Glucose biosensor based on disposable electrochemical paper-based transducers fully fabricated by screen-printing.

This paper describes a new approach for the massive production of electrochemical paper-based analytical devices (ePADs). These devices are fully fabricated by screen-printing technology and consist of a lineal microfluidic channel delimited by hydrophobic walls (patterned with diluted ultraviolet screen-printing ink in chromatographic paper grade 4) and a three-electrode system (printed with carbon and/or Ag/AgCl conductive inks). The printing process was characterised and optimized for pattern each layer with only one squeeze sweep. These ePADs were used as transducers to develop a glucose biosensor. Ionic strength/pH buffering salts, electrochemical mediator (ferricyanide) and enzyme (glucose dehydrogenase FAD-dependent) were separately stored along the microfluidic channel in order to be successively dissolved and mixed after the sample dropping at the entrance. The analyses required only 10 µl and the biosensors showed good reproducibility (RSD = 6.2%, n = 10) and sensitivity (0.426 C/M cm2), wide linear range (0.5-50 mM; r2 = 0.999) and low limit of detection (0.33 mM). Furthermore, the new biosensor was applied for glucose determination in five commercial soft-drinks without any sample treatment before the analysis. These samples were also analysed with a commercial enzymatic-kit assay. The results indicated that both methods provide accurate results.

Synthesis and functionalization of dextran-based single-chain nanoparticles in aqueous media.

Water-dispersible dextran-based single-chain polymer nanoparticles (SCPNs) were prepared in aqueous media and under mild conditions. Radiolabeling of the resulting biocompatible materials allowed the study of lung deposition of aqueous aerosols after intratracheal nebulization by means of single-photon emission computed tomography (SPECT), demonstrating their potential use as imaging contrast agents.

Redox properties of the iron-sulfur clusters in activated Fe-hydrogenase from Desulfovibrio vulgaris (Hildenborough).

The periplasmic Fe-hydrogenase from Desulfovibrio vulgaris (Hildenborough) contains three iron-sulfur prosthetic groups: two putative electron transferring [4Fe-4S] ferredoxin-like cubanes (two F-clusters), and one putative Fe/S supercluster redox catalyst (one H-cluster). Combined elemental analysis by proton-induced X-ray emission, inductively coupled plasma mass spectrometry, instrumental neutron activation analysis, atomic absorption spectroscopy and colorimetry establishes that elements with Z > 21 (except for 12-15 Fe) are present in 0.001-0.1 mol/mol quantities, not correlating with activity. Isoelectric focussing reveals the existence of multiple charge conformers with pI in the range 5.7-6.4. Repeated re-chromatography results in small amounts of enzyme of very high H2-production activity determined under standardized conditions (approximately 7000 U/mg). The enzyme exists in two different catalytic forms: as isolated the protein is 'resting' and O2-insensitive; upon reduction the protein becomes active and O2-sensitive. EPR-monitored redox titrations have been carried out of both the resting and the activated enzyme. In the course of a reductive titration, the resting protein becomes activated and begins to produce molecular hydrogen at the expense of reduced titrant. Therefore, equilibrium potentials are undefined, and previously reported apparent Em and n values [Patil, D. S., Moura, J. J. G., He, S. H., Teixeira, M, Prickril, B. C., DerVartanian, D. V., Peck, H. D. Jr, LeGall, J. & Huynh, B.-H. (1988) J. Biol. Chem. 263, 18,732-18,738] are not thermodynamic quantities. In the activated enzyme an S = 1/2 signal (g = 2.11, 2.05, 2.00; 0.4 spin/protein molecule), attributed to the oxidized H cluster, exhibits a single reduction potential, Em,7 = -307 mV, just above the onset potential of H2 production. The midpoint potential of the two F clusters (2.0 spins/protein molecule) has been determined either by titrating active enzyme with the H2/H+ couple (E,m = -330 mV) or by dithionite-titrating a recombinant protein that lacks the H-cluster active site (Em,7.5 = -340 mV). There is no significant redox interaction between the two F clusters (n approximately 1).

Application of hydrogenase in biotechnological conversions.

Evidence will be presented in this review article that the application of hydrogenase has large biotechnological possibilities. Our investigations show: Fast reaction of hydrogenase at an electrode surface to reduce H+; Photochemical production of H2 by hydrogenase by photosensitized Ru-complexes dissolved in reversed micellar membranes and vectorial H+ transport through the membrane to the water phase; The production of fine chemicals in reversed micelles by a system containing specific enzymes, hydrogenase and H2. The rules to obtain maximal conversion rates with this system will be presented.

A study of one of the iron-sulphur clusters in oxidized hydrogenase from Megasphaera elsdenii by magnetic-circular-dichroism spectroscopy.

The m.c.d. spectrum of the oxidized state of hydrogenase from Megasphaera elsdenii has been measured at liquid-helium temperatures. This oxidation state of the enzyme displays a characteristic rhombic e.p.r. signal with g-values of 2.101, 2.052 and 2.005 assigned previously to a [4Fe-4S]3+ cluster as in oxidized HiPIP (high-potential iron-sulphur protein) [Van Dijk, Grande, Mayhew & Veeger (1980) Eur. J. Biochem. 107, 251-261]. The low-temperature m.c.d. spectrum shows no features attributable to an oxidized four-iron cluster of the HiPIP type, but does reveal broad, positive peaks at 460 and 730 nm, which magnetize in a manner untypical of a spin S = 1/2 cluster with g-values close to 2. The m.c.d. spectrum is most closely similar to that of dye-oxidized P-clusters known in the enzyme nitrogenase. It is therefore proposed that the rhombic e.p.r. spectrum at a g-value close to 2 arises from an m.c.d.-silent radical species that may be related chemically to the cysteine persulphide species, RS-S., recently found in the hexacyanoferrate-oxidized seven-iron ferredoxin of Azotobacter vinelandii [Morgan, Stephens, Devlin, Stout, Melis & Burgess (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 1931-1935].

The importance of quantitative Mössbauer spectroscopy of MoFe-protein from Azotobacter vinelandii.

The Mössbauer spectra of MoFe-protein of Azotobacter vinelandii, as isolated under dithionite and taken at temperatures from 125 K to 175 K, are the sums of four resolved quadrupole doublets. Our results indicate that the currently accepted interpretation of these doublets can be questioned. Our data reduction method converts the Mössbauer transmission spectra to source lineshape deconvolved absorption spectra linear in iron. We used these absorption spectra to determine the stoichiometry of the Fe clusters in MoFe-protein and we obtained much better fits if we assumed that there are four iron atoms in the 'Fe2+, doublet, two iron atoms in the 'S' doublet, twelve iron atoms in the 'D' doublet and sixteen iron atoms in the 'M' doublet. Therefore we propose that the MoFe-cofactor contains one molybdenum and eight iron atoms ('M'). We also argue that none of the previous Mössbauer spectroscopic studies have been performed on the highest-activity preparation now obtainable, nor has there been any study to prove that the Mössbauer spectra are independent of activity. We consider that the Mössbauer spectroscopic studies of the MoFe-protein of nitrogenase are a re-opened and unsolved problem.

Electron paramagnetic resonance and other properties of hydrogenases isolated from Desulfovibrio vulgaris (strain Hildenborough) and Megasphaera elsdenii.

The hydrogenases of Desulfovibrio vulgaris and Megasphaera elsdenii are compared with respect to some of their physical properties. In addition to Fe the only metal ions that are present in significant amounts are Ni and Cu. From cluster extrusion experiments it follows that the D. vulgaris enzyme contains three 4 Fe-4S clusters, while M. elsdenii hydrogenase only releases part of its Fe-S clusters. The resting D. vulgaris enzyme shows only a small 3 Fe-xS type of EPR signal (maximum 5% electron equivalent). This amount can be increased to approximately 25% by treatment with ferricyanide, with a concomitant large decrease in activity. The M. elsdenii enzyme shows in its oxidized state a normal Hipip (high-potential iron-sulphur protein) type of EPR spectrum. After a reduction/oxidation cycle the D. vulgaris enzyme also shows a weak Hipip type of EPR spectrum. In the reduced state both enzymes show complex spectra. By integration of those spectra it is shown that 1.5 electron equivalents are present. The complex spectra do not arise from nuclear hyperfine interactions but are partially due to electron spin interactions. It is proposed that the spectrum of reduced D. vulgaris hydrogenase consists of a sum of three different ferredoxin-like spectra.

Kinetic properties of hydrogenase isolated from Desulfovibrio vulgaris (Hildenborough).

Hydrogenase of Desulfovibrio vulgaris shows nonlinear kinetics in hydrogen production with both the natural electron carrier, cytochrome c3, and the artificial donor, methyl viologen semiquinone. Increasing concentrations of salt progressively inhibit the hydrogen production, as do increasing amounts of dimethylsulfoxide (Me2SO). Hydrogen consumption activity does not change up to 30% (v/v) of Me2SO. Preincubation in Me2SO up to 55% (v/v) does not affect the hydrogen uptake or production. The production activity of the enzyme shows an optimum around pH 6. When plotted as a function of redox potential the activity can be fitted to a Nernst equation with n = 1. Midpoint potentials calculated at various values follow approximately the hydrogen electrode to pH 6. Thereafter, there is a shift of about 40 mV to higher redox potentials.

A pulse-radiolysis study of cytochrome c3. Kinetics of the reduction of cytochrome c3 by methyl viologen radicals and the characterisation of the redox properties of cytochrome c3 from Desulfovibrio vulgaris (Hildenborough).

1. Pulse-radiolysis experiments were performed in the presence of methyl viologen and cytochrome c3. After the pulse, methyl viologen radicals are formed and the kinetics of these radicals with cytochrome c3 are studied, The reaction between cytochrome c3 and methyl viologen radicals (MV+) is diffusion controlled. The ionic strength dependence and the pH-dependence of this reaction were studied. From the ionic strength dependence (at pH 7.8) we found that the net charge of the fully oxidized cytochrome c3 molecule was Z = + 4.7 +/- 0.7. 2. After the pulse an equilibrium is reached for the reaction of MV+ with cytochrome c3. From this equilibrium an apparent midpoint potential can be obtained. The apparent midpoint potential of this multihaem molecule was found to depend on the degree of reduction, alpha. With the help of the Nernst equation an empirical equation is obtained to describe this dependence of the midpoint potential: E0 = - 0.250 - 0.088 alpha (in V). 3. An estimation is made of the energy of interaction between the haems due to electrostatic interactions (delta epsilon less than 32 mV) and due to ionic strength effects (- 12 mV less than delta epsilon less than 26 mV). The results suggest that the redox properties of the individual haems in the cytochrome c3 molecule are dependent on the degree of reduction of the other haems in the molecule. 4. The reaction of cytochrome c3 with MV+ or with ethanol radicals (EtOH) has been compared with the reactions of horse-heart cytochrome c and of metmyoglobin with the same radicals. The reaction of MV+ or EtOH with horse-heart cytochrome c is found to be diffusion controlled; the reactions with metmyoglobin on the other hand are most probably controlled by an activation energy.

On the molecular and submolecular structure of the semiquinone cations of alloxazines and isoalloxazines as revealed by electron-paramagnetic-resonance spectroscopy.

The thermodynamically stable and, therefore, analytically most important alloxazine and isoalloxazine radical cations have been studied in detail by electron paramagnetic resonance (EPR) spectroscopy. Isotopic and chemical substitutions have been made as in earlier studies with the less stable neutral and anionic species. The experimental spectra have been calculated with the aid of a more sophisticated computer-simulation program than previously used. Excellent fits were obtained only when all of the following atoms were taken into account in the hyperfine coupling scheme: N-5 H, N-10 H or CH3, C-6 H, C-7 H, C-8 H or CH3 and C-9 H. An additional but small coupling constant was required for the fit. This latter coupling constant is assigned to the nitrogen atom(s) of the pyrimidine subnucleus of (iso)alloxazine radical cations. The EPR-active proton is attached to N-5 as we also found for the neutral flavosemiquinone. The alloxazine and isoalloxazine radical cations exhibit an identical hyperfine coupling scheme but differ especially in the pyrazine nucleus with respect to the spin density distribution. This suggests that the geometrical structure of the two kinds of radicals is somewhat different. The highest spin density is, however, located at N-5 of (iso)alloxazine as has been found for the other flavosemiquinone species. The hyperfine coupling constants are interpreted in terms of spin densities and comparison is made with the most recently available quantum chemical calculations. All monomeric flavosemiquinone species are compared with each other and their differences in the submolecular structure are discussed briefly.

Fluorescence polarization and energy-transfer studies on the pyruvate dehydrogenase complex of Escherichia coli.

We have attached eosin maleimide specifically to the lipoyl group of the pyruvate dehydrogenase complex isolated from Escherichia coli. Using this as the fluorescence acceptor and the intrinsic FAD of the lipoamide dehydrogenase subunit as the fluorescence donor, we confirmed previous measurements with other probes, in which it was suggested that the flavin moiety is at a substantial distance (over 4.5 nm) from the labeled lipoyl group. Since the lipoyl group must apply electrons to the FAD during the catalytic decarboxylation of pyruvate, we have investigated several potential mechanisms whereby this could happen. Movement within the complex, possibly triggered by the presence of substrate, seemed to be a strong possibility. Complex labeled with fluorophores on the accessible sulfhydryls, or on the lipoyl functions, did not give evidence of such triggering upon addition of substrate as judged by both static and dynamic fluorescence depolarization. The mobility of the subunits of labeled lipoamide dehydrogenase exceeded that expected for the total complex. Pyrene maleimide bound to the lipoyl functions also exhibited considerably faster rotations than the predicted one of the whole complex (tau c > 3 micros). This suggests that a constant movement within the complex, coupled with the rotation of the lipoyl group, may bring the active sites of the complex transiently close enough together to interact on a time scale much faster than enzyme turnover. At the same time, the lipoyl group and the active sites of the complex can spend most of their time at points which are rather distant from each other.

Protein mobility inside pyruvate dehydrogenase complexes as reflected by laser-pulse fluorometry. A new approach to multi-enzyme catalysis.

The fluorescence decay curves of the flavin in all pyruvate dehydrogenase complexes studied here are consistent with a two-exponential fit. One of the lifetimes calculated is very short, as demonstrated by experiments in which a mode-locked argon-ion laser was used for excitation. In three complexes out of the four which were investigated, about equal weights for the amplitudes of the two lifetimes are found. In the three-component complex from Azotobacter vinelandii this is not the case. No effects of the protein concentration on the lifetimes of the fluorophore were found in the concentration range studied. A small but significant difference in lifetime is observed for the A. vinelandii complexes when coenzyme-free complex is compared with complex to which Mg2+ and thiamin diphosphate are added. The correlation time calculated from the polarized decay of the flavin fluorescence at 11 degrees C is around 40 ns and 50 ns for A. vinelandii complexes and Escherichia coli complexes respectively. This correlation time is of the same order as the rotational correlation time of free lipo-amide dehydrogenase itself, but much shorter than would be expected from the molecular weights of the complexes. Models explaining the two lifetimes are discussed. A catalytic mechanism based on the internal mobility of the lipoamide dehydrogenase inside the multi-enzyme complex is proposed.

Properties of the hydrogenase of Megasphaera elsdenii.

The catalytic activities of Megasphaera elsdenii hydrogenase are stimulated by salts. The stimulation is due to the anion: the more chaotropic the anion, the greater the effect. Dithionite-reduced and dye-oxidised preparations of hydrogenase are inactivated by reaction with oxygen. The inactivation of the reduced enzyme by excess oxygen follows pseudo-first-order kinetics; the reaction order for the oxidised enzyme has not been established. The rate of oxygen-inactivation is decreased by bovine serum albumin. The hydrogen production activity decreases in the presence of dimethylsulphoxide and ethylene glycol. The hydrogen oxidation activity is stimulated by dimethylsulphoxide, and the activity remains linear with time at concentrations up to 50% (v/v). Above 70% dimethylsulphoxide the steady-state activity of hydrogenase is abolished for both types of activity. The enzyme is more stable in a hydrogen atmosphere than in an argon atmosphere, and the oxidized enzyme is more stable than the reduced enzyme. The enzyme is isolated in the presence of dithionite and it is therefore reduced. When the enzyme is oxidized by treatment with 2,6-dichloroindophenol or with (bi)sulphite, its activity increases by up to 65%; this activation is not reversed when the enzyme is re-reduced. The increase in activity is associated with a change of the redox potential of the incubation medium to a less negative value; half of the maximum activation occurs at -0.41 V. The electron paramagnetic resonance spectrum of the dithionite-reduced hydrogenase resembles that of a reduced ferredoxin-type of spectrum with two 4Fe-4S clusters. The spectrum of the oxidized enzyme is similar to that of Chromatium high-potential iron-sulphur protein. No redox potentials can be ascribed to these spectra since the redox system changes upon freezing to liquid helium temperatures.

Purification and properties of hydrogenase from Megasphaera elsdenii.

A hydrogenase has been purified to homogeneity from the soluble fraction of the rumen bacterium Megasphaera elsdenii, the overall purification is 200 times with a yield of 14%. The pure enzyme consists of a single polypeptide chain with Mr approximately 50 000 which contains 12 atoms of non-haem iron and 12 atoms of acid-labile sulphide. The enzyme is rapidly inactivated by O2 and it is therefore purified under nitrogen and in the presence of sodium dithionite. The optical spectrum of the enzyme, after removal of the dithionite with air, shows a peak at 275 nm (epsilon 275 nm = 143 mM-1 cm-1) and a shoulder between 350 nm and 400 nm (epsilon 400 nm = 46 mM-1 cm-1). The enzyme catalyses hydrogen production from sodium dithionite at a low rate. The rate is greatly enhanced by addition of the electron donors flavodoxin, ferredoxin and methyl viologen. The kinetic data with these three electron donors suggest co-operativity, but no indication of self-association of the enzyme was obtained. Sodium chloride enhances the rate of hydrogen production with methyl viologen semiquinone and changes the kinetic behaviour of the enzyme with this electron donor, but causes inhibition of the reactions mediated by ferredoxin and flavodoxin. Two kinetic models were developed which are consistent with the kinetic data of the three electron donors tested. The apparent co-operativity for the hydrogen production can be fitted with the mathematical form of those models. The identical kinetic behaviour of the hydrogenase with the one-electron donors flavodoxin and methyl viologen semiquinone monomer and the two-electron donor ferredoxin indicates that the hydrogenase accepts two electrons in two separate, independent steps and further indicates that the two (4Fe-4S) clusters of the donor ferredoxin are independent. The interpretation of the kinetic data with methyl viologen semiquinone is complicated by the fact that the semiquinone dimerises, and that the formation of the dimer is enhanced by salt. Taking into account the association of this donor, the activity of the enzyme with methyl viologen semiquinone can be described by the sum of the activities of the enzyme with methyl viologen monomer and methyl viologen dimer. The enzyme catalyses the oxidation of hydrogen gas with methyl and benzyl viologen as electron acceptors to their semiquinone forms; both electron acceptors show Michaelis-Menten kinetics. The hydrogen oxidation activity with both electron acceptors is stimulated by addition of sodium chloride. The kinetic data of the oxidation of hydrogen with the two-electron acceptors used are consistent with the porposed models, if it is assumed that the pathway followed is compulsory. At this moment no choice can be made between the models proposed.

Fluorescence energy-transfer studies on the pyruvate dehydrogenase complex isolated from Azotobacter vinelandii.

Fluorescence energy transfer has been employed to estimate the minimum distance between each of the active sites of the 4 component enzymes of the pyruvate dehydrogenase multienzyme complex from Azotobacter vinelandii. No energy transfer was seen between thiochrome diphosphate, bound to the pyruvate decarboxylase active site, and the FAD of the lipoamide dehydrogenase active site. Likewise, several fluorescent sulfhydryl labels, which were specifically bound to the lipoyl moiety of lipoyl transacetylase, showed no energy transfer to either the flavin or thiochrome diphosphate. These observations suggest that all the active centers of the complex are quite far apart (greater than or equal to 40 nm), at least during some stages of catalysis. These results do not preclude the possibility that the distances change during catalysis. Several of the fluorescent probes used possessed multiple fluorescent lifetimes, as shown by determination of lifetime averages by both phase and modulation measurements on a phase fluorimeter. These lifetimes are shown to result from multiple factors, not necessarily related to multiple protein conformations.

Symmetry and asymmetry of the pyruvate dehydrogenase complexes from Azotobacter vinelandii and Escherichia coli as reflected by fluorescence and spin-label studies.

Fluorescence-lifetime measurements of FAD bound to lipoamide dehydrogenase from Azotobacter vinelandii and Escherichia coli were performed. It is shown from these results that the two FAD groups in the isolated dimeric enzyme, as well as in the enzyme in the intact complex of E. coli, are in non-equivalent surroundings. This contrasts with the near equivalence of the FAD groups of both the enzyme and complex isolated from A. vinelandii. Reduction of the complex with Mg2+, thiamine pyrophosphate and pyruvate or with NADH enables the attachment of a maleimide analogue specifically to the lipoyl moieties of the transacetylase(s). Spin label [N-(1-oxyl-2,2,5,5-tetramethyl-3-pyrrolidinyl)maleimide] introduced in such a way proves the existence of at least two different micro-environments around the lipoyl moieties in complex isolated from A. vinelandii. Electron paramagnetic resonance spectra of the specifically spin-labelled complexes from E. coli and A. vinelandii, when dissolved in tricine [N-tris(hydroxymethyl)-methylglycine] buffer, show interactions of at least two electron spins with each other, which indicate that the lipoyl moieties are rather close together. Fluorescent label [N-(1-anilinonaphthyl-4)maleimide] is specifically attached to the lipoyl moiety of the high-Mr transacetylase of the freshly isolated complex from A. vinelandii. From the large differences in the apparent lifetimes tau p and tau m, as detected by phase fluorimetry, it is shown that this fluorscent label is distributed in different micro-environments. The differences observed in energy transfer between fluorescent label, attached to the lipoyl moiety of the high-Mr transacetylase, indicate different conformations of the complex from A. vinelandii. Upon introduction of the label after reduction with NADH a much larger energy transfer, thus a shorter distance, is observed between the label and FAD than when reduction is performed with Mg2+, thiamine pyrophosphate and pyruvate. A similar conformation dependence upon reduction is found for the pyruvate dehydrogenase complex from E. coli. It is thus proposed that the transacetylase of E. coli and the high-Mr transacetylase of A. vinelandii are both non-symmetrically distributed within the complex.