Carboxylate groups on the manganese-stabilizing protein are required for efficient binding of the 24 kDa extrinsic protein to photosystem II

The effects of the modification of carboxylate groups on the manganese-stabilizing protein on the binding of the 24 kDa extrinsic protein to Photosystem II were investigated. Carboxylate groups on the manganese-stabilizing protein were modified with glycine methyl ester in a reaction facilitated by 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide. The manganese-stabilizing protein which was modified while associated with NaCl-washed membranes could bind to calcium chloride-washed PS II membranes and reconstitute oxygen evolution in a manner similar to that observed for unmodified manganese-stabilizing protein (Frankel, L.K, Cruz, J. C. and Bricker, T. M. (1999) Biochemistry 38, 14271-14278). However, PS II membranes reconstituted with this modified protein were defective in their ability to bind the extrinsic 24 kDa protein of Photosystem II. Mapping of the sites of modification was carried out by trypsin and Staphylococcus V8 protease digestion of the modified protein and analysis by MALDI mass spectrometry. These studies indicated that the domains (1)E-(71)D, (97)D-(144)D, and (180)D-(187)E are labeled when the manganese-stabilizing protein is bound to NaCl-washed Photosystem II membranes. We hypothesize that modified carboxylates, possibly residues (1)E, (32)E, (139)E, and/or (187)E, in these domains are responsible for the altered binding affinity of the 24 kDa protein observed.     

Structural organization of proteins on the oxidizing side of photosystem II. Two molecules of the 33-kDa manganese-stabilizing proteins per reaction center.

The 33-kDa manganese-stabilizing protein stabilizes the manganese cluster in the oxygen-evolving complex. There has been, however, a considerable amount of controversy concerning the stoichiometry of this photosystem II (PS II) component. In this paper, we have verified the extinction coefficient of the manganese-stabilizing protein by amino acid analysis, determined the manganese content of oxygen-evolving photosystem II membranes and reaction center complex using inductively coupled plasma spectrometry, and determined immunologically the amount of the manganese-stabilizing protein associated with photosystem II. Oxygen-evolving photosystem II membranes and reaction center complex preparations contained 258 +/- 11 and 67 +/- 3 chlorophyll, respectively, per tetranuclear manganese cluster. Immunoquantification of the manganese-stabilizing protein using mouse polyclonal antibodies on "Western blots" demonstrated the presence of 2.1 +/- 0.2 and 2.0 +/- 0.3 molecules of the manganese-stabilizing protein/tetranuclear manganese cluster in oxygen-evolving PS II membranes and highly purified PS II reaction center complex, respectively. Since the manganese-stabilizing protein co-migrated with the D2 protein in our electrophoretic system, accurate immunoquantification required the inclusion of CaCl2-washed PS II membrane proteins or reaction center complex proteins in the manganese-stabilizing protein standards to compensate for the possible masking effect of the D2 protein on the binding of the manganese-stabilizing protein to Immobilon-P membranes. Failure to include these additional protein components in the manganese-stabilizing protein standards leads to a marked underestimation of the amount of the manganese-stabilizing protein associated with these photosystem II preparations.     

Interaction of CPa-1 with the manganese-stabilizing protein of photosystem II: identification of domains on CPa-1 which are shielded from N-hydroxysuccinimide biotinylation by the manganese-stabilizing protein.

The structural organization of photosystem II proteins has been investigated by use of the amino group-labeling reagent N-hydroxysuccinimidobiotin (NHS-biotin) and calcium chloride-washed photosystem II membranes. We have previously shown that the presence of the extrinsic, manganese-stabilizing protein on photosystem II membranes prevents the modification of lysyl residues located on the chlorophyll protein CPa-1 (CP-47) by NHS-biotin [Bricker, T. M., Odom, W. R., & Queirolo, C. B. (1988) FEBS Lett. 231, 111-117]. Upon removal of the manganese-stabilizing protein by calcium chloride-washing, CPa-1 can be specifically modified by treatment with NHS-biotin. Preparative quantities of biotinylated CPa-1 were subjected to chemical cleavage with cyanogen bromide. Two major biotinylated peptides were identified with apparent molecular masses of 11.8 and 15.7 kDa. N-terminal sequence analysis of these peptides indicated that the 11.8-kDa peptide was 232G-330M and that the 15.7-kDa peptide was 360P-508V. The 15.7-kDa CNBr peptide was subjected to limited tryptic digestion. The two smallest tryptic fragments identified migrated at apparent molecular masses of 9.1 (nonbiotinylated) and 7.5 kDa (biotinylated). N-terminal sequence analysis and examination of the predicted amino acid sequences of these peptides suggest that the 9.1-kDa fragment was 422R-508V and that the 7.5-kDa fragment was 360P-421A. These results strongly suggest that two NHS-biotinylated domains, 304K-321K and 389K-419K, become exposed on CPa-1 when the manganese-stabilizing protein is removed by CaCl2 treatment. Both of these domains lie in the large extrinsic loop E of CPa-1.     

Oxygen evolution in the absence of the 33-kilodalton manganese-stabilizing protein.

There has been a considerable amount of controversy concerning the ability of photosystem II to evolve oxygen in the absence of the 33-kDa, manganese-stabilizing protein. Early reports indicated that some capacity for oxygen evolution existed in manganese-stabilizing protein-depleted membranes while more recent studies have suggested that the observed oxygen evolution activity arose from residual manganese-stabilizing protein present in the salt-washed preparations. In this paper, it is conclusively demonstrated that significant rates of steady-state oxygen evolution are observed in oxygen-evolving photosystem II membranes in the absence of detectable quantities of the manganese-stabilizing protein. More then 99% of the manganese-stabilizing protein was removed by either one CaCl2 or two NaCl-urea washes. The amount of manganese-stabilizing protein removed was quantified immunologically using mouse polyclonal antibodies. Oxygen evolution rates of 115-140 mumol of O2 (mg of Chl)-1 h-1 were observed in the NaCl-urea-washed preparations. These rates represent about 24% of the rate observed in untreated membranes [450-600 mumol of O2 (mg of Chl)-1 h-1]. Somewhat lower, although still significant rates were observed in the CaCl2-washed preparations. Optimal rates of oxygen-evolving activity in NaCl-urea-washed membranes which are devoid of the manganese-stabilizing protein required high concentrations of calcium and chloride.     

The manganese-stabilizing protein is required for photosystem II assembly/stability and photoautotrophy in higher plants

Interfering RNA was used to suppress the expression of two genes that encode the manganese-stabilizing protein of photosystem II in Arabidopsis thaliana, MSP-1 (encoded by psbO-1, At5g66570), and MSP-2 (encoded by psbO-2, At3g50820). A phenotypic series of transgenic plants was recovered that expressed high, intermediate, and low amounts of these two manganese-stabilizing proteins. Chlorophyll fluorescence induction and decay analyses were performed. Decreasing amounts of expressed protein led to the progressive loss of variable fluorescence and a marked decrease in the fluorescence quantum yield (F(v)/F(m)) in both the absence and the presence of dichloromethylurea. This result indicated that the amount of functional photosystem II reaction centers was compromised in the plants that exhibited intermediate and low amounts of the manganese-stabilizing proteins. An analysis of the decay of the variable fluorescence in the presence of dichlorophenyldimethylurea indicated that charge recombination between Q ((A-)) and the S(2) state of the oxygen-evolving complex was seriously retarded in the plants that expressed low amounts of the manganese stabilizing proteins. This may have indicated a stabilization of the S(2) state in the absence of the extrinsic component. Immunological analysis of the photosystem II protein complement indicated that significant losses of the CP47, CP43, and D1 proteins occurred upon the loss of the manganese-stabilizing proteins. This indicated that these extrinsic proteins were required for photosystem II core assembly/stability. Additionally, although the quantity of the 24-kDa extrinsic protein was only modestly affected by the loss of the manganese-stabilizing proteins, the 17-kDa extrinsic protein dramatically decreased. The control proteins ribulose bisphosphate carboxylase and cytochrome f were not affected by the loss of the manganese-stabilizing proteins; the photosystem I PsaB protein, however, was significantly reduced in the low expressing transgenic plants. Finally, it was determined that the transgenic plants that expressed low amounts of the manganese-stabilizing proteins could not grow photoautotrophically.     

Site-directed mutagenesis of conserved C-terminal tyrosine and tryptophan residues of PsbO, the photosystem II manganese-stabilizing protein, alters its activity and fluorescence properties

The extrinsic photosystem II PsbO subunit (manganese-stabilizing protein) contains near-UV CD signals from its complement of aromatic amino acid residues (one Trp, eight Tyr, and 13 Phe residues). Acidification, N-bromosuccinimide modification of Trp, reduction or elimination of a disulfide bond, or deletion of C-terminal amino acids abolishes these signals. Site-directed mutations that substitute Phe for Trp241 and Tyr242, near the C-terminus of PsbO, were used to examine the contribution of these residues to the activity and spectral properties of the protein. Although this substitution is, in theory, conservative, neither mutant binds efficiently to PSII, even though these proteins appear to retain wild-type solution structures. Removal of six residues from the N-terminus of the W241F mutant restores activity to near-wild-type levels. The near-UV CD spectra of the mutants are modified; well-defined Tyr and Trp peaks are lost. Characterizations of the fluorescence spectra of the full-length WF and YF mutants indicate that Y242 contributes significantly to PsbO's Tyr fluorescence emission and that an excited-state tyrosinate could be present in PsbO. Deletion of W241 shows that this residue is a major contributor to PsbO's fluorescence emission. Loss of function is consistent with the proposal that a native C-terminal domain is required for PsbO binding and activity, and restoration of activity by deletion of N-terminal amino acids may provide some insights into the evolution of this important photosynthetic protein.     

Construction and characterization of cyanobacterial mutants lacking the manganese-stabilizing polypeptide of photosystem II.

Mutants of the cyanobacterium Synechocystis sp. Pasteur Culture Collection (PCC) 6803 that specifically lack the extrinsic 33-kDa manganese-stabilizing polypeptide of the photosystem II oxygen-evolving complex have been constructed by two independent methods. Cartridge mutagenesis was used to insertionally inactivate the psbO gene of one mutant and completely delete the psbO gene of the other mutant. These mutants have no detectable manganese-stabilizing polypeptide, but they do accumulate steady-state levels of the intrinsic photosystem II polypeptides D1, D2, and CP-43 that are comparable to wild-type, as determined by immunoblot analysis. Measurement of the evolution of the relative quantum yields of chlorophyll fluorescence following actinic flash excitation indicates that though the concentration of reaction centers in mutant cells is comparable to that of wild-type cells, approximately 40% of these centers harbor a fluorescence-quenching species other than P680+. The mutants are capable of photoautotrophic growth at a slower rate than that of wild-type. Under conditions of Ca2+ depletion where wild-type growth is unaffected, the mutants are unable to grow at all. The manganese-stabilizing protein, therefore, enhances the binding of Ca2+ or protects the reaction center at low Ca2+ concentrations. The mutant evolve oxygen at approximately 70% of the wild-type rate, but are completely photoinactivated by high light intensities. Our results indicate that the manganese-stabilizing polypeptide is not absolutely required for photosystem II assembly or function in cyanobacteria, but its absence does lead to an enhanced sensitivity to photoinhibition.     

The role of carboxyl groups on the chitosanase and CMCase activity of a bifunctional enzyme purified from a commercial cellulase with EDC modification

The carboxyl groups of the bifunctional cellulase–chitosanase (CCBE), purified from a commercial cellulase prepared from Trichoderma viride were modified using the water-soluble carbodiimide 1-ethyl-3-(3-dimethyl-aminopropyl) carbodiimide (EDC). The EDC modified CCBE lost 80–90% of its chitosnase activity and 20% of its carboxylmethyl cellulase (CMCase) activity; meanwhile, its conformation changed slightly, which altered the substrate binding affinity to chitosan, without affecting its binding to CMC. However, the modification did not alter the structure integrity. The dynamic analysis of modification indicated that the CCBE possessed two carboxylates essential for its chitosanase activity and one carboxyl group for its CMCase activity. One of the two carboxylates involved in chitosanase activity was deduced to be the proton donator, and the other may function for substrate recognition, while the only catalytic carboxyl group for CMCase activity probably also acted as a proton donator.     

Association of the 17-kDa extrinsic protein with photosystem II in higher plants

The structural association of the spinach 17-kDa extrinsic protein of photosystem II with other extrinsic and membrane-bound components of the photosystem was investigated by labeling the 17-kDa extrinsic protein with the amino-group-specific reagent N-hydroxysuccinimidobiotin both on intact photosystem II membranes or as a free protein in solution. After isolation of the biotinylated molecules, the modified 17-kDa proteins were allowed to rebind to photosystem II membranes which were depleted of the 17-kDa component. Differential binding of the protein biotinylated in solution compared to unmodified 17-kDa protein or 17-kDa protein modified on PS II membranes was observed. This indicated possible steric or ionic interference because of biotinylated lysyl residues present on the protein modified in solution. Biotinylated sites on the different modified 17-kDa proteins were identified by trypsin and Staphylococcus V8 protease digestion, followed by affinity chromatography enrichment of the biotinylated peptides and analysis of the peptide fragment mixture by nanospray liquid chromatography-tandem mass spectrometry. Four lysyl residues that were modified when the protein was biotinylated in solution were not biotinylated when the protein was modified on the PS II membrane (90K, 96K, 101K, and 102K). These residues appear to identify a protein domain involved in the interaction of the 17-kDa protein with the other components of the photosystem.     

N-Bromosuccinimide modification of tryptophan 241 at the C-terminus of the manganese stabilizing protein of plant photosystem II influences its structure and function

Life on earth depends upon the ability of oxygenic photosynthesis to oxidize water to molecular oxygen. This process is catalyzed by water–plastoquinone oxido-reductase complex. In addition to the photosystem II (PSII) reaction core, it includes a manganese stabilizing protein (MSP) that plays an important regulatory role in the process in plants and algae. Tryptophan 241, located at the carboxyl-terminus of the MSP, is its sole tryptophan. Modification of MSP by N-bromosuccinimide (NBS) was carried out to explore the role of Trp241 in maintaining its structure and function. Data and arguments are presented to show that it is Trp241, not other tyrosines in MSP, that is involved in the modification and changes observed in this study. Further, the pH-dependence of the modification and the comparison of features of fluorescence spectra of MSP suggested that Trp241 is buried in the hydrophobic interior of the protein. Hydropathy analysis revealed that Trp241 is located in the middle of the hydrophobic region at the C-terminus of MSP. Circular dichroism spectroscopy showed that NBS modification of Trp241 dramatically modified the protein structure. The affinity of MSP to PSII decreased greatly after the modification of Trp241, and no oxygen-evolving activity was recovered after its reconstitution. This study provides a novel demonstration that Trp241 at the C-terminus hydrophobic region of the MSP is critical for maintaining appropriate structure and function of MSP.     

Deletion Mutagenesis of the Cytochrome b559 Protein Inactivates the Reaction Center of Photosystem II

In green plant-like photosynthesis, oxygen evolution is catalyzed by a thylakoid membrane-bound protein complex, photosystem II. Cytochrome b559, a protein component of the reaction center of this complex, is absent in a genetically engineered mutant of the cyanobacterium, Synechocystis 6803 [Pakrasi, H.B., Williams, J.G.K., and Arntzen, C.J. (1988). EMBO J. 7, 325-332]. In this mutant, the genes psbE and psbF, encoding cytochrome b559, were deleted by targeted mutagenesis. Two other protein components, D1 and D2 of the photosystem II reaction center, are also absent in this mutant. However, two chlorophyll-binding proteins, CP47 and CP43, as well as a manganese-stabilizing extrinsic protein component of photosystem II are stably assembled in the thylakoids of this mutant. Thus, this deletion mutation destabilizes the reaction center of photosystem II only. The mutant also lacks a fluorescence maximum peak at 695 nm (at 77 K) even though the CP47 protein, considered to be the origin of this fluorescence peak, is present in this mutant. We propose that the fluorescence at 695 nm originates from an interaction between the reaction center of photosystem II and CP47. The deletion mutant shows the absence of variable fluorescence at room temperature, indicating that its photosystem II complex is photochemically inactive. Also, photoreduction of QA, the primary acceptor quinone in photosystem II, could not be detected in the mutant. We conclude that cytochrome b559 plays at least an essential structural role in the reaction center of photosystem II.     

Interaction of CPa-1 with the manganese-stabilizing protein of photosystem II: identification of domains cross-linked by 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide.

The structural organization of photosystem II proteins has been investigated by use of the zero-length protein cross-linking reagent 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide and monoclonal and polyclonal antibody reagents. Photosystem II membranes were treated with 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide which cross-links amino groups to carboxyl groups which are in van der Waals contact. This treatment did not affect the oxygen evolution rates of these membranes and increased the retention of oxygen evolution after CaCl2 washing. Analysis of the proteins cross-linked by this treatment indicated that two cross-linked species with apparent molecular masses of 95 and 110 kDa were formed which cross-reacted with antibodies against both the 33-kDa manganese-stabilizing protein and the chlorophyll protein CPa-1. Cleavage of the 110-kDa cross-linked species with cyanogen bromide followed by N-terminal sequence analysis was used to identify the peptide fragments of CPa-1 and the manganese-stabilizing protein which were cross-linked. Two cyanogen bromide fragments were identified with apparent molecular masses of 50 and 25 kDa. N-Terminal sequence analysis of the 50-kDa cyanogen bromide fragment indicates that this consists of the C-terminal 16.7-kDa fragment of CPa-1 and the intact manganese-stabilizing protein. This strongly suggests that the manganese-stabilizing protein is cross-linked to the large extrinsic loop domain of CPa-1. N-Terminal analysis of the 25-kDa cyanogen bromide fragment indicates that this consists of the C-terminal 16.7-kDa peptide of CPa-1 and the N-terminal 8-kDa peptide of the manganese-stabilizing protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Formation of mixed disulfide adducts at cysteine-281 of the lactose repressor protein affects operator and inducer binding parameters

The lactose repressor protein has been modified with three sulfhydryl-specific reagents which form mixed disulfide adducts. Methyl methanethiosulfonate (MMTS) and 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) completely reacted with all three cysteine residues, whereas only partial reaction was observed with didansylcystine. Cysteines-107 and -140 reacted stoichiometrically with MMTS and DTNB, while Cys-281 was modified only at higher molar ratios. Didansylcystine reacted primarily with cysteines-107 and -140. Affinity of MMTS-modified repressor for 40 base pair operator DNA was decreased 30-fold compared to unmodified repressor, and this decrease correlated with modification of cysteine-281. DTNB-modified repressor bound operator DNA with a 50-fold weaker affinity than unmodified repressor. Modification of the lac repressor with didanylcystine decreased operator binding only 4-fold, and nonspecific DNA binding increased 3-fold compared to unmodified repressor. No change in the inducer equilibrium binding constant was observed following modification with any of these reagents. In contrast, inducer association and dissociation rate constants were decreased approximately 50-fold for repressor completely modified with MMTS or DTNB, while didansylcystine had minimal effect on inducer binding kinetics. Correlation between modification of Cys-281 and the observed decrease in rate constants indicates that this region of the protein regulates the accessibility of the sugar binding site. The parallel between the increase in the Kd for repressor binding to operator, the altered rate constant for inducer binding, and modification of cysteine-281 suggests that this region of the protein is crucially involved in the function of the repressor protein.     

The double mutation ΔL6MW241F in PsbO, the photosystem II manganese stabilizing protein, yields insights into the evolution of its structure and function

The W241F mutation in spinach manganese-stabilizing protein (PsbO) decreases binding to photosystem II (PSII); its thermostability is increased and reconstituted activity is lower [Wyman et al. (2008) Biochemistry 47, 6490-6498]. The results reported here show that W241F cannot adopt a normal solution structure and fails to reconstitute efficient Cl⁻ retention by PSII. An N-terminal truncation of W241F, producing the ΔL6MW241F double mutant that resembles some features of cyanobacterial PsbO, significantly repairs the defects in W241F. Our data suggest that the C-terminal F → W mutation likely evolved in higher plants and green algae in order to preserve proper PsbO folding and PSII binding and assembly, which promotes efficient Cl⁻ retention in the oxygen-evolving complex.     

Inorganic cofactor stabilization and retention: the unique functions of the two PsbO subunits of eukaryotic photosystem II

Eukaryotic PsbO, the photosystem II (PSII) manganese-stabilizing protein, has two N-terminal sequences that are required for binding of two copies of the protein to PSII [Popelkova, H., et al. (2002) Biochemistry 41, 10038-10045; Popelkova, H., et al. (2003) Biochemistry 42, 6193-6200]. In the work reported here, a set of selected N-terminal truncation mutants of PsbO that affect subunit binding to PSII were used to determine the effects of PsbO stoichiometry on the Mn, Ca(2+), and Cl(-) cofactors and to characterize the roles of each of the PsbO subunits in PSII function. Results of the experiments with the PsbO-depleted PSII membranes reconstituted with the PsbO deletion mutants showed that the presence of PsbO does not affect Ca(2+) retention by PSII in steady-state assays of activity, nor is it required for Ca(2+) to protect the Mn cluster against reductive inhibition in darkness. In contrast to the results with Ca(2+), PsbO increases the affinity of Cl(-) for the active site of the O(2)-evolving complex (OEC) as expected. These results together with other data on activity retention suggest that PsbO can stabilize the Mn cluster by facilitating retention of Cl(-) in the OEC. The data presented here indicate that each of two copies of PsbO has a distinctive function in PSII. Binding of the first PsbO subunit fully stabilizes the Mn cluster and enhances Cl(-) retention, while binding of the second subunit optimizes Cl(-) retention, which in turn maximizes O(2) evolution activity. Nonspecific binding of some PsbO truncation mutants to PSII has no functional significance.     

Age dependent alterations in photosystem II acceptor side in Cucumis sativus cotyledonary leaf thylakoids: analysis of binding characteristics of herbicide [14C]-atrazine.

Senescence induced temporal changes in photosystems can be conveniently studied in cotyledonary leaves. We monitored the protein, chlorophyll and electron transport activities in Cucumis sativus cv Poinsette cotyledonary leaves and observed that by 20th day, there was a 50%, 41% and 30-33% decline in the chlorophyll, protein and photosystem II activity respectively when compared to 6th day cotyledonary leaves taken as control. We investigated the changes in photosystem II activity (O2 evolution) as a function of light intensity. The photosystem II functional antenna decreased by 27% and the functional photosystem II units decreased by 30% in 20-day old cotyledonary leaf thylakoids. The herbicide [14C]-atrazine binding assay to monitor specific binding of the herbicide to the acceptor side of photosystem II reaction centre protein, D1, showed an increase in the affinity for atrazine towards D1 protein and decrease in the QB binding sites in 20th day leaf thylakoids when compared to 6th day leaf thylakoids. The western blot analysis also suggested a decrease in steady state levels of D1 protein in 20th day cotyledonary leaf thylakoids as compared to 6th day sample which is in agreement with [14C]-atrazine binding assay and light saturation kinetics.     

Interaction of cytochrome c with cytochrome c oxidase studied by monoclonal antibodies and a protein modifying reagent.

C/57 black mice were immunized with beef heart cytochrome c oxidase, generating 48 hybrid cell lines that secrete antibodies against the different subunits of the enzyme. Immunoblot analysis showed reactions with 7 of the 13 subunits. Among the monoclonal antibodies produced, only those to subunit II gave significant inhibition; these inhibited the enzyme activity completely and prevented cytochrome c binding to the enzyme. Epitope mapping studies indicate that a peptide including residues 200-227 reacts with the antibody, suggesting that the C-terminus of the protein is essential for the binding of this antibody. The carboxyl modifying reagent 1-ethyl-3-[3-(trimethylammonio)propyl]carbodiimide (ETC) was chosen to investigate further the relationship between antibody and cytochrome c binding domains. ETC caused 50% inhibition of the enzyme activity with a first-order time during the first 20 min; a slower reaction over 3 h resulted in 90% inhibition. Cytochrome c binding to the oxidase was inhibited to a similar extent as cytochrome c oxidation, and protection against both effects was afforded by the presence of cytochrome c during ETC modification. Anion-exchange of FPLC of the modified forms of cytochrome oxidase revealed extensive inhomogeneity, indicating random derivatization of a number of different carboxyls even during the first-order reaction, and precluding identification of carboxyl residues related to a specific phase of the reaction. Cytochrome c and the subunit II-specific antibody protected against radioactive labeling of subunit II by ETC in the presence of [14C]glycine ethyl ester, demonstrating that the antibody and cytochrome c occupy significant and overlapping areas on the subunit II surface.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutagenesis of basic residues R151 and R161 in manganese-stabilizing protein of photosystem II causes inefficient binding of chloride to the oxygen-evolving complex

Manganese-stabilizing protein of photosystem II, an intrinsically disordered polypeptide, contains a high ratio of charged to hydrophobic amino acid residues. Arg151 and Arg161 are conserved in all known MSP sequences. To examine the role of these basic residues in MSP structure and function, three mutants of spinach MSP, R151G, R151D, and R161G, were produced. Here, we present evidence that replacement of Arg151 or Arg161 yields proteins that have lower PSII binding affinity, and are functionally deficient even though about 2 mol of mutant MSP/mol PSII can be rebound to MSP depleted PSII membranes. R161G reconstitutes O(2) evolution activity to 40% of the control, while R151G and R151D reconstitute only 20% of the control activity. Spectroscopic and biochemical techniques fail to detect significant changes in solution structure. More extensive O(2) evolution assays revealed that the Mn cluster is stable in samples reconstituted with each mutated MSP, and that all three Arg mutants have the same ability to retain Ca(2+) as the wild-type protein. Activity assays exploring the effect of these mutations on retention of Cl(-), however, showed that the R151G, R151D, and R161G MSPs are defective in Cl(-) binding to the OEC. The mutants have Cl(-) K(M) values that are about four (R161G) or six times (R151G and R151D) higher than the value for the wild-type protein. The results reported here suggest that conserved positive charges on the manganese-stabilizing protein play a role in proper functional assembly of the protein into PSII, and, consequently, in retention of Cl(-) by the O(2)-evolving complex.     

Binding of Lipoic Acid Induces Conformational Change and Appearance of a New Binding Site in Methylglyoxal Modified Serum Albumin

The binding of lipoic acid (LA), to methylglyoxal (MG) modified BSA was studied using isothermal titration calorimetry in combination with enzyme kinetics and molecular modelling. The binding of LA to BSA was sequential with two sites, one with higher binding constant and another comparatively lower. In contrast the modified protein showed three sequential binding sites with a reduction in affinity at the high affinity binding site by a factor of 10. CD results show appreciable changes in conformation of the modified protein as a result of binding to LA. The inhibition of esterase like activity of BSA by LA revealed that it binds to site II in domain III of BSA. The pH dependence of esterase activity of native BSA indicated a catalytic group with a pK(a) = 7.9 +/- 0.1, assigned to Tyr411 with the conjugate base stabilised by interaction with Arg410. Upon modification by MG, this pK(a) increased to 8.13. A complex obtained by docking of LA to BSA and BSA in which Arg410 is modified to hydroimidazolone showed that the long hydrocarbon chain of lipoic acid sits in a cavity different from the one observed for unmodified BSA. The molecular electrostatic potential showed that the modification of Arg410 reduced the positive electrostatic potential around the protein-binding site. Thus it can be concluded that the modification of BSA by MG resulted in altered ligand binding characteristics due to changes in the internal geometry and electrostatic potential at the binding site.     

An activated glutamate residue identified in photosystem II at the interface between the manganese-stabilizing subunit and the D2 polypeptide

Photosystem II (PSII) catalyzes the oxidation of water during oxygenic photosynthesis. PSII is composed both of intrinsic subunits, such as D1, D2, and CP47, and extrinsic subunits, such as the manganese-stabilizing subunit (MSP). Previous work has shown that amines covalently bind to amino acid residues in the CP47, D1, and D2 subunits of plant and cyanobacterial PSII, and that these covalent reactions are prevented by the addition of chloride in plant preparations depleted of the 18- and 24-kDa extrinsic subunits. It has been proposed that these reactive groups are carbonyl-containing, post-translationally modified amino acid side chains (Ouellette, A. J. A., Anderson, L. B., and Barry, B. A. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 2204-2209 and Anderson, L. B., Ouellette, A. J. A., and Barry, B. A. (2000) J. Biol. Chem. 275, 4920-4927). To identify the amino acid binding site in the spinach D2 subunit, we have employed a biotin-amine labeling reagent, which can be used in conjunction with avidin affinity chromatography to purify biotinylated peptides from the PSII complex. Multidimensional chromato-graphic separation and multistage mass spectrometry localizes a novel post-translational modification in the D2 subunit to glutamate 303. We propose that this glutamate is activated for amine reaction by post-translational modification. Because the modified glutamate is located at a contact site between the D2 and manganese-stabilizing subunits, we suggest that the modification is important in vivo in stabilizing the interaction between these two PSII subunits. Consistent with this conclusion, mutations at the modified glutamate alter the steady-state rate of photosynthetic oxygen evolution.