A novel thermostable nitrile hydratase

A novel, nitrile-degrading, thermophilic microorganism belonging to the genus Bacillus and most closely related to strain DSM 2349 has been isolated. The strain grew optimally at 65°C with the constitutive expression of a thermostable intracellular nitrile hydratase. No aromatic-specific "benzonitrilase" activity was detected under any conditions. The enzyme, an α₂β₂ heterotetramer with a native molecular weight of 110 kDa, was purified to homogeneity. N-terminal sequence data showed no homology to known bacterial α subunit sequences but had a high level of identity with other bacterial N-terminal β subunit sequences. The purified enzyme had a broad pH-activity range (50% activity limits were pH 5.1 and 8.7) and was stable in aqueous solution up to 60°C in the absence of either substrates or substrate analogues. Substrate specificity was restricted to aliphatic nitriles, but an unusual preference for branched and cyclic aliphatic nitriles was noted. Turnover rates under optimum reaction conditions were 746 and 4580 sec⁻¹ for acetonitrile and valeronitrile, respectively. Received: December 1, 1997 / Accepted: February 24, 1998     

Biotransformation of nitriles by rhodococci

Rhodococci have been shown to be capable of a very wide range of biotransformations. Of these, the conversion of nitriles into amides or carboxylic acids has been studied in great detail because of the biotechnological potential of such activities. Initial investigations used relatively simple aliphatic nitriles. These studies were quickly followed by the examination of the regio- and stereoselective properties of the enzymes involved, which has revealed the potential synthetic utility of rhodococcal nitrile biotransforming enzymes. Physiological studies on rhodococci have shown the importance of growth medium design and bioreactor operation for the maximal conversion of nitriles. This in turn has resulted in some truly remarkable biotransformation activities being obtained, which have been successfully exploited for commercial organic syntheses (e.g. acrylamide production from acrylonitrile).The two main types of enzyme involved in nitrile biotransformations by rhodococci are nitrile hydratases (amide synthesis) and nitrilases (carboxylic acid synthesis with no amide intermediate released). It is becoming clear that many rhodococci contain both activities and multiple forms of each enzyme, often induced in a complex way by nitrogen containing molecules. The genes for many nitrile-hydrolysing enzymes have been identified and sequenced. The crystal structure of one nitrile hydratase is now available and has revealed many interesting aspects of the enzyme structure in relationship to its catalytic activity and substrate selectivity.     

Transformation of the herbicide 2,6-dichlorobenzonitrile to the persistent metabolite 2,6-dichlorobenzamide (BAM) by soil bacteria known to harbour nitrile hydratase or nitrilase

In soil the herbicide 2,6-dichlorobenzonitrile (dichlobenil) is degraded to the persistent metabolite 2,6-dichlorobenzamide (BAM) which has been detected in 19% of samples taken from Danish groundwater. We tested if common soil bacteria harbouring nitrile-degrading enzymes, nitrile hydratases or nitrilases, were able to degrade dichlobenil in vitro. We showed that several strains degraded dichlobenil stoichiometrically to BAM in 1.5–6.0 days; formation of the amide intermediate thus showed nitrile hydratase rather than nitrilase activity, which would result in formation of 2,6-dichlorobenzoic acid. The non-halogenated␣analogue benzonitrile was also degraded, but here the benzamide intermediate accumulated only transiently showing nitrile hydratase followed by amidase activity. We conclude that a potential for dichlobenil degradation to BAM is found commonly in soil bacteria, whereas further degradation of the BAM intermediate could not be demonstrated.     

Characterisation of nitrilase and nitrile hydratase biocatalytic systems

Biocatalytic transformations converting aromatic and arylaliphatic nitriles into the analogous related amide or acid were investigated. These studies included synthesis of the -substituted nitrile 3-hydroxy-3-phenylpropionitrile, subsequent enrichment and isolation on this substrate of nitrile-degrading microorganisms from the environment, and a comparative study of enzymatic reactions of nitriles by resting cell cultures and enzymes. Each biocatalyst exhibited a distinctive substrate selectivity profile, generally related to the length of the aliphatic chain of the arylaliphatic nitrile and the position of substituents on the aromatic ring or aliphatic chain. Cell-free nitrilases generally exhibited a narrower substrate range than resting whole cells of Rhodococcus strains. The Rhodococcus strains all exhibited nitrile hydratase activity and converted -hydroxy nitriles (but did not demonstrate enantioselectivity on this substrate). The biocatalysts also mediated the synthesis of a range of -hydroxy carboxylic acids or amides from aldehydes in the presence of cyanide. The use of an amidase inhibitor permits halting the nitrile hydratase/amidase reaction at the amide intermediate.     

Nocardia globerula NHB-2: a versatile nitrile-degrading organism

A versatile nitrile-degrading bacterium was isolated by enrichment culture from the soil of a forest near Manali, Himachal Pradesh, India, and was identified as Nocardia globerula. This organism contains 3 enzymes with nitrile-degrading activity: nitrilase, nitrile hydratase, and amidase. Nocardia globerula NHB-2 cells grown on nutrient broth supplemented with 1% glucose and 0.1% yeast extract exhibited nitrile hydratase-amidase activity specific for saturated aliphatic nitriles or amide, while addition of acetonitrile in nutrient broth yielded cells with nitrile hydratase-amidase that in addition to saturated aliphatic nitriles-amide also hydrolyzed aromatic amide. Nocardia globerula NHB-2 cultivated on nutrient broth containing propionitrile exhibited nitrilase activity that hydrolyzed aromatic nitrile and unsaturated aliphatic nitrile. The versatility of this organism in the hydrolysis of various nitriles and amides makes it a potential bioresource for use in organic synthesis.     

Fungal nitrilases as biocatalysts: Recent developments

Of the numerous putative fungal nitrilases available from protein databases only a few enzymes were purified and characterized. The purified nitrilases from Fusarium solani, Fusarium oxysporum f. sp. melonis and Aspergillus niger share a preference for (hetero)aromatic nitriles, temperature optima between 40 and 50 °C and pH optima in the slightly alkaline region. On the other hand, they differ in their chemoselectivity, i.e. their tendency to produce amides as by-products. The production of fungal nitrilases is increased by up to three orders of magnitude on the addition of 2-cyanopyridine to the culture media. The whole-cell and subcellular biocatalysts were immobilized by various methods (LentiKats®; adsorption on hydrophobic or ion exchange resins; cross-linked enzyme aggregates). Operational stability was examined using continuous stirred membrane bioreactors. Fungal nitrilases appear promising for biocatalytic applications and biodegradation of nitrile environmental contaminants.     

Nitrile- and Amide-converting Microbial Enzymes: Stereo-, Regio- and Chemoselectivity

Biotransformations using microbial nitrile- and amide-converting enzymes have developed considerably in the recent years. Most processes profited from the stereo-, regio- and chemoselectivity of nitrile hydratases, nitrilases and amidases specific for primary or secondary amides. The aim of this review is to discuss the developments in this branch of biotransformations in the last ca. 5 years by taking highlights from research journals, patents and industrial applications.     

Nitrile- and Amide-converting Microbial Enzymes: Stereo-, Regio- and Chemoselectivity

Biotransformations using microbial nitrile- and amide-converting enzymes have developed considerably in the recent years. Most processes profited from the stereo-, regio- and chemoselectivity of nitrile hydratases, nitrilases and amidases specific for primary or secondary amides. The aim of this review is to discuss the developments in this branch of biotransformations in the last ca. 5 years by taking highlights from research journals, patents and industrial applications.     

Enrichment strategies for nitrile-hydrolysing bacteria

A series of enrichments with different nitriles as sole source of nitrogen was performed in order to obtain a relationship between the selective nitrogen source and (i) the enzyme systems that are synthesized by the isolates and (ii) the enzyme specificities for the utilization of the nitriles. Bacteria were enriched with 2-phenylpropionitrile, 2-(2-methoxyphenyl)propionitrile, 2-phenylbutyronitrile, ibuprofen nitrile, naproxen nitrile, ketoprofen nitrile, ketoprofen amide, benzonitrile, or naphthalenecarbonitrile as sole nitrogen source and succinate as sole source of carbon and energy. 2-Phenylpropionitrile as nitrogen source resulted predominantly in the enrichment of gram-negative bacteria, which harboured nitrilase and in some cases also amidase activity. In contrast, with the other nitriles used, a substantial majority of gram-positive strains, mainly of the genus Rhodococcus, were isolated. These strains contained predominantly a nitrile hydratase/amidase system. The nitrilases and nitrile hydratases showed R or S selectivity with generally poor optical yields. In contrast, the amidases were almost exclusively S-selective, often forming the optically pure acids with an enantiomeric excess above 99%. The conversion of different nitriles by the isolates was compared. The nitrile-hydrolysing systems of the new isolates usually showed high activity against those nitriles that were used for the enrichment of the bacteria. Received: 13 November 1996 / Received revision: 4 February 1997 / Accepted: 10 February 1997     

Isolation,identification and characterization of <Emphasis Type="Italic">Bacillus subtilis</Emphasis> ZJB-063, a versatile nitrile-converting bacterium

Strain ZJB-063, a versatile nitrile-amide-degrading strain, was newly isolated from soil in this study. Based on morphology, physiological tests, Biolog and the 16S rDNA sequence, strain ZJB-063 was identified as Bacillus subtilis. ZJB-063 exhibited nitrilase activity without addition of inducers, indicating that the nitrilase in B. subtilis ZJB-063 is constitutive. Interestingly, the strain exhibited nitrile hydratase and amidase activity with the addition of ɛ-caprolactam. Moreover, the substrate spectrum altered with the alteration of enzyme systems due to the addition of ɛ-caprolactam. The constitutive nitrilase was highly specific for arylacetonitriles, while the nitrile hydratase/amidase in B. subtilis ZJB-063 could not only hydrolyze arylacetonitriles but also other nitriles including some aliphatic nitriles and heterocyclic nitriles. Despite comparatively low activity, the amidase of hydratase/amidase system was effective in converting amides to acids. The versatility of this strain in the hydrolysis of various nitriles and amides makes it a potential biocatalyst in organic synthesis.     

Cloning and functional expression of a nitrile hydratase (NHase) from Rhodococcus equi TG328-2 in Escherichia coli, its purification and biochemical characterisation

The nitrile hydratase (NHase, EC 4.2.1.84) genes (α and β subunit) and the corresponding activator gene from Rhodococcus equi TG328-2 were cloned and sequenced. This Fe-type NHase consists of 209 amino acids (α subunit, M_r 23 kDa) and 218 amino acids (β subunit, M_r 24 kDa) and the NHase activator of 413 amino acids (M_r 46 kDa). Various combinations of promoter, NHase and activator genes were constructed to produce active NHase enzyme recombinantly in E. coli. The maximum enzyme activity (844 U/mg crude cell extract towards methacrylonitrile) was achieved when the NHase activator gene was separately co-expressed with the NHase subunit genes in E. coli BL21 (DE3). The overproduced enzyme was purified with 61% yield after French press, His-tag affinity chromatography, ultrafiltration and lyophilization and showed typical Fe-type NHase characteristics: besides aromatic and heterocyclic nitriles, aliphatic ones were hydrated preferentially. The purified enzyme had a specific activity of 6,290 U/mg towards methacrylonitrile. Enantioselectivity was observed for aromatic compounds only with E values ranging 5–17. The enzyme displayed a broad pH optimum from 6 to 8.5, was most active at 30°C and showed the highest stability at 4°C in thermal inactivation studies between 4°C and 50°C.     

Kinetic and structural studies on roles of the serine ligand and a strictly conserved tyrosine residue in nitrile hydratase

Nitrile hydratases (NHase), which catalyze the hydration of nitriles to amides, have an unusual Fe³⁺ or Co³⁺ center with two modified Cys ligands: cysteine sulfininate (Cys-SO₂ ⁻) and either cysteine sulfenic acid or cysteine sulfenate [Cys-SO(H)]. Two catalytic mechanisms have been proposed. One is that the sulfenyl oxygen activates a water molecule, enabling nucleophilic attack on the nitrile carbon. The other is that the Ser ligand ionizes the strictly conserved Tyr, activating a water molecule. Here, we characterized mutants of Fe-type NHase from Rhodococcus erythropolis N771, replacing the Ser and Tyr residues, αS113A and βY72F. The αS113A mutation partially affected catalytic activity and did not change the pH profiles of the kinetic parameters. UV–vis absorption spectra indicated that the electronic state of the Fe center was altered by the αS113A mutation, but the changes could be prevented by a competitive inhibitor, n-butyric acid. The overall structure of the αS113A mutant was similar to that of the wild type, but significant changes were observed around the catalytic cavity. Like the UV–vis spectra, the changes were compensated by the substrate or product. The Ser ligand is important for the structure around the catalytic cavity, but is not essential for catalysis. The βY72F mutant exhibited no activity. The structure of the βY72F mutant was highly conserved but was found to be the inactivated state, with αCys114-SO(H) oxidized to Cys-SO₂ ⁻, suggesting that βTyr72 affected the electronic state of the Fe center. The catalytic mechanism is discussed on the basis of the results obtained.     

Diversity of Nitrile Hydratase and Amidase Enzyme Genes in Rhodococcus erythropolis Recovered from Geographically Distinct Habitats

A molecular screening approach was developed in order to amplify the genomic region that codes for the α- and β-subunits of the nitrile hydratase (NHase) enzyme in rhodococci. Specific PCR primers were designed for the NHase genes from a collection of nitrile-degrading actinomycetes, but amplification was successful only with strains identified as Rhodococcus erythropolis. A hydratase PCR product was also obtained from R. erythropolis DSM 43066^T, which did not grow on nitriles. Southern hybridization of other members of the nitrile-degrading bacterial collection resulted in no positive signals other than those for the R. erythropolis strains used as positive controls. PCR-restriction fragment length polymorphism-single-strand conformational polymorphism (PRS) analysis of the hydratases in the R. erythropolis strains revealed unique patterns that mostly correlated with distinct geographical sites of origin. Representative NHases were sequenced, and they exhibited more than 92.4% similarity to previously described NHases. The phylogenetic analysis and deduced amino acid sequences suggested that the novel R. erythropolis enzymes belonged to the iron-type NHase family. Some different residues in the translated sequences were located near the residues involved in the stabilization of the NHase active site, suggesting that the substitutions could be responsible for the different enzyme activities and substrate specificities observed previously in this group of actinomycetes. A similar molecular screening analysis of the amidase gene was performed, and a correlation between the PRS patterns and the geographical origins identical to the correlation found for the NHase gene was obtained, suggesting that there was coevolution of the two enzymes in R. erythropolis. Our findings indicate that the NHase and amidase genes present in geographically distinct R. erythropolis strains are not globally mixed.     

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.     

Characterization of a new cobalt-containing nitrile hydratase purified from urea-induced cells of Rhodococcus rhodochrous J1

A new cobalt-containing nitrile hydratase was purified from extracts of urea-induced cells from Rhodococcus rhodochrous J1 in seven steps. At the last step, the enzyme was crystallized by adding ammonium sulfate. Nitrile hydratase was a 500-530-kDa protein composed of two different subunits (alpha subunit 26 kDa, beta subunit 29 kDa). The enzyme contained approximately 11-12 mol cobalt/mol enzyme. A concentrated solution of highly purified nitrile hydratase exhibited a broad absorption spectrum in the visible range, with an absorption maxima at 410 nm. The enzyme had a wide substrate specificity. Aliphatic saturated or unsaturated nitriles as well as aromatic nitriles, were substrates for the enzyme. The optimum pH of the hydratase was pH 6.5-6.8. The enzyme was more stable than ferric nitrile hydratases. The amino-terminal sequence of each subunit of R. rhodochrous J1 enzyme was determined and compared with that of ferric nitrile hydratases. Prominent similarities were observed with the beta subunit. However, the amino acid sequence of the alpha subunit from R. rhodochrous J1 was quite different from that of the ferric enzymes.     

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.     

Diversity of nitrile hydratase and amidase enzyme genes in Rhodococcus erythropolis recovered from geographically distinct habitats

A molecular screening approach was developed in order to amplify the genomic region that codes for the alpha- and beta-subunits of the nitrile hydratase (NHase) enzyme in rhodococci. Specific PCR primers were designed for the NHase genes from a collection of nitrile-degrading actinomycetes, but amplification was successful only with strains identified as Rhodococcus erythropolis. A hydratase PCR product was also obtained from R. erythropolis DSM 43066(T), which did not grow on nitriles. Southern hybridization of other members of the nitrile-degrading bacterial collection resulted in no positive signals other than those for the R. erythropolis strains used as positive controls. PCR-restriction fragment length polymorphism-single-strand conformational polymorphism (PRS) analysis of the hydratases in the R. erythropolis strains revealed unique patterns that mostly correlated with distinct geographical sites of origin. Representative NHases were sequenced, and they exhibited more than 92.4% similarity to previously described NHases. The phylogenetic analysis and deduced amino acid sequences suggested that the novel R. erythropolis enzymes belonged to the iron-type NHase family. Some different residues in the translated sequences were located near the residues involved in the stabilization of the NHase active site, suggesting that the substitutions could be responsible for the different enzyme activities and substrate specificities observed previously in this group of actinomycetes. A similar molecular screening analysis of the amidase gene was performed, and a correlation between the PRS patterns and the geographical origins identical to the correlation found for the NHase gene was obtained, suggesting that there was coevolution of the two enzymes in R. erythropolis. Our findings indicate that the NHase and amidase genes present in geographically distinct R. erythropolis strains are not globally mixed.     

DA-F127水凝胶包埋固定化含腈水合酶细胞

腈水合酶是一类可催化腈类化合物转化生成相应酰胺类物质的酶。含腈水合酶的游离细胞催化水合反应存在酶容易失活、细胞无法重复利用、分离纯化困难等缺陷,细胞固定化技术可有效解决这些问题。为探索合适的固定化方法,以含腈水合酶的重组E.coli细胞为研究对象,以固定化酶活回收率和批次反应情况为评价指标,筛选比较了几种常用的包埋固定化方法。结果表明,DA-F127水凝胶包埋固定化细胞不仅具有较高的酶活回收率,而且稳定性也很好。对该方法进行了固定化条件和操作稳定性优化,当DA-F127浓度为15%、UV光源距离为20cm、光照时间为6min、菌体含量为20mg/g 固定化细胞时,酶活回收率为89.74%,并且可以催化9批次150g/L的3-氰基吡啶完成转化,第九批次转化率可达98.26%。与游离细胞催化过程相比,单位质量游离细胞的烟酰胺产量提高了12倍,具有良好的工业应用前景。     

Conversion of aliphatic nitriles by the arylacetonitrilase from <Emphasis Type="Italic">Pseudomonas fluorescens</Emphasis> EBC191

The conversion of aliphatic nitriles by the arylacetonitrilase from Pseudomonas fluorescens EBC191 (NitA) was analyzed. The nitrilase hydrolysed a wide range of aliphatic mono- and dinitriles and showed a preference for unsaturated aliphatic substrates containing 5–6 carbon atoms. In addition, increased reaction rates were also found for aliphatic nitriles carrying electron withdrawing substituents (e.g. chloro- or hydroxy-groups) close to the nitrile group. Aliphatic dinitriles were attacked only at one of the nitrile groups and with most of the tested dinitriles the monocarboxylates were detected as major products. In contrast, fumarodinitrile was converted to the monocarboxylate and the monocarboxamide in a ratio of about 65:35. Significantly different relative amounts of the two products were observed with two nitrilase variants with altered reaction specifities. NitA converted some aliphatic substrates with higher rates than 2-phenylpropionitrile, which is one of the standard substrates for arylacetonitrilases. This indicated that the traditional classification of nitrilases as “arylacetonitrilases”, “aromatic” or “aliphatic” nitrilases might require some corrections. This was also suggested by the construction of some variants of NitA which were modified in an amino acid residue which was previously suggested to be essential for the conversion of aliphatic substrates by a homologous nitrilase.     

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)