Characterization of Three Photosystem II Mutants in Zea mays L. Lacking a 32,000 Dalton Lamellar Polypeptide

Two fully blocked and one partially blocked photosystem II nuclear mutants have been selected in Zea mays. The fully blocked mutants lack photosystem II activity, variable fluorescence, the light-inducible C-550 signal, the high potential form of cytochrome b-559, and most or all of the low potential form of the cytochrome. The block in these mutants may primarily affect the reducing side of photosystem II, inasmuch as chloroplasts isolated from both mutants exhibit an elevated F695 fluorescence emission peak. The partially blocked mutant exhibits partial photosystem II activity and a reduction, but not the total loss of the variable fluorescence yield, the C-550 signal, and the high potential form of cytochrome b-559. Lamellae isolated from the fully blocked mutants are greatly deficient for a major lamellar polypeptide with an apparent molecular weight of 32,000 daltons, whereas lamellae from the partially blocked mutant show the partial loss of this same polypeptide, suggesting that the 32,000 dalton polypeptide is necessary for the proper function of photosystem II.     

Detection of a Precursor Polypeptide of the Rapidly-Synthesized 32,000-Dalton Thylakoid Protein in Spinach Chloroplasts

Spinach chloroplast RNA was translated in a wheat germ cell-freesystem in the presence of [³⁵S]methionine or [³H]lysine, andthe products were analyzed by SDS polyacrylamide gel electrophoresisand fluorography. A polypeptide with molecular mass of 2,000-Dalarger than the 32,000-Da thylakoid protein was detected asa major product labeled by [³⁵S]methionine but not by [³H]lysine.Peptide mapping of this polypeptide showed a pattern very closeto that of the 32,000-Da protein synthesized in isolated chloroplasts.A better separation of this polypeptide from the 32,000-Da proteinwas observed in the electrophoresis on polyacrylamide gel includingurea at 8 M. Pulse-labeling of the isolated chloroplasts showedthe occurrence of the larger molecular weight form, which wasconverted to the mature size by a chasing incubation with coldmethionine. These results suggested that the 32,000-Da proteinof spinach is translated primarily as a high molecular weightprecursor in the chloroplasts, as has been reported for otherplant species. (Received March 30, 1985; Accepted April 23, 1985)     

Subunit Organization of a Synechocystis Hetero-Oligomeric Thylakoid FtsH Complex Involved in Photosystem II Repair

FtsH metalloproteases are key components of the photosystem II (PSII) repair cycle, which operates to maintain photosynthetic activity in the light. Despite their physiological importance, the structure and subunit composition of thylakoid FtsH complexes remain uncertain. Mutagenesis has previously revealed that the four FtsH homologs encoded by the cyanobacterium Synechocystis sp PCC 6803 are functionally different: FtsH1 and FtsH3 are required for cell viability, whereas FtsH2 and FtsH4 are dispensable. To gain insights into FtsH2, which is involved in selective D1 protein degradation during PSII repair, we used a strain of Synechocystis 6803 expressing a glutathione S-transferase (GST)–tagged derivative (FtsH2-GST) to isolate FtsH2-containing complexes. Biochemical analysis revealed that FtsH2-GST forms a hetero-oligomeric complex with FtsH3. FtsH2 also interacts with FtsH3 in the wild-type strain, and a mutant depleted in FtsH3, like ftsH2⁻ mutants, displays impaired D1 degradation. FtsH3 also forms a separate heterocomplex with FtsH1, thus explaining why FtsH3 is more important than FtsH2 for cell viability. We investigated the structure of the isolated FtsH2-GST/FtsH3 complex using transmission electron microscopy and single-particle analysis. The three-dimensional structural model obtained at a resolution of 26 Å revealed that the complex is hexameric and consists of alternating FtsH2/FtsH3 subunits.     

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.     

A chloroplast membrane lacking Photosystem II. Thylakoid stacking in the absence of the Photosystem II particle

The polypeptide composition and membrane structure of a variegated mutant of tobacco have been investigated. The pale green mutant leaf regions contain chloroplasts in which the amount of membrane stacking has been reduced (although not totally eliminated). The mutant membranes are almost totally deficient in Photosystem II when compared to wild-type chloroplast membranes, but still show near-normal levels of Photosystem I activity. The pattern of membrane polypeptides separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows several differences between mutant and wild-type membranes, although the major chlorophyll-protein complexes described in many other plant species are present in both mutant and wild-type samples. Freeze-fracture analysis of the internal structure of these photosynthetic membranes shows that the Photosystem II-deficient membranes lack the characteristic large particle associated with the E fracture face of the thylakoid. These membranes also lack a tetramer-like particle visible on the inner (ES) surface of the membrane. The other characteristics of the photosynthetic membrane, including the small particles observed on the P fracture faces in both stacked and unstacked regions, and the characteristic changes in the background matrix of the E fracture face which accompany thylakoid stacking, are unaltered in the mutant. From these and other observations we conclude that the large (EF and ES) particle represents an amalgam of many components comprising the Photosystem II reaction complex, that the absence of one or more of its components may prevent the structure from assembling, and that in its absence, Photosystem II activity cannot be observed.     

Developmental Loss of Photosystem II Activity and Structure in a Chloroplast-Encoded Tobacco Mutant, Lutescens-1

Lutescens-1, a tobacco mutant with a maternally inherited dysfunction, displayed an unusual developmental phenotype. In vivo measurement of chlorophyll fluorescence revealed deterioration in photosystem II (PSII) function as leaves expanded. Analysis of thylakoid membrane proteins by polyacrylamide gel electrophoresis indicated the physical loss of nuclear- and chloroplast-encoded polypeptides comprising the PSII core complex concomitant with loss of activity. Freeze fracture electron micrographs of mutant thylakoids showed a reduced density, compared to wild type, of the EF_s particles which have been shown previously to be the structural entity containing PSII core complexes and associated pigment-proteins. The selective loss of PSII cores from thylakoids resulted in a higher ratio of antenna chlorophyll to reaction centers and an altered 77 K chlorophyll fluorescence emission spectra; these data are interpreted to indicate functional isolation of light-harvesting chlorophyll a/b complexes in the absence of PSII centers. Examination of PSII reaction centers (which were present at lower levels in mutant membranes) by monitoring the light-dependent phosphorylation of PSII polypeptides and flash-induced O₂ evolution patterns demonstrated that the PSII cores which were assembled in mutant thylakoids were functionally identical to those of wild type. We conclude that the lutescens-1 mutation affected the correct stoichiometry of PSII centers, in relation to other membrane constituents, by disrupting the proper assembly and maintenance of PSII complexes in lutescens-1 thylakoid membranes.     

Thylakoid membrane protein phosphorylation leads to a decrease in connectivity between Photosystem II reaction centers

The room-temperature fluorescence induction transients from stroma-free chloroplast membranes (in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea) have been analyzed to determine the effects of membrane protein phosphorylation on the connectivity between Photosystem (PS) II centers. Chloroplast membranes which have been incubated in the light with ATP exhibit: (1) a decrease in the variable fluorescence as a function of the initial fluorescence, (2) a shift from a sigmoidal to an exponential fluorescence induction curve, and (3) a reduced amount of the fast () component of the induction transient. These phenomenona are completely reversible by dark incubation of the samples (leading to protein dephosphorylation). We conclude that connectivity between PS II centers is reduced as a function of thylakoid membrane protein phosphorylation. This may in turn be the mechanism which increases the amount of absorbed excitation energy available to PS I.     

Characterization of a 47-Kilodalton Chlorophyll-Binding Polypeptide (CP-47) Isolated from a Photosystem II Core Complex

The purified photosystem II core complex from spinach with aparticle size of about 480 kDa and containing five constituentpolypeptides was further resolved by octyl-rß-D-glucopyranosidetreatment followed by separation by high-performance liquidchromatography using a gel-permeation column. Of the four clearlyseparated, chlorophyll-containing fractions, one with a particlesize of 170–180 kDa was composed entirely of a single,47-kDa polypeptide. This chlorophyll a-polypeptide containsrß-carotene and pheophytin a, but no plastoquinone.The number of chlorophyll a associated with this polypeptidein situ was estimated to be 6–7 and an oligomeric structureof this polypeptide in vivo was proposed on the basis of itschlorophyll/protein ratio and the isolated particle size. Thecomplex exhibited F-695 emission, but was photochemically inactive.The amino acid composition of the apoprotein was also determined. (Received March 12, 1984; Accepted June 7, 1984)     

Functional Analyses of the Plant Photosystem I-Light-Harvesting Complex II Supercomplex Reveal That Light-Harvesting Complex II Loosely Bound to Photosystem II Is a Very Efficient Antenna for Photosystem I in State II

State transitions are an important photosynthetic short-term response that allows energy distribution balancing between photosystems I (PSI) and II (PSII). In plants when PSII is preferentially excited compared with PSI (State II), part of the major light-harvesting complex LHCII migrates to PSI to form a PSI-LHCII supercomplex. So far, little is known about this complex, mainly due to purification problems. Here, a stable PSI-LHCII supercomplex is purified from Arabidopsis thaliana and maize (Zea mays) plants. It is demonstrated that LHCIIs loosely bound to PSII in State I are the trimers mainly involved in state transitions and become strongly bound to PSI in State II. Specific Lhcb1-3 isoforms are differently represented in the mobile LHCII compared with S and M trimers. Fluorescence analyses indicate that excitation energy migration from mobile LHCII to PSI is rapid and efficient, and the quantum yield of photochemical conversion of PSI-LHCII is substantially unaffected with respect to PSI, despite a sizable increase of the antenna size. An updated PSI-LHCII structural model suggests that the low-energy chlorophylls 611 and 612 in LHCII interact with the chlorophyll 11145 at the interface of PSI. In contrast with the common opinion, we suggest that the mobile pool of LHCII may be considered an intimate part of the PSI antenna system that is displaced to PSII in State I.     

Carbon Dioxide-Induced Oscillations in Fluorescence and Photosynthesis: Role of Thylakoid Membrane Energization in Regulation of Photosystem II Activity

The response of CO₂ fixation to a sudden increase in ambient CO₂ concentration has been investigated in intact leaf tissue from spinach (Spinacia oleracea) using a dual channel infrared gas analyzer. Simultaneous with these measurements, changes in fluorescence emission associated with a weak, modulated measuring beam were recorded. Application of brief (2-3 seconds) dark intervals enabled estimation of the dark fluorescence level (F_o) under both steady state and transient conditions. The degree of suppression of F_o level fluorescence in the light was strongly correlated with nonphotochemical quenching under all conditions. During CO₂-induced oscillations in photosynthesis under 2% O₂ the changes in nonphotochemical quenching anticipate changes in the rate of uptake of CO₂. At such low levels of O₂ and constant illumination, changes in the relative quantum efficiency of open photosystem II units were estimated as the ratio of the rate of CO₂ uptake and the photochemical quenching coefficient. Under the same conditions the relative quantum efficiency of photosystem II was found to vary inversely with the degree of nonphotochemical quenching. The relationship between changes in the rate of CO₂ uptake: photochemical quenching coefficient and nonphotochemical quenching was altered somewhat when the same experiment was conducted under 20% O₂. The results suggest that electron transport coupled to reduction of O₂ occurs to varying degrees with time during oscillations, especially when ambient O₂ concentrations are high.     

PHOTOSYSTEM II PROTEIN33, a Protein Conserved in the Plastid Lineage,Is Associated with the Chloroplast Thylakoid Membrane and Provides Stability to Photosystem II Supercomplexes in Arabidopsis

Photosystem II (PSII) is a multiprotein complex that catalyzes the light-driven water-splitting reactions of oxygenic photosynthesis. Light absorption by PSII leads to the production of excited states and reactive oxygen species that can cause damage to this complex. Here, we describe Arabidopsis (Arabidopsis thaliana) At1g71500, which encodes a previously uncharacterized protein that is a PSII auxiliary core protein and hence is named PHOTOSYSTEM II PROTEIN33 (PSB33). We present evidence that PSB33 functions in the maintenance of PSII-light-harvesting complex II (LHCII) supercomplex organization. PSB33 encodes a protein with a chloroplast transit peptide and one transmembrane segment. In silico analysis of PSB33 revealed a light-harvesting complex-binding motif within the transmembrane segment and a large surface-exposed head domain. Biochemical analysis of PSII complexes further indicates that PSB33 is an integral membrane protein located in the vicinity of LHCII and the PSII CP43 reaction center protein. Phenotypic characterization of mutants lacking PSB33 revealed reduced amounts of PSII-LHCII supercomplexes, very low state transition, and a lower capacity for nonphotochemical quenching, leading to increased photosensitivity in the mutant plants under light stress. Taken together, these results suggest a role for PSB33 in regulating and optimizing photosynthesis in response to changing light levels.PSII is a multiprotein complex in plants with 31 identified polypeptides (Wegener et al., 2011; Pagliano et al., 2013). It is associated with an extrinsic trimeric light-harvesting complex (LHC), forming the PSII-LHCII supercomplex. The PSII complex performs a remarkable biochemical reaction, the oxidation of water using light energy from the sun, which profoundly contributes to the overall biomass accumulation in the biosphere (Barber et al., 2004). Consequently, the stability and functional integrity of the PSII-LHCII supercomplex is crucially important for photosynthetic function. The energy of a photon, either absorbed directly by PSII or indirectly via energy transfer from adjacent antenna chlorophyll (Chl) molecules, excites the PSII reaction center P680. The excited state, P680*, can transfer an electron to pheophytin, producing the most powerful oxidant known in biology, P680⁺, which can remove electrons from water. Excessive input of excitation energy into PSII saturates the electron transfer system and causes either acceptor or donor site limitation in the complex. This results in increased production of reactive oxygen species (ROS): singlet oxygen at the PSII donor side and superoxide at the acceptor side (Munné-Bosch et al., 2013). Several protective mechanisms have been documented that decrease the production of singlet oxygen at the PSII donor side in photosynthetic eukaryotes. Notably, reducing energy transfer from LHC to PSII via nonphotochemical quenching (NPQ) is a key avoidance mechanism (Ruban and Murchie, 2012).Despite years of intensive study of PSII structure and function, new proteins that are associated with the PSII complex continue to be discovered, including an increasing number involved in the stability and organization of PSII-LHCII supercomplexes (García-Cerdán et al., 2011; Lu et al., 2011a; Wegener et al., 2011). Two complementary approaches (Merchant et al., 2007; Lu et al., 2008, 2011b; Ajjawi et al., 2010) that utilize phylogenomics (GreenCut) and large-scale phenotypic mutant screening (Chloroplast 2010 Project; http://www.plastid.msu.edu/) were employed by our groups to discover novel plant proteins with roles in photosynthesis. GreenCut identifies proteins found only in photosynthetic organisms, and it is likely that many of them are involved in biochemical processes associated with the structure, assembly, or function of the photosynthetic apparatus and the chloroplast that houses it (Merchant et al., 2007; Karpowicz et al., 2011). The Chloroplast 2010 Project was a large-scale reverse-genetic mutant screen in which thousands of homozygous Arabidopsis (Arabidopsis thaliana) transfer DNA (T-DNA) insertion lines were analyzed for defects in the rise and decay kinetics of Chl fluorescence (Lu et al., 2008, 2011a, 2011b; Ajjawi et al., 2010).The GreenCut and Chloroplast 2010 approaches both identified the Arabidopsis At1g71500 locus as encoding a protein of unknown function with potential relevance to photosynthesis. In this work, we demonstrate that plant lines carrying three independent mutations at this locus display severe light-induced photoinhibition due to a less stable supramolecular organization of PSII. Biochemical analyses revealed that this protein is associated with PSII complexes, and since the last described PSII protein was called PHOTOSYSTEM II PROTEIN32 (PSB32), we named the gene PSB33. The nuclear genome-encoded PSB33 is predicted to have a chloroplast transit peptide and a transmembrane domain. The biochemical analyses presented below indicate that PSB33 is required for the proper interaction and stability of PSII-LHCII supercomplexes and, in turn, in regulating photosynthesis in response to fluctuating light levels.     

Thylakoid Membrane Reduction Affects the Photosystem Stoichiometry in the Cyanobacterium Synechocystis sp. PCC 6803

Biogenesis of thylakoid membranes in both chloroplasts and cyanobacteria is largely not understood today. The vesicle-inducing protein in plastids 1 (Vipp1) has been suggested to be essential for thylakoid membrane formation in Arabidopsis (Arabidopsis thaliana), as well as in the cyanobacterium Synechocystis sp. PCC 6803, although its exact physiological function remains elusive so far. Here, we report that, upon depletion of Vipp1 in Synechocystis cells, the number of thylakoid layers in individual Synechocystis cells decreased, and that, in particular, the content of photosystem I (PSI) complexes was highly diminished in thylakoids. Furthermore, separation of native photosynthetic complexes indicated that PSI trimers are destabilized and the monomeric species is enriched. Therefore, depletion of thylakoid membranes specifically affects biogenesis and/or stabilization of PSI in cyanobacteria.In chloroplasts and cyanobacteria the energy transfer between PSI and PSII is regulated in a light-dependent manner (for a recent review, see Kramer et al., 2004). The two photosystems are connected by the cytochrome b₆f complex, and electron transfer from PSII via the cytochrome b₆f complex to PSI is believed to be regulated by the redox state of the plastoquinol pool potentially also involving the cytochrome b₆f complex (Fujita et al., 1987; Murakami and Fujita, 1993; Schneider et al., 2001, 2004; Pfannschmidt, 2003; Volkmer et al., 2007). Transfer of light energy to the two photosystems is mediated by light-harvesting complexes, and in cyanobacteria light is harvested by the soluble extramembranous phycobilisomes. The efficient energy transfer to PSI and PSII has to be balanced to synchronize the function of the two photosystems. In response to changing light intensities and qualities, energy coupling between the phycobilisomes and the photosystems changes, which allows a rapid adjustment of light absorbance by the individual photosystems. Furthermore, besides this short-term adaptation mechanism, it has been shown in many studies that on a longer term in cyanobacteria the ratio of the two photosystems changes depending on the light conditions (Manodori and Melis, 1986; Murakami and Fujita, 1993; Murakami et al., 1997). Upon shifting cyanobacterial cells from low-light to high-light growth conditions, the PSI-to-PSII ratio decreases due to selective suppression of the amount of functional PSI. In recent years, some genes have already been identified that are involved in this regulation of the photosystem stoichiometry (Hihara et al., 1998; Sonoike et al., 2001; Fujimori et al., 2005; Ozaki et al., 2007).Whereas in chloroplasts of higher plants and green algae the amounts of the two photosystems change in response to changing light conditions (Melis, 1984; Chow et al., 1990; Smith et al., 1990; Kim et al., 1993), it has already been noted a long time ago that the chloroplast ultrastructure also adapts to high-light and low-light conditions (Melis, 1984). Chloroplasts of plants grown under low light or far-red light have more thylakoid membranes than chloroplasts of plants grown under high light or blue light (Anderson et al., 1973; Lichtenthaler et al., 1981; Melis and Harvey, 1981). There appears to be a direct correlation between the chlorophyll content and the amount of thylakoids per chloroplast because light harvesting is increased by enhanced chlorophyll and thylakoid membrane content per chloroplast. Thus, chloroplasts adapt to high light both by a reduction of thylakoid membranes and by a decrease in the PSI-to-PSII ratio.Thylakoid membranes are exclusive features of both cyanobacteria and chloroplasts, and it still remains mysterious how formation of thylakoid membranes is organized. Many cellular processes, like lipid biosynthesis, membrane formation, protein synthesis in the cytoplasm and/or at a membrane, protein transport, protein translocation, and protein folding have to be organized and aligned for formation of internal thylakoid membranes. The recent observation that deletion of the vipp1 gene in Arabidopsis (Arabidopsis thaliana) results in complete loss of thylakoid membranes has indicated that Vipp1 is involved in biogenesis of thylakoid membranes. Further analysis has suggested that Vipp1 could be involved in vesicle trafficking between the inner envelope and the thylakoid membrane of chloroplasts (Kroll et al., 2001). Because of this, the protein was named Vipp1, for vesicle-inducing protein in plastids 1. Depletion of Vipp1 strongly affected the ability of cyanobacterial cells to form proper thylakoid membranes (Westphal et al., 2001) and, consequently, also in cyanobacteria Vipp1 appears to be involved in formation of thylakoid membranes. A Vipp1 depletion strain of Arabidopsis is deficient in photosynthesis, although the defect could not be assigned to a deficiency of a single photosynthetic complex, but appeared to be caused by dysfunction of the entire photosynthetic electron transfer chain (Kroll et al., 2001). Therefore, depletion of Vipp1 in Arabidopsis seems to affect thylakoid membrane formation rather than the assembly of thylakoid membrane protein complexes (Aseeva et al., 2007). However, for cyanobacteria, it is not clear yet how diminishing the amount of thylakoid membrane layers would affect the amount and stoichiometry of the two photosystems.Here, we present the generation and characterization of a Vipp1 depletion strain of the cyanobacterium Synechocystis sp. PCC 6803. Upon depletion of Vipp1, a decrease in thylakoid membrane pairs in the generated mutant strain and, furthermore, a significant decrease in active PSI centers was observed. Moreover, trimerization of PSI also appeared to be impaired in the mutant strain. These results suggest that thylakoid membrane perturbations caused by the Vipp1 depletion directly affects PSI assembly and stability in cyanobacterial thylakoid membranes.     

Photosystem II Complex in Vivo Is a Monomer

Photosystem II (PS II) complexes are membrane protein complexes that are composed of >20 distinct subunit proteins. Similar to many other membrane protein complexes, two PS II complexes are believed to form a homo-dimer whose molecular mass is ∼650 kDa. Contrary to this well known concept, we propose that the functional form of PS II in vivo is a monomer, based on the following observations. Deprivation of lipids caused the conversion of PS II from a monomeric form to a dimeric form. Only a monomeric PS II was detected in solubilized cyanobacterial and red algal thylakoids using blue-native polyacrylamide gel electrophoresis. Furthermore, energy transfer between PS II units, which was observed in the purified dimeric PS II, was not detected in vivo. Our proposal will lead to a re-evaluation of many crystallographic models of membrane protein complexes in terms of their oligomerization status.Photosystem II (PS II)3 complexes convert solar energy to biological redox energy. Through this reaction process, water molecules are oxidized and molecular oxygen is released as a byproduct (reviewed in Ref. 1), which is the only source of molecular oxygen upon which all aerobic organisms on earth rely. PS II core complexes are membrane protein complexes that are composed of >20 distinct subunit proteins and many functional cofactors, including chlorophylls (Chls), carotenoids, plastoquinone, and metal ions (2–5). Similar to many other membrane protein complexes (6–10), two PS II core complexes are believed to associate together to form a homo-dimer with a molecular mass of ∼650 kDa, as shown by crystallographic models (2, 3, 5).The PS II complex turns over dynamically, although it is quite an integrated complex; our current understanding is that the PS II complex that is damaged by high light is disintegrated into a monomeric form and is further dissociated to replace a degraded D1 protein with a de novo synthesized D1 (reviewed in Refs. 11 and 12). After the replacement, the PS II complex is integrated into a functional form as a dimer. It is supposed that PS II subunit proteins such as PsbI (13) or PsbTc (14) participate in the formation of the PS II dimer.Crystallographic models of PS II have enabled the determination of the accurate molecular architecture of PS II complexes, all of which are in a dimeric form. The most recent crystallographic model of the PS II dimer at 3.0-Å resolution revealed the presence of six detergent molecules located at the interface of the two monomers (5). Small structural fluctuations during the purification process might allow the invasion of those detergent molecules. However, it is also probable that the PS II complexes exist in the form of a monomer in vivo and the two distinct monomers become a dimer during the purification step incorporating detergents between their interfaces. This idea led us to investigate the actual form of PS II in vivo. Contrary to the above well known dimeric model of a functional PS II core complex, here we show that the PS II core complex functions and exists in a monomeric form in vivo.     

Involvement of Photosystem II in the ammonia metabolism of a heterotrophic cyanobacterium

Herbicides that bind specifically to Photosystem II greatly increased ammonia liberation by a heterotrophic cyanobacterium incubated with methionine sulfoximine anaerobically in light. Comparison of cells incubated under argon and nitrogen indicated that about one-half of the liberated ammonia came from endogenous sources, as well as from dinitrogen fixation. Chromatography of cell extracts revealed a light-induced, general breakdown of cellular proteins in the presence of methionine sulfoximide. Cultures grown on ammonia, and hence free of heterocysts and nitrogenase, liberated ammonia in the dark in nitrogen-free media with methionine sulfoximine and this liberation was inhibited separately by herbicides or light. A combination of light and herbicide, however, also enhanced ammonia liberation by these cells. Herbicidal Photosystem II inhibitors strongly inhibited light-induced assimilation of the ammonia analog, [¹⁴C]methylamine, by cyanobacteria. These results implicate Photosystem II directly in the ammonia metabolism of this cyanobacterium and suggest that herbicide-binding protein(s) of this system may regulate nitrogen assimilation coordinately with electron transport.     

Topography of the Protein Complexes of the Chloroplast Thylakoid Membrane : Studies of Photosystem II using Pronase Digestion and Chemical Labeling

The accessibility of various Photosystem II (PSII)-associated polypeptides to the protease pronase and the chemical modifier trinitrobenzene-sulfonic acid (TNBS) has been investigated. Three polypeptides with apparent molecular weight of 32, 21, and 16 kilodaltons, known to be associated with O₂ evolution, are all resistant to pronase digestion and TNBS labeling in intact thylakoids. All the polypeptides in the isolated PSII preparation were labeled with TNBS while a different pattern of labeling was observed when the PSII complex was isolated from TNBS-modified thylakoids. Attempts to prepare PSII particles from pronase-treated thylakoids using the Triton X-100 solubilization method were unsuccessful. Pronase-treated thylakoids were probed with antisera against the chlorophyll proteins of PSII using immunoblotting techniques. This allowed for a positive identification of proteolytic fragments from the respective proteins. The results are discussed in relation to the transmembrane organization of PSII in spinach thylakoids.     

Polypeptide composition of the purified Photosystem II pigment-protein complex from spinach

The Photosystem II pigment-protein complex, the chlorophyll α-protein comprising the reaction center of Photosystem II, was prepared from EDTA-treated spinach chloroplasts by digitonin extraction, sucrose-gradient centrifugation, DEAE-cellulose column chromatography, and isoelectrofocussing on Ampholine.The dissociated pigment-protein complex exhibits two polypeptide subunits that migrate in SDS-polyacrylamide gel with electrophoretic mobilities corresponding to molecular weights of approximately 43 000 and 27 000. The chlorophyll was always found in the free pigment zone at the completion of the electrophoresis. Heat-treatment of the sample (100°C, 90 s) for electrophoresis caused association of the two polypeptides into large aggregates. It is concluded that these two polypeptides, 43 000 and 27 000, are valid structural or functional components of Photosystem II pigment-protein complex.     

Dynamics of In Vivo Membrane Processes in Algal Thylakoids as Analyzed from Chlorophyll Fluorescence Induction using the Photosystem II and Thylakoid Models

Biophysics - The OJIPSMT pattern of chlorophyll (Chl) a fluorescence induction (FI) was obtained using Scenedesmus obliquus (Scenedesmus) microalgal cells exposed, after dark adaptation, to...     

Polypeptide composition of a Photosystem II core complex. Presence of a herbicide-binding protein

The polypeptide composition of a Photosystem II (PS II) core complex from higher plant chloroplasts has been characterized by subjecting the isolated complex to sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Two polypeptides in the 40–50 kDa size class, attributed to the chlorophyll a-binding apoproteins of PS II, were resolved when the urea concentration in the SDS-polyacrylamide gel electrophoresis was greater than 1 M. The two chlorophyll a-binding proteins were dissimilar in their primary structure based upon their different hydrolysis products on SDS-polyacrylamide gel electrophoresis following papain treatment. The core complex contained three additional polypeptides. Two polypeptides in the 30–34 kDa size class were resolved when the urea concentration in the gel system was increased to greater than 4 M. One of the polypeptides in this size class was identified as the herbicide-binding protein from azido[¹⁴C]atrazine labeling studies. The herbicide-binding protein displayed an anomalous electrophoretic migration behavior in SDS-polyacrylamide gel electrophoresis in the presence or absence of urea; its apparent molecular weight decreased when the urea concentration increased. The fifth protein component of the core complex was attributed to cytochrome b-559 which was found to consist of the ascorbate- and dithionite-reducible forms in the samples prior to SDS solubilization.