Isolation and crystallization of CP47, a Photosystem II chlorophyll binding protein. Degradation of CP47 upon dissociation from the core complex

The CP47 protein was isolated from Photosystem II membranes by using a combination of the detergents n-dodecyl-β-D-maltoside and octyl-β-D-thioglucoside. The purified CP47 was used in a series of crystallization experiments, which yielded highly reproducible hexagonal crystals. Immunoblot analysis revealed that the isolated CP47 undergoes degradation even under dim light conditions. This degradation takes place after the protein has been dissociated from the core complex. Proteolysis experiments with trypsin demonstrated that the dissociation of the CP47 from the PS II core complex results in changes that render the protein sensitive to proteolysis. This revised version was published online in June 2006 with corrections to the Cover Date.     

Partial degradation of the extrinsic 23-kDa protein of the Photosystem II complex of spinach

Chymotrypsin eliminated nine amino acid residues at the amino-terminal side of the extrinsic 23-kDa protein of the oxygen-evolving Photosystem II complex of spinach. The resultant 22-kDa fragment was able to bind to the Photosystem II complex but with lowered binding affinity. However, once the 22-kDa fragment bound to the complex, it retained most functions of the 23-kDa protein; the fragment provided a binding site for the extrinsic 18-kDa protein, preserved a tight trap for Ca²⁺ in the complex, and shifted the optimum Cl⁻ concentration for oxygen evolution from 30 to 10 mM, although it was less effective in sustaining oxygen evolution at Cl⁻ concentrations below 10 mM. These observations suggest that the elimination of nine amino acid residues at the amino-terminal region of the 23-kDa protein does not significantly alter the conformation of the protein, except for partial modification of its binding site and its interaction with Cl⁻.     

On the role of the N-terminus of the extrinsic 33 kDa protein of Photosystem II

The role of the N-terminus of the extrinsic 33 kDa protein of Photosystem II has been investigated by means of site-directed mutagenesis and cross-linking. Replacement of Asp-9 resulted in a dramatic increase in proteolytic sensitivity leading to the degradation of the protein forming a 31 kDa fragment with an undefined N-terminus. This fragment was unable to restore oxygen evolution. However, the variants of the 33 kDa protein which remained intact could reconstitute oxygen evolution as effectively as the wild-type protein. Cross-linking experiments with a water-soluble carbodiimide revealed that mutagenesis of residue D9 led to the disruption of an intramolecular salt bridge. Therefore we suggest that the N-terminus of the 33 kDa protein is necessary for maintaining the binding ability of the protein to Photosystem II but might not be involved in binding itself.     

Increased tolerance to thermal inactivation of oxygen evolution in spinach Photosystem II membranes by substitution of the extrinsic 33-kDa protein by its homologue from a thermophilic cyanobacterium

Chloroform-methanol-extractable lipids account for about 5% by weight of dry cells of the acidophilic, autotrophic, mesophilic, ferrous compound-oxidising, cell wall-less archaeon Ferroplasma acidiphilum strain Y(T), about 90% of these being contributed by phospholipids and glycophospholipids. The most abundant constituent (about 55% of total lipids) was purified by DEAE cellulose and silica gel column chromatography. By means of matrix-assisted laser desorption ionisation mass spectrometry, infrared spectroscopy, (1)H-nuclear magnetic resonance spectroscopy, and chemical degradation experiments it was established to be beta-D-glucopyranosyl caldarchaetidylglycerol, the isopranyl chains of which have a cyclopentane ring each.     

Function of the 23 kDa extrinsic protein of Photosystem II as a manganese binding protein and its role in photoactivation

The function of the extrinsic 23 kDa protein of Photosystem II (PSII) was studied with respect to Mn binding and its ability to supply Mn to PSII during photoactivation, i.e. the light-dependent assembly of the tetramanganese cluster. The extrinsic proteins and the Mn cluster were removed by TRIS treatment from PSII-enriched membrane fragments and purified by anion exchange chromatography. Room temperature EPR spectra of the purified 23 kDa protein demonstrated the presence of Mn. Photoactivation was successful with low Mn concentrations when the 23 kDa protein was present, while in its absence a higher Mn concentration was needed to reach the same level of oxygen evolution activity. In addition, the rate of photoactivation was significantly accelerated in the presence of the 23 kDa protein. It is proposed that the 23 kDa protein plays an important role in providing Mn during the process of PSII assembly and that it acquires Mn during the light-induced turnover of D1 in the PSII damage-repair cycle and delivers Mn to repaired PSII.     

Chloride binding proteins: mechanistic implications for the oxygen-evolving complex of Photosystem II

Chloride plays a key role in activating the photosynethetic oxygen-evolving complex (OEC) of Photosystem II, but the OEC is only one of many enzymes affected by this anion. Some of the mechanistic features of Cl^– involvement in water-splitting resemble those of other proteins whose structure and chemistry are known in detail. An overview of the similarities and differences between these Cl^–-binding systems is presented.The literature survey for this Minireview was, for the most part, completed in 1987.     

The structure and function of the 33 kDa extrinsic protein of Photosystem II: A critical assessment

In this review the structure and function of the 33 kDa protein of Photosystem II is examined. Significant controversies exist concerning the solution secondary structure of the protein, the location of its binding site(s) within Photosystem II, the amino acid residues of the 33 kDa protein required for binding and its stoichiometry within the photosystem. The studies which examine these topics are considered from a critical perspective. A hypothetical model of the folding of the 33 kDa extrinsic protein which is supported by site-specific labeling studies and site-directed mutagenesis experiments is presented. Additionally, the function of the protein within the photosystem is unclear. We present a hypothesis that the 33 kDa protein is involved in maintaining the chloride associated with photosynthetic oxygen evolution in close proximity to the oxygen-evolving site.     

Manganese binding to the 23 kDa extrinsic protein of Photosystem II

The recombinant form of the extrinsic 23 kDa protein (psbP) of Photosystem II (PSII) was studied with respect to its capability to bind Mn. The stoichiometry was determined to be one manganese bound per protein. A very high binding constant, K_A = 10^− 17 M^− 1, was determined by dialysis of the Mn containing protein against increasing EDTA concentration. High Field EPR spectroscopy was used to distinguish between specific symmetrically ligated Mn(II) from those non-specifically Mn(II) attached to the protein surface. Upon Mn binding PsbP exhibited fluorescence emission with maxima at 415 and 435 nm when tryptophan residues were excited. The yield of this blue fluorescence was variable from sample to sample. It was likely that different conformational states of the protein were responsible for this variability. The importance of Mn binding to PsbP in the context of photoactivation of PSII is discussed.     

Effect of the manganese complex on the binding of the extrinsic proteins (17, 23 and 33 kDa) of Photosystem II

Selective extraction-reconstitution experiments with the extrinsic Photosystem II polypeptides (33 kDa, 23 kDa and 17 kDa) have demonstrated that the manganese complex and the 33 kDa polypeptide are both necessary structural elements for the tight binding of the water soluble 17 and 23 kDa species. When the manganese complex is intact the 33 kDa protein interacts strongly with the rest of the photosynthetic complex. Destruction of the Mn-complex has two dramatic effects: i) The binding of the 33 kDa polypeptide is weaker, since it can be removed by exposure of the PS II system to 2 M NaCl, and ii) the 17 and 23 kDa species do not rebind to Mn-depleted Photosystem II membranes that retain the 33 kDa protein.Abbreviations Chl chlorophyll - HQ hydroquinone - MES 2(N-morpholino)ethanesulfonic acid - PS II Photosystem II - Tris 2-amino-2-hydroxymethylpropane-1,3-diol     

Regulation of Photosystem II core protein phosphorylation at the substrate level: Light induces exposure of the CP43 chlorophyll a protein complex to thylakoid protein kinase(s)

Light induces conformational changes in the CP43 chl-a-protein antenna complex in isolated PS II core-complexes exposing phosphorylation site(s) to PS II core-associated protein kinase(s), to added solubilized thylakoid protein kinase(s), as well as to tryptic cleavage. The substrate-activation effect is demonstrated by exposure of the PS II cores to light during the kinase assay as well as by preillumination of the PS II cores in which the endogenous kinase(s) has been inactivated by treatment with N-ethylmaleimid. In the latter case, phosphorylation was performed in darkness following addition of the solubilized protein kinase(s). The solubilized protein kinase(s) does not require light activation. The apparent molecular masses of the main protein kinase(s) associated with the PS II cores (about 31–35 kDa and 45 kDa) differ from that of the major protein kinase present in solubilized preparations obtained from spinach thylakoids (64 kDa). The light-induced exposure of CP43 increases with the light intensity in the range of 20–100 μmol photons m⁻² s⁻¹ as demonstrated by preillumination of N-ethylmaleimid treated cores followed by addition of the solubilized protein kinase(s) and performing the phosphorylation assay in darkness. This revised version was published online in June 2006 with corrections to the Cover Date.     

The unusually strong stabilizing effects of glycine betaine on the structure and function of the oxygen-evolving Photosystem II complex

Natural osmoregulatory substances (osmolytes) allow a wide variety of organisms to adjust to environments with high salt and/or low water content. In addition to their role in osmoregulation, some osmolytes protect proteins from denaturation and deactivation by, for example, elevated temperature and chaotropic compounds. A ubiquitous protein-stabilizing osmolyte is glycine betaine (N-trimethyl glycine). Its presence has been reported in bacteria, in particular cyanobacteria, in animals and in plants from higher plants to algae. In the present review we describe the experimental evidence related to the ability of glycine betaine to enhance and stabilize the oxygen-evolving activity of the Photosystem II protein complexes of higher plants and cyanobacteria. The osmolyte protects the Photosystem II complex against dissociation of the regulatory extrinsic proteins (the 18 kD, 23 kD and 33 kD proteins of higher plants and the 9 kD protein of cyanobacteria) from the intrinsic components of the Photosystem II complex, and it also stabilizes the coordination of the Mn cluster to the protein cleft. By contrast, glycine betaine has no stabilizing effect on partial photosynthetic processes that do not involve the oxygen-evolving site of the Photosystem II complex. It is suggested that glycine betaine might act, in part, as a solute that is excluded from charged surface domains of proteins and also as a contact solute at hydrophobic surface domains.     

Structural predictions on the 33 kDa extrinsic protein associated to the oxygen evolving complex of photosynthetic organisms

Modern computational methods for protein structure prediction have been used to study the structure of the 33 kDa extrinsic membrane protein, associated to the oxygen evolving complex of photosynthetic organisms. A multiple alignment of 14 sequences of this protein from cyanobacteria, algae and plants is presented. The alignment allows the identification of fully conserved residues and the recognition of one deletion and one insertion present in the plant sequences but not in cyanobacteria. A tree of similarity, deduced from pair-wise comparison and cluster analysis of the sequences, is also presented. The alignment and the consensus sequence derived are used for prediction the secondary structure of the protein. This prediction indicates that it is a mainly-beta protein (25–38% of -strands) with no more than 4% of -helix. Fold recognition by threading is applied to obtain a topological 2D model of the protein. In this model the secondary structure elements are located, including several highly conserved loops. Some of these conserved loops are suggested to be important for the binding of the 33 kDa protein to Photosystem II and for the stability of the manganese cluster. These structural predictions are in good agreement with experimental data reported by several authors.     

Chlorophyll fluorescence transients of Photosystem II membrane particles as a tool for studying photosynthetic oxygen evolution

The rise of the chlorophyll fluorescence yield of Photosystem II (PS II) membranes as induced by high-intensity actinic light comprises only two distinct phases: (1) the initial O-J increase and (2) the subsequent J-P increase. Partial inhibition of the PS II donor side by heating or washing procedures which remove peripheral PS II proteins or cofactors of the oxygen-evolving complex results in decrease of magnitude and rate of the J-P phase. The rate constant of the J-P increase is directly proportional to the steady-state rate of oxygen evolution; complete suppression of the J-P phase corresponds to full inhibition. A characteristic dip after J-level is observed only in Tris-washed or severely heated PS II membranes; manganese release correlates with appearance of the dip after J-level as verified by EPR spectroscopy. Presence of stabilizing cosolutes (glycine betaine, sucrose) or addition of donor-side cofactors (bicarbonate, chloride, calcium) to PS II membranes before heating (47 °C, 5 min) diminishes J-P phase suppression and prevents dip appearance, whereas the addition after heating is without effect. In conclusion, analysis of chlorophyll fluorescence transients of PS II membranes is a potentially useful tool for investigations on photosynthetic oxygen evolution. A decreased rate of the J-P phase can be employed as a convenient indicator for partial inhibition of oxygen-evolution activity; the appearance of a dip after J-level is suggestive of manganese release. This revised version was published online in June 2006 with corrections to the Cover Date.     

Selective extraction of CP 26 and CP 29 proteins without affecting the binding of the extrinsic proteins (33, 23 and 17 kDa) and the DCMU sensitivity of a Photosystem II core complex

A highly purified oxygen evolving Photosystem II core complex was isolated from PS II membranes solubilized with the non-ionic detergent n-octyl--D-thioglucoside. The three extrinsic proteins (33, 23 and 17 kDa) were functionally bound to the PS II core complex. Selective extraction of the 22, 10 kDa, CP 26 and CP 29 proteins demonstrated that these species are not involved in the binding of the extrinsic proteins (33, 23 and 17 kDa) or the DCMU sensitivity of the Photosystem II complex.Abbreviations Chl chlorophyll - DCBQ 2,6-dichloro-p-benzoquinone - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - LHC light-harvesting complex - MES 2-(N-morpholino)ethanesulfonic acid - OGP n-octyl--d-glucoside - OTG n-octyl--d-thioglucoside - PAGE polyacrylamide gel electrophoresis - PS II Photosystem II - SDS sodium dodecyl sulfate     

The structure and function of CP47 and CP43 in Photosystem II

This Minireview presents a summary of recent investigations examining the structure and functions of the Photosystem II chlorophyll-proteins CP47 and CP43, updating our previous review which appeared in 1990 (TM Bricker, Photosynth Res 24: 1–13). Since this time, numerous studies have clarified the roles of these chlorophyll-proteins within the photosystem. Biochemical, molecular and structural studies (electron and X-ray diffraction) have demonstrated the close association of these components with the photochemical reaction center of the photosystem and with the extrinsic oxygen evolution enhancer proteins. This revised version was published online in June 2006 with corrections to the Cover Date.     

Function of the 23 kDa extrinsic protein of Photosystem II as a manganese binding protein and its role in photoactivation

The function of the extrinsic 23 kDa protein of Photosystem II (PSII) was studied with respect to Mn binding and its ability to supply Mn to PSII during photoactivation, i.e. the light-dependent assembly of the tetramanganese cluster. The extrinsic proteins and the Mn cluster were removed by TRIS treatment from PSII-enriched membrane fragments and purified by anion exchange chromatography. Room temperature EPR spectra of the purified 23 kDa protein demonstrated the presence of Mn. Photoactivation was successful with low Mn concentrations when the 23 kDa protein was present, while in its absence a higher Mn concentration was needed to reach the same level of oxygen evolution activity. In addition, the rate of photoactivation was significantly accelerated in the presence of the 23 kDa protein. It is proposed that the 23 kDa protein plays an important role in providing Mn during the process of PSII assembly and that it acquires Mn during the light-induced turnover of D1 in the PSII damage-repair cycle and delivers Mn to repaired PSII.     

Low-frequency fourier transform infrared spectroscopy of the oxygen-evolving complex in Photosystem II*

In this communication, we report our progress on the development of low-frequency Fourier transform infrared (FTIR) spectroscopic techniques to study metal-substrate and metal-ligand vibrational modes in the Photosystem II/oxygen-evolving complex (PS II/OEC). This information will provide important structural and mechanistic insight into the OEC. Strong water absorption in the low-frequency region (below 1000 cm⁻¹), a lack of suitable materials, and temperature control problems have limited previous FTIR spectroscopic studies of the OEC to higher frequencies (>1000 cm⁻¹). We have overcome these technical difficulties that have blocked access to the low-frequency region and have developed successive instruments that allow us to move deeper into the low-frequency region (down to 350 cm⁻¹), while increasing both data accumulation efficiency and S/N ratio. We have detected several low-frequency modes in the S₂/S₁spectrum that are specifically associated with these two states. Our results demonstrate the utility of FTIR techniques in accessing low-frequency modes in Photosystem II and in proteins generally. This revised version was published online in June 2006 with corrections to the Cover Date.     

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.     

Cross-reconstitution of the extrinsic proteins and Photosystem II complexes from Chlamydomonas reinhardtii and Spinacia oleracea

Cross-reconstitution of the extrinsic proteins and Photosystem II (PS II) from a green alga, Chlamydomonas reinhardtii, and a higher plant,Spinacia oleracea, was performed to clarify the differences of binding properties of the extrinsic proteins between these two species of organisms. (1) Chlamydomonas PsbP and PsbQ directly bound to Chlamydomonas PS II independent of the other extrinsic proteins but not to spinach PS II. (2) Chlamydomonas PsbP and PsbQ directly bound to the functional sites of Chlamydomonas PS II independent of the origins of PsbO, while spinach PsbP and PsbQ only bound to non-functional sites on Chlamydomonas PS II. (3) Both Chlamydomonas PsbP and spinach PsbP functionally bound to spinach PS II in the presence of spinach PsbO. (4) While Chlamydomonas PsbP functionally bound to spinach PS II in the presence of Chlamydomonas PsbO, spinach PsbP bound loosely to spinach PS II in the presence of Chlamydomonas PsbO with no concomitant restoration of oxygen evolution. (5) Chlamydomonas PsbQ bound to spinach PS II in the presence of Chlamydomonas PsbP and PsbO or spinach PsbO but not to spinach PS II in the presence of spinach PsbP and Chlamydomonas PsbO or spinach PsbO. (6) Spinach PsbQ did not bind to spinach PS II in the presence of Chlamydomonas PsbO and PsbP. On the basis of these results, we showed a simplified scheme for binding patterns of the green algal and higher plant extrinsic proteins with respective PS II.     

Molecular topology of the Photosystem II chlorophyll a binding protein,CP 43: Topology of a thylakoid membrane protein

We have used antibodies generated against synthetic peptides to determine the topology of the 43 kD chlorophyll a binding protein (CP 43) of Photosystem II. Based on the pattern of proteolytic fragments detected (on western blots) by peptide specific antibodies, a six transmembrane span topological model, with the amino and carboxyl termini located on the stromal membrane surface, is predicted. This structure is similar to that predicted for CP 47, a PS II chlorophyll a binding protein (Bricker T (1990) Photosynth Res 24: 1–13). The model is discussed in reference to the possible location of chlorophyll binding sites.This work was supported by National Institutes of Health Research Grant, GM40703 and U.S. Department of Energy Grant, DE-FG01-92ER20076 (to R.T.S.).