Bruno Guigliarelli

Relating diffusion along the substrate tunnel and oxygen sensitivity in hydrogenase

In hydrogenases and many other redox enzymes, the buried active site is connected to the solvent by a molecular channel whose structure may determine the enzymes selectivity with respect to substrate and inhibitors. The role of these channels has been addressed using crystallography and molecular dynamics, but kinetic data are scarce. Using protein film voltammetry, we determined and then compared the rates of inhibition by CO and O2 in ten NiFe hydrogenase mutants and two FeFe hydrogenases. We found that the rate of inhibition by CO is a good proxy of the rate of diffusion of O2 toward the active site. Modifying amino acids whose side chains point inside the tunnel can slow this rate by orders of magnitude. We quantitatively define the relations between diffusion, the Michaelis constant for H2 and rates of inhibition, and we demonstrate that certain enzymes are slowly inactivated by O2 because access to the active site is slow.

NarJ is a specific chaperone required for molybdenum cofactor assembly in nitrate reductase A of Escherichia coli

The formation of active membrane‐bound nitrate reductase A in Escherichia coli requires the presence of three subunits, NarG, NarH and NarI, as well as a fourth protein, NarJ, that is not part of the active nitrate reductase. In narJ strains, both NarG and NarH subunits are associated in an unstable and inactive NarGH complex. A significant activation of this complex was observed in vitro after adding purified NarJ‐6His polypeptide to the cell supernatant of a narJ strain. Once the apo‐enzyme NarGHI of a narJ mutant has become anchored to the membrane via the NarI subunit, it cannot be reactivated by NarJ in vitro. NarJ protein specifically recognizes the catalytic NarG subunit. Fluorescence, electron paramagnetic resonance (EPR) spectroscopy and molybdenum quantification based on inductively coupled plasma emission spectroscopy (ICPES) clearly indicate that, in the absence of NarJ, no molybdenum cofactor is present in the NarGH complex. We propose that NarJ is a specific chaperone that binds to NarG and may thus keep it in an appropriate competent‐open conformation for the molybdenum cofactor insertion to occur, resulting in a catalytically active enzyme. Upon insertion of the molybdenum cofactor into the apo‐nitrate reductase, NarJ is then dissociated from the activated enzyme.

Experimental approaches to kinetics of gas diffusion in hydrogenase

Hydrogenases, which catalyze H2 to H+ conversion as part of the bioenergetic metabolism of many microorganisms, are among the metalloenzymes for which a gas-substrate tunnel has been described by using crystallography and molecular dynamics. However, the correlation between protein structure and gas-diffusion kinetics is unexplored. Here, we introduce two quantitative methods for probing the rates of diffusion within hydrogenases. One uses protein film voltammetry to resolve the kinetics of binding and release of the competitive inhibitor CO; the other is based on interpreting the yield in the isotope exchange assay. We study structurally characterized mutants of a NiFe hydrogenase, and we show that two mutations, which significantly narrow the tunnel near the entrance of the catalytic center, decrease the rates of diffusion of CO and H2 toward and from the active site by up to 2 orders of magnitude. This proves the existence of a functional channel, which matches the hydrophobic cavity found in the crystal. However, the changes in diffusion rates do not fully correlate with the obstruction induced by the mutation and deduced from the x-ray structures. Our results demonstrate the necessity of measuring diffusion rates and emphasize the role of side-chain dynamics in determining these.

[NiFe] hydrogenases from the hyperthermophilic bacterium Aquifex aeolicus : properties, function, and phylogenetics

Genes potentially coding for three distinct [NiFe] hydrogenases are present in the genome of Aquifex aeolicus. We have demonstrated that all three hydrogenases are expressed under standard growth conditions of the organism. Two hydrogenases were further purified to homogeneity. A periplasmically oriented hydrogenase was obtained in two forms, i.e., as a soluble enzyme containing only the two essential subunits and as a detergent-solubilized complex additionally containing a membrane-integral b-type cytochrome. The second hydrogenase purified was identified as a soluble cytoplasmic enzyme. The isolated enzymes were characterized with respect to biochemical/biophysical parameters, activity, thermostability, and substrate specificity. The phylogenetic positioning of all three hydrogenases was analyzed. A model for the metabolic roles of the three enzymes is proposed on the basis of the obtained results.

Structural and redox plasticity in the heterodimeric periplasmic nitrate reductase

The structure of the respiratory nitrate reductase (NapAB) from Rhodobacter sphaeroides, the periplasmic heterodimeric enzyme responsible for the first step in the denitrification process, has been determined at a resolution of 3.2 Å. The di-heme electron transfer small subunit NapB binds to the large subunit with heme II in close proximity to the [4Fe-4S] cluster of NapA. A total of 57 residues at the N- and C-terminal extremities of NapB adopt an extended conformation, embracing the NapA subunit and largely contributing to the total area of 5,900 Å2 buried in the complex. Complex formation was studied further by measuring the variation of the redox potentials of all the cofactors upon binding. The marked effects observed are interpreted in light of the three-dimensional structure and depict a plasticity that contributes to an efficient electron transfer in the complex from the heme I of NapB to the molybdenum catalytic site of NapA.

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.

Isolation and characterization of the pyruvate-ferredoxin oxidoreductase from the sulfate-reducing bacterium Desulfovibrio africanus

We report the first purification and characterization of a pyruvate-ferredoxin oxidoreductase (POR) from a sulfate-reducing bacterium, Desulfovibrio africanus. The enzyme as isolated is highly stable in the presence of oxygen and exhibits a specific activity of 14 U/mg. D. africanus POR is a 256 kDa homodimer which contains thiamine pyrophosphate (TPP) and iron-sulfur clusters. EPR spectroscopic study of the enzyme indicates the presence of three [4Fe-4S]2+/1- centers/subunits. The midpoint potentials of the three centers are -390 mV, -515 mV and -540 mV. The catalytic mechanism of POR involves a free radical intermediate which disappears when coenzyme A is added. This behaviour is discussed in terms of an electron-transport chain from TPP to the acceptor. The enzyme activated by dithioerythritol shows an exceptionally high activity compared with other mesophile PORs and becomes very sensitive to oxygen in contrast to the enzyme before activation. The comparison of EPR spectra given by the as isolated and activated enzymes shows that neither the nature, nor the arrangement of FeS centers are affected by the activation process. D. africanus ferredoxins I and II are involved as the physiological electron carriers of the enzyme. POR was shown to be located in the cytoplasm by immunogold labelling.

The coordination and function of the redox centres of the membrane-bound nitrate reductases

Abstract. Under anaerobic conditions and in the presence of nitrate, the facultative anaerobe Escherichia coli synthesises an electron-transport chain comprising a primary dehydrogenase and the terminal membrane-bound nitrate reductase A (NarGHI). This review focuses on recent advances obtained on the structure and function of the three protein subunits of membrane-bound nitrate reductases. We discuss a global architecture for the Mo-bisMGD-containing subunit (NarG) and a coordination model for the four [Fe–S] centres of the electron-transfer subunit (NarH) and for the two b-type haems of the anchor subunit NarI.

Mapping α‐helical induced folding within the intrinsically disordered C‐terminal domain of the measles virus nucleoprotein by site‐directed spin‐labeling EPR spectroscopy

Using site‐directed spin‐labeling EPR spectroscopy, we mapped the region of the intrinsically disordered C‐terminal domain of measles virus nucleoprotein (NTAIL) that undergoes induced folding. In addition to four spin‐labeled NTAIL variants (S407C, S488C, L496C, and V517C) (Morin et al. (2006), J Phys Chem 110: 20596‐20608), 10 new single‐site cysteine variants were designed, purified from E. coli, and spin‐labeled. These 14 spin‐labeled variants enabled us to map in detail the gain of rigidity of NTAIL in the presence of either the secondary structure stabilizer 2,2,2‐trifluoroethanol or the C‐terminal domain X (XD) of the viral phosphoprotein. Different regions of NTAIL were shown to contribute to a different extent to the binding to XD, while the mobility of the spin labels grafted at positions 407 and 460 was unaffected upon addition of XD; that of the spin labels grafted within the 488–502 and the 505–522 regions was severely and moderately reduced, respectively. Furthermore, EPR experiments in the presence of 30% sucrose allowed us to precisely map to residues 488–502, the NTAIL region undergoing α‐helical folding. The mobility of the 488–502 region was found to be restrained even in the absence of the partner, a behavior that could be accounted for by the existence of a transiently populated folded state. Finally, we show that the restrained motion of the 505–522 region upon binding to XD is due to the α‐helical transition occurring within the 488–502 region and not to a direct interaction with XD. Proteins 2008.

Hydrogenases in sulfate-reducing bacteria function as chromium reductase

AbstractThe ability of sulfate-reducing bacteria (SRB) to reduce chromate VI has been studied for possible application to the decontamination of polluted environments. Metal reduction can be achieved both chemically, by H2S produced by the bacteria, and enzymatically, by polyhemic cytochromes c3. We demonstrate that, in addition to low potential polyheme c-type cytochromes, the ability to reduce chromate is widespread among [Fe], [NiFe], and [NiFeSe] hydrogenases isolated from SRB of the genera Desulfovibrio and Desulfomicrobium. Among them, the [Fe] hydrogenase from Desulfovibrio vulgaris strain Hildenborough reduces Cr(VI) with the highest rate. Both [Fe] and [NiFeSe] enzymes exhibit the same Km towards Cr(VI), suggesting that Cr(VI) reduction rates are directly correlated with hydrogen consumption rates. Electron paramagnetic resonance spectroscopy enabled us to probe the oxidation by Cr(VI) of the various metal centers in both [NiFe] and [Fe] hydrogenases. These experiments showed that Cr(VI) is reduced to paramagnetic Cr(III), and revealed inhibition of the enzyme at high Cr(VI) concentrations. The significant decrease of both hydrogenase and Cr(VI)-reductase activities in a mutant lacking [Fe] hydrogenase demonstrated the involvement of this enzyme in Cr(VI) reduction in vivo. Experiments with [3Fe-4S] ferredoxin from Desulfovibrio gigas demonstrated that the low redox [Fe-S] (non-heme iron) clusters are involved in the mechanism of metal reduction by hydrogenases.