Improvement of stability of nitrile hydratase via protein fragment swapping

Nitrile hydratase (NHase), which catalyzes the hydration of nitriles to amides, is the key enzyme for the production of amides in industries. However, the poor stability of this enzyme under the reaction conditions is a drawback of its industrial application. In this study, we aimed to improve the stability of NHase (PpNHase) from Pseudomonas putida NRRL-18668 using a homologous protein fragment swapping strategy. One thermophilic NHase fragment from Comamonas testosteroni 5-MGAM-4D and two fragments from Pseudonocardia thermophila JCM3095 were selected to swap the corresponding fragments of PpNHase. Seven chimeric NHases were designed using STAR (site targeted amino recombination) software and molecular dynamics to determine the crossover sites for fragment recombination. All constructed chimeric NHases showed 1.4- to 3.5-fold enhancement in thermostability and six of them become more tolerant to high-concentration product. Notably, one of these NHases, 3AB, exhibited a 1.4 ± 0.05-fold increase in activity compared to the wild-type PpNHase. Circular dichroism spectrum analysis and homology modeling revealed that the 3AB slightly differed in secondary structure from wild-type PpNHase. The 3AB constructed in this study is useful for further industrial application, and the method for designing the chimeric protein using homologous protein fragment swapping without a decrease in activity may be a strategy to improve the stability of other enzymes.     

Rhodococcus pyridinovorans MW3, a bacterium producing a nitrile hydratase

Rhodococcus pyridinovorans MW3 was isolated from an arable land of manioc from the Congo for its ability to transform acrylonitrile to acrylamide. This strain contains a cobalt nitrile hydratase (NHase) showing high sequence homology with NHases so far described. The specific NHase activity was 97 U mg(-1) dry wt. NHase production by R. pyridinovorans MW3 was urea and Co-dependent. The NHase was active for acrylamide up to 60% (w/v) indicating its potential for acrylamide production.     

Enzyme Immobilization on Ion Exchangers by Forming an Enzyme Coating with Transglutaminase as a Crosslinker

Southern hybridization analysis using the genes encoding the α- and β-subunits of nitrile hydratase (NHase) from Rhodococcus sp. N-774 as probe suggested that two R. erythropolis strains, JCM6823 and JCM2892, among 31 strains mainly from Japan Culture of Microorganisms (JCM) have NHase genes. Restriction analysis of DNA fragments showing positive hybridization showed that each fragment carried a nucleotide sequence very similar to that of the NHase genes from Rhodococcus sp. N-774. Nucleotide sequence analysis of the DNA fragment cloned from R. erythropolis JCM6823 showed the presence of the genes encoding the α- and β-subunits of NHase, which show 94.7% and 96.2% identity in amino acid sequence to those of Rhodococcus sp. N-774, respectively, as well as a C-terminal portion of the amidase gene upstream from these genes. Despite the extremely high amino acid sequence similarity in both NHases and amidases from R. erythropolis JCM6823 and Rhodococcus sp. N-774, the NHases and amidases from R. erythropolis strains showed broader substrate specificity when compared to those from Rhodococcus sp. N-774. This suggests that a very limited number of amino acid residues are responsible for the difference in substrate specificity. Although the NHase of Rhodococcus sp. N-774 are constitutively produced, the NHases of both R. erythropolis strains were inducibly produced by addition of ε-caprolactam as an inducer.     

Chaperone-assisted maturation of the recombinant Fe-type nitrile hydratase is insufficient for fully active expression in Escherichia coli

Nitrile hydratase (NHase) has attracted substantial attention for industrial applications to produce large-scale amides. Several NHases have been investigated for functional expression in Escherichia coli (E. coli). A Fe-type NHase was obtained from an acetamiprid-degrading bacterium, Pseudoxanthomonas sp. AAP-7 and functionally expressed in E. coli BL21 (DE3). No significant NHase activity was detected from the E. coli expressing either the NHase gene alone or NHase and P46K genes transcribed as one unit. Purified recombinant NHase, co-expressed with P46K on two separate plasmids, exhibited the maximal enzyme activity. Furthermore, a GST tag attached to the N-terminus of α subunit resulted in a slight increase in the solubility and stability of NHase compared with a His tag at the C-terminus of β subunit. When co-expressed with the chaperones GroEL-GroES, the yield of the soluble recombinant NHase was improved substantially, while a small decrease in NHase activity was observed. The putative activator P46K was strictly required for production of the recombinant NHase for full enzyme activity, although the chaperones GroEL-GroES appeared to assist NHase to fold properly. This study of the expression of a fully active Fe-type NHase would provide another example to enhance our understanding of NHase biosynthesis.     

Nitrile Hydratase and Its Application to Industrial Production of Acrylamide

Nitrile hydratase (NHase) was discovered in our laboratory. This enzyme was purified and characterized from various microorganisms. NHases are roughly classified into two groups according to the metal involved: Fe-type and Co-type. NHases are expected to have great potential as catalysts in organic chemical processing because they can convert nitriles to the corresponding higher-value amides under mild conditions. We have used microbial enzymes for the production of useful compounds; NHase has been used for the industrial production (production capacity: 30,000 tons/year) of acrylamide from acrylonitrile. This is the first successful example of a biotransformation process for the manufacture of a commodity chemical. This review summarizes the history of NHase studied not only from a basic standpoint but also from an applied point of view.     

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.     

Metallochaperone function of the self-subunit swapping chaperone involved in the maturation of subunit-fused cobalt-type nitrile hydratase

The transition metal (iron or cobalt) is a mandatory part that constitutes the catalytic center of nitrile hydratase (NHase). The incorporation of the cobalt ion into cobalt-containing NHase (Co-NHase) was reported to depend on self-subunit swapping and the activator of the Co-NHase acts as a self-subunit swapping chaperone for subunit exchange. Here we discovered that the activator acting as a metallochaperone transferred the cobalt ion into subunit-fused Co-NHase. We successfully isolated two activators, P14K and NhlE, which were the activators of NHases from Pseudomonas putida NRRL-18668 and the activator of low-molecular-mass NHase from Rhodococcus rhodochrous J1, respectively. Cobalt content determination demonstrated that NhlE and P14K were two cobalt-containing proteins. Substitution of the amino acids involved in the C-terminus of the activators affected the activity of the two NHases, indicating that the potential cobalt-binding sites might be located at the flexible C-terminal region. The cobalt-free NHases could be activated by either of the two activators, and both the two activators activated their cognate NHase more efficiently than did the noncognate ones. This study provided insights into the maturation of subunit-fused NHases and confirmed the metallochaperone function of the self-subunit swapping chaperone.     

腈类物降解菌多样性和产腈水合酶研究进展

腈水合酶催化反应在有机合成领域已有广泛的应用。作为一类重要的催化剂,腈水合酶可以将腈类物质转化为相应的酰胺。由于这种酶具有固有的立体和区域选择性,在精细化工领域已成为绿色、温和、对同分异构体具有选择性的催化剂。同时腈水合酶在生物修复和环境保护中也起着重要作用。综述了目前国内外腈水合酶的研究进展,包括降解腈类的微生物多样性、腈水合酶的催化特性、产腈水合酶菌株的改造以及腈水合酶相关基因的克隆与研究。对固定化酶和腈水合酶的应用也进行了叙述。     

Rapid and specific identification of nitrile hydratase (NHase)-encoding genes in soil samples by polymerase chain reaction

A polymerase chain reaction (PCR) protocol was developed for the specific detection of genes coding nitrile hydratase (NHase). Primer design was based on the highly conserved sequences found in the coding region of the alpha-subunit gene corresponding to the metal-binding site. Purified genomic DNA from bacterial strains or directly from soil can serve as the target for the PCR, thus affording a simple and rapid method for screening NHase genes. The primer pairs, NHCo1/NHCo2 and NHFe1/NHFe2 yield PCR products corresponding to a partial coding sequence of cobalt and iron NHase genes, respectively. Using the PCR method, both types of iron- and cobalt-NHase-encoding genes were detected in DNA from pure cultures and soil samples. Furthermore consensus primers allowed rapid cloning and expression of novel NHases in Escherichia coli.     

Chaperone-assisted expression,purification, and characterization of recombinant nitrile hydratase NI1 from Comamonas testosteroni

Nitrile hydratases (NHases) are industrially important iron- and cobalt-containing enzymes that are used in the large-scale synthesis of acrylamide. Heterologous expression of NHases has been complicated by the fact that other proteins (activators or metallochaperones) appear to be required to produce NHases in their catalytically active form. We report a novel heterologous system for the expression of catalytically active iron-containing NI1 NHase in Escherichia coli, involving coexpression with the E. coli GroES and GroEL chaperones. The purified recombinant enzyme was found to be highly similar to the enzyme purified from Comamonas testosteroni according to its spectroscopic features, catalytic properties with various substrates, and post-translational modifications. In addition, we report a rapid and convenient spectrophotometric method to monitor the activity of NI1 NHase during purification.     

Cloning, nucleotide sequence and expression in Escherichia coli of two cobalt-containing nitrile hydratase genes from Rhodococcus rhodochrous J1.

Rhodococcus rhodochrous J1 produces two kinds of cobalt-containing nitrile hydratases (NHases); one is a high molecular mass-NHase (H-NHase) and the other is a low molecular mass-NHase (L-NHase). Both NHases are composed of two subunits of different sizes (alpha and beta subunits). The H- and L-NHase genes were cloned into Escherichia coli by a DNA-probing method using the NHase gene of Rhodococcus sp. N-774, a ferric ion-containing NHase producing strain, as the hybridization probe and their nucleotide sequences were determined. In each of the H- and L-NHase genes, the open reading frame for the beta subunit was located just upstream of that for the alpha subunit, which probably belongs to the same operon. The amino acid sequences of each subunit of the H- and L-NHases from R. rhodochrous J1 showed generally significant similarities to those from Rhodococcus sp. N-774, but the arrangement of the coding sequences for two subunits is reverse of the order found in the NHase gene of Rhodococcus sp. N-774. Each of the NHase genes was expressed in E. coli cells under the control of lac promoter, only when they were cultured in the medium supplemented with CoCl2.     

Self-Subunit Swapping Occurs in Another Gene Type of Cobalt Nitrile Hydratase

Self-subunit swapping is one of the post-translational maturation of the cobalt-containing nitrile hydratase (Co-NHase) family of enzymes. All of these NHases possess a gene organization of <β-subunit> <α-subunit> <activator protein>, which allows the activator protein to easily form a mediatory complex with the α-subunit of the NHase after translation. Here, we discovered that the incorporation of cobalt into another type of Co-NHase, with a gene organization of <α-subunit> <β-subunit> <activator protein>, was also dependent on self-subunit swapping. We successfully isolated a recombinant NHase activator protein (P14K) of Pseudomonas putida NRRL-18668 by adding a Strep-tag N-terminal to the P14K gene. P14K was found to form a complex [α(StrepP14K)₂] with the α-subunit of the NHase. The incorporation of cobalt into the NHase of P. putida was confirmed to be dependent on the α-subunit substitution between the cobalt-containing α(StrepP14K)₂ and the cobalt-free NHase. Cobalt was inserted into cobalt-free α(StrepP14K)₂ but not into cobalt-free NHase, suggesting that P14K functions not only as a self-subunit swapping chaperone but also as a metallochaperone. In addition, NHase from P. putida was also expressed by a mutant gene that was designed with a <β-subunit> <α-subunit> <P14K> order. Our findings expand the general features of self-subunit swapping maturation.     

Cloning and expression of the nitrile hydratase and amidase genes from Bacillus sp. BR449 into Escherichia coli

A moderate thermophile, Bacillus sp. BR449 was previously shown to exhibit a high level of nitrile hydratase (NHase) activity when growing on high levels of acrylonitrile at 55 degrees C. In this report, we describe the cloning of a 6.1 kb SalI DNA fragment encoding the NHase gene cluster of BR449 into Escherichia coli. Nucleotide sequencing revealed six ORFs encoding (in order), two unidentified putative proteins, amidase, NHase beta- and alpha-subunits and a small putative protein of 101 amino acids designated P12K. Spacings and orientation of the coding regions as well as their gene expression in E. coli suggest that the beta-subunit, alpha-subunit, and P12K genes are co-transcribed. Analysis of deduced amino acid sequences indicate that the amidase (348 aa, MW 38.6 kDa) belongs to the nitrilase-related aliphatic amidase family, and that the NHase beta- (229 aa, MW 26.5 kDa) and alpha- (214 aa, MW 24.5 kDa) subunits comprise a cobalt-containing member of the NHase family, which includes Rhodococcus rhodochrous J1 and Pseudomonas putida 5B NHases. The amidase/NHase gene cluster differs both in arrangement and composition from those described for other NHase-producing strains. When expressed in Escherichia coli DH5alpha, the subcloned NHase genes produced significant levels of active NHase enzyme when cobalt ion was added either to the culture medium or cell extracts. Presence of the P12K gene and addition of amide compounds as inducers were not required for this expression.     

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.     

Stability study on the nitrile hydratase of Nocardia sp. 108: From resting cells to crude enzyme preparation

In recent years nitrile hydratases (NHases) have drawn increasing attention due to their critical roles in organic synthesis. In the present paper an extensive investigation on the stability and activity of NHase from Nocardia sp. 108, which has succeeded in industrial application in China, was conducted by bioconversion of acrylonitrile to acrylamide in a batch manner. A study of cultivation demonstrated that biosynthesis of NHase changed significantly with the time of the culture, and the optimal NHase biosynthesis phase was 45 h after inoculation with NHase activity of a biomass of 1209.8 U/g. A stability study indicated that both crude enzyme preparations exhibited a good stability when exposed to a pH 7.2 tris-HCl buffer at 4°C for 4 h. The text was submitted by the authors in English.     

Mutational study on alphaGln90 of Fe-type nitrile hydratase from Rhodococcus sp. N771

Nitrile hydratase (NHase) from Rhodococcus sp. N771 is a non-heme iron enzyme having post-translationally modified cysteine ligands, alphaCys112-SO2H and alphaCys114-SOH. We replaced alphaGln90, which is conserved in all known NHases and involved in the hydrogen-bond network around the catalytic center, with glutamic acid or asparagine. The kcat of alphaQ90E and alphaQ90N mutants decreased to 24% and 5% that of wild type respectively, but the effect of mutations on Km was not very significant. In both mutants, the alphaCys114-SOH modification appeared to be responsible for the catalysis as in native NHase. We crystallized the nitrosylated alphaQ90N mutant and determined its structure at a resolution of 1.43 A. The structure was basically identical to that of native nitrosylated NHase except for the mutated site and its vicinity. The structural difference between native and alphaQ90N mutant NHases suggested the importance of the hydrogen bond networks between alphaGln90 and the iron center for the catalytic activity.     

Nitrile hydratases (NHases): At the interface of academia and industry

Nitrile hydratase (NHase, EC 4.2.1.84) is one of the key enzymes of nitrile metabolism in a large number of microbes that catalyses the hydration of nitriles to corresponding amides, and has been successfully adopted in chemical industry for production of acrylamide, nicotinamide and 5-cyanovaleramide. However, NHase is still under active consideration of enzymologists to expand its potential for synthesis of various amides. Most of the NHases have been reported for their limited substrates acceptability, low enantioselectivity and thermostability and therefore a considerable improvement is required for developing as robust biocatalyst for synthesis of a range of organic amides. Studies on biochemical properties, gene configuration, active-site chemical models and site-directed mutagenesis have given the insight into the structural and functional characteristics of NHase. Keeping in view, the present review critically describes the available information on natural sources (based on activity and phylogenetic analysis), biochemical properties, catalysis–structure relationship, molecular expression and potential applications of this enzyme.     

New inhibitors of iron-containing nitrile hydratases

There is growing evidence in the literature emphasizing the significance of the post-translational modification of cysteine thiols to sulfenic acids (SOH), which have been found in a number of proteins. Crystallographic and mass spectrometric evidence has shown the presence of this group in an inactive form of the industrially important enzyme nitrile hydratase (NHase). This oxidized cysteine is unique in that it forms part of the coordination sphere of the low-spin iron III at the active site of the enzyme. The presence of this unstable sulfenic group in the active form of NHase is the subject of some controversy. To try to detect this function in NHase, we have studied the inhibitory effect on nitrile hydration of reagents known to react with sulfenic acids. Two NHases were studied, namely, Rhodococcus rhodochrous R312 NHase and Comamonas testosteroni NI1 NHase, and the reagents used were meta-chlorocarbonyldicyano-phenylhydrazone (m-ClCP), 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-Cl), and 2-nitro-5-thiocyanato-benzoic acid (NTBA). Following this approach we report three novel inhibitors of NHases. In addition, we report thiocyanate reagents that can be used to monitor NHase activity spectroscopically.     

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.