On electron transfer.

The tunneling transfer of electrons between two sites, appropriate to biological intermolecular electron transfer, contains physical considerations which are not important in the tunneling transfer between two metals. Analyses (such as the recent one by Hales) based on the well-known formula for the latter but applied to the former case are quantitatively and qualitatively misleading.     

Respiratory electron transfer activity in an asolectin-isooctane reverse micellar system.

Bovine heart submitochondrial particles (SMP) were solubilized in an asolectin isooctane reverse micellar system and the functionality of the respiratory chain was tested by spectroscopic and amperometric techniques. Electron transfer rate supported by NADH was very slow as evidenced by the low cytochrome reduction levels attained over long incubation periods. In the presence of KCN, NADH caused 34% and 12.5% reduction of the cytochromes aa3 and c, respectively, and negligible reduction of cytochrome b. Supplementation of the system with menadione rose the NADH-dependent reduction of all the cytochromes to levels that were close to the total content. However, no measurable O2 uptake activity took place in the presence of NADH plus menadione, or with ascorbate (or NADH) plus TMPD reducing systems. Therefore, it is suggested that in the organic medium, electron transfer from NADH to O2 is arrested at the terminal oxidase step. Cytochrome oxidase reduced by ascorbate (or NADH) plus TMPD seems to be trapped in its half reduced state (ie, a2+ a3(3+)). Although it is poorly reactive with O2, it can transfer electrons back to cytochrome c and TMPD. The electron transfer block to O2 was overcome when PMS was used instead of TMPD. This seems to be due to the recognized capacity of PMSH2 to carry out simultaneous reduction of both a CuA and a3 CuB redox centers of cytochrome oxidase. The cytochrome oxidase reaction in the organic solvent was highly sensitive to KCN (Ki 1.9 microM) and showed bell-shaped kinetics towards the PMS concentration and a sigmoidal response to water concentration, reaching its maximal turnover number (18 s-1) at 4 mM PMS and 1.1% (v/v) water.(ABSTRACT TRUNCATED AT 250 WORDS)     

Optical investigation of the electron transfer protein azurin-gold nanoparticle system

The hybrid system obtained by conjugating the protein azurin, which is a very stable and well-described protein showing a unique interplay among its electron transfer and optical properties, with 20-nm sized gold nanoparticles has been investigated. Binding of azurin molecules to gold nanoparticle surface results in the red shift of the nanoparticle resonance plasmon band and in the quenching of the azurin single tryptophan fluorescence signal. These findings together with the estimate of the hydrodynamic radius of the composite, obtained by means of Dynamic Light Scattering, are consistent with the formation of a monolayer of protein molecules, with preserved natural folding, on nanoparticle surface. The fluorescence quenching of azurin bound molecules is explained by an energy transfer from protein to metal surface and it is discussed in terms of the involvement of the Az electron transfer route in the interaction of the protein with the nanoparticle.     

The thermodynamics and kinetics of electron transfer in the cytochrome P450cam enzyme system.

In anaerobic environments the first electron transfer in substrate-free P450cam is known to be thermodynamically unfavourable, but in the presence of dioxygen the reduction potential for the reaction shifts positively to make electron transfer thermodynamically favourable. Nevertheless a slower rate of electron transfer is observed in the substrate-free P450cam compared to substrate-bound P450cam. The ferric haem centre in substrate-free P450cam changes from six co-ordinate to five co-ordinate when reduced whereas in substrate-bound P450cam the iron centre remains five co-ordinate in both oxidation states. The slower rate of electron transfer in the substrate-free P450cam is therefore attributed to a larger reorganisation energy as predicted by Marcus theory.     

The iron-sulfur cluster of electron transfer flavoprotein-ubiquinone oxidoreductase is the electron acceptor for electron transfer flavoprotein

Electron transfer flavoprotein-ubiquinone oxidoreductase (ETF-QO) accepts electrons from electron transfer flavoprotein (ETF) and reduces ubiquinone from the ubiquinone pool. It contains one [4Fe-4S] (2+,1+) and one FAD, which are diamagnetic in the isolated oxidized enzyme and can be reduced to paramagnetic forms by enzymatic donors or dithionite. In the porcine protein, threonine 367 is hydrogen bonded to N1 and O2 of the flavin ring of the FAD. The analogous site in Rhodobacter sphaeroides ETF-QO is asparagine 338. Mutations N338T and N338A were introduced into the R. sphaeroides protein by site-directed mutagenesis to determine the impact of hydrogen bonding at this site on redox potentials and activity. The mutations did not alter the optical spectra, EPR g-values, spin-lattice relaxation rates, or the [4Fe-4S] (2+,1+) to FAD point-dipole interspin distances. The mutations had no impact on the reduction potential for the iron-sulfur cluster, which was monitored by changes in the continuous wave EPR signals of the [4Fe-4S] (+) at 15 K. For the FAD semiquinone, significantly different potentials were obtained by monitoring the titration at 100 or 293 K. Based on spectra at 293 K the N338T mutation shifted the first and second midpoint potentials for the FAD from +47 and -30 mV for wild type to -11 and -19 mV, respectively. The N338A mutation decreased the potentials to -37 and -49 mV. Lowering the midpoint potentials resulted in a decrease in the quinone reductase activity and negligible impact on disproportionation of ETF 1e (-) catalyzed by ETF-QO. These observations indicate that the FAD is involved in electron transfer to ubiquinone but not in electron transfer from ETF to ETF-QO. Therefore, the iron-sulfur cluster is the immediate acceptor from ETF.     

Chemically gated electron transfer. A means of accelerating and regulating rates of biological electron transfer

Long-range protein electron transfer [ET] reactions may be relatively slow because of long ET distance and low driving force. It is possible to dramatically increase the rate of such nonadiabatic reactions by using an adiabatic chemical reaction to activate the system for rapid ET. Three such examples are discussed; nitrogenase, pyruvate:ferredoxin oxidoreductase, and the methylamine dehydrogenase-amicyanin complex. In each example, the faster activated ET reaction is gated (i.e., rate-limited) by the chemical reaction. However, the reaction rate is still orders of magnitude greater than that of the ungated true ET reaction in the absence of chemical activation. Models are presented to describe the mechanisms of activation in the context of ET theory, and the relevance of such chemically gated ET to the regulation of metabolism is discussed.     

Rate enhancement of the electron transfer the adrenodoxin-adrenodoxin reductase system by dicarboxylic acids

The rate of electron transport in the cytochrome P-450 system in adrenocortical mitochondria was studied with purified adrenodoxin reductase, adrenodoxin and cytochrome c. Oxaloacetate enhanced the rate at concentrations of less than 1 mM; malate, succinate and fumarate enhanced the rate to a lesser extent; and pyruvate and alpha-ketoglutarate had no appreciable effect. The rate enhancement was observed when the reagents were preincubated with adrenodoxin, but not with adrenodoxin reductase. Rate enhancement was also evident when the rate limiting step was at adrenodoxin in the electron transport system.     

Virtual intermediates in photosynthetic electron transfer.

We explore the possibility of virtual transfer in the primary charge separation of photosynthetic bacteria within the context of several types of experimental data. We show that the peak that might be expected in the virtual rate as electric fields vary the intermediate state energy is severely broadened by coupling to high-frequency modes. The Stark absorption kinetics data are thus consistent with virtual transfer in the primary charge separation. High-frequency coupling also makes the temperature dependence weak over a wide range of parameters. We demonstrate that Stark fluorescence anisotropy data, usually taken as evidence of virtual transfer, can in fact be consistent with two-step transfer. We suggest a two-pulse excitation experiment to quantify the contributions from two-step and virtual transfer. We show that virtual absorption into a charge transfer state can make a substantial contribution to the Stark absorption spectrum in a way that is not related to any derivative of the absorption spectrum.     

Activation of electron transfer reactions of the blue proteins.

Thermal activation of electron transfer reactions of the blue proteins is considered in terms of vibronic coupling. Use of the electron paramagnetic resonance spectral distribution to obtain an estimate of the force constant for the relevant protein mode is proposed and demonstrated. This analysis leads to a model in which the configurations of the cupric and cuprous sites are displaced only a few degrees from each other, both being close to the configuration midway between planar and tetrahedral.     

Comparative and evolutionary aspects of the photosynthetic electron transfer system of purple bacteria

The cyclic electron transfer system in purple bacteria is composed of the photosynthetic reaction center, the cytochromebc ₁ complex, cytochromec ₂, and ubiquinone. These components share many characteristics with those of photosynthesis and respiration in other organisms. Studies of the cyclic electron transfer system have provided useful insights about the evolution and general mechanisms of membranous energy-conserving systems. The photosynthetic system in purple bacteria may represent a prototype of highly efficient, energy-conserving electron transfer systems in the organisms. Recipient of the Botanical Society Award of Young Scientists, 1992