Reductively activated nitrous oxide reductase reacts directly with substrate

In the terminal step of bacterial denitrification, N2O is converted to N2 at the mu4-sulfide bridged tetranuclear CuZ center of nitrous oxide reductase. The enzyme can be activated by reduced methyl viologen, with up to a 15-fold increase in specific activity. The reductively activated nitrous oxide reductase from Achromobacter cycloclastes was isolated and characterized by visible absorption and EPR spectroscopy, and both methods showed that the CuZ center can attain a [4Cu(I)] oxidation state. When N2O was added to the activated, reductant-free enzyme, distinct spectral changes were observed, indicating that this state of the enzyme interacts with substrate. This was further supported by the detection of 15N-labeled product in the absence of steady-state turnover conditions. A new absorption band around 970 nm appeared following reaction of activated nitrous oxide reductase with N2O, which may represent a catalytic intermediate state of the enzyme.     

Activation of N2O reduction by the fully reduced micro4-sulfide bridged tetranuclear Cu Z cluster in nitrous oxide reductase

The tetranuclear CuZ cluster catalyzes the two-electron reduction of N2O to N2 and H2O in the enzyme nitrous oxide reductase. This study shows that the fully reduced 4CuI form of the cluster correlates with the catalytic activity of the enzyme. This is the first demonstration that the S = 1/2 form of CuZ can be further reduced. Complementary DFT calculations support the experimental findings and demonstrate that N2O binding in a bent mu-1,3-bridging mode to the 4CuI form is most efficient due to strong back-bonding from two reduced copper atoms. This back-donation activates N2O for electrophilic attack by a proton.     

Redox dependent conformational changes in the mixed valence form of the cytochrome c oxidase from p. The reorganization of glutamic acid 278 is coupled to the electron transfer from/to heme a and the binuclear center. denitrificans

In this work we present the separation of FTIR difference signals induced by electron transfer to/from the redox centers of the cytochrome c oxidase from P. denitrificans and compare electrochemically induced FTIR difference spectra with those induced by CO photolysis. FTIR difference spectra of rebinding of CO to the half reduced (mixed valence) form of the cytochrome c oxidase after photolysis reflect the conformational changes induced by the rebinding of CO and by electron transfer reactions from heme a3 to heme a and further on to CUA. During this process, heme a3 (and CUB) are oxidized, whereas heme a and CuA are reduced. By subtracting these difference spectra from an electrochemically induced FTIR difference spectrum, where all four cofactors are reduced, the contributions for heme a3 (and CuB) could be separated. Correspondingly, the spectral contributions of heme a and CuA have been separated. The comparison of these spectra with the spectra calculated for the hemes on the basis of their redox dependent changes previously published in Hellwig et al., (Biochemistry 38, (1999) 1685-1694) show a high degree of similarity, except for additional signals coupled to the reorganization of the binuclear center upon CO rebinding. The separated spectra clearly show that the signals attributed to Glu278, an amino acid discussed to be crucial for proton pumping, is coupled to electron transfer to/from heme a and the binuclear heme a3-CuB center.     

Spectroscopic, computational, and kinetic studies of the mu4-sulfide-bridged tetranuclear CuZ cluster in N2O reductase: pH effect on the edge ligand and its contribution to reactivity

A combination of spectroscopy and density functional theory (DFT) calculations has been used to evaluate the pH effect at the CuZ site in Pseudomonas nautica (Pn) nitrous oxide reductase (N2OR) and Achromobacter cycloclastes (Ac) N2OR and its relevance to catalysis. Absorption, magnetic circular dichroism, and electron paramagnetic resonance with sulfur K-edge X-ray absorption spectra of the enzymes at high and low pH show minor changes. However, resonance Raman (rR) spectroscopy of PnN2OR at high pH shows that the 415 cm-1 Cu-S vibration (observed at low pH) shifts to higher frequency, loses intensity, and obtains a 9 cm-1 18O shift, implying significant Cu-O character, demonstrating the presence of a OH- ligand at the CuICuIV edge. From DFT calculations, protonation of either the OH- to H2O or the mu4-S2- to mu4-SH- would produce large spectral changes which are not observed. Alternatively, DFT calculations including a lysine residue at an H-bonding distance from the CuICuIV edge ligand show that the position of the OH- ligand depends on the protonation state of the lysine. This would change the coupling of the Cu-(OH) stretch with the Cu-S stretch, as observed in the rR spectrum. Thus, the observed pH effect (pKa approximately 9.2) likely reflects protonation equilibrium of the lysine residue, which would both raise E degrees and provide a proton for lowering the barrier for the N-O cleavage and for reduction of the [Cu4S(im)7OH]2+ to the fully reduced 4CuI active form for turnover.     

Insights into the mechanism of N2O reduction by reductively activated N2O reductase from kinetics and spectroscopic studies of pH effects

Nitrous oxide reductase (N2OR) from Achromobacter cycloclastes (Ac) can be reductively activated with reduced methyl viologen over a broad range of pH. Activated Ac N2OR displays a complex activity profile as a function of the pH at which catalytic turnover is measured. Spectroscopic and steady-state kinetics data suggest that [H+] has multiple effects on both the activation and the catalytic reactions. These experimental results are in good agreement with previous theoretical studies, which suggested that the transition state is stabilized by H-bonding interactions between the active site and an N2O-derived intermediate bound to the catalytic CuZ cluster.     

Ruthenium bisbipyridine complexes of horse heart cytochrome c: characterization and comparative intramolecular electron-transfer rates determined by pulse radiolysis and flash photolysis

The reaction of [Ru(bpy)2L(H2O)]2+ (bpy = 2,2'-bipyridine, L = imidazole, water) with reduced horse heart cytochrome c results in coordination of [RuII(bpy)2L] at the His 33 and His 26 sites. Coordination at the His 33 site gave a diastereomeric [RuII(bpy)2L]-His-cyt c(II) mixture favoring the lambda-Ru form regardless of the substituent on the bipyridine ligands, while substitution at the more buried His 26 site gave an isomeric distribution that varies according to the substituent on the bipyridine ligands. The diastereomeric aquoproteins (L = H2O) are distinguished by their redox potentials and their conversion to the corresponding fluorescent imidazole proteins. Intramolecular electron transfer between the reduced ruthenium bipyridine and cyt c(III) in [RuII(bpy.)(bpy)L]-His33-cyt c(III) was determined by reductive pulse radiolysis using the aqueous electron as a reducing agent, kret = (2.0 +/- 0.3) x 10(5) s-1, and kret is independent of the sixth ligand L = H2O, imidazole. In addition, the rate constant for intramolecular electron transfer from cyt c(II) to the ruthenium(III) center in [RuIII(bpy)2L]-His33-cyt c(II) was determined by oxidative pulse radiolysis using azide and carbonate radicals. This rate is very sensitive to the nature of the sixth ligand. When L = H2O, the intramolecular electron-transfer rate for the major diastereomer lambda-cis-[RuIII (bpy)2(H2O)]-His33-cyt c(II) is k = 1.1 x 10(4) s-1 and is independent of pH between 5.6 and 8.3. The minor delta-cis-[RuIII(bpy)2(H2O)]-His33-cyt c(II) isomer has pH-dependent electrochemistry and a lower rate of intramolecular electron transfer. Complete conversion from L = H2O to L = imidazole is slow, requiring more than 7 days in 1 M imidazole. A lower limit (k > 2 x 10(6) s-1) for the intramolecular electron-transfer rate constant in [RuIII(bpy)2(L)]-His33-cyt c(II), L = imidazole, could be obtained by pulse radiolysis in the absence of the slower reacting aquo species. This observation is in agreement with the value of 3 x 10(6) s-1 measured by flash photolysis. Earlier pulse radiolysis experiments primarily measured the aquoligated ruthenium protein, while the flash photolysis experiments measured the imidazole-ligated fraction because it is the only species oxidatively quenched in the photoinduced reactions. Intramolecular electron-transfer reactions for a new series of ruthenium bipyridine complexes, [Ru(dabpy)2L]-His33-cyt c proteins (dabpy = 4,4'-diamino-2,2'-bipyridine) (L = imidazole, pyridine, isonicotinamide and pyrazine), proceed with lower driving force, resulting in slower rate constants amenable to measurement by oxidative pulse radiolysis. The electron-transfer rate constants for this series spanned a wide range of the Marcus log k vs delta G plot.     

Direct immobilization of native yeast iso-1 cytochrome C on bare gold: fast electron relay to redox enzymes and zeptomole protein-film voltammetry

Cyclic voltammetry shows that yeast iso-1-cytochrome c (YCC), chemisorbed on a bare gold electrode via Cys102, exhibits fast, reversible interfacial electron transfer (k(0) = 1.8 x 10(3) s(-1)) and retains its native functionality. Vectorially immobilized YCC relays electrons to yeast cytochrome c peroxidase, and to both cytochrome cd(1) nitrite reductase (NIR) and nitric oxide reductase from Paracoccus denitrificans, thereby revealing the mechanistic properties of these enzymes. On a microelectrode, we measured nitrite turnover by approximately 80 zmol (49 000 molecules) of NIR, coadsorbed on 0.65 amol (390 000 molecules) of YCC.     

Laser photoinitiated nitrosylation of 3-electron reduced Nm europaea hydroxylamine oxidoreductase: kinetic and thermodynamic properties of the nitrosylated enzyme

Hydroxylamine-cytochrome c554 oxidoreductase (HAO) catalyzes the 4-e(-) oxidation of NH(2)OH to NO(2)(-) by cytochrome c554. The electrons are transferred from NH(2)OH to a 5-coordinate heme known as P(460), the active site of HAO. From P(460), c-type hemes transport the electrons through the enzyme to a remote solvent-exposed c-heme, where cyt c554 reduction occurs. When 3-60 microM NO* are photogenerated by laser flash photolysis of N,N'-bis-(carboxymethyl)-N,N'-dinitroso-1,4-phenylenediamine, in a solution containing approximately 1 microM HAO prereduced by 3 e(-)/subunit, the HAO c-heme pool is subsequently oxidized by up to 1 e(-)/HAO subunit. The reaction rate for HAO oxidation shows first-order dependence on [HAO], and zero-order dependence on [NO*] (k(obs) = 1250 +/- 150 s(-)(1)). However, the total HAO oxidized shows hyperbolic dependence on [NO*]. We suggest that NO* first binds reversibly to P(460) giving a {Fe(NO)}(6) moiety. Intramolecular electron transfer (IET) from the c-heme pool then reduces P(460) to {Fe(NO)}.(7) The overall binding constant (K) for formation of {Fe(NO)}(7) from free NO* and 3-e(-) reduced HAO was measured at (7.7 +/- 0.6) x10(4) M(-1). This value is larger than that for typical ferriheme proteins ( approximately 10(4) M(-1)), but much smaller than that for the corresponding ferroheme proteins ( approximately 10(11) M(-1)). The final product generated by nitrosylating 3-e(-) reduced HAO is believed to be the same species obtained by adding NH(2)OH to the fully oxidized enzyme. The experiments described herein suggest that when NH(2)OH and HAO first react, only two of the NH(2)OH electrons end up in the c-heme pool. The other two remain at P(460) as part of an {Fe(NO)}(7) moiety. These results are discussed in relation to earlier studies that investigated the effect of putting fully oxidized and fully reduced HAO under 1 atm of NO*.     

Biomaterial engineered electrodes for bioelectronics

A series of single-cysteine-containing cytochrome c, Cyt c, heme proteins including the wild-type Cyt c (from Saccharomyces cerevisiae) and the mutants (V33C, Q21C, R18C, G1C, K9C and K4C) exhibit direct electrical contact with Au-electrodes upon covalent attachment to a maleimide monolayer associated with the electrode. With the G1C-Cyt c mutant, which includes the cysteine residue in the polypeptide chain at position 1, the potential-induced switchable control of the interfacial electron transfer was observed. This heme protein includes a positively charged protein periphery that surrounds the attachment site and faces the electrode surface. Biasing of the electrode at a negative potential (-0.3 V vs. SCE) attracts the reduced Fe(II)-Cyt c heme protein to the electrode surface. Upon the application of a double-potential-step chronoamperometric signal onto the electrode, where the electrode potential is switched to +0.3 V and back to -0.3 V, the kinetics of the transient cathodic current, corresponding to the re-reduction of the Fe(III)-Cyt c, is controlled by the time interval between the oxidative and reductive potential steps. While a short time interval results in a rapid interfacial electron-transfer, ket1 = 20 s-1, long time intervals lead to a slow interfacial electron transfer to the Fe(III)-Cyt c, ket2 = 1.5 s-1. The fast interfacial electron-transfer rate-constant is attributed to the reduction of the surface-attracted Fe(III)-Cyt c. The slow interfacial electron-transfer rate constant is attributed to the electrostatic repulsion of the positively charged Cyt c from the electrode surface, resulting in long-range electron transfer exhibiting a lower rate constant. At intermediate time intervals between the oxidative and reductive steps, two populations of Cyt c, consisting of surface-attracted and surface-repelled heme proteins, are observed. Crosslinking of a layered affinity complex between the Cyt c and cytochrome oxidase, COx, on an Au-electrode yields an electrically-contacted, integrated, electrode for the four-electron reduction of O2 to water. Kinetic analysis reveals that the rate-limiting step in the bioelectrocatalytic reduction of O2 by the integrated Cyt c/COx electrode is the primary electron transfer from the electrode support to the Cyt c units.     

Fast reduction of a copper center in laccase by nitric oxide and formation of a peroxide intermediate

The rapid reduction of one of the copper atoms (type 2) of tree laccase by nitric oxide (NO) has been detected. Addition of NO to native laccase in the presence of oxygen leads to EPR changes consistent with fast reduction and slow reoxidation of this metal center. These events are paralleled by optical changes that are reminiscent of formation and decay of the peroxide intermediate in a fraction of the enzyme population. Formation of this species is only possible if the trinuclear copper cluster (type 2 plus type 3) is fully reduced. This condition can only be met if, as suggested previously, a fraction of the enzyme contains both type 3 coppers already reduced before addition of NO. Our data are consistent with this assumption. We have suggested recently that fast reduction of copper is the mechanism by which NO interacts with the oxidized dinuclear center in cytochrome c oxidase. The present experiments using laccase strongly support this view and suggest this reaction as a general mechanism by which copper proteins interact with NO. In addition, this provides an unexploited way to produce a stable peroxide intermediate in copper oxidases in which the full complement of copper atoms is present. This enables the O-O scission step in the catalytic cycle to be studied by electron addition to the peroxide derivative through the native electron entry site, type 1 copper.     

Spectroscopic studies of metal binding and metal selectivity in Bacillus subtilis BSco, a Homologue of the Yeast Mitochondrial Protein Sco1p

Sco1 is a mitochondrial membrane protein involved in the assembly of the CuA site of cytochrome c oxidase. The Bacillus subtilis genome contains a homologue of yeast Sco1, YpmQ (hereafter termed BSco), deletion of which leads to a phenotype lacking in caa3 (CuA-containing) oxidase activity but expressing normal levels of aa3 (quinol) oxidase activity. Here, we report the characterization of the metal binding site of BSco in its Cu(I)-, Cu(II)-, Zn(II)-, and Ni(II)-bound forms. Apo BSco was found to bind Cu(II), Zn(II), and Ni(II) at a 1:1 protein/metal ratio. The Cu(I) protein could be prepared by either dithionite reduction of the Cu(II) derivative or by reconstitution of the apo protein with Cu(I). X-ray absorption (XAS) spectroscopy showed that Cu(I) was coordinated by two cysteines at 2.22 +/- 0.01 A and by a weakly bound low-Z scatterer at 1.95 +/- 0.03 A. The Cu(II) derivative was reddish-orange and exhibited a strong type-2 thiolate to Cu(II) transition around 350 nm. Multifrequency electron paramagnetic resonance (EPR), electron-nuclear double resonance (ENDOR), and electron spin-echo envelope modulation (ESEEM) studies on the Cu(II) derivative provided evidence of one strongly coupled histidine residue, at least one strongly coupled cysteine, and coupling to an exchangeable proton. XAS spectroscopy indicated two cysteine ligands at 2.21 A and two O/N donor ligands at 1.95 A, at least one of which is derived from a coordinated histidine. The Zn(II) and Ni(II) derivatives were 4-coordinate with MS2N(His)X coordination. These results provide evidence that a copper chaperone can engage in redox chemistry at the metal center and may suggest interesting redox-based mechanisms for metalation of the mixed-valence CuA center of cytochrome c oxidase.     

Kinetic origin of the chelate effect. Base hydrolysis, H-exchange reactivity, and structures of syn,anti-[Co(cyclen)(NH3)2]3+ and syn,anti-[Co(cyclen)(diamine)]3+ ions (diamine = H2N(CH2)2NH2, H2N(CH2)3NH2)

The synthesis of syn,anti-[Co(cyclen)en](ClO4)3 (1(ClO4)3) and syn,anti-[Co(cyclen)tn](ClO4)3 (2(ClO4)3) is reported, as are single-crystal X-ray structures for syn,anti-[Co(cyclen)(NH3)2](ClO4)3 (3(ClO4)3). 3(ClO4)3: orthorhombic, Pnma, a = 17.805(4) A, b = 12.123(3) A, c = 9.493(2) A, alpha = beta = gamma = 90 degrees, Z = 4, R1 = 0.030. 1(ClO4)3: monoclinic, P2(1)/n, a = 8.892(2) A, b = 15.285(3) A, c = 15.466(3) A, alpha = 90 degrees, beta = 91.05(3) degrees, gamma = 90 degrees, Z = 4, R1 = 0.0657. 2Br3: orthorhombic, Pca2(1) a = 14.170(4) A, b = 10.623(3) A, c = 12.362(4) A, alpha = beta = gamma = 90 degrees, Z = 4, R1 = 0.0289. Rate constants for H/D exchange (D2O, I = 1.0 M, NaClO4, 25 degrees C) of the syn and anti NH protons (rate law: kobs = ko + kH[OD-]) and the apical NH, and the NH3 and NH2 protons (rate law: kobs = kH[OD-]) in the 1, 2, and 3 cations are reported. Deprotonation constants (K = [Co(cyclen-H)(diamine)2+]/[Co(cyclen)(diamine)3+][OH-]) were determined for 1 (5.5 +/- 0.5 M-1) and 2 (28 +/- 3 M-1). In alkaline solution 1, 2, and 3 hydrolyze to [Co(cyclen)(OH)2]+ via [Co(cyclen)(amine)OH)]2+ monodentates. Hydrolysis of 3 is two step: kobs(1) = kOH(1)[OH-], kobs(2) = ko + kOH(2)[OH-] (kOH(1) = (2.2 +/- 0.4) x 10(4) M-1 s-1, ko = (5.1 +/- 1.2) x 10(-4) s-1, kOH(2) = 1.0 +/- 0.1 M-1 s-1). Hydrolysis of 2 is biphasic: kobs(1) = k1K[OH-]/(1 + K[OH-] (k1 = 5.0 +/- 0.2 s-1, K = 28 M-1), kobs(2) = k2K2[OH-]/(1 + K2[OH-]) (k2 = 3.5 +/- 1.2 s-1, K2 = 1.2 +/- 0.8 M-1). Hydrolysis of 1 is monophasic: kobs = k1k2KK2[OH-]2/(1 + K[OH-1])(k-1 + k2K2[OH-]) (k1 = 0.035 +/- 0.004 s-1, k-1 = 2.9 +/- 0.6 s-1, K = 5.5 M-1, k2K2 = 4.0 M-1 s-1). The much slower rate of chelate ring-opening in 1, compared to loss of NH3 from 3, is rationalized in terms of a reduced ability of the former system to allow the bond angle expansion required to produce the SN1CB trigonal bipyramidal intermediate.     

Effect of electron availability on selectivity of O2 reduction by synthetic monometallic Fe porphyrins

Herein we report that biomimetic analogues of cytochrome c oxidase (CcO) couple reduction of O(2) to oxidation of a single-electron carrier, Ru(NH(3))(6)(2+), under steady-state catalytic turnover. Higher Ru(II) concentrations favor the 4-electron vs 2-electron O(2) reduction pathway. Our data indicate that the capacity of electrode-adsorbed Fe-only porphyrins to catalyze reduction of O(2) to H(2)O is due to high availability of electrons and is eliminated under the biologically relevant slow electron delivery.     

Weak interactions and molecular recognition in systems involving electron transfer proteins

Electrostatic interactions and other weak interactions between amino acid side chains on protein surfaces play important roles in molecular recognition, and the mechanism of their intermolecular interactions has gained much interest. We established that charged peptides are useful for investigating the molecular recognition character of proteins and their molecular interaction induced structural changes. Positively charged lysine peptides competitively inhibited electron transfer from reduced cytochrome f (cyt f or cytochrome c (cyt c) to oxidized plastocyanin (PC), due to neutralization of the negatively charged site of PC by formation of PC-lysine peptide complexes. Lysine peptides also inhibited electron transfer from cyt c to cytochrome c peroxidase. Likewise, negatively charged aspartic acid peptides interacted with the positively charged sites of cytfand cyt c, and competitively inhibited electron transfer from reduced cytfor cyt c to oxidized PC and from [Fe(CN)6]4- to oxidized cyt c. Changes in the geometry and a shift to a higher redox potential of the active site Cu of PC on oligolysine binding were detected by spectroscopic and electrochemical measurements, owing to the absence of absorption in the visible region for lysine peptides. Structural and redox potential changes were also observed for cyt f and cyt c by interaction with aspartic acid peptides.     

Multifrequency EPR and redox reactivity investigations of a bis(mu-thiolato)-dicopper(II,II) complex

From a new tripodal ligand [N2SS'H] with mixed N, S(thioether), and S(thiolate) donor set, the corresponding bis(mu-thiolato)dicopper(II) complex has been prepared and characterized. X-ray crystallographic analysis of the complex [Cu2(N2SS')2](ClO4)2.C4H10O (1) demonstrates that the two five-coordinated Cu atoms are bridged by two thiolates leading to a nearly planar Cu2S2 core with a Cu1...Cu1* distance of 3.418(8) A and a large bridging angle Cu1S1Cu1* of 94.92 degrees. X-band (10 GHz), Q-band (34 GHz), and F-Band (115 GHz) EPR spectra of 1 are consistent with a weakly coupled dicopper(II,II) center attributed to an S = 1 state. Simulations for the three frequencies are obtained with a unique set of electronic parameters. The mean values of the spin Hamiltonian parameters for 1 are D = 0.210(3) cm(-1), E = 0.0295(5) cm(-1), |E/D| = 0.140, gx = 2.030(2), gy = 2.032(2), gz = 2.128(2). The electrochemical one-electron reduction of 1 generates the mixed-valent CuIICuI species. EPR and UV-vis spectra are consistent with a type I localized mixed-valent species, while dinuclear CuA centers of native cytochrome c oxidase (CcO)1-3 or nitrous oxide reductase (N2OR)4 have a delocalized CuIICuI mixed-valent state. After reoxidation of the CuIICuI species, the initial complex 1 is regenerated through a reversible interconversion process.     

Mechanism of N2O reduction by the mu4-S tetranuclear CuZ cluster of nitrous oxide reductase

Reaction thermodynamics and potential energy surfaces are calculated using density functional theory to investigate the mechanism of the reductive cleavage of the N-O bond by the mu(4)-sulfide-bridged tetranuclear Cu(Z) site of nitrous oxide reductase. The Cu(Z) cluster provides an exogenous ligand-binding site, and, in its fully reduced 4Cu(I) state, the cluster turns off binding of stronger donor ligands while enabling the formation of the Cu(Z)-N(2)O complex through enhanced Cu(Z) --> N(2)O back-donation. The two copper atoms (Cu(I) and Cu(IV)) at the ligand-binding site of the cluster play a crucial role in the enzymatic function, as these atoms are directly involved in bridged N(2)O binding, bending the ligand to a configuration that resembles the transition state (TS) and contributing the two electrons for N(2)O reduction. The other atoms of the Cu(Z) cluster are required for extensive back-bonding with minimal sigma ligand-to-metal donation for the N(2)O activation. The low reaction barrier (18 kcal mol(-)(1)) of the direct cleavage of the N-O bond in the Cu(Z)-N(2)O complex is due to the stabilization of the TS by a strong Cu(IV)(2+)-O(-) bond. Due to the charge transfer from the Cu(Z) cluster to the N(2)O ligand, noncovalent interactions with the protein environment stabilize the polar TS and reduce the activation energy to an extent dependent on the strength of proton donor. After the N-O bond cleavage, the catalytic cycle consists of a sequence of alternating protonation/one-electron reduction steps which return the Cu(Z) cluster to the fully reduced (4Cu(I)) state for future turnover.     

VECTORIAL ELECTRON TRANSPORT ACROSS LIPID VESICLE MEMBRANES DRIVE BY TWO PHOTOREACTIONS. II. PHOTOCHEMICAL REGENERATION OF REDUCED CYTOCHROME c BY FLAVIN TRIPLET STATE AND ETHYLENEDIAMINETETRAACETIC ACID IN THE INNER COMPARTMENT AND REDUCTION OF FERREDOXIN BY CHLOROPHYLL TRIPLET STATE IN THE OUTER COMPARTMENT

We have attempted to mimic natural photosynthesis with regard to the photogeneration of a powerful reductant, using a negatively charged lipid bilayer vesicle system incorporating two photoreactions sensitized by a flavin analog (flavin mononucleotide [FMN]) and chlorophyll (chl) in their respective triplet states. Ethylenediamine-tetraacetic acid (EDTA) in the inner aqueous compartment was used as a sacrificial electron donor to the FMN triplet, and ferredoxin in the outer aqueous compartment served as the final electron acceptor (mediated via triplet electron transfer chain in this multicomponent system to be elucidated. By itself, EDTA does not function as an effective donor to membran-bound oxidized chl (chl^+.), which is formed by electron transfer from triplet chl to the viologen follwed by transbilayer electron migration. This is a consequence of electrostatic repulsive interactions with the negatively charged membrane. This limitation is avoided when FMN is used as a photomediator between EDTA and chl^+.. The overall reaction is dramatically increased in rate by enclosing cytochrom c together with EDTA and FMN in the inner compartment. The rate constant of the key step in the reaction, i.e. elctron transfer from reduced cytochrome c, generated via photoreduction by the FMN/EDTA system, to chl^+. is increased 20-fold over that obtained with cytochrome c alone as the elctron donor. One of the important constraints that limited the net electron transfer across the bilayer to 50% of the added cytochrome, i.e. inhibition by oxidized cytochrome c formed in the inner compartment, is avoided by the inclusion of the second photoreaction in this system, thus allowing photoreduction of all of the added ferredoxin to be achieved. This system provides a model for a photochemical energy storage process that utilizes two photorections operating in series resulting in electron flow across a lipid bilayer membrane.     

Diazeniumdiolate ions as leaving groups in anomeric displacement reactions: a protection-deprotection strategy for ionic diazeniumdiolates

Diazeniumdiolate ions [R2N-N(O)=N-O-] are of growing interest pharmacologically for their ability to generate up to two molar equivalents of bioactive nitric oxide (NO) spontaneously on protonating the amino nitrogen. Accordingly, their stability increases as the pH is raised. Here we show that the corresponding beta-glucosides [R2N-N(O)=N-O-Glc] decreased in stability with pH; when R2N was diethylamino, the rate equation was kobs = ko + kOH- [OH-], where ko = 7.8 x 10-7 s-1 and kOH- = 5.3 x 10-3 M-1 s-1. The primary products were 1,6-anhydroglucose and the regenerated R2N-N(O)=N-O- ion. The results were qualitatively similar to those of beta-glucosyl fluoride and p-nitrophenoxide, whose hydrolyses have been rationalized as proceeding via a glycal oxide intermediate. This chemistry offers a convenient strategy for protecting heat- and acid-sensitive diazeniumdiolate ions during manipulations that would otherwise destroy them. As an example, a poly(urethane) film that generated NO in physiological buffer at a surface flux comparable to that of the mammalian vascular endothelium was prepared by glucosylating the ionic diazeniumdiolate group attached to the diol monomer before reacting it with the bis-isocyanate, then removing the saccharide with base when the protecting group was no longer needed.     

CHLOROPHYLEPHOTOSENSITIZED ELECTRON TRANSFER BETWEEN CYTOCHROME c AND A LIPID-MODIFIED TRANSPARENT INDIUM OXIDE ELECTRODE

Both direct and chlorophyll-photosensitized electron transfer reactions between cytochrome c and a lipid-modified indium oxide electrode have been studied by cyclic voltammetry and photoelectrochemistry. The lipid films consisted of egg phosphatidylcholine (PC), either alone or in combination with the negatively charged surfactant dihexadecylphosphate (DHP-), and contained varying amounts of chlorophyll. The photocurrents were either ca-thodic, when cytochrome c was used in its oxidized form in the supporting electrolyte, or anodic when the reduced form of cytochrome c was present, with a magnitude that depended on the PC concentration and the applied voltage. Quantum efficiencies of the anodic and cathodic photocurrents reached their maxima (5% and 10/o, respectively), at an intermediate PC concentration (5 mg/mL in the membrane-forming solution), conditions under which the diffusion-controlled electrochemical response of cytochrome c was also maximal. Incorporation of DHP^- into the PC film increased both the direct and chlorophyll-photosensitized currents, presumably due to electrostatic binding of the positively charged cytochrome c to the electrode surface.