VECTORIAL ELECTRON TRANSPORT ACROSS LIPID VESICLE MEMBRANES DRIVEN BY TWO PHOTOREACTIONS. I. ETHYLENEDIAMINETETRAACETIC ACID AS AN ELECTRON DONOR via FLAVIN TRIPLET STATE IN THE INNER COMPARTMENT AND CYTOCHROME c AS AN ELECTRON ACCEPTOR FROM CHLOROPHYLL TRIPLET STATE IN THE OUTER COMPARTMENT

Negatively charged vesicle suspensions containing chlorophyll a (chl) dissolved in the lipid bilayer, flavin mononucleotide (FMN) and/or ethylenediaminetetraacetic acid (EDTA) enclosed in the inner compartment as electron sources and oxidized cytochrome c (cyt c[ox]) in the outer compartment as an electron acceptor have been studied using laser flash photolysis and steady-state irradiation methods. Cytochrome c initially quenches the chl triplet state (³chl) generating the chlorophyll cation radical (chi⁺′) in the membrane. Reverse electron transfer from cyt c(red) to chl^+. subsequently occurs in a kinetically biphasic reaction, with rate constants of 430 pT 30 and 21.9 pT 1.7 s^?1 for the fast and slow phases, respectively. In the absence of FMN, reduction of chl⁺′ by EDTA in the inner compartment can be observed during steady-state irradiation but not in a laser flash photolysis experiment. This is due to a low reaction yield, which is probably limited by the repulsive electrostatic interaction between EDTA and the negatively charged membrane. When FMN was enclosed together with EDTA in the inner Compartment, the reaction yield of vectorial electron transfer across the bilayer from EDTA to cyt c(oX) was increased by a factor of six during steadystate white light irradiation. Laser flash photolysis and steady-state irradiation experiments using red and blue light excitation have demonstrated that the enhancement mechanism involves the formation of fully reduced FMN by blue light-sensitized photooxidation of EDTA via the flavin triplet state, occumng simultaneously with red lightsensitized electron transfer to cyt c via the chlorophyll triplet state.     

CHLOROPHYLL PHOTOSENSITIZED ELECTRON TRANSFER REACTIONS IN LIPID VESICLES:ENHANCEMENT IN YIELD OF VECTORIAL ELECTRON TRANSFER ACROSS THE BILAYER FROM REDUCED CYTOCHROME c TO OXIDIZED FERREDOXIN BY ADDITION OF VALINOMYCIN PLUS POTASSIUM ION

Chlorophyll photosensitized electron transfer across a vesicle bilayer from reduced cytochrome c in the inner compartment to oxidized ferredoxin in the outer compartment, using propylene diquat as a mediator, has been investigated using both steady-state and laser flash photolysis methods. One of the factors limiting the quantum yield is the transmembrane potential, which is formed during sample preparation and is increased by the electron transfer process across the membrane bilayer. This limitation can be diminished by the incorporation of valinomycin into the bilayer in the presence of potassium ion. The overall quantum yield can be approximately doubled (up to a total of 22% based on the chlorophyll triplet which is quenched, and 2.8% based on the absorbed quanta) by valinomycin addition. Another quantum yield limitation arises from the accumulation of oxidized cytochrome c in the inner aqueous compartment, which is formed as a consequence of the transbilayer electron transport process and can quench triplet chlorophyll on the inner side of the vesicle. The chlorophyll cation radical generated in this way can participate in the electron exchange equilibrium between chlorophyll molecules located within the bilayer, and thus inhibit electron flow from inside to outside. This acts to limit the extent of cytochrome c oxidation to less than or equal to 50% of the original amount.     

TRIPLET STATE STUDIES OF FLAVINS BY ELECTRON PARAMAGNETIC RESONANCE—I

Abstract— The triplet state of flavin derivatives and d-amino acid oxidase was observed by electron paramagnetic resonance at 77°K.
Flavin triplets (Δ m =± 2) originate from the isoalloxazine ring and are resonant at 1560 guass.The half-life of the FMN triplet in 1 N HCl is 15 nisec.This life-time is prolonged indirectly by the presence of paramagnetic species, such as oxygen or free radicals.
The flavin triplet state is pH dependent.In neutral solution the nlaximum triplet yield is obtained and the longest life-time is observed.The triplet state is affected by intra-and inter-molecular complex formation, FAD is partially quenched by indirectly substituted adenine.Tryptophan quenches completely the FMN triplet.The FAD triplet of d-amino acid oxidase is enhanced but the life-time is shortened relative to a pure FAD solution.     

THE PHOTOREDUCTION OF FLAVINS BY AMINO ACIDS AND EDTA. A CONTINUOUS AND FLASH PHOTOLYSIS STUDY

Abstract— Primary and secondary photochemical processes in oxygen-free aqueous solution have been characterised for FMN alone and in the presence of EDTA and four amino acids using nanosecond and microsecond flash photolysis and continuous photolysis techniques. The relative contributions of oneelectron and two-electron (group or hydride transfer) reactions to the deactivation of the triplet has been determined by comparing the radical concentration (560 nm) with the bleaching of the ground state (446 nm). It was concluded that one-electron reactions (hydrogen atom or electron abstraction) are the major mode of reactivity of the flavin triplet state with all the suhstrates studied.
The nature of the reactions of the flavin semiquinone radical have been studied quantitatively by microsecond flash photolysis. These secondary reactions consist of either a 'back reaction' between the flavin and substrate radicals (tryptophan or glycyl-tyrosine) or the transfer of a second electron (or hydrogen atom) from the substrate radical to the flavin radical (EDTA, methionine and possibly cysteine) to form reduced flavin and oxidised substrate. From a comparison of the quantum yields of formation of reduced flavin using 'flash' and continuous irradiation, an additional pathway for the decay of the flavin radical is suggested to occur at low light intensities in the presence of glycyl-tyrosine or histidine.     

CHLOROPHYLL PHOTOSENSITIZED ELECTRON TRANSFER REACTIONS IN LIPID BILAYER VESICLES: VECTORIAL ELECTRON TRANSFER ACROSS THE BILAYER FROM REDUCED CYTOCHROME c IN THE INNER COMPARTMENT TO OXIDIZED FERREDOXIN IN THE OUTER COMPARTMENT

A negatively charged large unilamellar vesicle system containing a membrane-bound photo-sensitizer (chlorophyll, Chi), a reduced redox protein [cytochrome c, cyt c(red)] in the inner aqueous compartment, an oxidized redox protein [ferredoxin, Fd(ox)] in the outer aqueous compartment, and propylene diquat (PDQ²⁺) as a mediator, was investigated using both flash and steady-state photolysis techniques. The results demonstrate that the light-generated triplet state of Chi (³Chl) was initially quenched by PDQ²⁺ at the outer membrane surface to form Chi cation radical (Chl⁺) and the reduced diquat (PDQ⁺). This was succeeded by a biphasic recombination between Chi⁺ and PDQ⁺. The slow phase of the recombination process, which represents reverse electron transfer between Chl⁺ and those PDQ⁺ molecules which escaped from the membrane surface, could be suppressed effectively both by the reduction of Chl^ in the inner monolayer of the vesicles by cyt c(red), and by the reoxidation of PDQ⁺ by Fd(ox) in the outer aqueous compartment. These reactions lead to the permanent accumulation of oxidized and reduced product proteins, i.e. cyt c(ox) in the inner compartment and Fd(red) in the outer compartment. The yields of such accumulation were 11%, based on the ³Chl quenched, and 1.4%, based on absorbed quanta, under the conditions used in the present study. This system mimics one of the key events in natural photosynthesis and results in an appreciable storage of electromagnetic energy in the reaction products.     

THE FLAVIN-SENSITIZED PHOTOOXIDATION OF NUCLEOTIDES—II. THE PARTICIPATION OF THE FLAVIN TRIPLET STATE

Abstract— –A study has been made of the effects of a series of nucleotides upon the electronic excited states of lumiflavin in order to determine the mechanism of their flavin-sensitized oxidation. A hydrogen-abstraction mechanism is ruled out, because if the nucleotide acts as a reducing agent for the excited dye molecules, it should increase the rate of reduction of the dye when the irradiation is carried out in the absence of oxygen. However, each of the nucleotides studied was found to reduce the rate of anaerobic photoreduction. While oxidation by an intermediate species such as the dye 'moloxide' or singlet oxygen is not entirely ruled out, our evidence suggests that the initial reaction is between the nucleotide and the flavin triplet. This results in a loss of the triplet excitation energy and is a very efficient reaction, guanosine monophosphate shewing 36 per cent of the triplet quenching efficiency of potassium iodide. The relative rates of reaction of the nucleotides with the flavin triplet exactly parallels their quantum yields of sensitized photo-oxidation. The formation of ground-state complexes between flavin and nucleotide and the participation of the singlet excited state of the flavin are not considered to be important.     

PHOTOCHEMICAL INVESTIGATIONS OF OXAZINE, THIAZINE AND SELENAZINE DYES. THE REACTIVITY OF PROTOLYTIC TRIPLET FORMS IN ELECTRON TRANSFER REACTIONS

Abstract— The photoreduction of oxonine, thionine and selenine with the reducing agent allylthiourea was investigated by flash photolysis. The oxonine triplet state was produced by triplet-triplet energy transfer with 9,10-dibromoanthracene as donor. For all three dyes the rate constant of the electron transfer is considerably higher for the acid triplet form than that of the corresponding reaction of the basic triplet form. It is shown that the higher reactivity of the acid triplet can be related to its higher reduction potential which is available from the difference of the pK values of triplet and semiquinone of the dye.     

THE KINETICS OF REDUCTION OF CYTOCHROME c BY SEMI-REDUCED FLAVIN

Abstract— Flavin mononucleotide radicals, FMNH', generated by laser flash photolysis of FMN in the presence of the electron donors, histidine, guanosine monophosphate or EDTA, were found to reduce cytochrome c with an apparent rate constant of 6 ± 10⁷ M ⁻¹ s⁻¹. These flash photolysis results were, however, complicated by the electron donor radicals formed simultaneously which, particularly with EDTA, also lead to reduction of cytochrome c. Pulse radiolysis of a nitrous oxide saturated aqueous solution of FMN containing a high concentration of HCOONa, leads to the exclusive formation of FMNH'. By adding small concentrations of cytochrome c to this solution, a rate constant of 4.0 ± 10⁻¹ M ⁻¹ s⁻¹ was obtained for the reduction of cytochrome c by FMNH'. Replacement of the HCOONa by EDTA in such solutions leads to further routes for reduction of cytochrome c on radiolysis. as in the photolytic situation. The relevance of these results to flavin-photosensitised reduction of cytochrome c and other components of the mitochondrial electron transport chain is discussed.     

QUENCHING OF OXONINE EXCITED STATES BY EDTA VIA ELECTRON TRANSFER AND DEACTIVATION PROCESSES. A COMPARATIVE STUDY OF EXCITED SINGLET AND TRIPLET STATE REACTIVITY

The quenching of excited singlet oxonine by EDTA in aqueous solution leads mainly to deactivation of the dye to the ground state and, to a lesser extent, to electron abstraction. The rate constants for these processes have been measured and compared to those for the same reactions involving the oxonine triplet state. The rate constant of electron abstraction is about ten times greater via the singlet state than via the triplet state. However, the rate constant of deactivation to the ground state is 10³-10⁴ times greater for the excited singlet state than for the triplet state, so that the efficiency of electron transfer is much smaller for the singlet state.     

FLAVIN-PHOTOREDUCTION BY CYANIDE: NUCLEOPHILIC ADDITION IN THE EXCITED TRIPLET STATE

Abstract— Flavin photochemistry as well as biochemistry consists of competitive 1e⁻ - and 2e⁻ -reduction pathways, depending on the nature of the substrate. We show that cyanide ion is a photosubstrate which suppresses 1e⁻-oxidoreduction and leads to exclusive formation of 6- and 9-cyano-1,5-dihydroflavin. The photoreduction mechanism is thus revealed as a nucleophilic addition of cyanide ion at the excited flavin triplet. Preparative photochemistry and isolation and characterization of cyanoflavins have been done, as well as thorough mechanistic studies by conventional flash photolysis. In contrast, nitrite ion is shown to be a normal photosubstrate for flavins leading to exclusive 1e⁻ -transfer followed by back donation.     

Flavin-mediated photoreactions in artificial systems: a possible model for the blue-light photoreceptor pigment in living systems.

Abstract— The photoreduction of cytochrome c and the photostimulation of oxygen uptake were studied in solutions of flavin and cytochrome as a possible model system for similar photoreactions which have been observed in vivo. Light causes the photoreduction of the flavin. Under aerobic conditions the photoreduced flavin reacts with oxygen to form the superoxide anion which in turn can reduce cytochrome c. Dismutation of the superoxide anions forms hydrogen peroxide which mediates the dark oxidation of the photoreduced cytochrome. Superoxide formation and dismutation also account for the light-induced oxygen uptake. Action spectra confirm the role of flavin in the photoreduction of cytochrome c and the photostimulation of oxygen uptake. Under anaerobic conditions the photoreduced flavin reduces cytochrome c directly. In the presence of an electron donor only catalytic amounts of flavin are required. In the absence of an added electron donor flavin itself can act as the electron donor if substrate amounts are present. Azide inhibits all of these flavin-mediated photoresponses. Azide also inhibits the photoreduction of cytochrome b which occurs in the mycelium of Newospora.     

ELECTROSTATIC EFFECTS IN THE PHOTOREDUCTION OF FLAVINS BY EDTA

The anaerobic photoreduction of riboflavin, flavin mononucleotide, N(3)-carboxymethylriboflavin, N(3)-methyl-lumiflavin, and lumiflavin by EDTA was studied in aqueous solution over the pH range 2.5–10. The electrostatic effects of the electron donor-acceptor pair produce a secondary effect on the reactivity, and this effect can be predicted from the product of the charges (Z_D x Z_A). The trianonic and tetraanonic species of EDTA have nitrogens which are free from intramolecular hydrogen bonding, and these species are potentially the most reactive. However, in some pH regions the electrostatic effect can become the dominant factor when both the electron donor and acceptor become negatively charged. The excited states of flavins are susceptible to charge effects whether the charge is localized on the side chain or involves the isoalloxazine ring system.     

MECHANISM OF PHOTOREDUCTION OF THIAZINE DYES BY EDTA STUDIED BY FLASH PHOTOLYSIS-II. pH DEPENDENCE OF ELECTRON ABSTRACTION RATE CONSTANT OF THE DYES IN THEIR TRIPLET STATE

Abstract— The pH dependence of the apparent reactivity of thiazine dyes in their triplet states has been studied in aqueous solutions, using as electron donor HY^-3, the trianionic species of ethylene diamine tetraacetic acid (EDTA), in the pH range 4–8. The pH dependence is found to be related to a change in the degree of protonation of the triplet excited dye. The apparent reactivity and lifetime of two differently protonated forms of thionine, azur B and methylene blue were determined by classical and dye-laser flash techniques, making it possible to evaluate the rate constant for electron abstraction of these molecules in their triplet states. It is found that: (a) protonation on the ring nitrogen increases the electron-abstraction rate constant of the triplet-state species about twenty-fold, and (b) methylation on the side amino groups decreases it.     

TRIPLET STATE STUDIES OF FLAVlNS BY ELECTRON PARAMAGNETTC RESONANCE-III

Abstract— A continuation of studies is presented on the excited triplet state of flavins using EPR techniques. Detailed experiments are reported on the triplet state of flavin-mono-nucleotide (FMN) and flavin-adenine-dinucleotide (FAD). Action spectra of triplet yield are explained in terms of the optical absorption for FMN and FAD. Effects of light saturation, concentration quenching and oxygen on the triplet state are discussed. It is suggested that the rate constant k ₃ for the intersystem crossover from the excited singlet to the triplet state is increased by oxygen and quenchers such as KI. Detailed kinetic studies are presented on the formation of the triplet state.     

THE EFFECT OF 8α-SUBSTITUTION ON FLAVIN TRIPLET STATE AND SEMIQUINONE PROPERTIES AS INVESTIGATED BY FLASH PHOTOLYSIS*

Abstract— Flash photolysis techniques have been used to study the effect of 8α-substitution on flavin triplet state formation and decay and on the properties of neutral and anionic serniquinones. Compared with riboflavin, the N(1) and N(3) isomers of 8α-histidylriboflavin show a lower triplet yield (?10%) and a faster rate of decay (? 4-Cfold). Acetylation of the histidyl a-amino groups and of the flavin ribityl side chain results in a 2-fold increase in triplet yield and a 2-fold slower rate of decay. The yield of neutral 8α-substituted flavin semiquinones upon flash photolysis in the presence of EDTA was approximately 50% that given by riboflavin. These substituted flavin neutral semiquinones dismutated at a rate 2–3 times slower than the corresponding unsubstituted form, although the anionic semiquinones dismutated at approximately the same rate. In the presence of oxygen, the kinetics of semiquinone decay changed from second order to pseudo-first order upon raising the pH, thus showing anionic semiquinone oxidation as seen previously with unsnbstituted flavins. The pK values for the ionization of the neutral 8α-substituted Aavin semiquinones are 1–1.5 units lower than the unsubstituted form. The anionic 8α-substituted flavin semiquinones react with oxygen at a rate 2–10 times more slowly than does the riboflavin form. Such alterations in properties probably reflect the electron-withdrawing effect of the 8α-substituents on the flavin ring system.     

SPINACH FERREDOXIN REDUCTION BY MEMBRANE-BOUND CHLOROPHYLL TRIPLET STATE VIA A DIQUAT MEDIATOR

Abstract Laser flash photolysis experiments have shown that the diquat analog containing a propylene bridge (PDQ²⁺), when electrostatically bound to negatively-charged vesicles containing chlorophyll, is able to mediate the rapid reduction ( k = 1.1 × 10⁵ s^-1) of spinach ferredoxin via electron transfer quenching of triplet state chlorophyll. The kinetics of formation and decay of reduced ferredoxin are consistent with a mechanism involving complex formation between oxidized ferredoxin and vesicle-bound PDQ²⁺. Under optimal conditions, approximately 15% of the quenched triplets yield reduced ferredoxin. This process is a model for soluble ferredoxin reduction which occurs in green plant photosystem I, and results in an appreciable storage of electromagnetic energy in the reaction products.     

THE REDUCTION AND QUENCHING OF PHOTOEXCITED FLAVINS BY EDTA

Riboflavin was irradiated anaerobically in aqueous EDTA solutions over the pH range 2.5–10. In other dye systems (Bonneau and Pereyre, 1975), only the trivalent anion of EDTA was found to have significant reactivity for photoreduction. For riboflavin, the reactivity begins with monoanionic EDTA, and the reactivity is markedly increased as the charge increases. This suggests that the charge on the reductant is more important to the electron transfer process for riboflavin than the formation of a nonhydrogen bonded nitrogen site on EDTA. At high concentrations of EDTA in the pH range 4–8, quenching of the photoreduction occurs, which can be explained by an energy transfer between the excited singlet state of riboflavin and trianionic EDTA, possibly as an association complex. The rate constants for the photoreduction of riboflavin by the monovalent, divalent, and trivalent anions of EDTA are 1.0 times 10⁷M^-1 s^-l, 4.8 times 10′M^-1 s^-l, and 2.0 times 10⁸M^-1s^-1, respectively. The rate constant for the singlet state quenching by trianionic EDTA is 3 times 10⁹M^-l s^-1, and the limiting quantum yield for intersystem crossing for riboflavin in aqueous solution is 0.50 ± 0.05.     

REDOX PROTEINS AS ELECTRON ACCEPTORS FROM CHLOROPHYLL TRIPLET STATE IN LIPID BILAYER VESICLES: KINETICS OF REDUCTION OF MEMBRANE RECONSTITUTED CYTOCHROME c OXIDASE MEDIATED BY 2,5-DI-t-BUTYL BENZOQUINONE AND CYTOCHROME c

Laser flash photolysis was used to determine the kinetics of electron transfer between membrane-bound triplet chlorophyll (3C), cytochrome c (cyt c) located in the external water phase, and vesicle-reconstituted cytochrome c oxidase (CCO). 2,5-Di-t-butyl benzoquinone (2,5 TBQ) was used as an electron transfer mediator between 3C and cyt c. A light-induced cyclic electron transfer sequence between the redox components was observed (3C----2.5 TBQ----cyt c----CCO----C+.). Under optimum conditions of membrane surface charge and ionic strength, the overall efficiency of CCO reduction (based on 3C generated by the laser flash) was 14%. Under the anaerobic conditions used, CCO reoxidation (occurring via electron transfer to C+.) was quite slow (halftime approx. 1 s at 75 mM ionic strength). The multicomponent system displayed a high level of stability, as indicated by its ability to undergo many cycles of reduction and reoxidation without any apparent degradation of the components. These results demonstrate the feasibility of constructing complex electron transfer chains, including both soluble and membrane-bound redox proteins, in artificial lipid bilayers, whose properties can be readily controlled by manipulating parameters such as ionic strength and membrane composition.     

PRODUCTION OF HYDROGEN BY A PHOTOGALVANIC CELL WITH A FLAVIN MONONUCLEOTIDE-EDTA SYSTEM

Abstract— The operation of a photogalvanic cell, [Pt[flavin mononucleotide (FMN)-EDTA, pH7][5NH₂SO₄]Pt], leads to the production of hydrogen at the cathode. The neutral semiquinone radical, arising from a one electron reduction of the FMN triplet state by EDTA, has been proposed as the most probable species exhibiting photogalvanic effect.     

Photochemically activated electron transport across unilamellar liposomes using coenzyme q10 and vitamin K1 as carriers

Large unilamellar Liposomes (LUVs) were prepared containing a photoreduction solution based upon flavin mononucleotide (FMN) and dispersed in a solution of cytochrome c^III, buffered at pH 7.4. On illumination with visible light (440 nm) reduced FMN was produced within the LUVs. When the liposomal membrane was constituted with unsaturated phospholipid and contained coenzyme Q₁₀ or vitamin K₁, electron and proton transport occurred across the membrane and external cytochrome c was reduced. In the absence of these quinones or if saturated lipid was used to prepare the liposome or if cholesterol was present, no electron transport took place. Addition of cardiolipin (negatively charged) appeared to increase the rate of transmembrane reduction. The system models a step in the Q-cycle.