Electrochemical Studies of Tirapazamine: Generation of the One-Electron Reduction Product

The electrochemical properties of the benzotriazine di-N-oxide, tirapazamine (SR4233), and the mono-and zero-N-oxides, SR4317 and SR4330 respectively, have been investigated in dimethylformamide and acetonitrile. The voltammetry of tirapazamine is complicated, with up to 6 reduction steps being identified, depending on the solvent. Both SR4317 and SR4330 show two reduction steps. The first reduction of all three compounds is a reversible or quasi-reversible step, which is assigned to a 1-electron addition. Cyclic voltammetric studies show that the anion radical product is stable, although the tirapazamine 1-electron addition product shows a tendency to participate in a chemical following reaction. Subsequent reduction steps are all highly irreversible in nature. The 2nd electron transfer of SR4317 results in the formation of the free base, SR4330, which is identified voltammetrically. Comparison is made with the voltammetric behaviour of quinoline and quinoline-oxide.     

Electrochemical Properties As A Function of Ph for the Benzotriazine DI-N-Oxides

The electrochemistry of five benzotriazine di-N-oxides has been examined by cyclic voltammetry and differential pulse and dc polarographies as a function of pH. Between the pH range 8.5 and 2 the trend to less negative potentials with lowering of pH can be described by an equation of the type Ep = - apH + b. Comparison has been made with the mono- and zero-N-oxides which were found to show virtually identical trends in electron affinity with pH. The general electrochemical characteristics for the di- and mono-N-oxides under acidic conditions were found to be comparable with the zero-N-oxide. This was particularly the case on repeat scanning in the cyclic voltammetric mode. The redox mechanism involved reduction by a 4-electron addition step and subsequent loss of the A-oxide group(s) yielding the intact benzotriazine heterocycle. The helerocycle was also redox active, involving a reversible 2-electron reduction. for the di-N-oxides these two stages could be identified as separate processes at alkaline pH, but ony a single step at acidic values. The mono-N-oxide in which the electrochemical behaviour was dominated by the triazine, showed only a single reduction step, although the single N-oxide group was redox active.     

Electron Transfer Reactions in RB90745, A Bioreductive Drug Having Both Aromatic N-Oxide and Nitroarene Moieties

The bifunctional hypoxia-specific cytotoxin RB90745, has a nitroimidazole moiety attached to an imidazo[1,2,-a]quinoxaline mono-N-oxide with a spacer/linking group. The reduction chemistry of the drug was studied by pulse radiolysis using the one electron reductant CO₂^˙-. As N-oxides and nitro compounds react with CO₂^˙- at diffusion controlled rates, initial reaction produced a mixture of the nitro radical (λ_max 410 nm) and the N-oxide radical (λ_max 550 nm) in a few microseconds. Subsequently an intramolecular electron transfer (IET) was observed (k = 1.0 ± 0.25 × 10³ s^-1 at pH 5-9), from the N-oxide to the more electron-affinic nitro group. This was confirmed by the first order decay rate of the radical at 550 nm and formation at 410 nm, which was independent of both the concentration of the parent compound and the radicals. The rates of electron transfer and the decay kinetics of the nitro anion radicals were pH dependent and three different pK_aS could be estimated for the one electron reduced species: 5.6 (nitroimidazole group) and 4.3, and 7.6 (N-oxide function). The radicals react with oxygen with rate constants of 3.1 × 10⁷ and 2.8 × 10⁶ dm³ mol^-1 s^-1 observed at 575 nm and 410 nm respectively. Steady state radiolysis studies indicated four electron stoichiometry for the reduction of the compound.     

The electrochemical preparation of FAD/ZnO with hemoglobin film-modified electrodes and their electroanalytical properties

Flavin adenine dinucleotide (FAD)-modified zinc oxide self-assembly films were prepared using repeated cyclic voltammetry. The electrochemical reaction of the hemoglobin with the FAD/ZnO self-assembly film-modified electrodes and their electrocatalytic properties were investigated. This paper describes the successful loading of the electrochemically active molecules of hemoglobin and FAD along with ZnO by electrochemical method. In addition to the cyclic voltammetry, an electrochemical quartz crystal microbalance was used to study the growth mechanism and the properties of the films. The FAD/zinc oxide films exhibited a single redox couple, which corresponded to the FAD redox couple. The electrocatalytic properties of the O2, H2O2, trichloroacetic acid and SO(3)2- were studied by the FAD/zinc oxide films in the absence or in the presence of hemoglobin. The electrocatalytic reduction current had been developed from the cathodic peak of the FAD/zinc oxide redox couple. The electrocatalytic process involved an interaction of hemoglobin and FAD/GC film-modified electrode to increase the electrocatalytic reduction current. The electrocatalytic reduction of O2 using the FAD/zinc oxide films was investigated by cyclic voltammetry and rotating ring-disk electrode methods.     

Selective interaction of tirapazamine with DNA bases and DNA

An electrochemical model has been used to study the reductive activation of the hypoxic cell cytotoxin tirapazamine (TPZ, 3-amino-1,2,4-benzotriazine-1,4-dioxide). Cyclic voltammetry and controlled potential electrolysis have been used to generate and study the 1-electron reduction product, the assumed biologically active species. Cyclic voltammetry of tirapazamine in dimethylformamide shows a quasi-reversible 1-electron reduction with the product showing a tendency to participate in a following chemical reaction. Controlled potential electrolysis to generate the 1-electron reduction product was unsuccessful due to the formation of a new redox-active species at less negative reduction potentials. However, the cyclic voltammetry of tirapazamine in the presence of E. coli DNA shows a decrease in the lifetime of the radical anion, signifying direct interaction with the DNA. The radical lifetime also decreased in the presence of adenine, thymine and guanine, but increased upon addition of cytosine and ribose. The study shows that cyclic voltammetry is an extremely useful tool for investigating the interaction between bio-reductive drugs and biological target molecules.     

Selective interaction of tirapazamine with DNA bases and DNA

An electrochemical model has been used to study the reductive activation of the hypoxic cell cytotoxin tirapazamine (TPZ, 3-amino-1,2,4-benzotriazine-1,4-dioxide). Cyclic voltammetry and controlled potential electrolysis have been used to generate and study the 1-electron reduction product, the assumed biologically active species. Cyclic voltammetry of tirapazamine in dimethylformamide shows a quasi-reversible 1-electron reduction with the product showing a tendency to participate in a following chemical reaction. Controlled potential electrolysis to generate the 1-electron reduction product was unsuccessful due to the formation of a new redox-active species at less negative reduction potentials. However, the cyclic voltammetry of tirapazamine in the presence of E. coli DNA shows a decrease in the lifetime of the radical anion, signifying direct interaction with the DNA. The radical lifetime also decreased in the presence of adenine, thymine and guanine, but increased upon addition of cytosine and ribose. The study shows that cyclic voltammetry is an extremely useful tool for investigating the interaction between bio-reductive drugs and biological target molecules.     

Electrochemical Characteristics of Nitro-Heterocyclic Compounds of Biological Interest. II. Nitrosochloramphenicol

The electrochemical Characteristics of nitrosochloramphenicol have been studied in aqueous buffer systems (pH 7.1) using direct current (d.c.) and differential pulse polarography. cyclic voltammetry and coulometric techniques. Up to 4 charge-transfer steps can be identified. The first reduction step is reversible both chemically and electrochemically. the charge-transfer product showing no tendency to undergo further reaction on the electrochemical time-scale. In contrast, the second reduction step is irreversible, with the product undergoing a fast following reaction to yield a redox-active species which was detected by cyclic voltammetry. From the data and by comparison with related systems. two reduction mechanisms are possible and are discussed.     

Electrochemical Characteristics of Nitro-Heterocyclic Compounds of Biological Interest: I. The Influence of Solvent

The electrochemical properties of three nitroimidazoles, a nitropyrazole, a nitrofuran and three nitroben-zenoid compounds have been extensively investigated in a range of solvents. The reduction pathway for the nitro group is independent of the cyclic function to which it is attached, but is strongly influenced by the nature of the solvent. In aqueous media, generally, a single, irreversible 4-electron reduction occurs to give the hydroxylamine. In aprotic media (dimethylformamide, methylene chloride or dimethylsulphoxide), a reversible one-electron reduction takes place to form a stable nitro radical anion. At more negative values, a further 3-electron reduction occurs, irreversibly to give the hydroxylamine. In mixed aqueous-organic systems, intermediate behaviour is found, with the reversibility of the RNO₂/RNO₂^- couple increasing with addition of organic medium. The control of the reduction pathway, by changing the electrolytic medium is discussed in relation to the biological activities of the drugs and identification of the short-lived reduction intermediate responsible for DNA damage.     

Electrochemistry of pterin cofactors and inhibitors of nitric oxide synthase.

Tetrahydrobiopterin (BH4) is an essential cofactor of nitric oxide synthase (NOS), but its function is not fully understood. Specifically, it is unclear whether BH4 participates directly in electron transfer. We investigated the redox properties of BH4 and several other pteridines with cyclic voltammetry and Osteryoung square wave voltammetry. BH4 was oxidized at a potential of +0.27 V vs normal hydrogen electrode (NHE); the corresponding reductive signal after the reversal of the scan direction was very small. Instead, reduction occurred at a potential of -0.16 V vs NHE; there was no corresponding oxidative signal. These two transitions were interdependent, indicating that the reductive wave at -0.16 V represented the regeneration of BH4 from its product of oxidation at +0.27 V. Similar voltammograms were obtained with tetrahydroneopterin and 6,7-dimethyltetrahydropterin, both of which can substitute for BH4 in NOS catalysis. Completely different voltammograms were obtained with 7,8-dihydrobiopterin, sepiapterin, 2'-deoxysepiapterin, and autoxidized BH4. These 7,8-dihydropterins, which do not sustain NOS catalysis, were oxidized at much higher potentials (+0.82-1.04 V vs NHE), and appreciable reduction did not occur between +1.2 and -0.8 V, in line with the concept of a redox role for BH4 in NOS catalysis. However, the electrochemical properties of the potent pterin-site NOS inhibitor 4-amino-BH4 resembled those of BH4, whereas the active pterin cofactor 5-methyl-BH4 was not re-reduced after oxidation. We conclude that the 2-electron redox cycling of the pterin cofactor between BH4 and quinonoid dihydrobiopterin is not essential for NO synthesis. The data are consistent with 1-electron redox cycling between BH4 and the trihydrobiopterin radical BH3(*).     

Electrochemical study of the reduction of toyocamycin and sangivamycin in aqueous media

The redox behaviour of two antibiotics, toyocamycin and sangivamycin, structurally related pyrrolopyrimidine nucleosides, and their reduction products in buffered aqueous media, have been examined by direct current polarography and cyclic voltammetry. Both compounds exhibit one 3-electron polarographic wave in the pH range 1-6. Macroscale electrolysis at the crest of the polarographic wave was followed electrochemically and by UV spectroscopy. The photochemical transformation of the reduction products on UV irradiation has been examined. It was found that the reduction of both compounds occurs in the pyrimidine ring, leading to two reduction products. One of these (lambda max = 306 nm) is photochemically reversible to the parent compound.     

Electrochemical Characteristics of Nitro-Heterocyclic Compounds of Biological Interest. II. Nitrosochloramphenicol

The electrochemical Characteristics of nitrosochloramphenicol have been studied in aqueous buffer systems (pH 7.1) using direct current (d.c.) and differential pulse polarography. cyclic voltammetry and coulometric techniques. Up to 4 charge-transfer steps can be identified. The first reduction step is reversible both chemically and electrochemically. the charge-transfer product showing no tendency to undergo further reaction on the electrochemical time-scale. In contrast, the second reduction step is irreversible, with the product undergoing a fast following reaction to yield a redox-active species which was detected by cyclic voltammetry. From the data and by comparison with related systems. two reduction mechanisms are possible and are discussed.     

Layer-by-layer fabrication and direct electrochemistry of glucose oxidase on single wall carbon nanotubes

Layer-by-layer assembly of glucose oxidase (GOx) with single-wall carbon nanotubes (SWCNTs) is achieved on the electrode surface based on the electrostatic attraction between positively charged GOx in pH 3.8 buffer and negatively charged carboxylic groups of CNTs. The cyclic voltammetry and electrochemical impedance spectroscopy are used to characterize the formation of multilayer films. In deaerated buffer solutions, the cyclic voltammetry of the multilayer films of {GOx/CNT}_n shows two pairs of well-behaved redox peaks that are assigned to the redox reactions of CNTs and GOx, respectively, confirming the effective immobilization of GOx on CNTs using the layer-by-layer technique. The redox peak currents of GOx increase linearly with the increased number of layers indicating the uniform growth of GOx in multilayer films. The dependence of the cyclic voltammetric response of GOx in multilayer films on the scan rate and pH is also studied. A linear decrease of the reduction current of oxygen at the {GOx/CNT}-modified electrodes with the addition of glucose suggests that such multilayer films of GOx retain the bioactivity and can be used as reagentless glucose biosensors.     

Redox properties of the calcium chelator Fura-2 in mimetic biomembranes

Fura-2 is one of the most commonly used fluorescent dyes to analyze the cytosolic Ca(2+) concentration ([Ca(2+)](i)) of living cells. Fura-2-dependent measurements of [Ca(2+)](i) are susceptible to changes of pH, reactive oxygen species concentration and membrane potential. Fura-2 is often loaded over the lipophilic cell membrane into the cytosol of a cell in its esterified form (Fura-2/AM) which is then cleaved by endogenous esterases. We have analyzed the electrochemical properties of Fura-2/AM and Fura-2 salt by cyclic voltammetry ("three-phase" and "thin-film" electrode methods). Using Fura-2/AM as a redox facilitator, we were able to mimic the transport of various ions across a lipophilic barrier. We show that Fura-2/AM in this biomimetic set-up can be reversibly oxidized in a single electrochemical step. Its redox reaction was highly proton sensitive in buffers with pH< or =6. At physiological pH of around 7.0, the oxidation of Fura-2/AM was coupled to an uptake of mono-anions across the liquid-liquid interface. The voltage-dependence of the redox cycle was sensitive to the free Ca(2+) concentration, either after de-esterification of Fura-2/AM, or when Fura-2 salt was used. The complex between Fura-2 and Ca(2+) ions is ionic (complexation occurs via the dissociated negative groups of Fura forms), while the redox transformations in Fura-2 occurs at the nitrogen atoms of the amino groups. Our results suggest that redox transformations of the Fura-2 forms do not affect the binding ability toward Ca(2+) ions and thus do not interfere with [Ca(2+)](i) measurements.     

Reductive activation of mitomycins A and C by vitamin C

The anticancer drug mitomycin C produces cytotoxic effects after being converted to a highly reactive bis-electrophile by a reductive activation, a reaction that a number of 1-electron or 2-electron oxidoreductase enzymes can perform in cells. Several reports in the literature indicate that ascorbic acid can modulate the cytotoxic effects of mitomycin C, either potentiating or inhibiting its effects. As ascorbic acid is a reducing agent that is known to be able to reduce quinones, it could be possible that the observed modulatory effects are a consequence of a direct redox reduction between mitomycin C and ascorbate. To determine if this is the case, the reaction between mitomycin C and ascorbate was studied using UV/Vis spectroscopy and LC/MS. We also studied the reaction of ascorbate with mitomycin A, a highly toxic member of the mitomycin family with a higher redox potential than mitomycin C. We found that ascorbate is capable to reduce mitomycin A efficiently, but it reduces mitomycin C rather inefficiently. The mechanisms of activation have been elucidated based on the kinetics of the reduction and on the analysis of the mitosene derivatives formed after the reaction. We found that the activation occurs by the interplay of three different mechanisms that contribute differently, depending on the pH of the reaction. As the reduction of mitomycin C by ascorbate is rather inefficiently at physiologically relevant pH values we conclude that the modulatory effect of ascorbate on the cytotoxicity of mitomycin C is not the result of a direct redox reaction and therefore this modulation must be the consequence of other biochemical mechanisms.     

A High Voltage Aqueous Zinc–Organic Hybrid Flow Battery

Water‐soluble redox‐active organic molecules have attracted extensive attention as electrical energy storage alternatives to redox‐active metals that are low in abundance and high in cost. Here an aqueous zinc–organic hybrid redox flow battery (RFB) is reported with a positive electrolyte comprising a functionalized 1,4‐hydroquinone bearing four (dimethylamino)methyl groups dissolved in sulfuric acid. By utilizing a three‐electrolyte, two‐membrane configuration this acidic positive electrolyte is effectively paired with an alkaline negative electrolyte comprising a Zn/[Zn(OH)₄]^2? redox couple and a hybrid RFB is operated at a high operating voltage of 2.0 V. It is shown that the electrochemical reversibility and kinetics of the organic redox species can be enhanced by an electrocatalyst, leading to a cyclic voltammetry peak separation as low as 35 mV and enabling an enhanced rate capability.     

Tuning the redox properties of a [4Fe-4S] center to modulate the activity of Mo-bisPGD periplasmic nitrate reductase

Molybdoenzymes are ubiquitous in living organisms and catalyze, for most of them, oxidation-reduction reactions using a large range of substrates. Periplasmic nitrate reductase (NapAB) from Rhodobacter sphaeroides catalyzes the 2-electron reduction of nitrate into nitrite. Its active site is a Mo bis-(pyranopterin guanine dinucleotide), or Mo-bisPGD, found in most prokaryotic molybdoenzymes. A [4Fe-4S] cluster and two c-type hemes form an intramolecular electron transfer chain that deliver electrons to the active site. Lysine 56 is a highly conserved amino acid which connects, through hydrogen-bonds, the [4Fe-4S] center to one of the pyranopterin ligands of the Mo-cofactor. This residue was proposed to be involved in the intramolecular electron transfer, either defining an electron transfer pathway between the two redox cofactors, and/or modulating their redox properties.In this work, we investigated the role of this lysine by combining site-directed mutagenesis, activity assays, redox titrations, EPR and HYSCORE spectroscopies. Removal of a positively-charged residue at position 56 strongly decreased the redox potential of the [4Fe-4S] cluster at pH?8 by 230?mV to 400?mV in the K56H and K56M mutants, respectively, thus affecting the kinetics of electron transfer from the hemes to the [4Fe-4S] center up to 5 orders of magnitude. This effect was partly reversed at acidic pH in the K56H mutant likely due to protonation of the imidazole ring of the histidine. Overall, our study demonstrates the critical role of a charged residue from the second coordination sphere in tuning the reduction potential of the [4Fe-4S] cluster in RsNapAB and related molybdoenzymes.     

Electroactive centers in Euphorbia latex and lentil seedling amine oxidases

The electrochemical behavior of redox centers in the active site of amine oxidases from lentil seedlings and Euphorbia characias latex was investigated using a mercury film electrode. Tyrosine-derived 6-hydroxydopa quinone (TPQ) and copper ions in the active site are redox centers of these amine oxidases. The enzymes undergo two reduction processes at negative potentials related to the reduction of the TPQ cofactor to the corresponding hydroquinones and the reduction of copper ions, (Cu(II)-->Cu(I)). Copper depleted enzymes, prepared by reduction with dithionite followed by dialysis against cyanide, undergo only one reduction process. Nyquist diagrams, recorded at potentials corresponding to the reduction of cofactors as dc-offset, represent charge transfer impedance followed by a Warburg-type line at low frequencies, indicating the occurrence of a diffusion controlled process in the rate-limiting step of the reduction process.     

Electrochemical studies of η5-cyclopentadienyliron hexafluorophosphates of η6-substituted arenes and η6-heterocycles

Polarographic half-wave potentials for two reduction steps of 49 cyclopentadienyliron complexes of substituted arenes or heterocycles in dimethylformamide were determined. A fast cyclic voltammetry (10–40 V/s) was used to study the electron transfer kinetics of some of these complexes. After correction for the double layer effects, the rate constants of all the complexes studied show that the transfer of electrons in the second reduction step occurs significantly faster than in the first one. This was interpreted as a result of greater delocalization of electrons in the 20-electron complexes of iron compared to the 19-electron complexes.     

Simulation of the electrochemical behavior of multi-redox systems. Current potential studies on multiheme cytochromes.

The direct unmediated electrochemical response of the tetrahemic cytochrome c3 isolated from sulfate reducers Desulfovibrio baculatus (DSM 1743) and D. vulgaris (strain Hildenborough), was evaluated using different electrode systems [graphite (edge cut), gold, semiconductor (InO2) and mercury)] and different electrochemical methods (cyclic voltammetry and differential pulse voltammetry). A computer program was developed for the theoretical simulation of a complete cyclic voltammetry curve, based on the method proposed by Nicholson and Shain [Nicholson, R.S. & Shain, I. (1964) Anal. Chem. 36, 706-723], using the Gauss-Legendre method for calculation of the integral equations. The experimental data obtained for this multi-redox center protein was deconvoluted in to the four redox components using theoretically generated cyclic voltammetry curves and the four mid-point reduction potentials determined. The pH dependence of the four reduction potentials was evaluated using the deconvolution method described.     

Electrochemical Characteristics of Nitro-Heterocyclic Compounds of Biological Interest: I. The Influence of Solvent

The electrochemical properties of three nitroimidazoles, a nitropyrazole, a nitrofuran and three nitroben-zenoid compounds have been extensively investigated in a range of solvents. The reduction pathway for the nitro group is independent of the cyclic function to which it is attached, but is strongly influenced by the nature of the solvent. In aqueous media, generally, a single, irreversible 4-electron reduction occurs to give the hydroxylamine. In aprotic media (dimethylformamide, methylene chloride or dimethylsulphoxide), a reversible one-electron reduction takes place to form a stable nitro radical anion. At more negative values, a further 3-electron reduction occurs, irreversibly to give the hydroxylamine. In mixed aqueous-organic systems, intermediate behaviour is found, with the reversibility of the RNO₂/RNO₂^? couple increasing with addition of organic medium. The control of the reduction pathway, by changing the electrolytic medium is discussed in relation to the biological activities of the drugs and identification of the short-lived reduction intermediate responsible for DNA damage.