Crystal structure of nitrile hydratase reveals a novel iron centre in a novel fold

Molecular characterisation of a novel thermophilic nitrile hydratase

The thermophilic soil isolate, Bacillus pallidus Dac521, expresses a constitutive nitrile hydratase. The purified enzyme was found to be a 110 kDa tetramer composed of two alpha and two beta subunits with molecular masses of 27 kDa and 29 kDa, respectively. The enzyme electrophoresed as a single protein band on native PAGE but two protein bands with isoelectric points of 4.7 and 5.5 on isoelectric focusing suggested the presence of isozymes. The purified enzyme was moderately thermostable up to 55 degrees C and the enzyme activity was stable over a broad pH range. Comparisons of the N-terminal amino acid sequences of the nitrile hydratase subunits with those of other nitrile hydratases showed up to 90% identity for the beta subunit sequence but no significant identity for the alpha subunit. The enzyme hydrolysed a narrow range of aliphatic substrates and did not hydrolyse any of the cyclic, hydroxy-, di- or aromatic nitriles tested. The activity was irreversibly inhibited by the aromatic nitrile, benzonitrile. The kinetic constants for acetonitrile, acrylonitrile and propionitrile compared favourably with those of mesophilic nitrile hydratases.

Cobalt proteins

In the form of vitamin B12, cobalt plays a number of crucial roles in many biological functions. However, recent studies have provided information on the biochemistry and bioinorganic chemistry of several proteins containing cobalt in a form other than that in the corrin ring of vitamin B12. To date, eight noncorrin-cobalt-containing enzymes (methionine aminopeptidase, prolidase, nitrile hydratase, glucose isomerase, methylmalonyl-CoA carboxytransferase, aldehyde decarbonylase, lysine-2,3-aminomutase, and bromoperoxidase) have been isolated and characterized. A cobalt transporter is involved in the metallocenter biosynthesis of the host cobalt-containing enzyme, nitrile hydratase. Understanding the differences between cobalt and nickel transporters might lead to drug development for gastritis and peptic ulceration.

Active sites of transition-metal enzymes with a focus on nickel

Since 1995, crystal structures have been determined for many transition-metal enzymes, in particular those containing the rarely used transition metals vanadium, molybdenum, tungsten, manganese, cobalt and nickel. Accordingly, our understanding of how an enzyme uses the unique properties of a specific transition metal has been substantially increased in the past few years. The different functions of nickel in catalysis are highlighted by describing the active sites of six nickel enzymes - methyl-coenyzme M reductase, urease, hydrogenase, superoxide dismutase, carbon monoxide dehydrogenase and acetyl-coenzyme A synthase.

Detection of a nitric oxide synthase possibly involved in the regulation of the Rhodococcus sp R312 nitrile hydratase

Crude homogenates from Rhodococcus sp 312 catalyze the conversion of L-arginine into L-citrulline and NO2-, the usual oxidation product of NO under aerobic conditions. They also catalyze the conversion of N omega-hydroxy-L-arginine (NOHA) into L-citrulline and NO2- with similar rates (10-15 and 100-150 nmol of product.min-1.(mg of protein)-1 respectively for the crude homogenate and for a fraction obtained from ammonium sulfate precipitation). L-citrulline formation is strongly inhibited by classical inhibitors of mammalian nitric oxide synthases (NOSs) such as N omega-methyl-L-arginine (NMA) and thio-L-citrulline (TC). Finally, the lack of inhibitory effects of EGTA, a classical inhibitor of constitutive mammalian NOSs, and the specific immunodetection of a 100 kD protein from Rhodococcus cytosol by an antibody raised against human inducible NOS, is in favor of the presence of a NOS similar to inducible mammalian NOSs in Rhodococcus sp 312. This NOS should be responsible for the NO-dependent inactivation of Rhodococcus Nitrile Hydratase (NHase) in the absence of light; it could regulate the activity of the latter enzyme.

Evidence for coupled electron and proton transfer in the [8Fe-7S] cluster of nitrogenase

Substrate reduction by nitrogenase requires electron transfer from a [4Fe-4S] cluster in the iron (Fe) protein component to an FeMo cofactor in the molybdenum-iron (MoFe) protein component in a reaction that is coupled to MgATP hydrolysis and component protein association and dissociation. An [8Fe-7S] (or P-) cluster in the MoFe protein has been proposed as an intermediate electron-transfer site, although how this cluster functions in electron-transfer remains unclear. In the present work, it is demonstrated that one redox couple of the P-cluster (P2+/1+) undergoes coupled electron and proton transfer, whereas a more reduced couple (P1+/N) does not involve a coupled proton transfer. Redox titrations of the MoFe protein P-cluster were performed, and the midpoint potential of the P2+/1+ couple (Em2) was found to be pH dependent, ranging from -224 mV at pH 6.0 to -348 mV at pH 8.5. A plot of Em2 versus the pH for this redox couple was linear and revealed a change of -53 mV/pH unit, indicating a single protonation event associated with reduction. From this plot, it was concluded that p is <6.0 and p is >8.5 in a proton-modified Nernst equation. In contrast, the midpoint potential for the P1+/N couple (Em1) was found to be -290 mV and was invariant over the pH range 6.0-8.5. These results indicate that the protonated species does not influence either the P1+ or the PN oxidation states. In addition, at physiological pH values, electron transfer is coupled to proton transfer for the P2+/1+ couple. The P-clusters are unique among [Fe-S] clusters in that they appear to be ligated to the protein through a serinate-gammaO ligand (betaSer188) and a peptide bond amide-N ligand (alphaCys88), in addition to cysteinate-S ligands. Elimination of the serinate ligand by replacement with a glycine was found to shift the Em values for both P-cluster couples by greater than +60 mV, however the pH dependence of Em2 was unchanged. These results rule out Ser188 as the protonated ligand responsible for the pH dependence of Em2. The implications of these results in understanding the nitrogenase electron-transfer mechanism are discussed.

Metalloenzyme nitrile hydratase: structure, regulation, and application to biotechnology

Nitrile hydratase (NHase), which catalyzes the hydration of nitriles to amides, has been used in the industrial production of acrylamide and nicotinamide. Recent studies on NHases, which are roughly classified into iron and cobalt types according to the metal involved, have clarified the photoactivation mechanism, the novel ligand structure of the metal-binding sites, the unique mechanism of the enzyme hyper-induction, and the occurrence of an accessory gene involved in cobalt-containing NHase formation. These detailed analyses have led to the development of biotechnological applications of NHase, including biotransformation and bioremediation.

Ga3+ as a functional substitute for Fe3+: preparation and characterization of the Ga3+Fe2+ and Ga3+Zn2+ forms of bovine spleen purple acid phosphatase

A general method has been developed that allows the specific substitution of both iron atoms in the enzyme bovine spleen purple acid phosphatase (BSPAP), which possesses a dinuclear iron center at the active site. The approach is demonstrated by the preparation and characterization (atomic absorption spectrometry, enzyme kinetics, optical spectroscopy, and electron paramagnetic resonance spectroscopy) of two metal-substituted forms in which the ferric iron has been replaced by Ga3+: Ga3+Fe2+-BSPAP and Ga3+Zn2+-BSPAP. Both forms are colorless but exhibit enzymatic activity comparable to that of the native Fe3+Fe2+-BSPAP. Small but consistent changes in kinetics parameters and pH profiles were detected both upon substitution of Fe3+ by Ga3+ and upon substitution of Fe2+ by Zn2+. These results constitute the first evidence that the diamagnetic Ga3+ ion can serve as a functional analogue of Fe3+ in an enzyme, and suggest a novel approach for the study of the role of Fe3+ in other iron enzymes.

Novel non-heme iron center of nitrile hydratase with a claw setting of oxygen atoms

The iron-containing nitrile hydratase (NHase) is a photoreactive enzyme that is inactivated in the dark because of persistent association with NO and activated by photo-dissociation of NO. The crystal structure at 1.7 A resolution and mass spectrometry revealed the structure of the non-heme iron catalytic center in the nitrosylated state. Two Cys residues coordinated to the iron were post-translationally modified to Cys-sulfenic and -sulfinic acids. Together with another oxygen atom of the Ser ligand, these modifications induced a claw setting of oxygen atoms capturing an NO molecule. This unprecedented structure is likely to enable the photo-regulation of NHase and will provide an excellent model for designing photo-controllable chelate complexes and, ultimately, proteins.

PROMISE: a database of information on prosthetic centres and metal ions in protein active sites

The PROMISE (Prosthetic centres andmetalions in protein activesites) database aims to gather together comprehensive sequence, structural, functional and bibliographic information on proteins which possess prosthetic centres, with an emphasis on active site structure and function. The database is available on the World Wide Web at http://bioinf.leeds.ac.uk/promise/

Structure of the photoreactive iron center of the nitrile hydratase from Rhodococcus sp. N-771. Evidence of a novel post-translational modification in the cysteine ligand

Nitrile hydratase (NHase) from Rhodococcus sp. N-771 is a photoreactive enzyme that is inactivated by nitrosylation of the non-heme iron center and activated by photodissociation of nitric oxide (NO). To obtain structural information on the iron center, we isolated peptide complexes containing the iron center by proteolysis. When the tryptic digest of the alpha subunit isolated from the inactive form was analyzed by reversed-phase high performance liquid chromatography, the absorbance characteristic of the nitrosylated iron center was observed in the peptide fragment, Asn105-Val-Ile-Val-Cys-Ser-Leu-Cys-Ser-Cys-Thr-Ala-Trp-Pro-Ile-Leu - Gly-Leu-Pro-Pro-Thr-Trp-Tyr-Lys128. The peptide contained 0.79 mol of iron/mol of molecule as well as endogenous NO. Subsequently, by digesting the peptide with thermolysin, carboxypeptidase Y, and leucine aminopeptidase M, we found that the minimum peptide segment required for the nitrosylated iron center is the 11 amino acid residues from alphaIle107 to alphaTrp117. Furthermore, by using mass spectrometry, protein sequence, and amino acid composition analyses, we have shown that the 112th Cys residue of the alpha subunit is post-translationally oxidized to a cysteine-sulfinic acid (Cys-SO2H) in the NHase. These results indicate that the NHase from Rhodococcus sp. N-771 has a novel non-heme iron enzyme containing a cysteine-sulfinic acid in the iron center. Possible ligand residues of the iron center are discussed.