Identification and characterization of a stable intermediate in photosystem I assembly in tobacco

Photosystem I (PSI) is the most efficient bioenergetic nanomachine in nature and one of the largest membrane protein complexes known. It is composed of 18 protein subunits that bind more than 200 co‐factors and prosthetic groups. While the structure and function of PSI have been studied in great detail, very little is known about the PSI assembly process. In this work, we have characterized a PSI assembly intermediate in tobacco plants, which we named PSI*. We found PSI* to contain only a specific subset of the core subunits of PSI. PSI* is particularly abundant in young leaves where active thylakoid biogenesis takes place. Moreover, PSI* was found to overaccumulate in PsaF‐deficient mutant plants, and we show that re‐initiation of PsaF synthesis promotes the maturation of PSI* into PSI. The attachment of antenna proteins to PSI also requires the transition from PSI* to mature PSI. Our data could provide a biochemical entry point into the challenging investigation of PSI biogenesis and allow us to improve the model for the assembly pathway of PSI in thylakoid membranes of vascular plants.     

A current assessment of photosystem II structure

This review covers the recent progress in the elucidation of the structure of photosystem II (PSII). Because much of the structural information for this membrane protein complex has been revealed by electron microscopy (EM), the review will also consider the specific technical and interpretation problems that arise with EM where they are of particular relevance to the structural data. Most recent reviews of photosystem II structure have concentrated on molecular studies of the PSII genes and on the likely roles of the subunits that they encode or they were mainly concerned with the biophysical data and fast absorption spectroscopy largely relating to electron transfer in various purified PSII preparations. In this review, we will focus on the approaches to the three-dimensional architecture of the complex and the lipid bilayer in which it is located (the thylakoid membrane) with special emphasis placed upon electron microscopical studies of PSII-containing thylakoid membranes. There are a few reports of 3D crystals of PSII and of associated X-ray diffraction measurements and although little structural information has so far been obtained from such studies (because of the lack of 3D crystals of sufficient quality), the prospects for such studies are also assessed.Abbreviations ATP adenosine triphosphate - Chl chlorophyll - CP chlorophyll-binding protein - EM electron microscopy - LHC light harvesting complex - NADP nicotinamide adenine dinucleotide phosphate - OEC oxygen evolution enhancing complex - PS photosystem - Tris tris-hydroxymethyl aminomethane     

Recent advances in understanding the assembly and repair of photosystem II

Background

Photosystem II (PSII) is the light-driven water:plastoquinone oxidoreductase of oxygenic photosynthesis and is found in the thylakoid membrane of chloroplasts and cyanobacteria. Considerable attention is focused on how PSII is assembled in vivo and how it is repaired following irreversible damage by visible light (so-called photoinhibition). Understanding these processes might lead to the development of plants with improved growth characteristics especially under conditions of abiotic stress.

Scope

Here we summarize recent results on the assembly and repair of PSII in cyanobacteria, which are excellent model organisms to study higher plant photosynthesis.

Conclusions

Assembly of PSII is highly co-ordinated and proceeds through a number of distinct assembly intermediates. Associated with these assembly complexes are proteins that are not found in the final functional PSII complex. Structural information and possible functions are beginning to emerge for several of these ‘assembly’ factors, notably Ycf48/Hcf136, Psb27 and Psb28. A number of other auxiliary proteins have been identified that appear to have evolved since the divergence of chloroplasts and cyanobacteria. The repair of PSII involves partial disassembly of the damaged complex, the selective replacement of the damaged sub-unit (predominantly the D1 sub-unit) by a newly synthesized copy, and reassembly. It is likely that chlorophyll released during the repair process is temporarily stored by small CAB-like proteins (SCPs). A model is proposed in which damaged D1 is removed in Synechocystis sp. PCC 6803 by a hetero-oligomeric complex composed of two different types of FtsH sub-unit (FtsH2 and FtsH3), with degradation proceeding from the N-terminus of D1 in a highly processive reaction. It is postulated that a similar mechanism of D1 degradation also operates in chloroplasts. Deg proteases are not required for D1 degradation in Synechocystis 6803 but members of this protease family might play a supplementary role in D1 degradation in chloroplasts under extreme conditions.     

Light-dependent phosphorylation of D1 reaction centre protein of photosystem II: hypothesis for the functional role in vivo

Reversible phosphorylation of the D1 reaction centre protein of photosystem II (PSII) occurs in thylakoid membranes of higher plants. The significance of D1 protein phosphorylation in the function of PSII is not yet clear. This paper summarizes the data implying that phosphorylation of D1 protein in higher plants is involved in the regulation of the repair cycle of photoinhibited PSII centres. Photoinhibition of PSII, D1 protein phosphorylation and degradation have been studied in vivo in higher plant leaves acclimated to different growth irradiances. It is shown that photoinhibitory illumination induces maximal phosphorylation of the D1 protein. Under these conditions D1 turnover is also saturated. We postulate that phosphorylation retards the degradation of damaged D1 protein under conditions where rapid replacement by a new D1 copy is not possible. This would protect PSII from total disassembly and degradation of all PSII subunits. We conclude that the phosphorylation of D1 protein and the regulation of D1 protein degradation may have evolved together. Furthermore, these characteristics seem to be related to the highly organized structure of higher-plant type thylakoid membranes, since the capability to phosphorylate D1 protein is restricted to seed plants.     

Photoinactivation and photoprotection of photosystem II in nature

Photosystem II plays a central role not only in energy transduction, but also in monitoring the molecular redox mechanisms involved in signal transduction for acclimation to environmental stresses. Central to the regulation of photosystem II (PSII) function as a light-driven molecular machine in higher plant leaves, is an inevitable photo-inactivation of one PSII after 10⁶–10⁷ photons have been delivered to the leaf, although the act of photoinactivation per se requires only one photon. PSII function in acclimated pea leaves shows a reciprocity between irradiance and the time of illumination, demonstrating that the photoinactivation of PSII is a light dosage effect, depending on the number of photons absorbed rather than the rate of photon absorption. Hence, PSII photoinactivation will occur at low as well as high irradiance. There is a heterogeneity of PSII functional stability, possibly with less stable PSII monomers being located in grana margins and more stable PSII dimers in appressed granal domains. Matching the inevitable photoinactivation of PSII, green plants have an intrinsic capacity for D1 protein synthesis to restore PSII function which is saturated at very low light. Photoinhibition of PSII in vivo is often a photoprotective strategy rather than a damaging process.     

The physiological significance of photosystem II heterogeneity in chloroplasts

Photosystem II in green plant chloroplasts displays heterogeneity both in the composition of its light-harvesting antenna and in the ability to reduce the plastoquinone pool. These two features are discussed in terms of chloroplast development and in view of a proposed photosystem II repair cycle.     

Dynamics of photosystem II heterogeneity in Dunaliella salina (green algae)

Based on the electron-transport properties on the reducing side of the reaction center, photosystem II (PS II) in green plants and algae occurs in two distinct forms. Centers with efficient electron-transport from Q_A to plastoquinone (Q_B-reducing) account for 75% of the total PS II in the thylakoid membrane. Centers that are photochemically competent but unable to transfer electrons from Q_A to Q_B (Q_B-nonreducing) account for the remaining 25% of total PS II and do not participate in plastoquinone reduction. In Dunaliella salina, the pool size of Q_B-nonreducing centers changes transiently when the light regime is perturbed during cell growth. In cells grown under moderate illumination intensity (500 E m^-2s^-1), dark incubation induces an increase (half-time 45 min) in the Q_B-nonreducing pool size from 25% to 35% of the total PS II. Subsequent illumination of these cells restores the steady-state concentration of Q_B-nonreducing centers to 25%. In cells grown under low illumination intensity (30 µE m^–2s^–1), dark incubation elicits no change in the relative concentration of Q_B-nonreducing centers. However, a transfer of low-light grown cells to moderate light induces a rapid (half-time 10 min) decrease in the Q_B-nonreducing pool size and a concomitant increase in the Q_B-reducing pool size. These and other results are explained in terms of a pool of Q_B-nonreducing centers existing in a steady-state relationship with Q_B-reducing centers and with a photochemically silent form of PS II in the thylakoid membrane of D. salina. It is proposed that Q_B-nonreducing centers are an intermediate stage in the process of damage and repair of PS II. It is further proposed that cells regulate the inflow and outflow of centers from the Q_B-nonreducing pool to maintain a constant pool size of Q_B-nonreducing centers in the thylakoid membrane.Abbreviations Chl chlorophyll - PS photosystem - Q_A primary quinone electron acceptor of PS II - Q_B secondary quinone electron acceptor of PS II - LHC light harvesting complex - F_o non-variable fluorescence yield - F_pl intermediate fluorescence yield plateau level - F_max maximum fluorescence yield - F_i mitial fluorescence yield increase from F_o to F_pl(F_pl-F_o) - F_v total variable fluorescence yield (F_max-F_o) - DCMU dichlorophenyl-dimethylurea     

Expression, assembly and auxiliary functions of photosystem II oxygen-evolving proteins in higher plants

The oxygen-evolving complex (OEC) of higher plant photosystem II (PSII) consists of an inorganic Mn₄Ca cluster and three nuclear-encoded proteins, PsbO, PsbP and PsbQ. In this review, we focus on the assembly of these OEC proteins, and especially on the role of the small intrinsic PSII proteins and recently found “novel” PSII proteins in the assembly process. The numerous auxiliary functions suggested during the past few years for the OEC proteins will likewise be discussed. For example, besides being a manganese-stabilizing protein, PsbO has been found to bind calcium and GTP and possess a carbonic anhydrase activity. In addition, specific roles have been suggested for the two isoforms of the PsbO protein in Arabidopsis thaliana. PsbP and PsbQ seem to play an additional role in the formation of PSII supercomplexes and in grana stacking, besides their originally recognized role in providing a proper calcium and chloride ion concentration for water splitting.     

Site-directed mutagenesis of the CP 47 protein of photosystem II: 167W in the lumenally exposed loop C is required for photosystem II assembly and stability

The intrinsic chlorophyll-protein CP 47 is a component of photosystem II which functions in both light-harvesting and oxygen evolution. Using site-directed mutagenesis we have produced the mutant W167S which lies in loop C of CP 47. This strain exhibited a 75% loss in oxygen evolution activity and grew extremely slowly in the absence of glucose. Examination of normalized oxygen evolution traces indicated that the mutant was susceptible to photoinactivation. Analysis of the variable fluorescence yield indicated that the mutant accumulated very few functional PS II reaction centers. This was confirmed by immunoblotting experiments. Interestingly, when W167S was grown in the presence of 20 M DCMU, the mutant continued to exhibit these defects. These results indicate that tryptophan 167 in loop C of CP 47 is important for the assembly and stability of the PS II reaction center.     

Evidence for an association of the early light-inducible protein (ELIP) of pea with photosystem II

The precursor to the nuclear-coded 17 kDa early light-inducible protein (ELIP) of pea has been transported into isolated intact chloroplasts. The location of the mature protein in the thylakoid membranes was investigated after using cleavable crosslinkers such as DSP and SAND in conjunction with immuno-fractionation methods and by application of mild detergent fractionation. We show that ELIP is integrated into the membranes via the unstacked stroma thylakoids. After isolation of protein complexes by solubilization of membranes with Triton X-100 and sucrose density-gradient centrifugation the crosslinked ELIP comigrates with the PS II core complex. Using SAND we identified ELIP as a 41–51 kDa crosslinked product while with DSP four products of 80 kDa, 70 kDa, 50–42 kDa and 23–21 kDa were found. The immunoprecipitation data suggested that the D₁-protein of the PS II complex is one of the ELIP partners in crosslinked products.Abbreviations chl chlorophyll - D₁ herbicide-binding protein - DSP dithiobis-(succinimidylpropionate) - ELIP early light-inducible protein - LHC I and LHC II light-harvesting chlorophyll a/b complex associated with photosystem I or II - PAGE polyacrylamide gel electrophoresis - poly(A)-rich RNA polyadenyd mRNA - PS I and PS II photosystems I and II - SAND sulfosuccinimidyl 2-(m-azido-o-nitro-benzamido)-ethyl-1,3-dithiopropionate - Triton X-100 octylphenoxypolyethoxyethanol     

Phosphorylation of photosystem II core proteins prevents undesirable cleavage of D1 and contributes to the fine‐tuned repair of photosystem II

Photosystem II (PSII) is a primary target for light‐induced damage in photosynthetic protein complexes. To avoid photoinhibition, chloroplasts have evolved a repair cycle with efficient degradation of the PSII reaction center protein, D1, by the proteases FtsH and Deg. Earlier reports have described that phosphorylated D1 is a poor substrate for proteolysis, suggesting a mechanistic role for protein phosphorylation in PSII quality control, but its precise role remains elusive. STN8, a protein kinase, plays a central role in this phosphorylation process. To elucidate the relationship between phosphorylation of D1 and the protease function we assessed in this study the involvement of STN8, using Arabidopsis thaliana mutants lacking FtsH2 [yellow variegated2 (var2)] and Deg5/Deg8 (deg5 deg8). In support of our presumption we found that phosphorylation of D1 increased more in var2. Furthermore, the coexistence of var2 and stn8 was shown to recover the delay in degradation of D1, resulting in mitigation of the high vulnerability to photoinhibition of var2. Partial D1 cleavage fragments that depended on Deg proteases tended to increase, with concomitant accumulation of reactive oxygen species in the mutants lacking STN8. We inferred that the accelerated degradation of D1 in var2 stn8 presents a tradeoff in that it improved the repair of PSII but simultaneously enhanced oxidative stress. Together, these results suggest that PSII core phosphorylation prevents undesirable cleavage of D1 by Deg proteases, which causes cytotoxicity, thereby balancing efficient linear electron flow and photo‐oxidative damage. We propose that PSII core phosphorylation contributes to fine‐tuned degradation of D1.     

The Arabidopsis PsbO2 protein regulates dephosphorylation and turnover of the photosystem II reaction centre D1 protein

The extrinsic photosystem II (PSII) protein of 33 kDa (PsbO), which stabilizes the water-oxidizing complex, is represented in Arabidopsis thaliana (Arabidopsis) by two isoforms. Two T-DNA insertion mutant lines deficient in either the PsbO1 or the PsbO2 protein were retarded in growth in comparison with the wild type, while differing from each other phenotypically. Both PsbO proteins were able to support the oxygen evolution activity of PSII, although PsbO2 was less efficient than PsbO1 under photoinhibitory conditions. Prolonged high light stress led to reduced growth and fitness of the mutant lacking PsbO2 as compared with the wild type and the mutant lacking PsbO1. During a short period of treatment of detached leaves or isolated thylakoids at high light levels, inactivation of PSII electron transport in the PsbO2-deficient mutant was slowed down, and the subsequent degradation of the D1 protein was totally inhibited. The steady-state levels of in vivo phosphorylation of the PSII reaction centre proteins D1 and D2 were specifically reduced in the mutant containing only PsbO2, in comparison with the mutant containing only PsbO1 or with wild-type plants. Phosphorylation of PSII proteins in vitro proceeded similarly in thylakoid membranes from both mutants and wild-type plants. However, dephosphorylation of the D1 protein occurred much faster in the thylakoids containing only PsbO2. We conclude that the function of PsbO1 in Arabidopsis is mostly in support of PSII activity, whereas the interaction of PsbO2 with PSII regulates the turnover of the D1 protein, increasing its accessibility to the phosphatases and proteases involved in its degradation.     

Preparation of highly enriched photosystem II membrane vesicles by a non-detergent method

An improved, non-detergent, method for preparative isolation of PS II membrane vesicles from spinach chloroplasts is presented. Thylakoids (chlorophyll (Chl) a/b ratio 2.8, Chl/P700 435) were fractionated by Yeda press treatment and aqueous two-phase partition to yield inside-out vesicles (1) (chl a/b 2.2, chl/P700 700). These vesicles were subjected a sonication — phase partitioning procedure; steps of sonication of inside-out vesicles, while still present in a dextran-polyethylene glycol two-phase system were alternated by phase partition. These steps selectively removed P700-containing membrane fragments from the inside-out vesicles and yielded a membrane fraction with improved PS II purity (Chl a/b ratio 1.9, Chl/P700 1500) and retained oxygen evolving capacity (295 mol O₂ mg Chl^-1 h^-1).     

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.     

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.     

Immunological characterization of photosystem II chlorophyll-binding proteins from the cyanobacterium,Aphanocapsa 6714

Chlorophyll-binding proteins from the cyanobacteriumAphanocapsa 6714 were identified by immunoblotting procedures. Three chlorophyll-binding complexes, CPIII, CPIIIa, and CPIIIb, were associated with PSII. CPIII likely serves as an antenna to PSII inAphanocapsa since it could be removed from active PSII core preparations without loss of activity. The CPIII' proteins cross-reacted to antibodies prepared against the maize PSII light-harvesting complex, LHC-II. The CPIIIa polypeptides cross-reacted to antibodies raised against theChlamydomonas PSII chlorophyll-proteins 5 and 6, indicating that this complex contains the major chlorophyll-binding species of the cyanobacterial PSII core. Lastly, an antibody prepared against the cyanobacterial 36-kDa chlorophyll-binding protein [Pakrasi, H., Riethman, H., and Sherman, L. (1985).Proc. Natl. Acad. Sci. USA 82, 6903–6907] recognized only the 36-kDa IIIb apoprotein, indicating that CPIIIb represents a distinct chlorophyll-protein complex.