Victor M. Fernandez

Purification and characterization of two distinct lipases from Candida cylindracea

We have purified and characterized two isoenzymes from a commercial lipase preparation of Candida cylindracea. The purification procedure includes ethanol precipitation and DEAE-Sephacel and Sephacryl HR 100 chromatographies. Lipase A and lipase B were purified 11-fold with a 5% and 21% recovery in activity, respectively. The enzymes have similar amino acid content, N-terminal sequence and molecular weight, but differ on neutral sugar content, hydrophobicity, presence of isoforms and stability to pH and temperature. They also show some differences in the substrate specificity.

Novel Polyphenol Oxidase Mined from a Metagenome Expression Library of Bovine Rumen BIOCHEMICAL PROPERTIES, STRUCTURAL ANALYSIS, AND PHYLOGENETIC RELATIONSHIPS

RL5, a gene coding for a novel polyphenol oxidase, was identified through activity screening of a metagenome expression library from bovine rumen microflora. Characterization of the recombinant protein produced in Escherichia coli revealed a multipotent capacity to oxidize a wide range of substrates (syringaldazine > 2,6-dimethoxyphenol > veratryl alcohol > guaiacol > tetramethylbenzidine > 4-methoxybenzyl alcohol > 2,2′-azino-bis(3-ethylbenzthiazoline-6-sulfonic acid) (ABTS) >> phenol red) over an unusually broad range of pH from 3.5 to 9.0. Apparent Km and kcat values for ABTS, syringaldazine, and 2,6-dimetoxyphenol obtained from steady-state kinetic measurements performed at 40 °C, pH 4.5, yielded values of 26, 0.43, and 0.45 μm and 18, 660, and 1175 s-1, respectively. The Km values for syringaldazine and 2,6-dimetoxyphenol are up to 5 times lower, and the kcat values up to 40 times higher, than values previously reported for this class of enzyme. RL5 is a 4-copper oxidase with oxidation potential values of 745, 400, and 500 mV versus normal hydrogen electrode for the T1, T2, and T3 copper sites. A three-dimensional model of RL5 and site-directed mutants were generated to identify the copper ligands. Bioinformatic analysis of the gene sequence and the sequences and contexts of neighboring genes suggested a tentative phylogenetic assignment to the genus Bacteroides. Kinetic, electrochemical, and EPR analyses provide unequivocal evidence that the hypothetical proteins from Bacteroides thetaiotaomicron and from E. coli, which are closely related to the deduced protein encoded by the RL5 gene, are also multicopper proteins with polyphenol oxidase activity. The present study shows that these three newly characterized enzymes form a new family of functional multicopper oxidases with laccase activity related to conserved hypothetical proteins harboring the domain of unknown function DUF152 and suggests that some other of these proteins may also be laccases.

Properties and reactivation of two different deactivated forms of Desulfovibrio gigas hydrogenase

Abstract It has previously been shown that Desulfovibrio gigas hydrogenase, as isolated, has a relatively low activity in the hydrogen-methyl viologen reductase assay, and that the activity is slowly stimulated up to 10-fold by hydrogen or strong reductants. The enzyme, before reductive activation, is also totally inactive in hydrogentritium exchange and hydrogen-dichloroindophenol (DCIP) reductase assays. The behaviour of the enzyme in various states of activation is discussed in terms of three different states: the active state, which is active in all assays, the unready state, which is totally inactive, and the ready state, which does not react with hydrogen, but which is rapidly activated by strong reductants. The conditions for the slow activation of the unready state of D. gigas hydrogenase have been investigated. The rate of activation was independent of enzyme concentration over a wide range, which rules out mechanisms involving intermolecular electron exchange. The rate was only slightly affected by pH in the range 6–9, but was strongly temperature-dependent, with activation energy 88 kJ · mol−1. The enzyme could be activated by dithiothreitol + the mediator dye, Indigo tetrasulphonate, but not by dithiothreitol alone. No effects were seen during treatments with weaker reductants, thioredoxin, iron, sulphide or nickel. These results indicate that the activation does not involve conversions of a metal centre or the cleavage of an accessible disulphide bridge. Presumably it involves an intramolecular change, possibly in the redox state or coordination of a metal centre. The active form of D. gigas hydrogenase was rapidly inactivated by oxygen, producing mostly the unready state, which could be reactivated only slowly. By contrast, anaerobic reoxidation by DCIP was able to convert the enzyme mostly to the ready state. This was identified as being inactive in hydrogen-tritium exchange and hydrogen-DCIP reductase assays but rapidly activated in the hydrogen-methyl viologen reductase assay (DCIP prevents this). It is suggested that a similar oxidation of the active enzyme may take place in the cell as a protection against oxygen.

Laccase electrode for direct electrocatalytic reduction of O2 to H2O with high-operational stability and resistance to chloride inhibition

Laccase from Trametes hirsuta basidiomycete has been covalently bound to graphite electrodes electrochemically modified with phenyl derivatives as a way to attach the enzyme molecules with an adequate orientation for direct electron transfer (DET). Current densities up to 0.5mA/cm(2) of electrocatalytic reduction of O(2) to H(2)O were obtained in absence of redox mediators, suggesting preferential orientation of the T1 Cu centre of the laccase towards the electrode. The covalent attachment of the laccase molecules to the functionalized electrodes permitted remarkable operational stability. Moreover, O(2) bioelectroreduction based on DET between the laccase and the electrode was not inhibited by chloride ions, whereas mediated bioelectrocatalysis was. In contrast, fluoride ions inhibited both direct and mediated electron transfers-based bioelectrocatalytic reduction of O(2). Thus, two different modes of laccase inhibition by halides are discussed.

Synthesis of cobalt ferrite core/metallic shell nanoparticles for the development of a specific PNA/DNA biosensor

Controlled synthesis of cobalt ferrite superparamagnetic nanoparticles covered with a gold shell has been achieved by an affinity and trap strategy. Magnetic nanoparticles are functionalized with a mixture of amino and thiol groups that facilitate the electrostatic attraction and further chemisorption of gold nanoparticles, respectively. Using these nanoparticles as seeds, a complete coating shell is achieved by gold salt-iterative reduction leading to monodisperse water-soluble gold-covered magnetic nanoparticles, with an average diameter ranging from 21 to 29 nm. These constitute a versatile platform for immobilization of biomolecules via thiol chemistry, which is exemplified by the immobilization of peptide nucleic acid (PNA) oligomers that specifically hybridize with complementary DNA molecules in solution. Hybridation with DNA probes has been measured using Rhodamine 6G fluorescence marker and the detection of a single nucleotide mutation has been achieved. These results suggest the PNA-nanoparticles application as a biosensor for DNA genotyping avoiding commonly time-consuming procedures employed.

Introduction of Methionines in the Gas Channel Makes [NiFe] Hydrogenase Aero-Tolerant

Hydrogenases catalyze the conversion between 2H(+) + 2e(-) and H(2)(1). Most of these enzymes are inhibited by O(2), which represents a major drawback for their use in biotechnological applications. Improving hydrogenase O(2) tolerance is therefore a major contemporary challenge to allow the implementation of a sustainable hydrogen economy. We succeeded in improving O(2) tolerance, which we define here as the ability of the enzyme to resist for several minutes to O(2) exposure, by substituting with methionines small hydrophobic residues strongly conserved in the gas channel. Remarkably, the mutated enzymes remained active in the presence of an O(2) concentration close to that found in aerobic solutions in equilibrium with air, while the wild type enzyme is inhibited in a few seconds. Crystallographic and spectroscopic studies showed that the structure and the chemistry at the active site are not affected by the mutations. Kinetic studies demonstrated that the inactivation is slower and reactivation faster in these mutants. We propose that in addition to restricting O(2) diffusion to the active site of the enzyme, methionine may also interact with bound peroxide and provide an assisted escape route for H(2)O(2) toward the gas channel. These results show for the first time that it is possible to improve O(2)-tolerance of [NiFe] hydrogenases, making possible the development of biohydrogen production systems.

Original design of an oxygen-tolerant [NiFe] hydrogenase: major effect of a valine-to-cysteine mutation near the active site.

Hydrogenases are efficient biological catalysts of H(2) oxidation and production. Most of them are inhibited by O(2), and a prerequisite for their use in biotechnological applications under air is to improve their oxygen tolerance. We have previously shown that exchanging the residue at position 74 in the large subunit of the oxygen-sensitive [NiFe] hydrogenase from Desulfovibrio fructosovorans could impact the reaction of the enzyme with O(2) (Dementin, S.; J. Am. Chem. Soc. 2009, 131, 10156-10164; Liebgott, P. P.; Nat. Chem. Biol. 2010, 6, 63-70). This residue, a valine in the wild-type enzyme, located at the bottleneck of the gas channel near the active site, has here been exchanged with a cysteine. A thorough characterization using a combination of kinetic, spectroscopic (EPR, FTIR), and electrochemical studies demonstrates that the V74C mutant has features of the naturally occurring oxygen-tolerant membrane-bound hydrogenases (MBH). The mutant is functional during several minutes under O(2), has impaired H(2)-production activity, and has a weaker affinity for CO than the WT. Upon exposure to O(2), it is converted into the more easily reactivatable inactive form, Ni-B, and this inactive state reactivates about 20 times faster than in the WT enzyme. Control experiments carried out with the V74S and V74N mutants indicate that protonation of the position 74 residue is not the reason the mutants reactivate faster than the WT enzyme. The electrochemical behavior of the V74C mutant toward O(2) is intermediate between that of the WT enzyme from D. fructosovorans and the oxygen-tolerant MBH from Aquifex aeolicus.

Electrochemical growth of Acidithiobacillus ferrooxidans on a graphite electrode for obtaining a biocathode for direct electrocatalytic reduction of oxygen

An aspect in microbial fuel cell research that is currently of great interest is the development of bacterial cathodes. Bacterial cathodes that catalyze oxygen reduction to water at low pH have the advantage of overcoming the kinetic limitations due to the requirement of 4 protons per molecule reduced. In this work we have studied the performance of a biocathode using as electrocatalyst an acidophile microorganism: Acidithiobacillus ferrooxidans. Growth of the microorganism directly on the electrode took place using an applied voltage of 0 V vs. SCE as the only energy source and without adding redox mediators to the solution. Current densities of up to 5 A m(-2) were measured for O2 reduction in the At. ferrooxidans cathode at pH 2.0 and the electrocatalytic wave was shifted 300 mV to higher potential compared to the control graphite electrodes without the bacterium.

Preferential Use of an Anode as an Electron Acceptor by an Acidophilic Bacterium in the Presence of Oxygen

ABSTRACT Several anaerobic metal-reducing bacteria have been shown to be able to donate electrons directly to an electrode. This property is of great interest for microbial fuel cell development. To date, microbial fuel cell design requires avoiding O2 diffusion from the cathodic compartment to the sensitive anodic compartment. Here, we show that Acidiphilium sp. strain 3.2 Sup 5 cells that were isolated from an extreme acidic environment are able to colonize graphite felt electrodes. These bacterial electrodes were able to produce high-density electrocatalytic currents, up to 3 A/m2 at a poised potential of +0.15 V (compared to the value for the reference standard calomel electrode) in the absence of redox mediators, by oxidizing glucose even at saturating air concentrations and very low pHs.

Amperometric mediated carbon paste biosensor based on D-fructose dehydrogenase for the determination of fructose in food analysis

A new mediated amperometric biosensor for fructose is described. The sensor is based on a commercially available D-fructose dehydrogenase. The enzyme is incorporated in a carbon paste matrix containing Os(bpy)2Cl2 as redox mediator that achieves electron transfer at 0·1 V (versus Ag/AgCl) with maximum apparent current densities of 1·2 mA/cm2. The dependence of the steady-state current on the loading of the mediator and the enzyme, other electrode construction parameters, the operating potential, the pH and the temperature was studied. In the steady-state mode the response current was directly proportional to D-fructose concentration from 0·2 to 20mM with a detection limit of 35 μM (signal-to-noise ratio, S/N, 3). In the flow injection analysis mode the response current was directly proportional to D-fructose concentration from 0·5 to 15 M with a detection limit of 115 μM (S/N 3). The sensor was used for the determination of fructose in food samples in a flow injection system and validated with a commercial enzyme kit.