Biotransformation of nitriles by Rhodococcus equi A4 immobilized in LentiKats

Whole cells of Rhodococcus equi A4, a producer of nitrile hydratase and amidase activities, were immobilized in lens-shaped hydrogel particles, LentiKats^®. The immobilized biocatalyst was applied to the biotransformation of benzonitrile, 3-cyanopyridine, (R,S)-3-hydroxy-2-methylenebutanenitrile and (R,S)-3-hydroxy-2-methylene-3-phenylpropanenitrile. The stability of the nitrile hydratase during the repeated use of the biocatalyst was dependent on the type of the substrate. The enzyme was most stable during the transformation of (R,S)-3-hydroxy-2-methylenebutanenitrile. No significant loss of the amidase activity was observed within the course of the biocatalytic reaction.     

Enantioselective production of 2,2-dimethylcyclopropane carboxylic acid from 2,2-dimethylcyclopropane carbonitrile using the nitrile hydratase and amidase of Rhodococcus erythropolis ATCC 25544

The enantioselective production of (S)-2,2-dimethylcyclopropane carboxylic acid was investigated in 53 Rhodococcus and Pseudomonas related strains. Rhodococcus erythropolis ATCC 25544 was selected as it showed the highest enantioselectivity. The enantioselectivity was due to the amidase activity in a two-step reaction involving nitrile hydratase. The enantiomeric excess of the amidase was highest at pH 7.0 and decreased significantly above 20 °C. For the enantioselective production of (S)-2,2-dimethylcyclopropane carboxylic acid, the optimum reaction conditions of the cells were determined to be pH 7.0, 20 °C, and 10% (v/v) methanol and were the same as the optimum pH and temperature for the enantioselective conversion by the amidase. Under these conditions, the R. erythropolis ATCC 25544 cells, which harbored nitrile hydratase and amidase enzymes, produced 45 mM (S)-2,2-dimethylcyclopropane carboxylic acid from racemic 100 mM 2,2-dimethylcyclopropane carbonitrile with an 81.8% enantiomeric excess after 64 h.     

Chemo- and enantioselective hydrolysis of nitriles and acid amides, respectively, with resting cells of Rhodococcus sp. C3II and Rhodococcus erythropolis MP50

The two new bacterial strains, Rhodococcus sp. C3II and Rhodococcus erythropolis MP50, which have been especially selected for the enantioselective hydrolysis of pharmaceutically interesting 2-arylpropionitriles like naproxen nitrile, have been applied for the hydrolysis of various aliphatic and aromatic nitriles and acid amides. From the enantioselective hydrolysis of racemic ibuprofen amide 4, 2-phenylbutyronitrile 5a as well as the profen-related atrolactamide 8 we deduce the decisive role of both an alkyl and aryl substituent in the -position to the nitrile or amide function for high enantioselectivity of the hydrolysis. Strain C3II and MP50 differ in the activity of their nitrile hydratase–amidase enzyme systems. This is of interest for the regioselective hydrolysis of the dinitriles 10a–13a to diacids 10f–13f. While strain C3II is suitable to preferentially produce mononitrile monoamide derivatives, strain MP50 can be used especially to form mononitrile monoacid and monoamide monoacid derivatives.     

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.     

Control of the nitrile-hydrolyzing enzyme activity in Rhodococcus rhodochrous IFO 15564: preferential action of nitrile hydratase and amidase depending on the reaction condition factors and its application to the one-pot preparation of amides from aldehydes

The reaction conditions towards the preferential action of either nitrile hydratase or amidase in the harvested whole cells of Rhodococcus rhodochrous IFO 15564 were elaborated. The amidase showed higher heat tolerance than the nitrile hydratase and, at 45 °C the amidase worked exclusively. DMSO assisted the preferential action of nitrile hydratase, however, at more than 30% (v/v) addition of DMF, the nitrile hydratase activity was completely lost and only amidase worked. A one-pot chemo-enzymatic conversion of aldehydes to amides [(1) aq. NH₃, I₂, DMSO; (2) Na₂S₂O₃; (3) harvested cells of R. rhodochrous] was established. Under these reaction conditions, most of the amidase was lost, and the incubation of the firstly formed intermediates, nitriles in aq. NH₃ was responsible for the selective inhibition of amidase. The freezing of harvested cells in an exhaustively deionized environment provided a long-term preservable “ready to use” for the organic chemist.     

Biotransformation of 3-substituted methyl (R,S)-4-cyanobutanoates with nitrile- and amide-converting biocatalysts

Whole cells of Rhodococcus equi A4 chemoselectively hydrolyzed methyl (R,S)-3-benzoyloxy-4-cyanobutanoate and methyl (R,S)-3-benzyloxy-4-cyanobutanoate into monomethyl (R,S)-3-benzoyloxyglutarate and monomethyl (R,S)-3-benzyloxyglutarate, respectively. The intermediates of the biotransformations were the corresponding amides which were also obtained using the purified nitrile hydratase from the same microorganism.     

A comparative molecular field analysis of the biotransformation of sulfides by Rhodococcus erythropolis

A comparative molecular field analysis (CoMFA) was used to model the efficacy with which the Rhodococcus erythropolis mono-oxygenase, DszC, catalyzes the enantioselective sulfoxidation of a broad range of substrates. Experimentally determined values of both the yield and enantiomeric excess for this reaction were employed to create these CoMFA models. A highly predictive CoMFA model was constructed for the prediction of enantiomeric excess of the sulfoxide product. The predictive ability of the model was demonstrated by both cross-validation of the training set (q² = 0.74) and for an external test set of substrates. The enantiomeric excesses of the members of the test set, which also included two amino acid sulfides that were structurally distinct from the membership of the training set, were predicted well by the CoMFA model. Product yield was not modelled well by any CoMFA model. Different models comparing the likely bioactive conformations of the substrates suggest that most compounds assume an ‘extended’ conformation upon binding. Contour diagrams illustrating significant substrate–enzyme interactions suggest that the model, which predicts the enantiomeric excess, is consistent with previous conclusions regarding the effect of various substrate substitutions on the enantiopurity of the product of the biotransformation.     

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 α-hydroxy amides and acids while retaining enantiopurity.     

Rhodococcus ruber CGMCC3090腈水合酶纯化、酶学性质及结晶研究

Rhodococcus ruber CGMCC309菌株为酰胺酶及腈水解酶双重缺陷菌株,研究表明该菌能产宽泛底物特异性的腈水合酶。对该菌株产生的新型腈水合酶(NHase-3090)进行纯化和结晶,并研究了其酶学性质。采用疏水、离子交换及凝胶过滤3种层析方法,使该酶纯化倍数达到17.14,得率高达26.2%。电泳分析表明,全酶分子量为105 kDa,由α(24.3 k Da)和β(28.0k Da)2个亚基组成,并构成α2β2四聚体。酶的最适p H和温度分别为7.5和30℃。该酶明显受不同金属离子影响。动力学研究表明,Km为178.8 m M;Vmax为209.1μmol/L·min·mg。研究发现3种金属离子Zn~(2+),CO~(2+)和Cd~(2+)有利于酶蛋白结晶。结晶最佳条件是:采用112-34#试剂(0.05mol/L水合硫酸镉、0.1mol/L HEPS和1.0mol/L三水醋酸钠),蛋白质浓度为15 mg/ml,结晶温度为16℃,p H为7.5,结晶时间为30 d。腈水合酶蛋白单晶经X射线衍射,分辨率达到了3.7。该腈水合酶的纯化和结晶为进一步深入研究其结构和功能奠定了基础。     

Cloning of the nitrile hydratase gene from Nocardia sp. in Escherichia coli and Pichia pastoris and its functional expression using site-directed mutagenesis

To obtain a recombinant Rhodococcus or Nocardia with not only higher enzymatic activity but also better operational stability and product-tolerance ability for bioconversion of acrylamide from acrylonitrile, an active and stable expression system of nitrile hydratase (NHase) was tried to construct as the technical platform of genetic manipulations. Two NHase genes, NHBA and NHBAX, from Nocardia YS-2002 were successfully cloned, based on bioinformatics design of PCR primers, and inserted into plasmid pUC18 and pET32a, respectively. Then, two recombinant Escherichia coli strains, JM105 (pUC18-NHBA) and BL21 (DE3) (pET32a-NHBAX) were constructed and their expressions of NHase were focused. The induction results showed that there was either no NHase activity in JM105 (pUC18-NHBA), or as low as 0.04 U (1 U=1 μmol acrylamide min⁻¹ mg⁻¹ dry cell) in BL21 (DE3) (pET32a-NHBAX). SDS-PAGE results showed that the -subunit of NHBA and NHBAX could not be efficiently expressed in both recombinant E. coli strains. The novel Pichia pastoris system was also applied to express NHase, but the expression level remained quite low (0.5–0.6 U) and the protein was unstable. For solving this problem, a possible genetic strategy, site-directed mutagenesis of the -subunit of the NHase was carried out. After the successful mutagenesis of the original rare start codon gtg into atg, a new recombinant strain, E. coli XL1-Blue (pUC18-NHBA^M), was screened and the NHase activity stably reached as high as 51 U under the same induction conditions.     

Characterization of cross-linked immobilized lipase from thermophilic mould Thermomyces lanuginosa using glutaraldehyde

Cross-linked enzyme aggregates (CLEAs) have emerged as an interesting biocatalyst design for immobilization. Using this approach, a 1,3 regiospecific, alkaline and thermostable lipase from Thermomyces lanuginosa was immobilized. Efficient cross-linking was observed when ammonium sulphate was used as precipitant along with a two fold increase in activity in presence of SDS. The TEM and SEM microphotographs of the CLEAs formed reveal that the enzyme aggregates are larger in size as compared to the free lipase due to the cross-linking of enzyme aggregates with glutaraldehyde. The stability and reusability of the CLEA with respect to olive oil hydrolysis was evaluated. The CLEA showed more than 90% residual activity even after 10 cycles of repeated use.     

High resolution X-ray molecular structure of the nitrile hydratase from Rhodococcus erythropolis AJ270 reveals posttranslational oxidation of two cysteines into sulfinic acids and a novel biocatalytic nitrile hydration mechanism

The crystal structure of Fe-type nitrile hydratase from Rhodococcus erythropolis AJ270 was determined at 1.3A resolution. The two cysteine residues (alphaCys(112) and alphaCys(114)) equatorially coordinated to the ferric ion were post-translationally modified to cysteine sulfinic acids. A glutamine residue (alphaGln(90)) in the active center gave double conformations. Based on the interactions among the enzyme, substrate and water molecules, a new mechanism of biocatalysis of nitrile hydratase was proposed, in which the water molecule activated by the glutamine residue performed as the nucleophile to attack on the nitrile which was simultaneously interacted by another water molecule coordinated to the ferric ion.     

A study in UF-membrane reactor on activity and stability of nitrile hydratase from Microbacterium imperiale CBS 498-74 resting cells for propionamide production

The bioconversion of propionitrile to propionamide was catalysed by nitrile hydratase (NHase) using resting cells of Microbacterium imperiale CBS 498-74 (formerly, Brevibacterium imperiale). This microorganism, cultivated in a shake flask, at 28 °C, presented a specific NHase activity of 34.4 U mg_DCW⁻¹ (dry cell weight). The kinetic parameters, K_m and V_max, tested in 50 mM sodium phosphate buffer, pH 7.0, in the propionitrile bioconversion was evaluated in batch reactor at 10 °C and resulted 21.6 mM and 11.04 μmol min⁻¹ mg_DCW⁻¹, respectively. The measured apparent activation energy, 25.54 kJ mol⁻¹, indicated a partial control by mass transport, more likely through the cell wall.

UF-membrane reactors were used for kinetic characterisation of the NHase catalysed reaction. The time dependence of enzyme deactivation on reaction temperature (from 5 to 25 °C), on substrate concentrations (from 100 to 800 mM), and on resting cell loading (from 1.5 to 200 μg  ml⁻¹) indicated: lower diffusional control (E_a=37.73 kJ mol⁻¹); and NHase irreversible damage caused by high substrate concentration. Finally, it is noteworthy that in an integral reactor continuously operating for 30 h, at 10 °C, 100% conversion of propionitrile (200 mM) was attained using 200 μg  ml⁻¹ of resting cells, with a maximum volumetric productivity of 0.5 g l⁻¹ h⁻¹.     

Evaluation of immobilized cytochrome P-448 from Saccharomyces cerevisiae using permeabilized whole cell, microsomal fraction and highly purified reconstituted forms, with benzopyrene-3-monooxygenase activity

Cytochrome P-448 from Saccharomyces cerevisiae in permeabilized whole cell, microsomal fraction and in a highly purified reconstituted benzopyrene-3-monooxygenase (EC 1.14.14.1) system have been immobilized on various supports. Calcium alginate was found to be especially useful and the kinetics of hydroxylation were close to that of the free enzyme system with all three forms of enzyme, even with permeabilized whole yeast cells (V _max of 664 pmol 3-hydroxybenzo(a)pyrene produced per h per nmol cytochrome P-448 compared with 1000 for free highly purified reconstituted enzyme system). Only the highly purified reconstituted form was successfully immobilized by BrCN-activated Sepharose-4B or by acrylamide. Both of these supports stabilized the highly purified reconstituted cytochrome P-448 benzopyrene-3-monooxygenase activity in prolonged storage at 4°C. Applications for various immobilized enzymes and cells are assessed.