The effect of an applied electric field on the charge recombination kinetics in reaction centers reconstituted in planar lipid bilayers

Gopher, Asher; Blatt, Yoav; Schönfeld, Mordechay; Okamura, M. Y.; Fehér, G.; Montal, Mauricio

doi:10.1016/s0006-3495(85)83784-x

Cited by 109 publications

(69 citation statements)

References 35 publications

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“…There are several examples that illustrate the extent to which the lifetime of the radical pair involving

Q_{A}^{\cdot ‐}

depends on the free energy difference associated with the electron transfer from

Q_{A}^{\cdot ‐}

to the nearby Pheo A . In Rhodobacter sphaeroides , the lifetime of the radical pair changes as a function of the energy gap between Q A and Pheo and this has been studied by substituting different quinones for Q A and by imposing an external field [47,49,50]. When the energy gap is smaller than around 350 meV then repopulation of the P + Pheo − state dominates; when the energy gap is larger than that, the direct tunnelling recombination reaction dominates [47,49,50].…”

Section: Type II Reaction Centresmentioning

confidence: 99%

“…In Rhodobacter sphaeroides , the lifetime of the radical pair changes as a function of the energy gap between Q A and Pheo and this has been studied by substituting different quinones for Q A and by imposing an external field [47,49,50]. When the energy gap is smaller than around 350 meV then repopulation of the P + Pheo − state dominates; when the energy gap is larger than that, the direct tunnelling recombination reaction dominates [47,49,50].…”

Section: Type II Reaction Centresmentioning

confidence: 99%

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Back‐reactions, short‐circuits, leaks and other energy wasteful reactions in biological electron transfer: Redox tuning to survive life in O₂

2012

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Edited by Miguel Teixeira and Ricardo LouroKeywords: Electron transfer Photosystem Evolution Cytochrome b c1 and b 6 f Bioenergetics Reactive oxygen species (ROS) Oxidative stress Protective reactions a b s t r a c tThe energy-converting redox enzymes perform productive reactions efficiently despite the involvement of high energy intermediates in their catalytic cycles. This is achieved by kinetic control: with forward reactions being faster than competing, energy-wasteful reactions. This requires appropriate cofactor spacing, driving forces and reorganizational energies. These features evolved in ancestral enzymes in a low O 2 environment. When O 2 appeared, energy-converting enzymes had to deal with its troublesome chemistry. Various protective mechanisms duly evolved that are not directly related to the enzymes' principal redox roles. These protective mechanisms involve fine-tuning of reduction potentials, switching of pathways and the use of short circuits, back-reactions and side-paths, all of which compromise efficiency. This energetic loss is worth it since it minimises damage from reactive derivatives of O 2 and thus gives the organism a better chance of survival. We examine photosynthetic reaction centres, bc 1 and b 6 f complexes from this view point. In particular, the evolution of the heterodimeric PSI from its homodimeric ancestors is explained as providing a protective back-reaction pathway. This ''sacrifice-of-efficiency-for-protection'' concept should be generally applicable to bioenergetic enzymes in aerobic environments.

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“…There are several examples that illustrate the extent to which the lifetime of the radical pair involving

Q_{A}^{\cdot ‐}

depends on the free energy difference associated with the electron transfer from

Q_{A}^{\cdot ‐}

Section: Type II Reaction Centresmentioning

confidence: 99%

Section: Type II Reaction Centresmentioning

confidence: 99%

Back‐reactions, short‐circuits, leaks and other energy wasteful reactions in biological electron transfer: Redox tuning to survive life in O₂

2012

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“…For bacteriorhodopsin, there is evidence that the electrochemical proton gradient established by the protein inhibits the steady‐state proton pumping process, and hence exerts control over the photochemical cycle of the protein [13,14]. With respect to the photosynthetic reaction center, no effects of Δ μ˜ H + on truly steady functioning (at time scales exceeding 1 s) have been reported, although the rates of electron transfer processes within the reaction center have been shown to be affected by externally applied electric fields [15–19]. In view of the biological importance of the photosynthetic reaction center, it seems important to establish whether it is subject to a backpressure effect, and if it is, whether this backpressure effect is similar to that experienced by bacteriorhodopsin [14,20–23] and by what mechanism it arises.…”

mentioning

confidence: 99%

Pumping capacity of bacterial reaction centers and backpressure regulation of energy transduction

Rotterdam

Westerhoff²,

Visschers³

et al. 2001

European Journal of Biochemistry

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Transduction of free-energy by Rhodobacter sphaeroides reaction-center-light-harvesting-complex-1 (RCLH1) was quantified. RCLH1 complexes were reconstituted into liposomal membranes. The capacity of the RCLH1 complex to build up a proton motive force was examined at a range of incident light intensities, and induced proton permeabilities, in the presence of artificial electron donors and acceptors. Experiments were also performed with RCLH1 complexes in which the midpoint potential of the reaction center primary donor was modified over an 85-mV range by replacement of the tyrosine residue at the M210 position of the reaction center protein by histidine, phenylalanine, leucine or tryptophan. The intrinsic driving force with which the reaction center pumped protons tended to decrease as the midpoint potential of the primary donor was increased. This observation is discussed in terms of the control of the energetics of the first steps in light-driven electron transfer on the thermodynamic efficiency of the bacterial photosynthetic process. The light intensity at which half of the maximal proton motive force was generated, increased with increasing proton permeability of the membrane. This presents the first direct evidence for so-called backpressure control exerted by the proton motive force on steady-state cyclic electron transfer through and coupled proton pumping by the bacterial reaction center.Keywords: thermodynamics; bacterial photosynthesis; electron transport; reaction center; proton motive force.The fundamental event in photosynthesis is the conversion of light-energy into (Gibbs) free-energy of protons. This process of energy transduction takes place in plants, algae and certain species of bacteria. The transmembrane electron transfer, or charge separation, process occurs in specialized pigment±protein complexes collectively known as photosynthetic reaction centers. The best understood reaction center is that of the purple photosynthetic bacteria, and in particular of the bacterium Rhodobacter sphaeroides. Not only the atomic structure of this reaction center is known [1±3] but it has also been subjected to intensive spectroscopic study. The reaction center (RC) is intimately associated with the LH1 light-harvesting complex, to form the so-called RCLH1`core' complex.In RCLH1 core complexes, the photosynthetic process is initiated by the absorption of a photon, usually by the bacteriochlorophyll (Bchl) or carotenoid molecules of the LH1 antenna that are present in excess over the reaction center pigments. Excitation energy captured by the antenna pigments is transferred to the reaction center on the timescale of a few tens of picoseconds [4], creating the first singlet excited state of the reaction center primary donor, P, (P*) and so transforming P into a powerful reductant that is capable of reducing the adjacent cofactors.Transmembrane electron transfer is a multistep reaction involving the donation of an electron to the (Q A ) ubiquinone-A located within the reaction center protein on the opposite sid...

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“…Optimal photochemical yield decreases slightly with stronger secondary force. Some evidence for the reduction in photochemical yield due to stronger membrane potential, opposing light-induced proton active transport, has been indeed observed in experiments (Gopher et al, 1985;Lao et al 1993). The back-pressure effect of proton pump acceleration in the presence of weaker secondary force (Fig.…”

Section: Discussionmentioning

confidence: 68%

Photosynthetic models with maximum entropy production in irreversible charge transfer steps

Juretić

Upanović

2003

Computational Biology and Chemistry

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Steady-state bacterial photosynthesis is modelled as cyclic chemical reaction and is examined with respect to overall efficiency, power transfer efficiency, and entropy production. A nonlinear flux-force relationship is assumed. The simplest two-state kinetic model bears complete analogy with the performance of an ideal (zero ohmic resistance of the P-N junction) solar cell. In both cases power transfer to external load is much higher than the 50% allowed by the impedance matching theorem for the linear flux-force relationship. When maximum entropy production is required in the transition with a load, one obtains high optimal photochemical yield of 97% and power transfer efficiency of 91%. In more complex photosynthetic models, entropy production is maximized in all irreversible electron/proton (non-slip) transitions in an iterative procedure. The resulting steady-state is stable with respect to an extremely wide range of initial values for forward rate constants. Optimal proton current increases proportionally to light intensity and decreases with an increase in the proton-motive force (the backpressure effect). Optimal affinity transfer efficiency is very high and nearly perfectly constant for different light absorption rates and for different electrochemical proton gradients. Optimal overall efficiency (of solar into proton-motive power) ranges from 10% (bacteriorhodopsin) to 19% (chlorophyll-based bacterial photosynthesis). Optimal time constants in a photocycle span a wide range from nanoseconds to milliseconds, just as corresponding experimental constants do. We conclude that photosynthetic proton pumps operate close to the maximum entropy production mode, connecting biological to thermodynamic evolution in a coupled self-amplifying process.

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The effect of an applied electric field on the charge recombination kinetics in reaction centers reconstituted in planar lipid bilayers

Cited by 109 publications

References 35 publications

Back‐reactions, short‐circuits, leaks and other energy wasteful reactions in biological electron transfer: Redox tuning to survive life in O₂

Back‐reactions, short‐circuits, leaks and other energy wasteful reactions in biological electron transfer: Redox tuning to survive life in O₂

Pumping capacity of bacterial reaction centers and backpressure regulation of energy transduction

Photosynthetic models with maximum entropy production in irreversible charge transfer steps

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The effect of an applied electric field on the charge recombination kinetics in reaction centers reconstituted in planar lipid bilayers

Cited by 109 publications

References 35 publications

Back‐reactions, short‐circuits, leaks and other energy wasteful reactions in biological electron transfer: Redox tuning to survive life in O2

Back‐reactions, short‐circuits, leaks and other energy wasteful reactions in biological electron transfer: Redox tuning to survive life in O2

Pumping capacity of bacterial reaction centers and backpressure regulation of energy transduction

Photosynthetic models with maximum entropy production in irreversible charge transfer steps

Contact Info

Product

Resources

About

Back‐reactions, short‐circuits, leaks and other energy wasteful reactions in biological electron transfer: Redox tuning to survive life in O₂

Back‐reactions, short‐circuits, leaks and other energy wasteful reactions in biological electron transfer: Redox tuning to survive life in O₂