Regeneration of the high-affinity manganese-binding site in the reaction center of an oxygen-evolution deficient mutant of Scenedesmus by protease action

The O₂-evolution deficient mutant (LF-1) of Scenedesmus obliquus inserts an unprocessed D1 protein into the thylakoid membrane and binds less than half the wild type (WT) level of Mn. LF-1 photosystem II (PS II) membrane fragments lack that part of the high-affinity Mn²⁺-binding site found in WT membranes which may be associated with histidine residues on the D1 protein (Seibert et al. 1989 Biochim Biophys Acta 974: 185–191). Hsu et al. (1987 Biochim Biophys Acta 890: 89–96) purport that the high-affinity site (characterized by competitive inhibition of DPC-supported DCIP photoreduction by M concentrations of Mn²⁺) in Mn-extracted PS II membranes is also the binding site for Mn functional in O₂ evolution. Proteases (papain, subtilisin, and carboxypeptidase A) can be used to regenerate the high-affinity Mn²⁺-binding site in LF-1 PS II membranes but not in thylakoids. Experiments with the histidine modifier, DEPC, suggest that the regenerated high-affinity Mn²⁺-binding sites produced by either subtilisin or carboxypeptidase A treatments were the same sites observed in WT membranes. However, none of the protease treatments produced LF-1 PS II membranes that could be photoactivated. Reassessment of the processing studies of Taylor et al. (1988 FEBS Lett 237: 229–233) lead us to believe that their procedure also does not result in substantial photoactivation of LF-1 PS II membranes. We conclude that (1) the unprocessed carboxyl end of the D1 protein in LF-1 is located on the lumenal side of the PS II membrane, (2) the unprocessed fragment physically obstructs or perturbs that part of the high-affinity Mn²⁺-binding site undetectable in LF-1, and (3) the D1 protein must be processed at the time of insertion into the membrane for normal O₂-evolution function to result.Abbreviations Chl chlorophyll - DCBQ 2,6-dichloro-1,4-benzoquinone - DCIP 2,6-dichlorophenol indophenol - DEPC diethylpryocarbonate - DPC 1,5-diphenylcarbazide - HEPES 4-(2-hydroxyethyl)-1-piperazine-ethanesulfonic acid - LDS-PAGE lithium dodecylsulfate polyacrylamide gel electrophoresis - LF-1 a low-fluorescent mutant of Scenedesmus obliquus - MES 4-morpholineethanesulfonic acid - PS II photosystem II - PMSF phenylmethylsulfonyl fluoride - RC photosystem II reaction center - Tris tris(hydroxymethyl)aminomethane - WT wild type Operated by the Midwest Research Institute for the U.S. Department of Energy under contract DE-AC-02-83CH10093.     

Protease treatments of photosystem II membrane fragments reveal that there are four separate high-affinity Mn-binding sites

The "high-affinity Mn-binding site" in Mn-depleted photosystem II (PS II) membrane fragments isolated from Scenedesmus obliquus was examined by using the diphenylcarbazide (DPC)/Mn2+ non-competitive inhibition assay [Preston, C., & Seibert, M. (1991) Biochemistry (preceding paper in this issue)]. Different proteases were used to degrade lumenal surface protein segments from these PS II membranes, and a total of four independent high-affinity Mn-binding sites (ligands) were identified. Carboxypeptidase A, subtilisin, and Staphylococcus aureus V8 protease each degrade one of two high-affinity Mn-binding sites sensitive to the histidine chemical modifier diethyl pyrocarbonate (DEPC). However, sequential treatment experiments indicate that subtilisin degrades a DEPC-sensitive Mn-binding site that is different from the one degraded by the other two proteases. Trypsin also was found to degrade one of the DEPC-sensitive Mn-binding sites (that degraded by carboxypeptidase A and V8 protease). In addition, trypsin degrades one of two 1-ethyl-3-[(3-dimethylamino)propyl]carbodiimide (EDC) sensitive Mn-binding sites, but only in the absence of the 30-kDa extrinsic protein. Thus, the 30-kDa extrinsic protein associated with O2 evolution appears to protect the EDC-sensitive binding site from trypsin degradation. No protease has yet been identified that will degrade the trypsin-insensitive EDC-sensitive Mn-binding site. Under the conditions of the assay (high DPC concentration), more than three Mn per reaction center were found bound to the membrane with a KM of about 0.4 microM, as determined by direct metal analysis. This is consistent with the idea that each of the four high-affinity sites binds (or provides a ligand for) one of four Mn.(ABSTRACT TRUNCATED AT 250 WORDS)     

A carboxylic residue at the high-affinity, Mn-binding site participates in the binding of iron cations that block the site

The role of carboxylic residues at the high-affinity, Mn-binding site in the ligation of iron cations blocking the site [Biochemistry 41 (2000) 5854] was studied, using a method developed to extract the iron cations blocking the site. We found that specifically bound Fe(III) cations can be extracted with citrate buffer at pH 3.0. Furthermore, citrate can also prevent the photooxidation of Fe(II) cations by YZ. Participation of a COOH group(s) in the ligation of Fe(III) at the high-affinity site was investigated using 1-ethyl-3-[(3-dimethylamino)propyl] carbodiimide (EDC), a chemical modifier of carboxylic amino acid residues. Modification of the COOH groups inhibits the light-induced oxidation of exogenous Mn(II) cations by Mn-depleted photosystem II (PSII[-Mn]) membranes. The rate of Mn(II) oxidation saturates at > or = 10 microM in PSII(-Mn) membranes and > or = 500 microM in EDC-treated PSII (-Mn) samples. Intact PSII(-Mn) membranes have only one site for Mn(II) oxidation via YZ (dissociation constant, Kd = 0.64 microM), while EDC-treated PSII(-Mn) samples have two sites (Kd = 1.52 and 22 microM; the latter is the low-affinity site). When PSII(-Mn) membranes were incubated with Fe(II) before modifier treatment (to block the high-affinity site) and the blocking iron cations were extracted with citrate (pH 3.0) after modification, the membranes contained only one site (Kd = 2.3 microM) for exogenous Mn(II) oxidation by Y(Z)() radical. In this case, the rate of electron donation via YZ saturated at a Mn(II) concentration > or = 15 microM. These results indicate that the carboxylic residue participating in Mn(II) coordination and the binding of oxidized manganese cations at the HAZ site is protected from the action of the modifier by the iron cations blocking the HAZ site. We concluded that the carboxylic residue (D1 Asp-170) participating in the coordination of the manganese cation at the HAZ site (Mn4 in the tetranuclear manganese cluster [Science 303 (2004) 1831]) is also involved in the ligation of the Fe cation(s) blocking the high-affinity Mn-binding site.     

pH Dependence of the Efficiency of Binding of Iron Cations to the Donor Side of Photosystem II

Light-induced interaction of Fe(II) cations with the donor side of Mn-depleted photosystem II (PS II(–Mn)) results in the binding of iron cations and blocking of the high-affinity (HA_Z) Mn-binding site. The pH dependence of the blocking was measured using the diphenylcarbazide/2,6-dichlorophenolindophenol test. The curve of the pH dependence is bell-shaped with pK ₁ = 5.8 and pK ₂ = 8.0. The pH dependence of the O₂-evolution mediated by PS II membranes is also bellshaped (pK ₂ = 7.6). The pH dependence of the process of electron donation from exogenous donors in PS II(–Mn) was studied to determine the location of the alkaline pH sensitive site of the electron transport chain. The data of the study showed that the decrease in the iron cation binding efficiency at pH > 7.0 during blocking was determined by the donor side of the PS II(–Mn). Mössbauer spectroscopy revealed that incubation of PS II(–Mn) membranes in a buffer solution containing ⁵⁷Fe(II) + ⁵⁷Fe(III) was accompanied by binding only Fe(III) cations. The pH dependence of the nonspecific Fe(III) cation binding is also described by the same bell-shaped curve with pK ₂ = 8.1. The treatment of the PS II(–Mn) membranes with the histidine modifier diethylpyrocarbonate resulted in an increase in the iron binding strength at alkaline pH. It is suggested that blocking efficiency at alkaline pH is determined by competition between OH^– and histidine ligand for Fe(III). Because the high-affinity Mn-binding site contains no histidine residue, this fact can be regarded as evidence that histidine is located at another (other than high-affinity) Fe(III) binding site. In other words, this means that the blockage of the high-affinity Mn-binding site is determined by at least two iron cations. We assume that inactivation of oxygen-evolving complex and inhibition of photoactivation in the alkaline pH region are also determined by competition between OH^– and a histidine residue involved in coordination of manganese cation outside the high-affinity site.     

Structural organization of the oxidizing side of photosystem II. Exogenous reductants reduce and destroy the Mn-complex in photosystems II membranes depleted of the 17 and 23 kDa polypeptides

Removal of 23 and 17 kDa water-soluble polypeptides from PS II membranes causes a marked decrease in oxygen-evolution activity, exposes the oxidizing side of PS II to exogenous reductants (Ghanotakis, D.F., Babcock, G.T. and Yocum, C.F. (1984) Biochim. Biophys. Acta 765, 388–398) and alters a high-affinity binding site for Ca²⁺ in the oxygen-evolving complex (Ghanotakis, D.F., Topper, J.N., Babcock, G.T. and Yocum, C.F. (1984) FEBS Lett. 170, 169–173). We have examined further the state of the functional Mn complex in PS II membranes from which the 17 and 23 kDa species have been removed by high-salt treatment. These membranes contain a structurally altered Mn complex which is sensitive to destruction by low concentrations of NH₂OH which cannot, in native PS II membranes, cause extraction of functional Mn. In addition to NH₂OH, a wide range of other small (H₂O₂, NH₂NH₂, Fe²⁺) and bulky (benzidine, hydroquinone) electron donors extract Mn (up to 80%) from the polypeptide-depleted PS II preparations. This extraction is due to reduction of the functional Mn complex since light, which would generate higher oxidation states within the Mn complex, prevents Mn release by reductants. Release of Mn by reductants does not extract the 33 kDa water-soluble protein implicated in Mn binding to the oxidizing side of PS II, although the protein can be partially or totally extracted from Mn-depleted preparations by exposure to high ionic strength or to high (0.8 M) concentrations of Tris. We view our results as evidence for a shield around the Mn complex of the oxygen-evolving complex comprised of the 33 kDa polypeptide along with the 23 and 17 kDa proteins and tightly bound Ca²⁺.     

Blocking of electron donation by Mn(II) to Y(Z*) following incubation of Mn-depleted photosystem II membranes with Fe(II) in the light

The donation of electrons by Mn(II) and Fe(II) to Y(Z*) through the high-affinity (HA(Z)) site in Mn-depleted photosystem II (PSII) membranes has been studied by flash-probe fluorescence yield measurements. Mn(II) and Fe(II) donate electrons to Y(Z*) with about the same efficiency, saturating this reaction at the same concentration (ca. 5 microM). However, following a short incubation of the membranes with 5 microM Fe(II), but not with Mn(II) in room light, added Mn(II) or Fe(II) can no longer be photooxidized by Y(Z)(*). This blocking effect is caused by specifically bound, photooxidized Fe [> or =Fe(III)] and is accompanied by a delay in the fluorescence yield decay kinetics attributed to the slowing down of the charge recombination rate between Q(a-) and Y(Z*). Exogenously added Fe(III), on the other hand, does not donate electrons to Y(Z*), does not block the donation of electrons by added Mn(II) and Fe(II), and does not change the kinetics of the decay of the fluorescence yield. These results demonstrate that the light-dependent oxidation of Fe(II) by Y(Z*) creates an Fe species that binds at the HA(Z) site and causes the blocking effect. The pH dependence of Mn(II) electron donation to Y(Z*) via the HA(Z) site and of the Fe-blocking effect is different. These results, together with sequence homologies between the C-terminal ends of the D1 and D2 polypeptides of the PSII reaction center and several diiron-oxo enzymes, suggest the involvement of two or perhaps more (to an upper limit of four to five) bound iron cations per reaction center of PSII in the blocking effect. Similarities in the interaction of Fe(II) and Mn(II) with the HA(Z) Mn site of PSII during the initial steps of the photoactivation process are discussed. The Fe-blocking effect was also used to investigate the relationship between the HA(Z) Mn site and the HA sites on PSII for diphenylcarbazide (DPC) and NH2OH oxidation. Blocking of the HA(Z) site with specifically bound Fe leads to the total inhibition of electron donation to Y(Z*) by DPC. Since DPC and Mn(II) donation to PSII is noncompetitive [Preston, C., and Seibert, M. (1991) Biochemistry 30, 9615-9624], the Fe bound to the HA(Z) site can also block the DPC donation site. On the other hand, electron donation by NH2OH to PSII still occurs in Fe-blocked membranes. Since hydroxylamine does not reduce the Fe [> or =Fe(III)] specifically bound to the HA(Z) site, NH2OH must donate to Y(Z*) through its own site or directly to P680+.     

Presence in Photosystem II Core Complexes of a 34-Kilodalton Polypeptide Required for Water Photolysis

Photosystem II (PSII) reaction center core complexes have been isolated and characterized from wild type (WT) Scenedesmus obliquus and from its LF-1 mutant. LF-1 thylakoids are blocked on the oxidizing side of PSII and have a reduced Mn content. Visible absorption and low temperature fluorescence spectra of both core complexes are identical and resemble those reported for spinach (Satoh, Butler 1978 Plant Physiol 61: 373-379). Lithium dodecyl sulfate-polycrylamide gel electrophoresis reveals that a protein alteration, originally observed in thylakoid membranes (Metz, Wong, Bishop 1980 FEBS Lett 114: 61-66), is retained in the PSII core particles. That is, a 34-kilodalton (kD) polypeptide, present in the WT core complex, is missing in the mutant, and the core complex of the mutant contains a 36-kD protein not present in the WT. The 34-kD intrinsic protein is also observed in O₂-evolving PSII preparations and PSII core complexes from spinach. It is distinct from the 33-kD extrinsic protein first reported by T. Kuwabara and N. Murata (1979 Biochim Biophys Acta 581: 228-236). We suggest that the 34-kD protein is a site of Mn binding in the PSII membrane.     

A carboxylic residue at the high-affinity, Mn-binding site participates in the binding of iron cations that block the site

The role of carboxylic residues at the high-affinity, Mn-binding site in the ligation of iron cations blocking the site [Biochemistry 41 (2000) 5854] was studied, using a method developed to extract the iron cations blocking the site. We found that specifically bound Fe(III) cations can be extracted with citrate buffer at pH 3.0. Furthermore, citrate can also prevent the photooxidation of Fe(II) cations by Y_Z. Participation of a COOH group(s) in the ligation of Fe(III) at the high-affinity site was investigated using 1-ethyl-3-[(3-dimethylamino)propyl] carbodiimide (EDC), a chemical modifier of carboxylic amino acid residues. Modification of the COOH groups inhibits the light-induced oxidation of exogenous Mn(II) cations by Mn-depleted photosystem II (PSII[−Mn]) membranes. The rate of Mn(II) oxidation saturates at ≥10 μM in PSII(−Mn) membranes and ≥500 μM in EDC-treated PSII (−Mn) samples. Intact PSII(−Mn) membranes have only one site for Mn(II) oxidation via Y_Z (dissociation constant, K_d = 0.64 μM), while EDC-treated PSII(−Mn) samples have two sites (K_d = 1.52 and 22 μM; the latter is the low-affinity site). When PSII(−Mn) membranes were incubated with Fe(II) before modifier treatment (to block the high-affinity site) and the blocking iron cations were extracted with citrate (pH 3.0) after modification, the membranes contained only one site (K_d = 2.3 μM) for exogenous Mn(II) oxidation by Y_Z radical. In this case, the rate of electron donation via Y_Z saturated at a Mn(II) concentration ≥15 μM. These results indicate that the carboxylic residue participating in Mn(II) coordination and the binding of oxidized manganese cations at the HA_Z site is protected from the action of the modifier by the iron cations blocking the HA_Z site. We concluded that the carboxylic residue (D1 Asp-170) participating in the coordination of the manganese cation at the HA_Z site (Mn4 in the tetranuclear manganese cluster [Science 303 (2004) 1831]) is also involved in the ligation of the Fe cation(s) blocking the high-affinity Mn-binding site.     

Phenylglyoxal modification of the Photosystem II reaction center

Time-resolved spectroscopic techniques, including optical flash photolysis and electron spin resonance (ESR), have been used in conjunction with fluorescence-induction and dye-reduction assays to monitor electron transport in Photosystem II (PS II) subchloroplast particles incubated with the covalent modifier, phenylglyoxal. Phenylglyoxal-modified digitonin (D-10) particles from spinach are characterized by a high initial fluorescence yield (Fi) and an abolition of the variable component of fluorescence (Fv); an inhibition of PS-II-mediated reduction of dichlorophenol indophenol (DPIP) by sym-diphenylcarbazide; an abolition of flash-induced absorption transients (t1/2 greater than 2 microseconds) at 820 nm attributed to the primary electron donor, P-680+; the inhibition of photoreduction of the acceptor Qa; and the elimination of the ESR Signal 2s and Signal 2f. These observations suggest the critical participation of specific arginine residues on both the oxidizing and reducing sides of Photosystem II and also implicate phenylglyoxal as a quinone-binding site inhibitor (Golbeck, J.H. and Warden, J.T. (1984) Biochim. Biophys. Acta 767, 263-271).     

Chemical modification of amine groups on PS II protein(s) retards photoassembly of the photosynthetic water-oxidizing complex

Four Mn atoms function as catalysts in the water-oxidizing complex located on the oxidizing side of PS II. We have studied the involvement of amine groups of the PS II proteins in photoligation of Mn2+ to the apo water-oxidizing complex, using the combined techniques of photoactivation and chemical modification with the modifiers methyl acetimidate (MAI), acetic acid N-hydroxysuccinimide ester (NHS), and 2,4,6-trinitrobenzenesulfonic acid (TNBS). Chemical modification of hydroxylamine-treated PS II core complexes decreased their capacity for restoration of oxygen evolution and photoligation of Mn2+ to the apo water-oxidizing complex (WOC), but did not affect their electron transfer activity in the vicinity of PS II. The number of functional high-affinity Mn-binding sites, but not of low-affinity sites, was significantly modulated by chemical modification. Kinetic analysis of photoactivation with the repetitive flashes revealed that the intermediate generated during a photoactivation process was destabilized by the chemical modification. To identify which proteins possess the amine groups involved in ligation of functional Mn, we examined the difference in NHS biotinylation between PS II core complexes with and without the Mn cluster. NHS biotinylation resulting in altered ligation of functional Mn apparently occurred on three proteins: an antenna chlorophyll binding protein (CP47), a light-harvesting chlorophyll protein (CP29), and another chlorophyll binding protein (PS II-S). Of these proteins, only the Mn-dependent biotinylation of CP47 was found to occur independently of the application of an NHS-masking concentration before removal of the functional Mn. These results suggest that lysyl residues of CP47, and perhaps also CP29 and PS II-S, function in direct photoligation of Mn2+ to the apo WOC.     

The electron-transfer site of spinach plastocyanin

Two sites for electron transfer have been proposed for plastocyanin: one near the copper ion and the other close to the acid patch formed by residues 42-45. Calculations of electrostatic properties of spinach plastocyanin and ionic strength dependences of electron-transfer reactions of this protein have been used to distinguish between these two sites. Calculations show that the electric potential field of spinach plastocyanin is highly asymmetric and that the protein has a dipole moment of 360 D. The negative end of the dipole axis emerges between the negative patches formed by residues 42-45, which is though to be the cation binding site, and residues 59-61. The angles between the dipole vector and vectors from the center of mass to the copper ion and to the acid patch are 90 degrees and 30 degrees, respectively. The angle between the dipole vector and a line from the center of mass to the site of electron transfer is evaluated from the ionic strength dependence of electron-transfer rates at pH 7.8 with the help of equations developed by Van Leeuwen et al. [van Leeuwen, J.W., Mofers, F.J.M., & Veerman, E.C.I. (1981) Biochim. Biophys. Acta 635, 434] and Van Leeuwen [van Leeuwen, J.W. (1983) Biochim. Biophys. Acta 743, 408]. The angles found are 85 degrees, 110 degrees, and 75 +/- 15 degrees for reactions with tris(1,10-phenanthroline)cobalt(III), hexacyanoferrate(III), and ferrocytochrome c, respectively. The electric potential field calculations suggest that the hexacyanoferrate(III) interaction angle corresponds to a unique site of minimum repulsion at the hydrophobic region of the protein surface, close to the copper ion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Further studies of the thylakoid membrane surface charges by particle electrophoresis

1. Above pH 4.3 the outer surface of thylakoid membranes isolated from pea chloroplasts is negatively charged but below this value it carries an excess of positive charge.2. Previously the excess negative charge has been attributed to the carboxyl groups of glutamic and aspartic acid residues (Nakatani, H.Y., Barber, J. and Forrester, J.A. (1978), Biochim. Biophys. Acta 504, 215–225) and in this paper it is argued from experiments involving treatments with 1,2-cyclohexanedione that the positive charges are partly due to the guanidino group of arginine.3. The electrophoretic mobility of granal (enriched in chlorophyll b and PS II activity) and stromal (enriched in PS I activity) lamellae isolated by the French Press technique were found to be the same.4. Treatment of the pea thylakoids with trypsin or pronase, sufficient to inhibit the salt induced chlorophyll fluorescence changes, increased their electrophoretic mobility indicating that additional negative charges had been exposed at the surface.5. Polylysine treatment also inhibited the salt induced chlorophyll fluorescence changes but unlike trypsin and pronase, decreased the net negative charge on the surface.6. The isoelectric point defined as the pH which gave zero electrophoretic mobility (about 4.3) was independent of the nature of the cations in the suspending medium (monovalent vs. divalent).     

Manganese proteins isolated from spinach thylakoid membranes and their role in O2 evolution. II. A binuclear manganese-containing 34 kilodalton protein, a probable component of the water dehydrogenase enzyme

Extraction conditions have been found which result in the retention of manganese to the 33-34 kDa protein, first isolated as an apoprotein by Kuwabara and Murata (Kuwabara, T. and Murata, N. (1979) Biochim. Biophys Acta 581, 228-236). By maintaining an oxidizing-solution potential, with hydrophilic and lipophilic redox buffers during protein extraction of spinach grana-thylakoid membranes, the 33-34 kDa protein is observed to bind a maximum of 2 Mn/protein which are not released by extended dialysis versus buffer. This manganese is a part of the pool of 4 Mn/Photosystem II normally associated with the oxygen-evolving complex. The mechanism for retention of Mn to the protein during isolation appears to be by suppression of chemical reduction of natively bound, high-valent Mn to the labile Mn(II) oxidation state. This protein is also present in stoichiometric levels in highly active, O2-evolving, detergent-extracted PS-II particles which contain 4-5 Mn/PS II. Conditions which result in the loss of Mn and O2 evolution activity from functional membranes, such as incubation in 1.5 mM NH2OH or in ascorbate plus dithionite, also release Mn from the protein. The protein exists as a monomer of 33 kDa by gel filtration and 34 kDa by gel electrophoresis, with an isoelectric point of 5.1 +/- 0.1. The protein exhibits an EPR spectrum only below 12 K which extends over at least 2000 G centered at g = 2 consisting of non-uniformly separated hyperfine transitions with average splitting of 45-55 G. The magnitude of this splitting is nominally one-half the splitting observed in monomeric manganese complexes having O or N donor ligands. This is apparently due to electronic coupling of the two 55Mn nuclei in a presumed binuclear site. Either a ferromagnetically coupled binuclear Mn2(III,III) site or an antiferromagnetically coupled mixed-valence Mn2(II,III) site are considered as possible oxidation states to account for the EPR spectrum. Qualitatively similar hyperfine structure splittings are observed in ferromagnetically coupled binuclear Mn complexes having even-spin ground states. The extreme temperature dependence suggests the population of low-lying excited states such as are present in weakly coupled dimers and higher clusters of Mn ions, or, possibly, from efficient spin relaxation such as occurs in the Mn(III) oxidation state. Either 1.5 mM NH2OH or incubation with reducing agents abolishes the low temperature EPR signal and releases two Mn(II) ions to solution. This is consistent with the presence of Mn(III) in the isolated protein.(ABSTRACT TRUNCATED AT 400 WORDS)     

Picosecond fluorescence kinetics in spinach chloroplasts at room temperature. Effects of Mg

Single-photon timing with picosecond resolution is used to investigate the effect of Mg²⁺ on the room-temperature fluorescence decay kinetics in broken spinach chloroplasts. In agreement with an earlier paper (Haehnel, W., Nairn, J.A., Reisberg, P. and Sauer, K. (1982) Biochim. Biophys. Acta 680, 161–173), we find three components in the fluorescence decay both in the presence and in the absence of Mg²⁺. The behavior of these components is examined as a function of Mg²⁺ concentration at both the F₀ and the F_max fluorescence levels, and as a function of the excitation intensity for thylakoids from spinach chloroplasts isolated in the absence of added Mg²⁺. Analysis of the results indicates that the subsequent addition of Mg²⁺ has effects which occur at different levels of added cation. At low levels of Mg²⁺ (less than 0.75 mM), there appears to be a decrease in communication between Photosystem (PS) II and PS I, which amounts to a decrease in the spillover rate between PS II and PS I. At higher levels of Mg²⁺ (about 2 mM), there appears to be an increase in communication between PS II units and an increase in the effective absorption cross-section of PS II, probably both of these involving the chlorophyll light-harvesting antenna.     

Model complexes suggest certain S-state changes of the photosynthetic water-oxidation enzyme may involve an Mn(II)-Mn(III) transition

The ultraviolet-visible absorbance differences spectra of Mn(II,III) and Mn(III,III) oxo-bridged carboxylate complexes are reported. The difference spectra are remarkably similar to those of the photosynthetic water-oxidation enzyme complex reported by Dekker et al. [(1984) Biochim. Biophys. Acta 764, 301-309] which were interpreted as being due exclusively to Mn(II----IV) transitions. This result indicates that certain S-state changes of the enzyme complex may instead involve Mn(II----III) transitions, and that difference spectra alone cannot be used with confidence to assign the Mn oxidation state changes during water oxidation.     

Putative Second Binding Site of DCMU on the Oxidizing Side of Photosystem II in Photosystem II Membranes Depleted of Functional Mn

The effects of DCMU on the oxidizing side of PS II were studiedwith Triton-solubilized PS II membranes depleted of functionalMn. 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) non-competitivelyinhibited the diphenylcarbazide-supported (DPC-supported) photoreductionof silicomolybdate (SiMo) at concentrations more than ten timeshigher than that required for inhibition of the DPC-supportedphotoreduction of 2,6-dichlorophenolindophenol (DCIP). The maximumfluorescence intensity was also reduced by DCMU at a similarconcentration to that required for the inhibition of the SiMophotoreduction. These findings suggest two inhibitory sitesof action of DCMU in PS II: one on the reducing side and oneon the oxidizing side of PS II. The inhibition constant forDCMU in the DPC-supported SiMo-photoreduction was 10 µMin every examination. The extent of inhibition was attenuatedby modifications of the PS II oxidizing side by the presenceof functional Mn, by photoinhibition and by chemical modificationsof histidine residues and acidic amino acid residues. Our resultssuggest that DCMU binds to the PS II oxidizing side near Z,D and the high-affinity Mn-binding sites. ¹ Present Address and address for all communications: NoriakiTamura (Dr.), Plant Physiology Laboratory Fukuoka Women's University,Kasumigaoka 1-1, Higashi-ku, Fukuoka, 813 Japan. FAX 092-661-2415.     

Iron bound to the high-affinity Mn-binding site of the oxygen-evolving complex shifts the pK of a component controlling electron transport via Y(Z)

Flash-probe fluorescence spectroscopy was used to compare the pH dependence of charge recombination between Y(Z)(*) and Q(a)(-) in Mn-depleted, photosystem II membranes [PSII(-Mn)] and in membranes with the high-affinity (HA(Z)) Mn-binding site blocked by iron [PSII(-Mn,+Fe); Semin, B. K., Ghirardi, M. L., and Seibert, M. (2002) Biochemistry 41, 5854-5864]. The apparent half-time for fluorescence decay (t(1/2)) in PSII(-Mn) increased from 9 ms at pH 4.4 to 75 ms at pH 9.0 [with an apparent pK (pK(app)) of 7.1]. The actual fluorescence decay kinetics can be fit to one exponential component at pH <6.0 (t(1/2) = 9.5 ms), but it requires an additional component at pH >6.0 (t(1/2) = 385 ms). Similar measurements with PSII(-Mn,+Fe) membranes show that iron binding has little effect on the maximum and minimum t(1/2) values measured at alkaline and acidic pHs but that it does shift the pK(app) from 7.1 to 6.1 toward the more acidic pK(app) value typical of intact membranes. Light-induced Fe(II) blocking of the PSII(-Mn) membrane is accompanied by a decrease in buffer Fe(II) concentration. This decrease was not the result of Fe(II) binding, but rather of its oxidation at two sites, the HA(Z) site and the low-affinity site. M?ssbauer spectroscopy at 80 K on PSII(-Mn,+Fe) samples, prepared under conditions providing the maximal blocking effect but minimizing the amount of nonspecifically bound iron cations, supports this conclusion since this method detected only Fe(III) cations bound to the membranes. Correlation of the kinetics of Fe(II) oxidation with the blocking parameters showed that blocking occurs after four to five Fe(II) cations were oxidized at the HA(Z) site. In summary, the blocking of the HA(Z) Mn-binding site by iron in PSII(-Mn) membranes not only prevents the access of exogenous donors to Y(Z) but also partially restores the properties of the hydrogen bond net found in intact PS(II), which in turn controls the rate of electron transport to Y(Z).     

Involvement of Carboxyl Groups of the PSII Reaction Center Proteins in Photoactivation of the Apo-Water-Oxidizing Complex

Involvement of residues of acidic amino acids in photo-ligationof manganese into the apo-water-oxidizing complex was investigatedby use of l-ethyl-3-[3-(dimethylami-no)propyl]carbodiimide (EDC),a water-soluble carboxyl modifier. Treatment of Mn-depletedPSII membranes by EDC in the presence of nucleophiles induceda loss of photoactivation capability in the Mn complex and partialloss of capability of photooxidation of Mn²⁺, but little decreasein the DCIP photoreduction supported by diphen-ylcarbazide.The inhibition of diphenylcarbazide-photo-oxidation by submicromolarMn²⁺, indicative of the intactness of high-affinity Mn-bindingsites, was apparently abolished by EDC treatment. From aminoacid quantitation analysis of Dl and D2 proteins and CP47 ofthe chemically-modified membranes, approximately three carboxylgroups of the D1 protein were found to be chemically-modifiedwith EDC after removal of the functional Mn. These results suggestthat acidic amino acids on the D1 protein are involved in photoactivationof the apo-water-oxidizing complex and probably in ligationof Mn to the water-oxidizing complex. (Received October 21, 1996; Accepted March 3, 1997)     

Picosecond fluorescence kinetics in spinach chloroplasts at room temperature. Effects of Mg2+

Single-photon timing with picosecond resolution is used to investigate the effect of Mg²⁺ on the room-temperature fluorescence decay kinetics in broken spinach chloroplasts. In agreement with an earlier paper (Haehnel, W., Nairn, J.A., Reisberg, P. and Sauer, K. (1982) Biochim. Biophys. Acta 680, 161–173), we find three components in the fluorescence decay both in the presence and in the absence of Mg²⁺. The behavior of these components is examined as a function of Mg²⁺ concentration at both the F₀ and the F_max fluorescence levels, and as a function of the excitation intensity for thylakoids from spinach chloroplasts isolated in the absence of added Mg²⁺. Analysis of the results indicates that the subsequent addition of Mg²⁺ has effects which occur at different levels of added cation. At low levels of Mg²⁺ (less than 0.75 mM), there appears to be a decrease in communication between Photosystem (PS) II and PS I, which amounts to a decrease in the spillover rate between PS II and PS I. At higher levels of Mg²⁺ (about 2 mM), there appears to be an increase in communication between PS II units and an increase in the effective absorption cross-section of PS II, probably both of these involving the chlorophyll $\text{a}\text{b}$ light-harvesting antenna.     

Coordination sphere and structure of the Mn cluster of the oxygen-evolving complex in photosynthetic organisms

The great similarity between the binding of Fe(II) and the high-affinity Mn-binding site in the Mn-depleted PSII membranes (Semin et al. (1996) FEBS Lett. 375, 223–226) suggests that the coordination sphere of Mn in PSII is also suitable for iron. A comparison is performed between the primary amino acid sequences of D1 and D2 and diiron-oxo enzymes with the function of oxygen activation. All conservative motifs (EXXH) and residues binding and stabilizing the diiron cluster in diiron-oxo enzymes have been found in the C-terminal domains of D1 and D2 polypeptides. On the basis of these sequence similarities we suggest a structural model for the manganese cluster in the oxygen-evolving complex.