Electrochemical analysis of Clostridium propionicum and its acrylic acid production in microbial fuel cells

Currently, acrylic acid is produced at a low yield by the resting cells of Clostridium propionicum with the supplement of extra electron acceptors. As an alternative way, acrylic acid production coupled with electricity generation was achieved by C. propionicum‐based microbial fuel cells (MFCs). Electricity was generated in the salt‐bridge MFCs with cysteine and resazurin in the anode chamber as mediators, and K₃Fe(CN)₆ as the cathode electron acceptor. Power generation was 21.78 mW/m² with an internal resistance of 9809 Ω. Cyclic voltammograms indicated the main mechanism of power production was the electron transfer facilitated by mediators in the system. In the salt‐bridge MFC system, 0.694 mM acrylic acid was produced together with electricity generation.     

The effect of physico-chemically immobilized methylene blue and neutral red on the anode of microbial fuel cell

A fast and cost effective immobilization of electron carriers, methylene blue (MB) and neutral red (NR) by pH shift was proposed to improve bioanodic performance. The adsorption of mediators onto the carbon cloth anode was verified using cyclic voltammogram (CV) and the effect of the immobilized mediators on acclimation, power density, and acetate removal of MFCs was investigated. A peak power density of P _max(MB) = 11.3 W/m³ was achieved over days 110 ∼ 120, as compared to P _max(Control) = 5.4 W/m³ and P _max(NR) = 3.1 W/m³ for the treated anode after 15 sequential fed-batch operations. The VFA removal rates however were similar for all MFC systems, ranging from 82 to 87%. It could be suggested that the increase in power density for the MB treated electrode resulted from an enhanced electron transport from exo-electrogenic bacteria. MB may also have a selective effect on the bacterial community during the start-up stage, increasing the voltage production and acetate removal from day 1 to 16. However, MFC with NR treated anode produced an initial voltage under 100 mV, with lower coulombic efficiency (CE). NR exhibited less favourable mediator molecule binding to the electrode surface, when subject to pH driven physico-chemical immobilization.     

Effect of redox mediators on nitrogenase and hydrogenase activities in Azotobacter vinelandii

In bioelectrochemical studies, redox mediators such as methylene blue, natural red, and thionine are used to studying the redox characteristics of enzymes in the living cell. Here we show that nitrogenase activity in Azotobacter vinelandii is completely inhibited by oxidized methylene blue (MB_o) when the concentration of this mediator in the medium is increased up to 72 M. This activity in A. vinelandii is somewhat inhibited by a coenzyme, ascorbic acid (AA). However, the nitrogenase activity within the A. vinelandii cell is unchanged even for a high concentration of oxidized natural red (NR_o) alone. Interestingly, these mediators and AA do not have the capacity to inhibit the H₂ uptake activity of the hydrogenase in A. vinelandii. Average active rates of 66 nM H₂ evolved/mg cell protein/min from the nitrogenase and 160 nM H₂-uptake/mg cell protein/min from the hydrogenase in A. vinelandii are found in aid of the activities of the enzymes for H₂ evolution and for H₂ uptake are compared. The activities of both enzymes in A. vinelandii are strongly inhibited by thionine having high oxidative potential. Mechanisms of various mediators acting in vivo for both enzymes in A. vinelandii are discussed.     

Impedance spectroscopy as a tool for non‐intrusive detection of extracellular mediators in microbial fuel cells

Endogenously produced, diffusible redox mediators can act as electron shuttles for bacterial respiration. Accordingly, the mediators also serve a critical role in microbial fuel cells (MFCs), as they assist extracellular electron transfer from the bacteria to the anode serving as the intermediate electron sink. Electrochemical impedance spectroscopy (EIS) may be a valuable tool for evaluating the role of mediators in an operating MFC. EIS offers distinct advantages over some conventional analytical methods for the investigation of MFC systems because EIS can elucidate the electrochemical properties of various charge transfer processes in the bio‐energetic pathway. Preliminary investigations of Shewanella oneidensis DSP10‐based MFCs revealved that even low quantities of extracellular mediators significantly influence the impedance behavior of MFCs. EIS results also suggested that for the model MFC studied, electron transfer from the mediator to the anode may be up to 15 times faster than the electron transfer from bacteria to the mediator. When a simple carbonate membrane separated the anode and cathode chambers, the extracellular mediators were also detected at the cathode, indicating diffusion from the anode under open circuit conditions. The findings demonstrated that EIS can be used as a tool to indicate presence of extracellular redox mediators produced by microorganisms and their participation in extracellular electron shuttling. Biotechnol. Bioeng. 2009; 104: 882–891. © 2009 Wiley Periodicals, Inc.     

Humic analog AQDS and AQS as an electron mediator can enhance chromate reduction by Bacillus sp. strain 3C3

Humus as an electron mediator is recognized as an effective strategy to improve the biological transformation and degradation of toxic substances, yet the action of humus in microbial detoxification of chromate is still unknown. In this study, a humus-reducing strain 3C₃ was isolated from mangrove sediment. Based on the analyses of morphology, physiobiochemical characteristics, and 16S rRNA gene sequence, this strain was identified Bacillus sp. Strain 3C₃ can effectively reduce humic analog anthraquinone-2,6-disulfonate (AQDS) and anthraquinone-2-sulfonate (AQS) with lactate, formate, or glucose as electron donors. When the cells were killed by incubation at 95°C for 30 min or an electron donor was absent, the humic reduction did not occur, showing that the humic reduction was a biochemical process. However, strain 3C₃ had low capability of chromate reduction under anaerobic conditions, despite of having strong tolerance of the toxic metal. But in the presence of humic substances AQDS or AQS, we found that chromate reduction by strain 3C₃ was enhanced greatly. Because strain 3C₃ is an effective humus-reducing bacterium, it is proposed that humic substances could serve as electron mediator to interact with chromate and accelerate chromate reduction. Our results suggest that chromate contaminations can be detoxified by adding humic analog (low to 0.1 mM) as an electron mediator in the microbial incubation.     

Der Einfluß von Redoxindicatoren auf die Säurebildung von Streptococcus lactis

Zusammenfassung Der Einfluß von acht Redoxindicatoren mit abgestuften Normalpotentialen zwischen E ₀=-340 mV und E ₀=+115 mV ist in einem Flüssigsubstrat auf die Säurebildung von Streptococcus lactis untersucht worden.Durch Farbstoffe mit Normalpotentialen zwischen-122 mV und +115 mV (Nilblau, Methylenblau, Brillantkresylblau, Toluylenblau) konnte die Milchsäurebildung, besonders bei niederen Farbstoffkonzentrationen (4·10^-5 und 10^-4 m/l), signifikant gefördert werden. Farbstoffe mit Normalpotentialen zwischen-289 mV und-122 mV (Safranin T, Phenosafranin, Janusgrün, Nilblau) hemmten dagegen die Produktion von Milchsäure in allen oder in der Mehrzahl der angewendeten Konzentrationen. Niblau, das am übergang der beiden Potentialbereiche liegt, förderte die Milchsäurebildung sehr stark bei niederen und hemmte ebenso stark bei höheren Konzentrationen.Die Bildung von flüchtigen Säuren wurde durch keinen der Farbstoffe gefördert. Eine Hemmung trat durch Farbstoffe mit Normalpotentialen zwischen-289 mV und +47 mV (Safranin T, Phenosafranin, Janusgrün, Nilblau, Methylenblau, Brillantkresylblau) ein. Janusgrün hemmte die Bildung flüchtiger Säuren in allen untersuchten Konzentrationen zwischen 4·10^-5 und 4·10^-4 m/l. Je weiter das Normalpotential des hemmenden Farbstoffes von dem Normalpotential des Janusgrüns abwich, desto geringer wurde die Hemmung in der geringsten Konzentrationsstufe von 4·10^-5 m/l. Diese Unterbindung der Hemmwirkung wirkte sich in Richtung auf negativere Normalpotentiale mehr aus als in Richtung auf positivere Normalpotentiale.Durch die beiden Farbstoffe mit den extremsten Normalpotentialen (Neutralrot E ₀=-340 mV, Toluylenblau E ₀=+115 mV) wurde weder die Produktion von Milchsäure noch die von flüchtigen Säuren merklich gehemmt. Eine Förderung der Milchsäurebildung konnte von beiden Farbstoffen nur durch Toluylenblan in der geringsten Konzentration (4×10^-5 m/l) erzielt werden.

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The influence of redox indicators on the acid formation in Streptococcus lactis

Summary The influence of 8 redox indicators with graded standard redox potentials between E ₀=-340 mV and E ₀=+115 mV was tested for the acidification by Streptococcus lactis in a liquid medium.By redox indicators with standard redox potentials between-122 mV and +115 mV (Nile blue, methylene blue, brillant cresyl blue, and toluylene blue) the formation of lactic acid could be significantly increased, especially with low dye concentrations (4×10^-5 and 10^-4 m/l). Dyes with standard redox potentials between-289 mV and-122 mV (safranine T, phenosafranine, Janus green, Nile blue) on the other hand retarded the production of lactic acid by Strept. lactis in all or most of the dye concentrations used. Nile blue-representing the transition point between the two sections of redox indicators-increased the production of lactic acid very much in low concentrations and inhibited it as much in high concentrations.The production of volatile acids was not increased by any dyestuff. It was delayed by dyes with standard redox potentials between-289 mV and +47 mV (safranine T, phenosafranine, Janus green, Nile blue, methylene blue, brillant cresyl blue). Janus green retarded the production of volatile acids in all analysed concentrations between 4×10^-5 and 4×10^-4 m/l. The greater the difference between the standard redox potential of the inhibiting dye and the standard redox potential of Janus green the smaller was the retarding effect in the lowest degree of concentration of 4×10^-5 m/l. This stopping of the retarding effect was more effective towards standard redox potentials more negative then towards more positive ones.The two dyes with the most extreme standard redox potentials (neutral red E ₀=-340 mV, toluylene blue E ₀=+115 mV) didn't obviously delay any acid formation, neither the production of lactic acid nor that of volatile acids. Of the two dyes only toluylene blue in the lowest concentration used (4×10^-5 m/l) caused an increased production of lactic acid.

     

Linkage of formate hydrogenlyase with anaerobic respiration in Proteus mirabilis

The linkage between the enzyme system catalysing formate hydrogenlyase and reductases involved in anaerobic respiration in intact cells of anaerobically grown Proteus mirabilis was studied. Reduction of nitrate and fumarate by molecular hydrogen or formate was possible under all growth conditions; reduction of tetrathionate and thiosulphate occurred only in cells harvested at late growth phase from a pH-regulated batch culture and not in cells harvested at early growth phase or in cells grown in pH-auxostat culture. Under all conditions, cells possessed the enzyme tetrathionate reductase. We conclude that linkage between tetrathionate reductase (catalysing also reduction of thiosulphate) and the formate hydrogenlyase chain is dependent on growth conditions. During reduction of high-potential oxidants such as fumarate, tetrathionate (when possible) or the artificial electron acceptor methylene blue by formate, there was no simultaneous H₂ evolution due to the formate hydrogenlyase reaction. H₂ production started only after complete reduction of methylene blue or fumarate, in the case of methylene blue after a lag phase without gas production. In preparations with a low fumarate reduction activity this was accompanied by an acceleration in CO₂ production. During reduction of thiosulphate (a low-potential oxidant) or of tetrathionate in the presence of benzyl viologen (a low-potential mediator) by formate, H₂ was evolved simultaneously. From this we conclude that formate hydrogenlyase is regulated by a factor that responds to the redox state of any electron acceptor couple present such that lyase activity is blocked when the acceptor couple is oxidised to too great an extent.     

Synergistic effect of laccase mediators on pentachlorophenol removal by Ganoderma lucidum laccase

Laccases have low redox potentials limiting their environmental and industrial applications. The use of laccase mediators has proven to be an effective approach for overcoming the low redox potentials. However, knowledge about the role played by the mediator cocktails in such a laccase-mediator system (LMS) is scarce. Here, we assembled different dual-agent mediator cocktails containing 2,2′-azino-bis-(3-ethylbenzothiazoline-6-sulfonate) (ABTS), vanillin, and/or acetovanillone, and compared their mediating capabilities with those of each individual mediator alone in oxidation of pentachlorophenol (PCP) by Ganoderma lucidum laccase. Cocktails containing ABTS and either vanillin or acetovanillone strongly promoted PCP removal compared to the use of each mediator alone. The removal enhancement was correlated with mediator molar ratios of the cocktails and incubation times. Analysis of the kinetic constants for each mediator compound showed that G. lucidum laccase was very prone to react with ABTS rather than vanillin and acetovanillone in the cocktails. Moreover, the presence of the ABTS radical (ABTS^+•) and vanillin or acetovanillone significantly enhanced PCP removal concomitant with electron transfer from vanillin or acetovanillone to ABTS^+•. These results strongly suggest that vanillin and acetovanillone mediate the reaction between ABTS and PCP via multiple sequential electron transfers among laccase and its mediators.     

Sustained generation of electricity by the spore-forming,Gram-positive, <Emphasis Type="Italic">Desulfitobacterium hafniense</Emphasis> strain DCB2

Desulfitobacterium hafniense strain DCB2 generates electricity in microbial fuel cells (MFCs) when humic acids or the humate analog anthraquinone-2,6-disulfonate (AQDS) is added as an electron-carrying mediator. When utilizing formate as fuel, the Gram-positive, spore-forming bacterium generated up to 400 mW/m² of cathode surface area in a single-chamber MFC with a platinum-containing air-fed cathode. Hydrogen, lactate, pyruvate, and ethanol supported electricity generation, but acetate, propionate, and butyrate did not. Scanning electron microscopy indicated that strain DCB2 colonized the surface of a current-generating anode but not of an unconnected electrode. The electricity was recovered fully within minutes after the exchange of the medium in the anode chamber and within a week after an exposure of a colonized anode to 90°C for 20 min. Of the six strains of Desulfitobacteria tested, all of which would reduce AQDS, only D. hafniense strain DCB2 continued to reduce AQDS and generate electricity for more than 24 h, indicating that reduction of the humate analog alone is insufficient to sustain electrode reduction.     

A new colorimetric microtitre model for the detection of Staphylococcus aureus biofilms

Aims: Research on biofilms requires validated quantitative models that focus both on matrix and viable bacterial mass. In this study, a new microplate model for the detection of Staphylococcus aureus biofilms was developed. Methods and Results: Dimethyl methylene blue (DMMB) dye was used to quantify biofilm matrix colorimetrically. Initially developed for the detection of glycosaminoglycans, the DMMB protocol was optimized for S. aureus biofilm research. In addition, the redox indicator resazurin was used to determine the viable bacterial biofilm burden. Conclusion: A new, simple and reproducible microplate test system based on DMMB and resazurin, offering a reliable differentiation between biofilm matrix and cellular activity, was developed and validated for the detection of S. aureus biofilms. Significance and Impact of the Study: The DMMB–resazurin microtitre plate model is a valuable tool for high capacity screening of biocides and for the development of synergistic mixtures of biocides, destroying both biofilm matrix and bacteria.     

Method for Detection of Microorganisms That Produce Gaseous Nitrogen Oxides

A method was developed to detect NO- or N₂O-producing bacteria in solid or liquid medium by their ability to oxidize the redox indicator resazurin from its reduced colorless form to its oxidized pink form. The method was sensitive to as little as 35 nM N₂O or 0.5 nM NO. Ninety-one percent of the colonies that oxidized resazurin on plates also produced N₂O in slant cultures. Forty-four percent of the colonies that did not oxidize resazurin did produce N₂O. This percentage was reduced to 15% when colonies in which the coloration was difficult to discern were picked to slants to determine whether they oxidized the slant. The production of N₂O preceded the oxidation of resazurin by liquid cultures of Escherichia coli and a sludge isolate. With the denitrifying sewage isolate, the disappearance of N₂O was followed by the return of resazurin to its reduced state. Wolinella succinogenes was found to produce small amounts of N₂O from NO₃⁻, which resulted in a transient oxidation of resazurin.     

Reactivity of Nitric Oxide with Cytochrome c Oxidase: Interactions with the Binuclear Centre and Mechanism of Inhibition

Nitric oxide (NO) has recently been recognized as an important biological mediator that inhibits respiration at cytochrome c oxidase (CcO). This inhibition is reversible and shows competition with oxygen, the K _i being lower at low oxygen concentrations. Although the species that binds NO in turnover has been suggested to contain a partially reduced binuclear center, the exact mechanism of the inhibition is not clear. Recently, rapid (ms) redox reactions of NO with the binuclear center have been reported, e.g., the ejection of an electron to cytochrome a and the depletion of the intermediates P and F. These observations have been rationalized within a scheme in which NO reacts with oxidized Cu_B leading to the reduction of this metal center and formation of nitrite in a very fast reaction. Electron migration from Cu_B to other redox sites within the enzyme is proposed to explain the optical transitions observed. The relevance of these reactions to the inhibition of CcO and metabolism of NO are discussed.     

Hydrogen metabolism in isolated heterocysts of Anabaena 7120

Isolated heterocysts of Anabaena 7120 evolve H₂ in an ATP-dependent nitrogenase-catalyzed process that is inhibited by N₂ and C₂H₂. Heterocysts have an active uptake hydrogenase that only requires an electron acceptor of positive redox potential, e.g., methylene blue, dichlorophenolindophenol or potassium ferricyanide. O₂ supplied at low partial pressures is a very effective physiological oxidant for H₂ uptake. High concentrations of O₂ are inhibitory to H₂ uptake. The oxyhydrogen reaction in heterocysts appears to be mediated by a cytochrome-cytochrome oxidase system, and it supports ATP synthesis via oxidative phosphorylation. Attempts to demonstrate acetylene reduction in isolated heterocysts employing H₂ as an electron donor were unsuccessful. It is suggested that the uptake hydrogenase functions to conserve reductant that otherwise would be dissipated via nitrogenase-catalyzed H₂ evolution.     

Use of Pseudomonas species producing phenazine-based metabolites in the anodes of microbial fuel cells to improve electricity generation

The rate of anodic electron transfer is one of the factors limiting the performance of microbial fuel cells (MFCs). It is known that phenazine-based metabolites produced by Pseudomonas species can function as electron shuttles for Pseudomonas themselves and also, in a syntrophic association, for Gram-positive bacteria. In this study, we have investigated whether phenazine-based metabolites and their producers could be used to improve the electricity generation of a MFC operated with a mixed culture. Both anodic supernatants obtained from MFCs operated with a Pseudomonas strain (P-PCA) producing phenazine-1-carboxylic acid (PCA) and those from MFCs operated with a strain (P-PCN) producing phenazine-1-carboxamide (PCN) exerted similarly positive effects on the electricity generation of a mixed culture. Replacing supernatants of MFCs operated with a mixed culture with supernatants of MFCs operated with P-PCN could double the currents generated. Purified PCA and purified PCN had similar effects. If the supernatant of an engineered strain overproducing PCN was used, the effect could be maintained over longer time courses, resulting in a 1.5-fold increase in the production of charge. Bioaugmentation of the mixed culture MFCs using slow release tubes containing P-PCN not only doubled the currents but also maintained the effect over longer periods. The results demonstrated the electron-shuttling effect of phenazine-based compounds produced by Pseudomonas species and their capacity to improve the performance of MFCs operated with mixed cultures. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Use of bitter gourd (Momordica charantia) peroxidase together with redox mediators to decolorize disperse dyes

In this study, salt fractionated bitter gourd (Momordica charantia) peroxidase was used for the decolorization of water-insoluble disperse dyes; Disperse Red 17 and Disperse Brown 1. Effect of nine different redox mediators; bromophenol, 2,4-dichlorophenol, guaiacol, 1-hydroxybenzotriazole, m-cresol, quinol, syringaldehyde, violuric acid, and vanillin on decolorization of disperse dyes by bitter gourd peroxidase has been investigated. Among these redox mediators, 1-hydroxybenzotriazole was the most effective mediator for decolorization of both the dyes by peroxidase. Bitter gourd peroxidase (0.36 U/mL) could decolorize Disperse Red 17 maximally 90% in the presence of 0.1 mM 1-hydroxybenzotriazole while Disperse Brown 1 was decolorized 65% in the presence of 0.2 mM 1-hydroxybenzotriazole. Maximum decolorization of these dyes was obtained within 1 h of incubation at pH 3.0 and temperature 40°C. The application of such enzyme plus redox mediator systems may be extendable to other recalcitrant and water insoluble synthetic dyes using novel redox mediators and peroxidases from other new and cheaper sources.     

Mutants of an electrogenic bacterium <Emphasis Type="Italic">Shewanella oneidensis</Emphasis> MR-1 with increased reducing activity

The mutants of Shewanella oneidensis MR-1 resistant to fosfomycin, a toxic analogue of phosphoenolpyruvate, were obtained. The mutants exhibited increased reducing activity and higher rates of lactate utilization. A correlation was shown between the rates of metabolism of oxidized substrates and the rate of reduction of methylene blue, a mediator of electron transport. The mutants of S. oneidensis MR-1 may be used in microbial fuel cells for intensification of energy production from organic compounds.     

Humic Acid Reduction by Propionibacterium freudenreichii and Other Fermenting Bacteria

Iron-reducing bacteria have been reported to reduce humic acids and low-molecular-weight quinones with electrons from acetate or hydrogen oxidation. Due to the rapid chemical reaction of amorphous ferric iron with the reduced reaction products, humic acids and low-molecular-weight redox mediators may play an important role in biological iron reduction. Since many anaerobic bacteria that are not able to reduce amorphous ferric iron directly are known to transfer electrons to other external acceptors, such as ferricyanide, 2,6-anthraquinone disulfonate (AQDS), or molecular oxygen, we tested several physiologically different species of fermenting bacteria to determine their abilities to reduce humic acids. Propionibacterium freudenreichii, Lactococcus lactis, and Enterococcus cecorum all shifted their fermentation patterns towards more oxidized products when humic acids were present; P. freudenreichii even oxidized propionate to acetate under these conditions. When amorphous ferric iron was added to reoxidize the electron acceptor, humic acids were found to be equally effective when they were added in substoichiometric amounts. These findings indicate that in addition to iron-reducing bacteria, fermenting bacteria are also capable of channeling electrons from anaerobic oxidations via humic acids towards iron reduction. This information needs to be considered in future studies of electron flow in soils and sediments.     

Peroxidase from Bacillus sp. VUS and its role in the decolorization of textile dyes

Peroxidase was purified by an ion exchange chromatography followed by gel filtration chromatography from dye degrading Bacillus sp. strain VUS. The optimum pH and temperature of the enzyme activity was 3.0 and 65°C, respectively. This enzyme showed more activity with n-propanol than other substrates tested viz. xylidine, 3-(3,4-dihydroxy phenyl) Lalanine (L-DOPA), hydroxyquinone, ethanol, indole, and veratrole. Km value of the enzyme was 0.076 mM towards n-propanol under standard assay conditions. Peroxidase was more active in presence of the metal ions like Li²⁺, Co²⁺, K²⁺, Zn²⁺, and Cu²⁺ where as it showed less activity in the presence of Ca²⁺ and Mn²⁺. Inhibitors like ethylenediamine tetraacetic acid (EDTA), glutamine, and phenylalanine inhibited the enzyme partially, while sodium azide (NaN₃) completely. The crude as well as the purified peroxidase was able to decolourize different industrial dyes. This enzyme decolourized various textile dyes and enhanced percent decolourization in the presence of redox mediators. Aniline was the most effective redox mediator than other mediators tested. Gas chromatography-Mass spectrometry (GC-MS) confirmed the formation of 7-Acetylamino-4-hydroxy-naphthalene-2-sulphonic acid as the final product of Reactive Orange 16 indicating asymmetric cleavage of the dye.     

Electromicrobial regeneration of pyridine nucleotides and other preparative redox transformations with Clostridium thermoaceticum

Clostridium thermoaceticum contains interesting enzymes suitable for redox reactions. Various AMAPOR (artificial-mediator-accepting pyridine-nucleotide oxidoreductase) activities were used for electromicrobial pyridine nucleotide regeneration. The combination of AMAPOR with commercially available pyridine-nucleotide-dependent oxidoreductases led to (S)-glutamate, (2R,3S)-isocitrate, (2S,3R)-isocitrate, 6-phosphogluconate and ribulose 5-phosphate. The redox equivalents were provided by electrochemically regenerated artificial mediators. Methylviologen or cobalt sepulchrate were used for NAD(P)H regeneration, whereas carboxamidomethylviologen (CAV) or anthraquinone sulphonates (AQ-S) were suitable for NAD(P)⁺ regeneration. With resting cells of C. thermoaceticum productivity numbers {mmol product/[biocatalyst (kg dry weight) × time (h)]} of about 30 000 for NADPH, 7000 for NADH and 14 000 for NADP⁺ regeneration could be reached. The cycle number for NADPH regeneration was up to 4300, that for NADP⁺ regeneration was at least 1600. An aldehyde and an alcohol oxidoreductase were used to reduce non-activated carboxylic acids to the alcohols and to dehydrogenate primary alcohols to the aldehydes or carboxylates. The electromicrobial reduction of 6-chloropyridine 3-carboxylate to the corresponding alcohol was compared with the reduction by CO as electron donor.The application of phenothiazine-dye-type mediators (thionine, methylene blue) converted primary alcohols to the aldehydes with productivity numbers up to 1400 in the presence of hydrazine as aldehyde scavenger. With CAV or AQ-S, alcohols were dehydrogenated to carboxylic acids with productivity numbers of almost 1700.