bound HCO^?₃, and, thus, after addition of a certain amount of ioxynil the concentration of the free herbicide increases when the HCO^?₃ concentration decreases. Therefore, the inhibition of electron transport by ioxynil increases at decreasing HCO^?₃ levels. Measurements on the effects of modification of lysine and arginine residues on the rate of electron transport are also presented: the rate of modification is faster in the presence than in the absence of HCO^?₃. Therefore, we suggest that surface-exposed lysine or arginine residues are not involved in binding of HCO^?₃ (or CO₂ or CO^2?₃) to its binding protein, but that HCO^?₃ influences the conformation of its binding environment such that the affinity for certain herbicides and the accessibility for amino acid modifiers are changed.     

Evaluation of the Specific Roles of Anions in Electron Transport and Energy Transfer Reactions in Photosynthesis

Ionic environment is important in regulating photosynthetic reactions. The roles of cations, Mn²⁺, Mg²⁺, Ca²⁺, Na⁺, and K⁺ as cofactors in electron transport, energy transfer, phosphorylation, and carbon assimilation are better known than the roles of anions, except for chloride and bicarbonate. Only a limited information exists on the roles and effects of nitri formate, sulphate, and phosphate. In this review, we evaluate and highlight the roles of some specific anions on electron transport as well as on excitation energy transfer processes in photosynthesis. Anions exert significant effects on thyla membrane conformation and membrane fluidity, possibly by redistributing the thylakoid membrane surface charges. The anion/cation induced phase transitions in the hydrophilic domains of the thylakoid membranes are probably responsible for the various structural and co-related functional changes under stress. Anions are also important in regulation of energy distribution between the two photosystems. Anions do not only divert more energy from photosystem (PS) 2 to PS1, but can also reverse the effect of cations on energy distribution in a valence-dependent manner. Anions affect also the structure of the photosynthetic apparatus and excitation energy distribution between the two photosystems.     

Ascorbate in thylakoid lumen as an endogenous electron donor to Photosystem II: Protection of thylakoids from photoinhibition and regeneration of ascorbate in stroma by dehydroascorbate reductase

Photoinhibition of the electron transport activity from tyrosine Z (Y_Z) in PS II to NADP⁺in Tris-treated thylakoids was suppressed by electron donation with either diphenylcarbazide or ascorbate (AsA) during the photoinhibition treatment. This suggests that AsA prevents donor side-induced photoinhibition in vivo as an endogenous donor. AsA in the lumen is photooxidized to monodehydroascorbate (MDA) in Tris-treated thylakoids, as detected by electron spin resonance spectrometry, but not in oxygenic thylakoids. Redox analysis of pyridine nucleotide in the presence of either MDA reductase or dehydroascorbate (DHA) reductase showed that the MDA photoproduced in the lumen is disproportionated to AsA and DHA, and the DHA leaking into the stroma is reduced to AsA by DHA reductase. No leakage of MDA through the thylakoid membrane was observed. Thus, the DHA-reducing enzyme system is indispensable in maintaining AsA concentrations in chloroplasts.     

Demonstration of Two Sites of Inhibition of Electron Transport by Protein Phosphorylation in Wheat Thylakoids

The effect of protein phosphorylation on electron transportactivities of thylakoids isolated from wheat leaves was investigated.Protein phosphorylation resulted in a reduction in the apparentquantum yield of whole chain and photosystem II (PSII) electrontransport but had no effect on photosystem I (PSI) activity.The affinity of the D1 reaction centre polypeptide of PSII tobind atrazine was diminished upon phosphorylation, however,this did not reduce the light-saturated rate of PSII electrontransport. Phosphorylation also produced an inhibition of thelight-saturated rate of electron transport from water or durohydroquinoneto methyl viologen with no similar effect being observed onthe light-saturated rate of either PSII or PSI alone. This suggeststhat phosphorylation produces an inhibition of electron transportat a site, possibly the cytochrome b₆/f complex, between PSIIand PSI. This inhibition of whole-chain electron transport wasalso observed for thylakoids isolated from leaves grown underintermittent light which were deficient in polypeptides belongingto the light-harvesting chlorophyll-protein complex associatedwith photosystem II (LHCII). Consequently, this phenomenon isnot associated with phosphorylation of LCHII polypeptides. Apossible role for cytochrome b₆/f complexes in the phosphorylation-inducedinhibition of whole chain electron transport is discussed. Key words: Electron transport, light harvesting, photosystem 2, protein phosphorylation, thylakoid membranes, wheat (Triticum aestivum)     

Development of the cation-induced stacking capacity during the biogenesis of higher plant thylakoids

We studied the capacity of the thylakoid membrane to form grana stacks in the presence of cations, monovalent or divalent, added to N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine “low-salt” disorganized plastids during their greening. Grana stacking was monitored by the yield of heavy subchloroplast fractions separated by differential centrifugation after digitonin disruption of plastids (J. H. Argyroudi-Akoyunoglou, 1976, Arch. Biochem. Biophys., 176, 267–274). Primary thylakoids of the agranal protochloroplasts formed in periodic light do not show the cation-induced stacking capacity of the mature green chloroplast thylakoids. Similarly, the cation effect saturates at lower cation concentrations in mature chloroplasts than in plastids of the early stages of greening. The capacity for cation-induced stacking and for saturation of the effect at low cation concentrations appears gradually after exposure to continuous light and parallel to the appearance of chlorophyll b and the polypeptides of the 25,000–30,000 molecular weight range of lipid-free thylakoids, probably derived from the chlorophyll b-rich chlorophyll protein Complex II. The thylakoid peripheral stroma proteins ribulosediphosphate carboxylase and the coupling factor protein are not involved in the cation-induced stacking, since their removal (H. Strotmann, H. Hesse, and K. Edelmann, 1973, Biochim. Biophys. Acta, 314, 202–210) does not affect the thylakoid aggregation.