Influence of protein phosphorylation on the electron-transport properties of Photosystem II

Many of the core proteins in Photosystem II (PS II) undergo reversible phosphorylation. It is known that protein phosphorylation controls the repair cycle of Photosystem II. However, it is not known how protein phosphorylation affects the partial electron transport reactions in PS II. Here we have applied variable fluorescence measurements and EPR spectroscopy to probe the status of the quinone acceptors, the Mn cluster and other electron transfer components in PS II with controlled levels of protein phosphorylation. Protein phosphorylation was induced in vivo by varying illumination regimes. The phosphorylation level of the D1 protein varied from 10 to 58% in PS II membranes isolated from pre-illuminated spinach leaves. The oxygen evolution and Q_A ⁻ to Q_B(Q_B ⁻) electron transfer measured by flash-induced fluorescence decay remained similar in all samples studied. Similar measurements in the presence of DCMU, which reports on the status of the donor side in PS II, also indicated that the integrity of the oxygen-evolving complex was preserved in PS II with different levels of D1 protein phosphorylation. With EPR spectroscopy we examined individual redox cofactors in PS II. Both the maximal amplitude of the charge separation reaction (measured as photo-accumulated pheophytin⁻) and the EPR signal from the Q_A ⁻ Fe²⁺ complex were unaffected by the phosphorylation of the D1 protein, indicating that the acceptor side of PS II was not modified. Also the shape of the S₂ state multiline signal was similar, suggesting that the structure of the Mn-cluster in Photosystem II did not change. However, the amplitude of the S₂ multiline signal was reduced by 35% in PS II, where 58% of the D1 protein was phosphorylated, as compared to the S₂ multiline in PS II, where only 10% of the D1 protein was phosphorylated. In addition, the fraction of low potential Cyt b ₅₅₉ was twice as high in phosphorylated PS II. Implications from these findings, were precise quantification of D1 protein phosphorylation is, for the first time, combined with high-resolution biophysical measurements, are discussed. This revised version was published online in June 2006 with corrections to the Cover Date.     

Light affects the accessibility of the thylakoid light harvesting complex II (LHCII) phosphorylation site to the membrane protein kinase(s)

Redox-controlled, reversible phosphorylation of the thylakoid light harvesting complex II (LHCII) regulates its association with photosystems (PS) I or II and thus, energy distribution between the two photosystems (state transition). Illumination of solubilized LHCII enhances exposure of the phosphorylation site at its N-terminal domain to protein kinase(s) and tryptic cleavage in vitro [Zer et al. (1999) Proc. Natl. Acad. Sci. U.S.A. 96, 8277-8282]. Here we report that short illumination (5-10 min, 15-30 micromol m(-2) s(-1)) enhances the accessibility of LHCII phosphorylation site to kinase(s) activity also in isolated thylakoids. However, prolonged illumination or higher light intensities (30 min, 80-800 micromol m(-2) s(-1)) prevent phosphorylation of LHCII in the isolated membranes as well as in vivo, although redox-dependent protein kinase activity persists in the illuminated thylakoids toward exogenous solubilized LHCII. This phenomenon, ascribed to light-induced inaccessibility of the phosphorylation site to the protein kinase(s), affects in a similar way the accessibility of thylakoid LHCII N-terminal domain to tryptic cleavage. The illumination effect is not redox related, decreases linearly with temperature from 25 to 5 degrees C and may be ascribed to light-induced conformational changes in the complex causing lateral aggregation of dephosphorylated LHCII bound to and/or dissociated from PSII. The later state occurs under conditions allowing turnover of the phospho-LHCII phosphate. The light-induced inaccessibility of LHCII to the membrane-bound protein kinase reverses readily in darkness only if induced under LHCII-phosphate turnover conditions. Thus, phosphorylation prevents irreversible light-induced conformational changes in LHCII allowing lateral migration of the complex and the related state transition process.     

Massive breakdown of the Photosystem II polypeptides in a mutant of the cyanobacterium Synechocystis sp. PCC 6803

Degradation of the D1 protein of the Photosystem II (PS II) complex was studied in the Fad6/desA::Km^r mutant of a cyanobacterium Synechocystis sp. PCC 6803. The D1 protein of the mutant was degraded during solubilization of thylakoid membranes with SDS at 0°C in darkness, giving rise to the 23 kDa amino-terminal and 10 kDa carboxy-terminal fragments. Moreover, the D2 and CP43 proteins were also degraded under such conditions of solubilization. Degradation of the D2 protein generated 24, 17 and 15.5 kDa fragments, and degradation of the CP43 protein gave rise to 28, 27.5, 26 and 16 kDa fragments. The presence of Ca²⁺ and urea protected the D1, D2 and CP43 proteins against degradation. Degradation of the D1 protein was also inhibited by the presence of a serine protease inhibitor suggesting that the putative protease involved belonged to the serine class of proteases. The protease had the optimum activity at pH 7.5; it was active at low temperature (0°C) but a brief heating (65°C) during solubilization destroyed the activity. Interestingly, the protease was active in isolated thylakoid membranes in complete darkness, suggesting that proteolysis may be a non-ATP-dependent process. Proteolytic activity present in thylakoid membranes seemed to reside outside of the PS II complex, as demonstrated by the 2-dimensional gel electrophoresis. These results represent the first (in vitro) demonstration of strong activity of a putative ATP-independent serine-type protease that causes degradation of the D1 protein in cyanobacterial thylakoid membranes without any induction by visible or UV light, by active oxygen species or by any chemical treatments.     

Reversible phosphorylation and turnover of the D1 protein under various redox states of Photosystem II induced by low temperature photoinhibition

Reversible phosphorylation and turnover of the D1 protein in vivo were studied under low-temperature photoinhibition of pumpkin leaves and under subsequent recovery at low light at 4 °C or 23 °C. The inactivation of PS II and photodamage to D1 were not enhanced during low-temperature photoinhibition when compared to that at room temperature. The PS II repair cycle, however, was completely blocked at 4 °C at the level of D1 degradation. Both the recovery of the photochemical activity of PS II and the degradation of the damaged D1 protein at low light at 23 °C were delayed about 1 hour after low-temperature photoinhibition, suggesting that in addition to the decrease in catalytic turnover of the enzyme, the protease was specifically inactivated in vivo at low temperature. The effect of low temperature on the other regulatory enzymes of PS II repair, protein kinase and phosphatase [Rintamäki et al. (1996) J Biol Chem 271: 14870-14875] was variable. The D1 protein kinase was operational at low temperature while dephosphorylation of the D1 protein seemed to be completely inhibited during low temperature treatment. Under subsequent recovery conditions at low light and 23 °C, the high phosphorylation level of D1 was sustained in leaf discs photoinhibited at low temperature, despite the recovery of the phosphatase activity. This high phosphorylation level of D1 was due to the persistently active kinase. The D1 kinase, previously shown to get activated by reduction of plastoquinone, was, however, found to be maximally active already at relatively low redox state of the plastoquinone pool. We suggest that phosphorylation of PS II centers increases the stability of PS II complexes and concomitantly improves their survival under stress conditions.     

Comparison of the phosphorylation of microtubule-associated protein tau by non-proline dependent protein kinases

Microtubule-associated protein tau from Alzheimer brain has been shown to be phosphorylated at several ser/thr-pro and ser/thr-X sites (Hasegawa, M. et al., J. Biol. Chem, 267, 17047–17054, 1992). Several proline-dependent protein kinases (PDPKs) (MAP kinase, cdc2 kinase, glycogen synthase kinase-3, tubulin-activated protein kinase, and 40 kDa neurofilament kinase) are implicated in the phosphorylation of the ser-thr-pro sites. The identity of the kinase(s) that phosphorylate that ser/thr-X sites are unknown. To identify the latter kinase(s) we have compared the phosphorylation of bovine tau by several brain protein kinases. Stoichiometric phosphorylation of tau was achieved by casein kinase-1, calmodulin-dependent protein kinase II, Gr kinase, protein kinase C and cyclic AMP-dependent protein kinase, but not with casein kinase-2 or phosphorylase kinase. Casein kinase-1 and calmodulin-dependent protein kinase II were the best tau kinases, with greater than 4 mol and 3 mol³²P incorporated, respectively, into each mol of tau. With the sequential addition of these two kinases,³²P incorporation approached 6 mol. Peptide mapping revealed that the different kinases largely phosphorylate different sites on tau. After phosphorylation by casein kinase-1, calmodulin-dependent protein kinase II, Gr kinase, cyclic AMP-dependent protein kinase and casein kinase-2, the mobility of tau isoforms as detected by SDS-PAGE was decreased. Protein kinase C phosphorylation did not produce such a mobility shift. Our results suggest that one or more of the kinases studied here may participate in the hyperphosphorylation of tau in Alzheimer disease. Such phosphorylation may serve to modulate the activaties of other tau kinases such as the PDPKs.Abbreviations PHF paired helical filaments - A-kinase cyclic AMP-dependent protein kinase - CaM kinase II calcium/calmodulin-dependent protein kinase II - C-kinase calcium-phospholipid-dependent protein kinase - CK-1 casein kinase-1 - CK-2 casein kinase-2 - Gr kinase calcium/calmodulin-dependent protein kinase from rat cerebellum - GSK-3 glycogen synthase kinase-3 - MAP kinase mitogen-activated protein kinase - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Light-stress-related changes in the properties of photosystem I

Light-stress-related changes in photosystem I (PS I) were analyzed in photoautotrophic cultured cells of Marchantia polymorpha L. High light treatment (30␣h; 1300 μmol photons · m⁻² · s⁻¹) reduced the PS I-mediated electron-transport rate by more than 50% and the photochemical efficiency of photosystem II (PS II) by about 35%. In photoinhibited cells, 76% of the PS II centers remained closed in low light, which is in agreement with a preferential impairment of PS I. Our data indicate that excessive linear electron transport is a cause of the loss in PS I activity. Two PS I forms could be isolated by sucrose-gradient ultracentrifugation of mildly solubilized thylakoid membranes. After high-light treatment one of these forms, which showed a larger light-harvesting complex (LHC) I antenna and a specific association of LHC IIb, was enriched. The effect could be suppressed by blockage of linear electron transport. It is suggested that PS I inactivation and state transitions caused the change in PS I organisation. Received: 19 August 1996 / Accepted: 24 October 1996     

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.     

Thylakoid protein phosphorylation is suppressed by 'free radical scavengers'. Correlation between PS II core protein degradation and thylakoid protein phosphorylation

Recent work has shown that the light-induced PS II core protein degradation, as monitored by immunostain reduction on Western blots, was stimulated even at low light during phosphorylation of thylakoid proteins in the presence of NaF, and that the thylakoid kinase inhibitor FSBA blocked completely the light- and ATP-stimulated degradation [Georgakopoulos and Argyroudi-Akoyunoglou (1997) Photosynth Res 53: 185–195]. To assess whether D1, D2 or both proteins are degraded, antibodies raised against D1/D2, or the D-E loop of D1 were used. Greatest immunostain reduction was observed with antibodies raised against D1/D2, immunostaining a 34 kDa protein on blots of 15% polyacrylamide-6 M urea gels, suggesting that the phosphorylation-induced degradation may be mainly directed against D2. To see how protein phosphorylation might be implicated in PS II core protein degradation we further tested the effect of free radical scavengers, on thylakoid protein phosphorylation. Active oxygen scavengers like n-propyl gallate, histidine, and imidazole, shown earlier to inhibit high light-induced D1 degradation, also suppressed the phosphorylation of thylakoid proteins; on the other hand, NaN3 and D-mannitol, known to stimulate light- induced D1 degradation did not suppress protein phosphorylation, whereas superoxide dismutase and catalase, known also to inhibit high light-induced D1 degradation, did not affect thylakoid protein phosphorylation. In addition, the ATP-induced degradation was also observed in the dark under conditions of kinase activation, and in the light under anaerobic conditions, that block light-induced degradation, whereas it was reduced in the absence of NaF, the phosphatase inhibitor. The results point to the involvement of a proteolytic system in PS II core protein degradation, which is active in its phosphorylated state.     

Cytochrome b6-f complex : The carburettor of exciton distribution in oxygenic photosynthesis

Efficient oxygenic photosynthesis not only requires synchronous turover and operation of photosystem I (PS I) and photosystem II (PS II) but also the preferential turnover of PS I for cyclic photophosphorylation to maintain required ATP and NADPH ratio during carbon dioxide reduction. Ohe initial higher rate of turnover of PS IIin viva is accounted by the fact that (i) PS I contains only about one-third of total chlorophylls, (ii) about 90% of light harvesting a/b protein (LAC) which accounts for about 50% of the total chlorophylls, remains associated with PS II as PS II-LHC II complexes (PS II_α and (iii) the ratio of PS II/PS I is always greater than unity, in the range of 1–2 : 1 under different environmental regimes. Ohe initial preferential feeding of PS II, due to its larger antenna, is bound to result in faster rate of turn over of PS II than PS I, leading to higher rate of reduction of an intersystem carrier than the rate of its oxidation by PS I. Ohe light dependent phosphorylation of a ‘mobile’ and small pool (−20%) of LHC II of PS II_α (possibly located at the edge of appressed regions of the membranes) increases the repulsive forces of LHC II resulting in its migration to non-appressed region associating itself with PS 1. Ohe phosphorylation itself is controlled by the redox state of an intermediate of electron transport. Several experimental approaches have provided evidence which suggest that (i) phosphorylation of LAC II involves interaction of cyt b5-f complex with LAC II kinase and the interaction of QA with cyt b₅-f complex and (ii) different kinases may be involved in phosphorylation of LHC IIversus PS II polypeptides. Ohe major purpose of light dependent LAC II phosphorylation and its consequent migration close to PS I appears to balance the rate of cyclicversus non-cyclic photophosphorylation. Ohe mechanism by which cyt b₅-f complex controls the activation of LAC II is not known. Ohe role of membrane bound ealmodulin, electron transfer through cyt b₆-f complex in activation of LAC II kinase should be explored.     

The interaction of visible and UV-B light during photodamage and repair of Photosystem II

In order to understand the mechanism of photodamage induced by solar radiation under natural conditions, we studied the interaction of visible and ultraviolet-B light in the inactivation and repair of the Photosystem II complex by using oxygen evolution and flash-induced chlorophyll fluorescence measurements. In isolated spinach thylakoids and Synechocystis 6803 cells, in which de novo protein synthesis is blocked by lincomycin, photodamage of Photosystem II by visible and UV-B light is characterized by linear semilogarithmic inactivation curves for both separate and combined illumination protocols. The extent of PS II inactivation obtained after combined illumination can be well simulated by assuming independent damaging events induced by visible and UV-B photons. In intact Synechocystis cells capable of protein repair, simultaneous illumination by visible and UV-B light impairs Photosystem II activity to a smaller extent than expected from the independent damaging events. This protective effect is pronounced at low visible light (130 μE m⁻² s⁻¹), but becomes negligible at high intensities (1300 μE m⁻² s⁻¹). Exposure of intact Synechocystis 6803 cells to direct sunlight leads to a rapid inactivation of PS II, accompanied by the accumulation of donor side inhibited centers. This phenomenon, which shows the impairment of the manganese cluster of water oxidation was not observed when the ultraviolet components of sunlight were filtered out. We conclude that visible and UV-B photons inactivate PS II via non-interacting mechanisms, which affect different target sites. In intact cells, the two spectral regions do interact, and results in synergistically enhanced protein repair capacity when UV-B radiation is accompanied by low intensity visible light, which provides protection against photodamage. However, this ameliorating effect becomes insignificant at high light intensities characteristic of direct sunlight. This revised version was published online in June 2006 with corrections to the Cover Date.     

Photosynthetic water oxidation: The protein framework

Approximately 20 protein subunits are associated with the PS II complex, not counting subunits of peripheral light-harvesting antenna complexes. However, it is not yet established which proteins specifically are involved in the water-oxidation process. Much evidence supports the concept that the D1/D2 reaction center heterodimer not only plays a central role in the primary photochemistry of Photosystem II, but also is involved in electron donation to P680 and in ligation of the manganese cluster. This evidence includes (a) the primary donor to P680 has been shown to be a redox-active tyrosyl residue (Tyr161) in the D1 protein, and (b) site-directed mutagenesis and computer-assisted modeling of the reaction center heterodimer have suggested several sites with a possible function in manganese ligation. These include Asp170, Gln165 and Gln189 of the D1 protein and Glu69 of the D2 protein as well as the C-terminal portion of the mature D1 protein. Also, hydrophilic loops of the chlorophyll-binding protein CP43 that are exposed at the inner thylakoid surface could be essential for the water-splitting process.In photosynthetic eukaryotes, three lumenal extrinsic proteins, PS II-O (33 kDa), PS II-P (23 kDa) and PS II-Q (16 kDa), influence the properties of the manganese cluster without being involved in the actual catalysis of water oxidation. The extrinsic proteins together may have multiple binding sites to the integral portion of PS II, which could be provided by the D1/D2 heterodimer and CP47. A major role for the PS II-O protein is to stabilize the manganese cluster. Most experimental evidence favors a connection of the PS II-P protein with binding of the Cl^- and Ca²⁺ ions required for the water oxidation, while the PS II-Q protein seems to be associated only with the Cl^- requirement. The two latter proteins are not present in PS II of prokaryotic organisms, where their functions may be replaced by a 10–12 kDa subunit and a newly discovered low-potential cytochrome c-550.Abbreviations PS II Photosystem II - PCC Pasteur Culture Collection     

Conventional protein kinase C isoenzymes undergo dephosphorylation in neutrophil-like HL-60 cells treated by chelerythrine or sanguinarine

The quaternary benzo[c]phenanthridine alkaloid chelerythrine is widely used as an inhibitor of protein kinase C (PKC). However, in biological systems chelerythrine interacts with an array of proteins. In this study, we examined the effects of chelerythrine and sanguinarine on conventional PKCs (cPKCs) and PKC upstream kinase, phosphoinositide-dependent protein kinase 1 (PDK1), under complete inhibition conditions of PKC-dependent oxidative burst. In neutrophil-like HL-60 cells, sanguinarine and chelerythrine inhibited N-formyl-Met-Leu-Phe, phorbol 12-myristate 13-acetate (PMA)-, and A23187-induced oxidative burst with IC₅₀ values not exceeding 4.6 μmol/L, but the inhibition of PMA-stimulated cPKC activity in intact cells required at least fivefold higher alkaloid concentrations. At concentrations below 10 μmol/L, sanguinarine and chelerythrine prevented phosphorylation of ∼80 kDa protein and sequestered ∼60 kDa phosphoprotein in cytosol. Moreover, neither sanguinarine nor chelerythrine impaired PMA-stimulated translocation of autophosphorylated PKCα/βII isoenzymes, but both alkaloids induced dephosphorylation of the turn motif in PKCα/βII. The dephosphorylation did not occur in unstimulated cells and it was not accompanied by PKC degradation. Furthermore, cell treatment with sanguinarine or chelerythrine resulted in phosphorylation of ∼70 kDa protein by PDK1. We conclude that PKC-dependent cellular events are affected by chelerythrine primarily by multiple protein interactions rather than by inhibition of PKC activity.     

The development of antenna complexes of barley (Hordeum vulgare cv. Akcent) under different light conditions as judged from the analysis of 77 K chlorophyll a fluorescence spectra

Using 77 K chlorophyll a (Chl a) fluorescence spectra in vivo, the development was studied of Photosystems II (PS II) and I (PS I) during greening of barley under intermittent light followed by continuous light at low (LI, 50 μmol m⁻² s⁻¹) and high (HI, 1000 μmol m⁻² s⁻¹) irradiances. The greening at HI intermittent light was accompanied with significantly reduced fluorescence intensity from Chl b excitation for both PS II (F685) and PS I (F743), in comparison with LI plants, indicating that assembly of light-harvesting complexes (LHC) of both photosystems was affected to a similar degree. During greening at continuous HI, a slower increase of emission from Chl b excitation in PS II as compared with PS I was observed, indicating a preferred reduction in the accumulation of LHC II. The following characteristics of 77 K Chl a fluorescence spectra documented the photoprotective function of an elevated content of carotenoids in HI leaves: (1) a pronounced suppression of Soret region of excitation spectra (410–450 nm) in comparison with the red region (670–690 nm) during the early stage of greening indicated a strongly reduced excitation energy transfer from carotenoids to the Chl a fluorescing forms within PS I and PS II; (2) changes in the shape of the excitation band of Chl b and carotenoids (460–490 nm) during greening under continuous light confirmed that the energy transfer from carotenoids to Chl a within PS II remained lower as compared with the LI plants. This revised version was published online in June 2006 with corrections to the Cover Date.     

Retardation of photo-induced changes in Photosystem I submembrane particles by glycinebetaine and sucrose

The protective role of co-solutes (glycinebetaine and sucrose) against photodamage in isolated Photosystem (PS) I submembrane particles illuminated (2000 μE m⁻² s⁻¹) for various time periods at 4 °C was studied. The photochemical activity of PS I in terms of electron transport measured as oxygen uptake and P700 photooxidation was significantly protected. A photoinduced enhancement of oxygen uptake observed during the first hours of strong light illumination attributed to denaturation or dissociation of membrane-bound superoxide dismutase [Rajagopal et al. (2003) Photochem. Photobiol 77: 284–291] was also retarded by glycinebetaine and sucrose. Chlorophyll photobleaching resulting in a decrease of absorbance and a blue-shift of the absorbance maximum in the red was greatly delayed in the presence of co-solutes. This phenomenon was also observed in the chlorophyll-protein (CP) complexes of PS I particles exposed to strong illumination separated on non-denaturing poly-acrylamide gels. In this case, a decrease in the absorbance of the CP1b band coinciding with an increase of CP1a during the course of illumination and ascribed to oxidative cross-linking (Rajagopal et al. 2003) was also retarded. Our results, thus, clearly demonstrated for the first time that co-solutes could minimize the alteration of photochemical activity and chlorophyll-protein complexes against photodamage of PS I submembranes particles. This revised version was published online in August 2006 with corrections to the Cover Date.     

Identification of the phosphorylation site of an 8.3 kDa protein from photosystem II of spinach

The four principal phosphoproteins of PS II cores (8.3, 32, 34 and 44 kDa) give rise to distinct tryptic phosphopeptides which have been purified by affinity chromatography on Fe³⁺-chelating Sepharose and reverse-phase HPLC. The tryptic phosphopeptide derived from the 8.3 kDa protein has the sequence NH₂-Ala-Thr-Gln-Thr-Val-Glu-Ser-Ser-Ser-Arg. It corresponds to the N-terminus of the chloroplast psbH gene product, except for the loss of the initiating N-formylmethionine. The peptide is phosphorylated on the first threonyl residue. Differences between the phosphorylation sites of the 8.3 kDa protein and LHC II are consistent with the hypothesis that thylakoids contain two distinct redox-controlled protein kinases differing in substrate specificity.     

The effect of hydration on protein flexibility in photosystem II of green plants studied by quasielastic neutron scattering

The effect of hydration on protein dynamics in photosystem II (PS II) membrane fragments from spinach has been investigated by using the method of quasielastic neutron scattering (QENS) at room temperature. The QENS data obtained indicate that the protein dynamics is strongly dependent on the extent of hydration. In particular, the hydration-induced activation of localized diffusive protein motions and Q_A⁻ reoxidation by Q_B in PS II appear to be correlated in their onset at a hydration value of about 45% relative humidity (r.h.). These findings underline the crucial functional relevance of localized diffusive protein motions on the picosecond-timescale for the reactions of light-induced photosynthetic water splitting under formation of plastoquinol and molecular oxygen in PS II of green plants. Advanced neutron scattering and complementary techniques to study biological systems. Contributions from the meetings, “Neutrons in Biology”, STFC Rutherford Appleton Laboratory, Didcot, UK, 11–13 July and “Proteins At Work 2007”, Perugia, Italy, 28–30 May 2007.     

光系统II蛋白磷酸化及其生理意义

蛋白磷酸化修饰在几乎所有的生命活动中都起重要的调节作用.该文结合作者研究组的研究工作,概述了光系统II(PS II)蛋白磷酸化的调节及其生理功能.PS II复合体中的核心组分D1、D2、CP43和PsbH蛋白以及外周捕光天线(LHC II)蛋白都可以发生磷酸化.PS II蛋白磷酸化受质醌(PQ)的氧化还原状态、细胞色素b6f (Cyt b6f ) 和硫氧还蛋白以及光调节.PS II蛋白磷酸化可以调节激发能在两种光系统(PS I和PS II)之间的分配,减轻光胁迫对PS II的压力,保护核心蛋白免于光破坏,稳定PS II复合体的结构.     

Three-dimensional model of zeaxanthin binding PsbS protein associated with nonphotochemical quenching of excess quanta of light energy absorbed by the photosynthetic apparatus

A three-dimensional model of the PsbS protein was built with the help of homology-modeling methods. This protein is also known as CP22 and is associated with the protection of photosystem II of thylakoid from excess quanta of light energy absorbed by the photosynthetic apparatus. PsbS is reported to bind two molecules of zeaxanthin at low pH (<5.0) and is believed to be essential for rapid nonphotochemical quenching (qE) of chlorophyll a fluorescence in photosystem II. An attempt was made to explain the pH modulation of the conformation of protein through salt-bridges Glu⁻(122)-Lys⁺(113) and Glu⁻(226)-Lys⁺(217). Binding of two molecules of zeaxanthin in the three-dimensional model of PsbS is postulated. The molecular mechanism of photoprotection by PsbS is explained through the model. 1 Backbone structure of the PsbS protein with two molecules of all trans zeaxanthin (ZEX). Residues Glu 90, 122, 194, 226 and Lys 113, 217 are shown. The figure is drawn with RASMOL (Molecular Visualization Program, RasMol V2.6, Roger Sayle, Glaxo Wellcome Research and Development, Stevenage, Hertfordshire, UK) Electronic Supplementary Material Supplementary material is available for this article at     

Light intensity determines the extent of mercury toxicity in the cyanobacterium Nostoc muscorum

The extent of mercury (Hg) toxicity in the heterocystous cyanobacterium Nostoc muscorum grown for 72 h in three different light intensities was tested for various physiological parameters viz. growth, pigment contents, photosynthesis, respiration, reactive oxygen species (ROS), malondialdehyde formation and antioxidants. A general reduction in growth and pigments, whole cell O₂-evolution, photosynthetic electron transport activities and ¹⁴CO₂-fixation was observed in a metal concentration–dependent manner, and this effect was more pronounced in high light (130 μmol photon m⁻² s⁻¹)–exposed cells as compared to low (10 μmol photon m⁻² s⁻¹) and normal (70 μmol photon m⁻² s⁻¹) light intensity–exposed cells; however, carotenoids and respiration showed reverse trend. Among photosynthetic electron transport activities, whole chain activity was found to be most sensitive in comparison with photosystem II (PS II) and photosystem I (PS I). Comparing the different photosynthetic processes, ¹⁴CO₂-fixation was most affected in cyanobacterial cells when exposed to Hg and different light intensities. After application of various exogenous electron donors, diphenyl carbazide was found to be more effective to restore PS II activity, suggesting that site of damage lies in between oxygen evolving complex and PS II. Level of oxidative stress (superoxide radical and lipid peroxidation) was maximum at 3.0 μM of Hg when coupled with high light intensity (except hydrogen peroxide). A dose-dependent increase in enzymatic antioxidants such as superoxide dismutase, peroxidase and catalase as well as non-enzymatic antioxidants such as proline, ascorbate, cysteine (except under high light intensity) and non-protein thiols [NP-SH] was observed, which further increased with the increase in light intensity. It was noticed that Hg intoxicates N. muscorum through ROS production, which is aggravated along with the increase in light intensity. Overall results suggest that the severity of the metal stress does increase with Hg concentrations but when coupled with light, it was the light intensity that determines the extent of Hg toxicity.     

Protein Kinase A Activation Phosphorylates the Rat ClC-2 Cl− Channel but Does Not Change Activity

Phosphorylation-dependent events have been shown to modulate the activity of several members of the mammalian CLC Cl⁻ channel gene family, including the inward rectifier ClC-2. In the present study we investigated the regulation of rat ClC-2 expressed in the TSA-201 cell line (a transformed HEK293 cell line that stably expresses the SV40 T-antigen) by protein kinases. Protein kinase A activation phosphorylated ClC-2 in vivo, whereas stimulation of protein kinase C with phorbol 12-myristate 13-acetate did not. In vitro labeling studies confirmed that protein kinase A could directly phosphorylate ClC-2, and that protein kinase C and Ca²⁺/calmodulin-dependent protein kinase II did not. Nevertheless, protein kinase A-dependent phosphorylation of CLC-2 failed to regulate either the magnitude or the kinetics of the hyperpolarization-activated Cl⁻ currents. Considered together, we demonstrate that protein kinase A activation results in the phosphorylation of rat ClC-2 in vivo, but this event is independent of Cl⁻ channel activity. Received: 20 November 2000/Revised: 28 March 2001