Enzymatic hydrolysis of cyanohydrins with recombinant nitrile hydratase and amidase from hodococcus erythropolis

Nitrile hydratase and amidase from Rhodococcus erythropolis CIMB11540 were both cloned and expressed in Escherichia coli. Crude cell free extracts were used for the hydrolysis of different aromatic cyanohydrins. Nitrile hydratase expression was increased up to 5-fold by redesign of the expression cassette. The recombinant enzymes were successfully used for the conversion of several cyanohydrins to the corresponding alpha-hydroxy amides and acids while retaining enantiopurity.     

Efficient inducible expression of nitrile hydratase in Corynebacterium glutamicum

Nitrile hydratases are important industrial catalysts to produce valuable amides. In this study, we describe a comprehensive and systematic approach to the development of an inducible expression system for enhanced nitrile hydratase expression in Corynebacterium glutamicum. Through promoter engineering, codon optimization and design of ribosome binding site sequences, the nitrile hydratase activity toward 3-cyanopyridine was improved from 0.33 U/mg DCW to 12.03 U/mg DCW in shake-flask culture. By introduction of the novel inducible mmp expression system, the nitrile hydratase activity was further elevated to 14.97 U/mg DCW. Finally, a high nitrile hydratase yield of 1432 U/mL was achieved in a fed-batch fermentation process and used for nicotinamide production. These results provide new insights for the development of heterologous protein expression systems in C. glutamicum.     

Over-production of stereoselective nitrile hydratase from Pseudomonas putida 5B in Escherichia coli : activity requires a novel downstream protein

The stereoselective nitrile hydratase (NHase) from Pseudomonas putida 5B has been over-produced in Escherichia coli. Maximal enzyme activity requires the co-expression of a novel downstream gene encoding a protein (P14K) of 127 amino acids, which shows no significant homology to any sequences in the protein database. Nitrile hydratase produced in transformed E. coli showed activity as high as 472 units/mg dry cell (sixfold higher than 5B), and retained the stereoselectivity observed in the native organism. Separated from the end of the β subunit by only 51 bp, P14K appears to be part of an operon that includes the α and β structural genes of nitrile hydratase, and other potential coding sequences. Received: 13 May 1997 / Received revision: 22 August 1997 / Accepted: 15 September 1997     

Expression control of nitrile hydratase and amidase genes in Rhodococcus erythropolis and substrate specificities of the enzymes

Bacterial amidases and nitrile hydratases can be used for the synthesis of various intermediates and products in the chemical and pharmaceutical industries and for the bioremediation of toxic pollutants. The aim of this study was to analyze the expression of the amidase and nitrile hydratase genes of Rhodococcus erythropolis and test the stereospecific nitrile hydratase and amidase activities on chiral cyanohydrins. The nucleotide sequences of the gene clusters containing the oxd (aldoxime dehydratase), ami (amidase), nha1, nha2 (subunits of the nitrile hydratase), nhr1, nhr2, nhr3 and nhr4 (putative regulatory proteins) genes of two R. erythropolis strains, A4 and CCM2595, were determined. All genes of both of the clusters are transcribed in the same direction. RT-PCR analysis, primer extension and promoter fusions with the gfp reporter gene showed that the ami, nha1 and nha2 genes of R. erythropolis A4 form an operon transcribed from the Pami promoter and an internal Pnha promoter. The activity of Pami was found to be weakly induced when the cells grew in the presence of acetonitrile, whereas the Pnha promoter was moderately induced by both the acetonitrile or acetamide used instead of the inorganic nitrogen source. However, R. erythropolis A4 cells showed no increase in amidase and nitrile hydratase activities in the presence of acetamide or acetonitrile in the medium. R. erythropolis A4 nitrile hydratase and amidase were found to be effective at hydrolysing cyanohydrins and 2-hydroxyamides, respectively.     

Metabolism of acrylonitrile by Klebsiella pneumoniae

A gram-negative rod-shaped bacterium capable of utilizing acrylonitrile as the sole source of nitrogen was isolated from industrial sewage and identified as Klebsiella pneumoniae. The isolate was capable of utilizing aliphatic nitriles containing 1 to 5 carbon atoms or benzonitrile as the sole source of nitrogen and either acetamide or propionamide as the sole source of both carbon and nitrogen. Gas chromatographic and mass spectral analyses of culture filtrates indicated that K. pneumoniae was capable of hydrolyzing 6.15 mmol of acrylonitrile to 5.15 mmol of acrylamide within 24 h. The acrylamide was hydrolyzed to 1.0 mmol of acrylic acid within 72 h. Another metabolite of acrylonitrile metabolism was ammonia, which reached a maximum concentration of 3.69 mM within 48 h. Nitrile hydratase and amidase, the two hydrolytic enzymes responsible for the sequential metabolism of nitrile compounds, were induced by acrylonitrile. The optimum temperature for nitrile hydratase activity was 55°C and that for amidase was 40°C; both enzymes had pH optima of 8.0.Abbreviations PBM phosphate buffered medium - GC gas chromatography - GC/MS gas chromatography/mass spectrometry     

Three Metabolites Produced by Valsa sp.

Two enzymes, nitrile hydratase and amidase, which participate in the conversion of trans-1,4- dicyanocyclohexane (t-DCC) to frans-4-cyanocyclohexane-l-carboxylic acid (t-MCC), a tranexamic acid intermediate, were purified and characterized. Nitrile hydratase was obtained in a homogeneous state. The molecular weight of the native enzyme was 61,400 and that of the subunit 26.900, indicating a dimer structure. Valeronitrile and butyronitrile were good substrates for the enzyme. The enzyme could also hydrate benzonitrile, p-hydroxybenzonitrile and 4-cyanobenzoic acid. t-DCC was ex-clusively hydrated to fnzws-4-cyanocycIohexane-l-car boxy amide (t-MCMA), further hydration of the nitrile group of t-MCMA and t-MCC not being observed. The presence of pyrroloquinoline quinone in the enzyme was confirmed. The presence of iron was also confirmed. The amidase of the strain was also purified. The latter enzyme could hydrate t-MCMA, yielding t-MCC. The enzyme was highly resistant to SH reagents.     

Enzymatic nitrile hydrolysis in low water systems

Nitrile hydratase from Rhodococcus sp. DSM 11397 and nitrilase from Pseudomonas. DSM 11387 both retained activity in various organic/aqueous biphasic mixtures. Both enzymes were most tolerant (66–109% retained activity) of C8 and C16 alkanes with log P values greater than 4.0. Some enzyme activity (<10% nitrile hydratase, <60% nitrilase) was also retained in monophasic water-saturated C6-C11 n-alkanols. © Rapid Science Ltd. 1998     

Nitrile hydrolysing activities of deep-sea and terrestrial mycolate actinomycetes

Nitrile metabolising actinomycetes previously recovered from deep-sea sediments and terrestrial soils were investigated for their nitrile transforming properties. Metabolic profiling and activity assays confirmed that all strains catalysed the hydrolysis of nitriles by a nitrile hydratase/amidase system. Acetonitrile and benzonitrile, when used as growth substrates for enzyme induction experiments, had a significant influence on the biotransformation activities towards various nitriles and amides. The specific activities of selected deep-sea and terrestrial acetonitrile-grown bacteria against a suite of nitriles and amides were higher than those of the only other reported marine nitrile-hydrolysing R. erythropolis, isolated from a shallow sediment. The increase of nitrile chain length appeared to have negative influence on the nitrile hydratase activity of acetonitrile-grown bacteria, but the same was not true for benzonitrile-grown bacteria. The nitrile hydratases and amidases were constitutive in 10 of the 16 deep-sea and terrestrial actinomycetes studied, and one strain showed an inducible hydratase and a constitutive amidase. Most of the deep-sea strains had constitutive activities and showed some of the highest activities and broadest substrate specificities of organisms included in this study. This revised version was published online in August 2006 with corrections to the Cover Date.     

Engineering Pichia pastoris for stereoselective nitrile hydrolysis by co-producing three heterologous proteins

A Pichia pastoris strain with stereoselective nitrile hydratase activity has been constructed by engineering the co-expression of three genes derived from Pseudomonas putida. Using a technique that could be widely applicable, the genes encoding nitrile hydratase α and β structural subunits and P14K accessory protein were first assembled as individual expression cassettes and then incorporated onto one plasmid, which was integrated into the P. pastoris chromosome. The resulting strain can be used as a catalyst for bioconversions requiring stereospecific nitrile hydrolysis. Received: 3 November 1998 / Received revision: 25 February1999 / Accepted: 14 March 1999     

Insights into catalytic activity of industrial enzyme Co-nitrile hydratase. Docking studies of nitriles and amides

Nitrile hydratase (NHase) is an enzyme containing non-corrin Co³⁺ in the non-standard active site. NHases from Pseudonocardia thermophila JCM 3095 catalyse hydration of nitriles to corresponding amides. The efficiency of the enzyme is 100 times higher for aliphatic nitriles then aromatic ones. In order to understand better this selectivity dockings of a series of aliphatic and aromatic nitriles and related amides into a model protein based on an X-ray structure were performed. Substantial differences in binding modes were observed, showing better conformational freedom of aliphatic compounds. Distinct interactions with postranslationally modified cysteines present in the active site of the enzyme were observed. Modeling shows that water molecule activated by a metal ion may easily directly attack the docked acrylonitrile to transform this molecule into acryloamide. Thus docking studies provide support for one of the reaction mechanisms discussed in the literature. Figure Crystalographic structure of Pseudonocardia thermophila JCM 3095 nitrile hydratase (a) and the non-standard active site (b)     

Cyanide Metabolism in Higher Plants: Cyanoalanine Hydratase is a NIT4 Homolog

Cyanoalanine hydratase (E.C. 4.2.1.65) is an enzyme involved in the cyanide detoxification pathway of higher plants and catalyzes the hydrolysis of β-cyano-l-alanine to asparagine. We have isolated the enzyme from seedlings of blue lupine (Lupinus angustifolius) to obtain protein sequence information for molecular cloning. In contrast to earlier reports, extracts of blue lupine cotyledons were found also to contain cyanoalanine-nitrilase (E.C. 3.5.5.4) activity, resulting in aspartic acid production. Both activities co-elute during isolation of cyanoalanine hydratase and are co-precipitated by an antibody directed against Arabidopsis thaliana nitrilase 4 (NIT4). The isolated cyanoalanine hydratase was sequenced by nanospray-MS/MS and shown to be a homolog of Arabidopsis thaliana and Nicotiana tabacum NIT4. Full-length cDNA sequences for two NIT4 homologs from blue lupine were obtained by PCR using degenerate primers and RACE-experiments. The recombinant LaNIT4 enzymes, like Arabidopsis NIT4, hydrolyze cyanoalanine to asparagine and aspartic acid but show a much higher cyanoalanine-hydratase activity. The two nitrilase genes displayed differential but overlapping expression. Taken together these data show that the so-called ‘cyanoalanine hydratase’ of plants is not a bacterial type nitrile hydratase enzyme but a nitrilase enzyme which can have a remarkably high nitrile-hydratase activity.     

Nitrile hydratase genes are present in multiple eukaryotic supergroups

Background

Nitrile hydratases are enzymes involved in the conversion of nitrile-containing compounds into ammonia and organic acids. Although they are widespread in prokaryotes, nitrile hydratases have only been reported in two eukaryotes: the choanoflagellate Monosiga brevicollis and the stramenopile Aureococcus anophagefferens. The nitrile hydratase gene in M. brevicollis was believed to have arisen by lateral gene transfer from a prokaryote, and is a fusion of beta and alpha nitrile hydratase subunits. Only the alpha subunit has been reported in A. anophagefferens.

Methodology/Principal Findings

Here we report the detection of nitrile hydratase genes in five eukaryotic supergroups: opisthokonts, amoebozoa, archaeplastids, CCTH and SAR. Beta-alpha subunit fusion genes are found in the choanoflagellates, ichthyosporeans, apusozoans, haptophytes, rhizarians and stramenopiles, and potentially also in the amoebozoans. An individual alpha subunit is found in a dinoflagellate and an individual beta subunit is found in a haptophyte. Phylogenetic analyses recover a clade of eukaryotic-type nitrile hydratases in the Opisthokonta, Amoebozoa, SAR and CCTH; this is supported by analyses of introns and gene architecture. Two nitrile hydratase sequences from an animal and a plant resolve in the prokaryotic nitrile hydratase clade.

Conclusions/Significance

The evidence presented here demonstrates that nitrile hydratase genes are present in multiple eukaryotic supergroups, suggesting that a subunit fusion gene was present in the last common ancestor of all eukaryotes. The absence of nitrile hydratase from several sequenced species indicates that subunits were lost in multiple eukaryotic taxa. The presence of nitrile hydratases in many other eukaryotic groups is unresolved due to insufficient data and taxon sampling. The retention and expression of the gene in distantly related eukaryotic species suggests that it plays an important metabolic role. The novel family of eukaryotic nitrile hydratases presented in this paper represents a promising candidate for research into their molecular biology and possible biotechnological applications.     

Nitrile hydratase-catalyzed production of isonicotinamide,picolinamide and pyrazinamide from 4-cyanopyridine, 2-cyanopyridine and cyanopyrazine in Rhodococcus rhodochrous J1

Nitrile hydratase, which occurs abundantly in cells of Rhodococcus rhodochrous J1, catalyzes the hydration of 4- and 2-cyanopyridine and cyanopyrazine to isonicotinamide, picolinamide and pyrazinamide, respectively. Using resting cells, the reaction conditions for the production of isonicotinamide, picolinamide and pyrazinamide were optimized. Under the optimum reaction conditions, 100% of the added 9 M 4-cyanopyridine, 8 M 2-cyanopyridine and 8 M cyanopyrazine was converted to isonicotinamide, picolinamide and pyrazinamide, respectively, without the formation of the corresponding acids. The highest yields achieved corresponded to 1099 g of isonicotinamide, 977 g of picolinamide and 985 g of pyrazinamide per litre of reaction mixture containing resting cells (1.17 g dry weight). The isonicotinamide, picolinamide and pyrazinamide were crystallized and then identified physicochemically. The substrate specificity of the Rhodococcus nitrile hydratase for various aromatic nitriles was also examined.     

Expression of nitrile hydratase gene of mutant 4D strain of Rhodococcus rhodochrous PA 34 in Pichia pastoris

The nitrile hydratase (NHase) gene of Rhodococcus rhodochrous PA-34 mutant 4D has been amplified by PCR, cloned and expressed in Pichia pastoris KM-71 using pHIL-D2 expression vector. The recombinant P. pastoris KM-71 exhibited active expression of the nitrile hydratase gene of the mutant 4D and has shown very good potential for the transformation of 3-cyanopyridine to nicotinamide. The recombinant P. pastoris KM-71 exhibited maximum NHase activity when cultivated in YPD medium was supplemented with 0.4?mM cobalt ions. The recombinant P. pastoris KM-71 showed maximum nitrile hydratase enzyme production, when incubated at 30?°C for 15?h.     

Hydroxynitrile Lyases from Prunus Seeds in the Preparation of Cyanohydrins

The hydroxynitrile lyase (HNL) activity of nine defatted Prunus seeds was compared for catalyzing the addition of HCN to aromatic, heteroaromatic and α,β-unsaturated aldehydes. Although the conversion and enantiomeric excess (ee) of the corresponding cyanohydrins were both influenced by the HNL source and the chemical structure of the aldehyde, Prunus HNLs were all suitable for the enantioselective preparation of cyanohydrins.     

Effects of Nitriles and Amides on the Growth and Nitrile Hydratase Activity of the Rhodococcus sp. Strain gt1

Effects of some nitriles and amides, as well as glucose and ammonium, on the growth and the nitrile hydratase (EC 4.2.1.84) activity of the Rhodococcus sp. strain gt1 isolated from soil were studied. The activity of nitrile hydratase mainly depended on the carbon and nitrogen supply to cells. The activity of nitrile hydratase was high in the presence of glucose and ammonium at medium concentrations and decreased at concentrations of glucose of more than 0.3%. Saturated unsubstituted aliphatic nitriles and amides were found to be a good source of nitrogen and carbon. However, the presence of nitriles and amides in the medium was not absolutely necessary for the expression of the activity of nitrile hydratase of the Rhodococcus sp. strain gt1.     

Nitrile Hydratase and Amidase from Rhodococcus rhodochrous Hydrolyze Acrylic Fibers and Granular Polyacrylonitriles

Rhodococcus rhodochrous NCIMB 11216 produced nitrile hydratase (320 nkat mg of protein⁻¹) and amidase activity (38.4 nkat mg of protein⁻¹) when grown on a medium containing propionitrile. These enzymes were able to hydrolyze nitrile groups of both granular polyacrylonitriles (PAN) and acrylic fibers. Nitrile groups of PAN40 (molecular mass, 40 kDa) and PAN190 (molecular mass, 190 kDa) were converted into the corresponding carbonic acids to 1.8 and 1.0%, respectively. In contrast, surfacial nitrile groups of acrylic fibers were only converted to the corresponding amides. X-ray photoelectron spectroscopy analysis showed that 16% of the surfacial nitrile groups were hydrolyzed by the R. rhodochrous enzymes. Due to the enzymatic modification, the acrylic fibers became more hydrophilic and thus, adsorption of dyes was enhanced. This was indicated by a 15% increase in the staining level (K/S value) for C.I. Basic Blue 9.     

Biochemical characterization of Rhodococcus erythropolis N′4 nitrile hydratase acting on 4-chloro-3-hydroxybutyronitrile

The Rhodococcus erythropolis strain (N′4) possesses the ability to convert 4-chloro-3-hydroxybutyronitrile into the corresponding acid. This conversion was determined to be performed by its nitrile hydratase and amidase. Ammonium sulfate fractionation, DEAE ion exchange chromatography, and phenyl chromatography were used to partially purify nitrile hydratase from cell-free extract. A SDS-PAGE showed that the partially purified enzyme had two subunits and gel filtration chromatography showed that it consisted of four subunits of α₂β₂. The purified enzyme had a high specific activity of 860 U mg⁻¹ toward methacrylonitrile. The enzyme was found to have high activity at low temperature range, with a maximum activity occurring at 25 °C and be stable in the presence of organic acids at higher temperatures. The enzyme exhibited a preference for aliphatic saturated nitrile substrates over aliphatic unsaturated or aromatic ones. It was inhibited by sulfhydryl, oxidizing, and serine protease inhibitors, thus indicating that essential cysteine and serine residues can be found in the active site.The purified nitrile hydratase was able to convert 4-chloro-3-hydroxybutyronitrile into the corresponding amide at 15 °C. GC analysis showed that the initial conversion rate of the reaction was 215 mg substrate consumed min⁻¹ mg⁻¹. This demonstrated that this enzyme could be used in conjunction with a stereoselective amidase to synthesize ethyl (S)-4-chloro-3-hydroxybutyrate, an intermediate for a hypercholesterolemia drug, Atorvastatin.     

Purification and characterization of a <Emphasis Type="Italic">Galactomyces reessii</Emphasis> hydratase that converts 3-methylcrotonic acid to 3-hydroxy-3-methylbutyric acid

Cell free extracts of Galactomyces reessii contain a hydratase as the key enzyme for the transformation of 3-methylcrotonic acid to 3-hydroxy-3-methylbutyric acid. Highest levels of hydratase activity were obtained during growth on isovaleric acid. The enzyme, an enoyl CoA hydratase, was purified 147-fold by precipitation with ammonium sulphate and successive chromatography over columns of DE-52, Blue Sepharose CL-6B and Sephacryl S-200. During purification, hydratase activity was measured spectrophotometrically (OD change at 263 nm) for 3-methylcrotonyl CoA and crotonyl CoA as substrates. The enzyme displayed highest activity with crotonyl CoA with a K _cat of 1,050,000 min⁻¹. The ratio of crotonyl CoA to 3-methylcrotonyl CoA activities was constant (20:1) during all steps of purification. The K _cat for crotonyl CoA was also about 20 times greater than the K _cat for 3-methylcrotonyl CoA (51,700 min⁻¹). The enzyme had pH and temperature optima at 7.0 and 35°C, a native M _r of 260±4.5 kDa and a subunit M _r of 65 kDa, suggesting that the enzyme was a homotetramer. The pI of the purified hydratase was 5.5, and the N-terminal amino acid sequence was VPEGYAEDLLKGKMMRFFDS. Hydratase activity for 3-methylcrotonyl CoA was competitively inhibited by acetyl CoA, propionyl CoA and acetoacetyl CoA. Journal of Industrial Microbiology & Biotechnology (2002) 28, 81–87 DOI: 10.1038/sj/jim/7000215 Received 27 June 2001/ Accepted in revised form 17 September 2001     

Molecular dynamics simulations of the photoactive protein nitrile hydratase

Nitrile hydratase (NHase) is an enzyme used in the industrial biotechnological production of acrylamide. The active site, which contains nonheme iron or noncorrin cobalt, is buried in the protein core at the interface of two domains, α and β. Hydrogen bonds between βArg-56 and αCys-114 sulfenic acid (αCEA114) are important to maintain the enzymatic activity. The enzyme may be inactivated by endogenous nitric oxide (NO) and activated by absorption of photons of wavelength λ < 630 nm. To explain the photosensitivity and to propose structural determinants of catalytic activity, differences in the dynamics of light-active and dark-inactive forms of NHase were investigated using molecular dynamics (MD) modeling. To this end, a new set of force field parameters for nonstandard NHase active sites have been developed. The dynamics of the photodissociated NO ligand in the enzyme channel was analyzed using the locally enhanced sampling method, as implemented in the MOIL MD package. A series of 1 ns trajectories of NHases shows that the protonation state of the active site affects the dynamics of the catalytic water and NO ligand close to the metal center. MD simulations support the catalytic mechanism in which a water molecule bound to the metal ion directly attacks the nitrile carbon.