G. Christen scite author profile

The rise of fluorescence as an indicator for P680(+)* reduction by YZ and the period-four oscillation of oxygen yield induced by a train of saturating flashes were measured in dark-adapted thylakoids as a function of pH in the absence of exogenous electron acceptors. The results reveal that: (i) the average amplitude of the nanosecond kinetics and the average of the maximum fluorescence attained at 100 micros after the flash in the acidic range decrease with decreasing pH; (ii) the oxygen yield exhibits a pronounced period-four oscillation at pH 6.5 and higher damping at both pH 5.0 and pH 8.0; (iii) the probability of misses in the Si-state transitions of the water oxidizing complex is affected characteristically when exchangeable protons are replaced by deuterons [at pH <6.5, the ratio alpha(D)/alpha(H) is larger than 1 whereas at pH >7.0 values of <1 are observed]. The results are discussed within the framework of a combined mechanism for P680(+)* reduction where the nanosecond kinetics reflect an electron transfer coupled with a "rocket-type" proton shift within a hydrogen bridge from YZ to a nearby basic group, X [Eckert, H.-J., and Renger, G. (1988) FEBS Lett. 236, 425-431], and subsequent relaxations within a network of hydrogen bonds. It is concluded that in the acidic region the hydrogen bond between YZ and X (most likely His 190 of polypeptide D1) is interrupted either by direct protonation of X or by conformational changes due to acid-induced Ca2+ release. This gives rise to a decreased P680(+)* reduction by nanosecond kinetics and an increase of dissipative P680(+)* recombination at low pH. A different mechanism is responsible for the almost invariant amplitude of nanosecond kinetics and increase of alpha in the alkaline region.

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The Role of Hydrogen Bonds for the Multiphasic P680⁺^• Reduction by Y_Z in Photosystem II with Intact Oxyen Evolution Capacity. Analysis of Kinetic H/D Isotope Exchange Effects

Christen

Ренгер

1999

Biochemistry

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The mechanism of multiphasic P680(+)* reduction by YZ has been analyzed by studying H/D isotope exchange effects on flash-induced changes of 830 nm absorption, DeltaA830(t), and normalized fluorescence yield, F(t)/F0, in dark-adapted thylakoids and PS II membrane fragments from spinach. It was found that (a) the characteristic period four oscillations of the normalized components of DeltaA830(t) relaxation and of F(t)/F0 rise in the nanosecond and microsecond time domain are significantly modified when exchangeable protons are replaced by deuterons; (b) in marked contrast to the normalized steady-state extent of the microsecond kinetics of 830 nm absorption changes which increases only slightly due to H/D exchange (about 10%) the Si state-dependent pattern exhibits marked effects that are most pronounced after the first, fourth, fifth, and eighth flashes; (c) regardless of data evaluation by different fit procedures the results lead to a consistent conclusion, that is, the relative extent of the back reaction between P680(+)*QA-* becomes enhanced in samples suspended in D2O; and (d) this enhancement is dependent on the Si state of the WOC and attains maximum values in S2 and S3, most likely due to a retardation of the "35 micros kinetics" of P680(+)* reduction. In an extension of our previous suggestion on the functional role of hydrogen bonding of YZ by a basic group X (Eckert, H.-J., and Renger, G. (1988) FEBS Lett. 236, 425-431), a model is proposed for the origin of the multiphasic P680(+)* reduction by YZ. Two types of different processes are involved: (a) electron transfer in the nanosecond time domain is determined by strength and geometry of the hydrogen bond between the O-H group of YZ and acceptor X, and (b) the microsecond kinetics reflect relaxation processes of a hydrogen bond network giving rise to a shift of the equilibrium P680(+)*YZ <==> P680YZ(OX) toward the right side. The implications of this model are discussed.

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Application of the Marcus theory for analysis of the temperature dependence of the reactions leading to photosynthetic water oxidation: results and implications

et al. 1998

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On the origin of the `35‐μs kinetics' of P680^+⋅ reduction in photosystem II with an intact water oxidising complex

1998

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The origin of the`35-W Ws kinetics' of P680 c reduction in photosystem II (PS II) with an intact water oxidising complex has been analysed by comparative measurements of laser flash induced changes of the 830-nm absorption and the relative quantum yield of chlorophyll (Chl) fluorescence. The latter parameter was monitored at a time resolution of 500 ns by using newly developed home built equipment [Reifarth, F., Christen, G. and Renger, G. (1997)

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Modification of the Water Oxidizing Complex in Leaves of the dgd1 Mutant of Arabidopsis thaliana Deficient in the Galactolipid Digalactosyldiacylglycerol

Reifarth

Christen

et al. 1997

Biochemistry

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The primary biochemical defect in the genetically well characterized dgd1 mutant of Arabidopsis thaliana causes a 90% reduction in the relative amount of the galactolipid digalactosyldiacylglycerol (DGDG). To study the effect of this DGDG deficiency on photosystem II (PS II), time-resolved transients of laser-flash-induced changes of the relative fluorescence quantum yield Fvar,rel(t) were measured in whole leaves from wild-type and the dgd1 mutant. The results obtained reveal (i) in untreated leaves the decay kinetics of Fvar, rel(t) reflecting QA.- reoxidation by endogenous plastoquinone are very similar in wild-type and the dgd1 mutant at room temperature, (ii) the Arrhenius plot of the temperature dependence of electron transfer from QA.- to QB exhibits a break point at about 19 degrees C in wild-type and about 12 degrees C in the dgd1 mutant, (iii) in leaves treated with DCMU the slow reoxidation of QA.- by the PS II donor side is blocked to a much higher extent in the dgd1 mutant (about 50%) compared to wild-type (about 10%), and iv) the normalized amplitude of Fvar,rel(t = 1 micros) reflecting the percentage of fast P680.+ reduction by YZ exhibits a characteristic period four oscillation in wild-type while this feature is strongly damped in the dgd1 mutant. Presumably, the severe DGDG deficiency is causing the thermal down shift of a lipid phase transition that affects the QA.- reoxidation by QB. Most strikingly, the properties of the WOC are modified as a result of reduced DGDG content. Thus, the lipid DGDG appears to be of structural relevance for the WOC.

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G. Christen

P680^+•Reduction Kinetics and Redox Transition Probability of the Water Oxidizing Complex as a Function of pH and H/D Isotope Exchange in Spinach Thylakoids

The Role of Hydrogen Bonds for the Multiphasic P680⁺^• Reduction by Y_Z in Photosystem II with Intact Oxyen Evolution Capacity. Analysis of Kinetic H/D Isotope Exchange Effects

Application of the Marcus theory for analysis of the temperature dependence of the reactions leading to photosynthetic water oxidation: results and implications

On the origin of the `35‐μs kinetics' of P680^+⋅ reduction in photosystem II with an intact water oxidising complex

Modification of the Water Oxidizing Complex in Leaves of the dgd1 Mutant of Arabidopsis thaliana Deficient in the Galactolipid Digalactosyldiacylglycerol

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G. Christen

P680+•Reduction Kinetics and Redox Transition Probability of the Water Oxidizing Complex as a Function of pH and H/D Isotope Exchange in Spinach Thylakoids

The Role of Hydrogen Bonds for the Multiphasic P680+• Reduction by YZ in Photosystem II with Intact Oxyen Evolution Capacity. Analysis of Kinetic H/D Isotope Exchange Effects

Application of the Marcus theory for analysis of the temperature dependence of the reactions leading to photosynthetic water oxidation: results and implications

On the origin of the `35‐μs kinetics' of P680+⋅ reduction in photosystem II with an intact water oxidising complex

Modification of the Water Oxidizing Complex in Leaves of the dgd1 Mutant of Arabidopsis thaliana Deficient in the Galactolipid Digalactosyldiacylglycerol

Contact Info

Product

Resources

About

P680^+•Reduction Kinetics and Redox Transition Probability of the Water Oxidizing Complex as a Function of pH and H/D Isotope Exchange in Spinach Thylakoids

The Role of Hydrogen Bonds for the Multiphasic P680⁺^• Reduction by Y_Z in Photosystem II with Intact Oxyen Evolution Capacity. Analysis of Kinetic H/D Isotope Exchange Effects

On the origin of the `35‐μs kinetics' of P680^+⋅ reduction in photosystem II with an intact water oxidising complex