Reductant-Sensitive Intermediates Involved in Multi-Quantum Process of Photoactivation of Latent O2-Evolving System

The inhibitory effects of some reducing agents on photoactivationof the latent O₂-evolving system were analyzed by investigatingtheir effects on the multi-quantum process involved in photoactivation,using intact chloroplasts prepared from intermittently flashedwheat leaves. Reducing agents accelerated the decay of boththe 1st and 2nd intermediates by factors of 2 to 3, respectively,but did not affect the rate of conversion from the 1st intermediateto the 2nd intermediate. Based on these results, the role ofthe light reaction in the photoactivation process was discussedin relation to the mechanism of Mn ligation in the O₂-evolvingsystem. (Received February 12, 1987; Accepted August 3, 1987)     

Low pH-Induced Dissociation of Three Extrinsic Proteins from O2-Evolving Photosystem II

Three extrinsic proteins involved in oxygen evolution reversiblydissociated from Photo-system II (PS II) membranes at acidicpHs showing distinctly different pH dependencies. The pHs forhalf dissociation of 17, 23 and 33 kDa extrinsic proteins weredetermined to be 5.0, 4.1 and 3.6, respectively. The half dissociationpHs of 17 and 23 kDa proteins were much lower than their respectiveisoelectric points, while that for 33 kDa protein was closeto its isoelectric point. It was suggested that protonationof the negatively charged binding domain on membrane proteinscauses dissociation of the former two extrinsic proteins, whereasprotonation of the extrinsic protein itself is responsible forthe dissociation of 33 kDa protein. Based on these, featuresof low pH-induced dissociation of extrinsic proteins and Mnfrom PS II were discussed. (Received September 25, 1990; Accepted February 13, 1991)     

Induction of Nonphotochemical Energy Dissipation and Absorbance Changes in Leaves (Evidence for Changes in the State of the Light-Harvesting System of Photosystem II in Vivo)

Simultaneous measurements of nonphotochemical quenching of chlorophyll fluorescence and absorbance changes in the 400- to 560-nm region have been made following illumination of dark-adapted leaves of the epiphytic bromeliad Guzmania monostachia. During the first illumination, an absorbance change at 505 nm occurred with a half-time of 45 s as the leaf zeaxanthin content rose to 14% of total leaf carotenoid. Selective light scattering at 535 nm occurred with a half-time of 30 s. During a second illumination, following a 5-min dark period, quenching and the 535-nm absorbance change occurred more rapidly, reaching a maximum extent within 30 s. Nonphotochemical quenching of chlorophyll fluorescence was found to be linearly correlated to the 535-nm absorbance change throughout. Examination of the spectra of chlorophyll fluorescence emission at 77 K for leaves sampled at intervals during this regime showed selective quenching in the light-harvesting complexes of photosystem II (LHCII). The quenching spectrum of the reversible component of quenching had a maximum at 700 nm, indicating quenching in aggregated LHCII, whereas the irreversible component represented a quenching of 680-nm fluorescence from unaggregated LHCII. It is suggested that this latter process, which is associated with the 505-nm absorbance change and zeaxanthin formation, is indicating a change in state of the LHCII complexes that is necessary to amplify or activate reversible pH-dependent energy dissipation, which is monitored by the 535-nm absorbance change. Both of the major forms of nonphotochemical energy dissipation in vivo are therefore part of the same physiological photoprotective process and both result from alterations in the LHCII system.     

Action Spectrum for Photoactivation of the Water-splitting System in Plastids of Intermittently Illuminated Wheat Leaves

The chloroplasts from wheat leaves developed under intermittent illumination (1 ms light + 12 min dark) were able to photoreduce DPIP with DPC as electron donor but unable to photoreduce DPIP with water as electron donor. On exposure of these leaves to continuous light, the Hill activity with water as electron donor was rapidly induced. The photoactivation was sensitive to the treatment with DCMU prior to exposure to continuous light. The action spectrum for the photoactivation showed a sharp band at 680 nm with a distinct shoulder at 650 nm, and was similar to the absorption spectrum of photosytem-2 particles. These data suggest that the electron transfer driven by photosystem 2 is essential for the activation of the water-splitting system in the chloroplasts of intermittently illuminated leaves.     

Development of Photosystem I and Photosystem II Activities in Leaves of Light-grown Maize (Zea mays)

To compare chloroplast development in a normally grown plant with etiochloroplast development, green maize plants (Zea mays), grown under a diurnal light regime (16-hour day) were harvested 7 days after sowing and chloroplast biogenesis within the leaf tissue was examined. Determination of total chlorophyll content, ratio of chlorophyll a to chlorophyll b, and O₂-evolving capacity were made for intact leaf tissue. Plastids at different stages of development were isolated and the electron-transporting capacities of photosystem I and photosystem II measured. Light saturation curves were produced for O₂-evolving capacity of intact leaf tissue and for photosystem I and photosystem II activities of isolated plastids. Structural studies were also made on the developing plastids. The results indicate that the light-harvesting apparatus becomes increasingly efficient during plastid development due to an increase in the photosynthetic unit size. Photosystem I development is completed before that of photosystem II. Increases in O₂-evolving capacity during plastid development can be correlated with increased thylakoid fusion. The pattern of photosynthetic membrane development in the light-grown maize plastids is similar to that found in greening etiochloroplasts.     

Effects of Hydroxylamine on Photosystem II: II. Photoreversal of the NH(2)OH Destruction of O(2) Evolution

The inactivation of O₂-evolving centers by NH₂OH extraction was shown to be reversible. This reversal required light and manganese. This light-induced restoration of active O₂-evolving centers was analyzed using three green algae and the blue-green alga, Anacystis nidulans. The following results were obtained: [List: see text]     

Changes in the Composition and Size Distribution of Soymilk Protein Particles by Heating

The protein particles in soymilk were fractionated in size by differential centrifugation. Particles of more than 100 nm in diameter (LSP) constituted 40% of the total protein in raw soymilk, 70% of the protein components being 11S globulin. LSP was not formed in the presence of 2-mercaptoethanol and sodium ascorbate. LSP was decreased by heating, and particles of 100–40 nm in diameter (MSP) were increased. The formation of MSP was not due to any degradation of LSP but to the combination of supernatant proteins of less than 40 nm in diameter with each other. MSP formed by heating contained the β subunit of 7S and the basic subunit of 11S as main components. The particles of more than 40 nm in diameter (LSP + MSP) constituted 50% of the total protein in both raw soymilk and soymilk.     

Stabilization of Photosystem II (O(2) Evolution) of Spinach Chloroplasts by Radiation-induced Immobilization

Spinach chloroplasts were immobilized with vinyl monomers by radiation-induced polymerization at low temperature and stored in buffer containing bovine serum albumin. The lifetime of O₂ evolution activity in photosystem II was prolonged remarkably in immobilized chloroplasts. Thermostability of immobilized chloroplasts stored in buffer containing bovine serum albumin was far better than that of immobilized chloroplasts in pure buffer and that of intact chloroplasts. When immobilized chloroplasts were stored in buffer including polyethylene glycol, the lifetime of O₂ evolution activity was longer than for those stored in buffer containing bovine serum albumin.     

Reversible Changes in Conformation of the 23-kDa Protein of Photosystem II and Their Relationship to the Susceptibility of the Protein to a Proteinase from Photosystem II Membranes

An aspartic proteinase was partially purified from PSII membranesof spinach. The 23-kDa protein of PSII was resistant to theproteinase when in its native form but became susceptible uponmodification by p-chloromercuriphenylsulfonic acid (pCMPS),upon incubation at pH 3, and upon incubation in dilute SDS.Conformational changes caused by pCMPS seemed to be restrictedto a localized region since the modified protein reconstitutedthe water-oxidizing complex with slightly less efficiency ascompared with the untreated protein. Under the three proteolyticconditions, cleavage occurred at the Asn-58-Leu-59 bond, suggestingthat the protein underwent similar conformational changes ineach case. Dithiothreitol, dialysis at pH 7, and neutral detergentssuppressed the facilitative effects of pCMPS, pH 3, and SDSon proteolysis, respectively. With the reversible changes insusceptibility, reversible changes in circular dichroism ofthe protein also occurred at 200–208 nm. These observationsindicate that the conformational changes are reversible andthe renaturation of the substrate was associated with the suppressionof the susceptibility. These results suggest that the scissilebond becomes reversibly exposed and susceptible to the proteinasein response to environmental changes. (Received November 23, 1994; Accepted February 7, 1995)     

Composition and catalase-like activity of Mn(II)-bicarbonate complexes

The composition and catalase-like activity of Mn2+ complexes with bicarbonate were investigated with voltammetry and kinetic methods (by the rate of O2 production from H2O2). Three linear sections were revealed on the dependence of the reduction potential of Mn2+ on logarithm of bicarbonate concentration (logC(NaHCO3)) having slopes equal to 0 mV/logC(NaHCO3), -14 mV/logC(NaHCO3), and -59 mV/logC(NaHCO3), corresponding to Mn2+ aqua complex (Mn2+(aq)) and to Mn2+-bicarbonate complexes of the composition [Mn2+(HCO3(-))]+ (at concentration of HCO3(-) 10-100 mM) and [Mn2+(HCO3(-))2]0 (at concentration of HCO3(-) 100-600 mM). Comparison of HCO3(-) concentration needed for the catalase-like activity of Mn2+ with the electrochemical data showed that only electroneutral complex Mn2+(HCO3(-))2 catalyzed decomposition of H2O2, whereas positively charged Mn2+(aq) complex and [Mn2+(HCO3(-))]+ were not active. The catalase-like activity of Mn2+ did not appear upon substitution of anions of carbonic acids (acetate and formate) for HCO3(-). The rate of O2 production in the system Mn2+-HCO3(-)-H2O2 (pH 7.4) is proportional to the second power of Mn2+ concentration and to the fourth power of HCO3(-) concentration that indicates simultaneous involvement of two Mn2+(HCO3(-))2 complexes in the reaction of H2O2 decomposition.     

Photoactivation of the Water-Oxidation System in Isolated Intact Chloroplasts Prepared from Wheat Leaves Grown under Intermittent Flash Illumination

Photoactivation of the latent oxygen-evolving system in intact chloroplasts isolated from wheat (Triticum aestivum L.) leaves grown under intermittent flash illumination was investigated, and the following results were obtained: (a) The water-oxidation activity generated on illuminating the isolated intact chloroplasts was as high as that generated in intact leaves, indicating that all the machinery necessary for the activity generation is assembled within intact chloroplasts. (b) The generation of water-oxidation activity was accompanied by enhancement of the activity of diphenylcarbazide-oxidation, and both processes share the same photochemical reaction but with respective rate-limiting dark reactions of different efficiencies. (c) A23187, an ionophore for divalent cations, strongly inhibited the generation of water-oxidation activity but did not affect the activity once generated, which suggested that Mn atoms in the chloroplasts are susceptible to the ionophore before photoactivation but turn immune after photoactivation. (d) The generation of water-oxidation activity was not affected by the inhibitors of ATP formation and CO(2) fixation, but was inhibited by nitrite, methylviologen and phenylmercuric acetate which suppress or inhibit the reduction of ferredoxin in intact chloroplasts. It was inferred that some factor(s) probably present in stroma to be reduced by PSI photoreaction is involved in the process of photoactivation.     

Photosystem II Regulation and Dynamics of the Chloroplast D1 Protein in Arabidopsis Leaves during Photosynthesis and Photoinhibition

Arabidopsis thaliana leaves were examined in short-term (1 h) and long-term (10 h) irradiance experiments involving growth, saturating and excess light. Changes in photosynthetic and chlorophyll fluorescence parameters and in populations of functional photosystem II (PSII) centers were independently measured. Xanthophyll pigments, 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU)-binding sites, the amounts of D1 protein, and the rates of D1 protein synthesis were determined. These comprehensive studies revealed that under growth or light-saturating conditions, photosynthetic parameters remained largely unaltered. Photoprotection occurred at light saturation indicated by a dark-reversible increase in non-photochemical quenching accompanied by a 5-fold increase in antheraxanthin and zeaxanthin. No consistent change in the concentrations of functional PSII centers, DCMU-binding sites, or D1 protein pool size occurred. D1 protein synthesis was rapid. In excess irradiance, quantum yield of O2 evolution and the efficiency of PSII were reduced, associated with a 15- to 20-fold increase in antheraxanthin and zeaxanthin and a sustained increase in nonphotochemical quenching. A decrease in functional PSII center concentration occurred, followed by a decline in the concentration of D1 protein; the latter, however, was not matched by a decrease in DCMU-binding sites. In the most extreme treatments, DCMU-binding site concentration remained 2 times greater than the concentration of D1 protein recognized by antibodies. D1 protein synthesis rates remained unaltered at excess irradiances.     

Effects of Hydroxylamine on Photosystem II: I. Factors Affecting the Decay of O(2) Evolution

Illumination of chloroplasts in the presence of NH₂OH (2 mm) leads to the destruction of all system II activities without affecting system I activity. The system II primary charge separation remains intact when incubated with this agent in the dark with release of one of the system II Mn pools and simultaneous destruction of O₂ evolving capacity. The size of the Mn pool associated with the O₂ evolving center is calculated to be 4 Mn/O₂-evolving center.     

Accessibility of tyrosine Y(.)(Z) to exogenous reductants and Mn(2+) in various Photosystem II preparations

The reduction of tyrosine Y(.)(Z) by benzidine and exogenous Mn(2+) was studied by kinetic EPR experiments in various Photosystem II (PSII) preparations. Using lanthanide treated PSII membranes it was demonstrated that neither the extrinsic polypeptides (17, 23 and 33 kDa) nor the Mn complex block the accessibility of Y(.)(Z) to exogenous reductants, such as benzidine. In addition, it was shown that in the presence of the native Mn complex exogenous Mn(2+) does not reduce Y(.)(Z).     

微管解聚剂和光合作用抑制型除草剂诱导的黑麦和玉米中蛋白质组分变化的比较研究

研究了黑麦、玉米在经甲基胺草膦和Atrazine两种除草剂处理后叶绿素含量、叶绿体和根尖分生组织内的蛋白质组份变化,实验结果表明,0.1 mg·L^-1的Atrazine可使黑麦中的叶绿素含量下降（分别从对照的1.72±0.034 mg·g^-1 FW下降到1.62±0.05 mg·g^-1 FW、1.25±0.015 mg·g^-1 FW）。2种除草剂均可使黑麦、玉米中的蛋白质组份产生改变,如当分别用0.1 mg·L^-1的Atrazine处理时,黑麦分生组织中,有4个蛋白质斑点,斑点7、斑点18~20被诱导产生,12个蛋白质斑点,斑点6、斑点8~17、斑点21消失。玉米分生组织中,有4个蛋白质斑点,斑点5、斑点14~16被诱导产生,4个蛋白质斑点,斑点17~20消失。黑麦叶绿体中,有两个蛋白质斑点被诱导产生,13个蛋白质斑点,斑点1~13消失,但Atrazine处理不引起玉米叶绿素含量和叶绿体蛋白质组份的变化。4 mg·L^-1 APM可引起黑麦和玉米分生组织蛋白质组份变化,在黑麦中,1个蛋白质斑点被诱导产生,4个蛋白质斑点,斑点2~5消失。玉米分生组织中,15个蛋白质斑点,斑点4~5、斑点7~16、斑点21~23被诱导产生,4个蛋白质斑点,斑点1~3、斑点6消失。APM均不能引起2种作物中叶绿素含量和叶绿体蛋白质组份的变化。     

Chemical oxidation and reduction of the O2-evolution center in Photosystem II

Treatment of Photosystem II (PS II) with low concentrations of hydroxylamine is known to cause a two-flash delay in the O₂-evolution pattern, and in the formation of the S₂-state multiline EPR signal, due to the two-electron reduction of the S₁-state by hydroxylamine to form the S_-1-state. Past work has shown that these delays are not reversed by washing out the hydroxylamine nor by adding DCBQ or ferricyanide to oxidize the residual hydroxylamine, but are reversed by illumination with two saturating flashes followed by a 30-min dark incubation. We have examined the effects of treatments aimed at restoring the normal flash-induced O₂-evolution pattern and S₂-state multiline EPR signal after treatment of PS II with 40 M hydroxylamine. In agreement with past work, we find that the two-flash delay in O₂ evolution is not reversed when the hydroxylamine is removed by three cycles of centrifugation and resuspension in hydroxylamine-free buffer nor by adding ferricyanide or DCBQ to oxidize the unreacted hydroxylamine. However, the normal flash-induced O₂-evolution pattern is restored by illumination with two saturating flashes followed by a 30-min dark incubation (after the sample was first treated with 40 M hydroxylamine and the unreacted hydroxylamine was removed); illumination with one saturating flash followed by a 30-min dark incubation is only partially effective. These results show that ferricyanide and DCBQ are not effective at oxidizing the S_-1-state to the S₁-state. In contrast, adding hypochlorite (OCl^-) after treatment with hydroxylamine restored the normal flash-induced O₂-evolution pattern and also restored the formation of the S₂-state multiline EPR signal by illumination at 200 K. We conclude that hypochlorite is capable of oxidizing the S_-1-state to the S₁-state. This is the first example of a chemical treatment that advances the delayed flash-induced O₂ evolution pattern.Abbreviations DCBQ 2,5-dichloro-p-benzoquinone - OEC O₂-evolving center     

Chloride facilitates Mn(III) formation during photoassembly of the Photosystem II oxygen-evolving complex

Photosynthesis Research - The Mn4Ca oxygen-evolving complex (OEC) in Photosystem II (PSII) is assembled in situ from free Mn2+, Ca2+, and water. In an early light-driven step, Mn2+ in a protein...     

Thermostability and Photostability of Photosystem II in Leaves of the Chlorina-f2 Barley Mutant Deficient in Light-Harvesting Chlorophyll a/b Protein Complexes

The chlorophyll-b-less chlorina-f2 barley mutant is deficient in the major as well as some minor light-harvesting chlorophyll-protein complexes of photosystem II (LHCII). Although the LHCII deficiency had relatively minor repercussions on the leaf photosynthetic performances, the responses of photosystem II (PSII) to elevated temperatures and to bright light were markedly modified. The chlorina-f2 mutation noticeably reduced the thermostability of PSII, with thermal denaturation of PSII starting at about 35[deg]C and 38.5[deg]C in chlorina-f2 and in the wild type, respectively. The increased susceptibility of PSII to heat stress in chlorina-f2 leaves was due to the weakness of its electron donor side, with moderate heat stress causing detachment of the 33-kD extrinsic PSII protein from the oxygen-evolving complex. Prolonged dark adaptation of chlorina-f2 leaves was also observed to inhibit the PSII donor side. However, weak illumination slowly reversed the dark-induced inhibition of PSII in chlorina-f2 and cancelled the difference in PSII thermostability observed between chlorina-f2 and wild-type leaves. The mutant was more sensitive to photoinhibition than the wild type, with strong light stress impairing the PSII donor side in chlorina-f2 but not in the wild type. This difference was not observed in anaerobiosis or in the presence of 3-(3,4-dichlorophenyl)- 1,1-dimethylurea, diuron. The acceptor side of PSII was only slightly affected by the mutation and/or the aforementioned stress conditions. Taken together, our results indicate that LHCII stabilize the PSII complexes and maintain the water-oxidizing system in a functional state under varying environmental conditions.