Nitrile Hydratase-Catalyzed Production of Nicotinamide from 3-Cyanopyridine in Rhodococcus rhodochrous J1

Nitrile hydratase, which occurs abundantly in cells of Rhodococcus rhodochrous J1 isolated from soil samples, catalyzes the hydration of 3-cyanopyridine to nicotinamide. By using resting cells, the reaction conditions for nicotinamide production were optimized. Under the optimum conditions, 100% of the added 12 M 3-cyanopyridine was converted to nicotinamide without the formation of nicotinic acid, and the highest yield achieved was 1,465 g of nicotinamide per liter of reaction mixture containing resting cells (1.48 g as dry cell weight) in 9 h. The nicotinamide produced was crystallized and then identified physicochemically. The further conversion of the nicotinamide to nicotinic acid was due to the low activity of nicotinamide as a substrate for the amidase(s) present in this organism.     

Bench scale conversion of 3-cyanopyidine to nicotinamide using resting cells of <Emphasis Type="Italic">Rhodococcus rhodochrous</Emphasis> PA-34

The nitrile hydratase (NHase, EC 3.5.5.1) activity of Rhodococcus rhodochrous PA-34 was explored for the conversion of 3-cyanopyridine to nicotinamide. The NHase activity (∼18 U/mg dry cell weight, dcw) was observed in 0.1 M phosphate buffer, pH 8.0 containing 1M 3-cyanopyridine as substrate, and 0.75 mg of resting cells (dry cell weight) per ml reaction mixture at 40°C. However, 25°C was more suitable for prolonged batch reaction at high substrate (3-cyanopyridine) concentration. In a batch reaction (1 liter), 7M 3-cyanopyridine (729 g) was completely converted to nicotinamide (855 g) in 12h at 25°C using 9.0 g resting cells (dry cell weight) of R. rhodochrous PA-34.     

Biosynthesis of nicotinic acid from 3-cyanopyridine by a newly isolated Fusarium proliferatum ZJB-09150

In this study, nitriles were used as sole sources of nitrogen in the enrichments to isolate nitrile-converting microorganisms. A novel fungus named ZJB-09150 possessing nitrile-converting enzymes was obtained with 3-cyanopyridine as sole source of nitrogen, which was identified by morphology, biology and 18S rDNA gene sequence as Fusarium proliferatum. It was found that F. proliferatum had ability to convert nitriles to corresponding acids or amides and showed wide substrate specificity to aliphatic nitriles, aromatic nitriles and ortho-substituted heterocyclic nitriles. The nitrile converting enzymes including nitrilase and nitrile hydratase in ZJB-09150 were induced by ε-caprolactam. Nitrilase obtained in this study showed high activity toward 3-cyanopyridine. It was active within pH 3.0–12.0 and temperature ranging from 25 to 65 °C with optimal at pH 9.0 and temperature 50–55 °C. The enzyme was thermostable and its half-life was 12.5 and 6 h at 45 and 55 °C, respectively. Under optimized reaction conditions, 60 mM 3-cyanopyridine was converted to nicotinic acid in 15 min, which indicated ZJB-09150 has potentials of application in large scale production of nicotinic acid.     

Transformation of 2- and 4-cyanopyridines by free and immobilized cells of nitrile-hydrolyzing bacteria

The transformation dynamics of 2- and 4-cyanopyridines by cells suspended and adsorbed on inorganic carriers has been studied in the Rhodococcus ruber gt1 possessing nitrile hydratase activity and the Pseudomonas fluorescens C2 containing nitrilase. It was shown that both nitrile hydratase and nitrilase activities of immobilized cells against 2-cyanopyridine were 1.5–4 times lower compared to 4-cyanopyridine and 1.6–2 times lower than the activities of free cells against 2-cyanpopyridine. The possibility of obtaining isonicotinic acid during the combined conversion of 4-cyanopyridine by a mixed suspension of R. ruber gt1 cells with a high level of nitrile hydratase activity and R. erythropolis 11-2 cells with a pronounced activity of amidase has been shown. Immobilization of Rhodococcus cells on raw coal and Pseudomonas cells on kaolin was shown to yield a heterogeneous biocatalyst for the efficient transformation of cyanopyridines into respective amides and carboxylic acids.     

A study of 2-cyanopyridine addition products in the coordination sphere of Ni(II)

The coordination of 2-cyanopyridine molecule to Ni(II) atom promotes a nucleophilic addition of solvent molecules (water, methanol, ethanol) to the nitrile group. The addition of water leads to the formation of solid complexes containing pyridine-2- carboxamide as a chelate ligand. An analogous reaction of 2-cyanopyridine with NiX₂ (X = Cl, Br, I, NCS) in methanolic solutions gives, however, complexes containing two or three molecules of O-methylpyridine-2-carboximidate. No nucleophilic addition of solvent occurred with 3- and 4-cyanopyridine under the same reaction conditions.The complexes under study exhibit an octahedral geometry. The structure and the mode of the ligand coordination have been determined by IR spectra.     

A propionitrile-induced nitrilase of <Emphasis Type="Italic">Rhodococcus</Emphasis> sp. NDB 1165 and its application in nicotinic acid synthesis

Rhodococcus sp. NDB 1165, a nitrile-transforming organism was isolated from temperate forest soil of Himalayas. The nitrilase (EC 3.5.5.2) activity of this organism had higher substrate specificity toward aromatic nitriles (benzonitrile, 3-cyanopyridine and 4-cyanopyridine) and unsaturated aliphatic nitrile (acrylonitrile) in comparison to saturated aliphatic nitriles (acetonitrile, propionitrile, butyronitrile and isobutyronitrile) nitrile and arylacetonitrile (phenylacetonitrile and indole-3-acetonitrile). The nitrilase of Rhodococcus sp. NDB 1165 was inducible in nature and propionitrile proved to be an efficient inducer. However, the salts of ferrous and cobalt ions had an inhibitory effect. Under optimized reaction conditions (pH 8.0 and temperature 45°C) the nitrilase activity of this organism was 2.39 ± 0.07 U/mg dry cell mass (dcm). The half-life of this enzyme was 150 min and 40 min at 45°C and 50°C respectively. However, it was quite stable at 40°C and around 58 % activity was retained even after 6 h at this temperature. The V _max and K _m value of this nitrilase were 1.67 μmol/ml min and 0.1 M respectively using 3-cyanopyridine as substrate. However, the decrease in V _max and K _m values (0.56 μmol/ml min and 0.02 M, respectively) were ␣observed at >0.05 M 3-cyanopyridine which revealed that this enzyme experienced uncompetitive inhibition at higher substrate concentrations. Under optimized reaction conditions, 1.6 M 3-cyanopyridine was successfully converted in to nicotinic acid using 2.0 mg resting cells (dcm)/ml reaction mixture in 11 h. This is the highest production of nicotinic acid i.e. 8.95 mg/mg resting cells (dcm)/h as compared to nitrilase systems reported hitherto.     

Nitrilase-Catalyzed Production of Nicotinic Acid from 3-Cyanopyridine in Rhodococcus rhodochrous J1

The nitrilase which occurs abundantly in cells of Rhodococcus rhodochrous J1 catalyzes the direct hydrolysis of 3-cyanopyridine to nicotinic acid without forming nicotinamide. By using resting cells, the reaction conditions for nicotinic acid production were optimized. Under the optimum conditions, 100% of the added 3-cyanopyridine could be converted to nicotinic acid, the highest yield achieved being 172 mg of nicotinic acid per 1.0 ml of reaction mixture containing 2.89 mg (dry weight) of cells in 26 h.     

Biotransformation of 3-cyanopyridine to nicotinic acid by free and immobilized cells of recombinant Escherichia coli

An efficient biocatalytic process for the production of nicotinic acid (niacin) from 3-cyanopyridine was developed using cells of recombinant Escherichia coli JM109 harboring the nitrilase gene from Alcaligenes faecalis MTCC 126. The freely suspended cells of the biocatalyst were found to withstand higher concentrations of the substrate and the product without any signs of substrate inhibition. Immobilization of the cells further enhanced their substrate tolerance, stability and reusability in repetitive cycles of nicotinic acid production. Under optimized conditions (37 °C, 100 mM Tris buffer, pH 7.5) for the immobilized cells, the recombinant biocatalyst achieved a 100% conversion of 1 M 3-cyanopyridine to nicotinic acid within 5 h at a cell mass concentration (fresh weight) of 500 mg/mL. The high substrate/product tolerance and stability of the immobilized whole cell biocatalyst confers its potential industrial use.     

Occurrence of Endogenous Pollen Growth Inhibitors, 4-Hydroxybenzoic Acid and 4-(β-D-Glucopyranosyloxy)benzoic Acid,in the Pollen of Pinus densiflora†

A Pseudomonas strain capable of using pyrazinamide as the sole source of nitrogen was isolated from soil. An aromatic amidase from the bacterium was purified 400-fold to homogeneous on polyacrylamide gel electrophoresis. The enzyme had a molecular weight of 43,000 by gel filtration on Sephadex G-150 and consisted of two identical subunits. The isoelectric point was at 4.45. Among the compounds tested, pyrazinamide (relative activity, 100%), nicotinamide (60%), and 5-methylpyrazinamide (3.4%) were hydrolyzed at considerable rates. Benzamide, picolinamide, and isonicotinamide were not substrates. Apparent Km of the enzyme for pyrazinamide and nicotinamide were 5.6 × 10 ^?5 m and below 5 × 10^?6 m, respectively. The enzyme was not able to hydrolyze aliphatic amides. The enzyme was most active between pH 6.5 and 10 and 75°C, and was stable between pH 5.5 and 8.5 and below 45°C.     

A new enzymatic method of nitrile synthesis by Rhodococcus sp. strain YH3-3

The substrate specificity of a novel aldoxime dehydratase from E-pyridine-3-aldoxime assimilating bacterium, Rhodococcus sp. strain YH3-3, was examined. The enzyme catalyzed a dehydration reaction of various aryl- and alkyl-aldoximes to form the corresponding nitriles, but did not act on arylalkyl- and substituted alkyl-aldoximes. Of various aldoximes tested, E-pyridine-3-aldoxime was the most suitable substrate for the enzyme. E-Pyridine-3-aldoxime analogs such as O-acetyl-E-pyridine-3-aldoxime, Z-pyridine-3-aldoxime, and E/Z-pyridine-3-aldehyde-hydrazone also acted as substrates and were converted to 3-cyanopyridine. Heat-treatment of the cells increased the accumulation of 3-cyanopyridine from E-pyridine-3-aldoxime because the nitrile degrading enzyme, nitrile hydratase was inactivated. Under the optimized reaction conditions (pH 7.0, 30°C), various nitriles were synthesized from the corresponding aldoximes in preparative scales with heat-treated cells of the strain. This is the first report on the microbial synthesis of nitriles from aldoximes.     

Characterization of a newly isolated strain Rhodococcus erythropolis ZJB-09149 transforming 2-chloro-3-cyanopyridine to 2-chloronicotinic acid

2-Chloronicotinic acid is receiving much attention for its effective applications as a key precursor in the synthesis of pesticides and medicines. In this study, a strain ZJB-09149 converting 2-chloro-3-cyanopyridine to 2-chloronicotinic acid was newly isolated and identified as Rhodococcus erythropolis, based on its physiological and biological tests, and 16S rDNA sequence analysis. In addition, the effects of inducer, carbon source and nitrogen source were examined. Maximum activity was achieved when the above parameters were set as 8 g/l ?-caprolactam, 7 g/l yeast extract and 5 g/l maltose. Moreover, the biotransformation pathway of 2-chloro-3-cyanopyridine to 2-chloronicotinic acid in strain ZJB-09149 was investigated as well. This study revealed that the nitrile hydratase (NHase) and amidase expressed in R. erythropolis ZJB-09149 are responsible for the conversion of 2-chloro-3-cyanopyridine. This is the first time to report on the biotransformation preparation of 2-chloronicotinic acid.     

Asymmetric synthesis of (S)-ethyl-4-chloro-3-hydroxybutanoate using Candida parapsilosis ATCC 7330

Asymmetric reduction of ethyl-4-chloro-3-oxobutanoate to (S)-ethyl-4-chloro-3-hydroxybutanoate in aqueous medium by resting cells of Candida parapsilosis ATCC 7330 was optimized. The influence of culture parameters (inoculum size, inoculum age and biocatalyst harvest time) and reaction parameters (co-substrate, resting cell, pH and substrate concentrations) on the asymmetric reduction were studied. It was found that these parameters significantly influenced the rate of the asymmetric reduction. Under the optimum conditions, the final concentration of (S)-ethyl-4-chloro-3-hydroxybutanoate, enantiomeric excess and the isolated yield of (S)-ethyl-4-chloro-3-hydroxybutanoate were 1.38 M (230 g/l), >99 and 95%, respectively. The space time yield was 115 mmol/lh, which is significantly higher than other whole cell biocatalysts reported so far.     

Hydration of 3-cyanopyridine to nicotinamide by crude extract nitrile hydratase

Summary The kinetic and stability characteristics of crude extract nitrile hydratase fromBrevibacterium R-312 were studied for the hydration of 3-cyanopyridine to nicotinamide. The enzyme was substrate and product inhibited and had the following kinetic constants:K _m =28 mM;K _p =36 mM;K _s =155 mM;V _m =5.8 mol/min/mg protein (25°C). Itsmaximum temperature and pH (phosphate buffer) were 35°C and 8.0, respectively and it had half-lives of 50 days, 10 days and 1 day at 4°C, 10°C and 25°C, respectively. The crude extract also exhibited amidase activity on nicotinamide, but it became significant only at nicotinamide concentrations greater than 300 mM. Mathematical models for batch and fed-batch hydrations were developed to account for substrate and product inhibitions and for enzyme decay. They predicted to within 10% experimental results for initial substrate and final product concentrations up to 300 mM; the accuracies decreased at higher concentrations primarily because of the relatively rapid hydrolysis of nicotinamide.     

Efficient cloning and expression of a thermostable nitrile hydratase in Escherichia coli using an auto-induction fed-batch strategy

A nitrile hydratase (NHase) gene from Aurantimonas manganoxydans was cloned and expressed in Escherichia coli BL21 (DE3). A downstream gene adjacent to the β-subunit was necessary for the functional expression of the recombinant NHase. The structural gene order of the Co-type NHase was α-subunit beyond β-subunit, different from the order typically reported for Co-type NHase genes. The NHase exhibited adequate thermal stability, with a half-life of 1.5 h at 50 °C. The NHase efficiently hydrated 3-cyanopyridine to produce nicotinamide. In a 1-L reaction mixture, 3.6 mol of 3-cyanopyridine was completely converted to nicotinamide in four feedings, exhibiting a productivity of 187 g nicotinamide/g dry cell weight/h. An industrial auto-induction medium was applied to produce the recombinant NHase in 10-L fermenter. A glycerol-limited feeding method was performed, and a final activity of 2170 U/mL culture was achieved. These results suggested that the recombinant NHase was efficiently cloned and produced in E. coli.     

Isolation and characterization of tetrahydrofuran-degrading Rhodococcus aetherivorans strain M8

We isolated tetrahydrofuran (THF)-degrading bacteria from waste sludge obtained from a chemical factory in Japan. The isolate designated as strain M8 was identified as Rhodococcus aetherivorans by sequence analysis of its 16S rRNA gene. It grew in a medium containing THF as the sole source of carbon and energy, and its optimal growth pH range and temperature were 6–9 and 37 °C, respectively. Strain M8 grew even in the presence of 35 mM THF. For its growth, this bacterium used 1,4-butanediol and γ-butyrolactone, which are supposed to be metabolites of THF. To elucidate the pathway involved in THF metabolism in strain M8, the resting cell reaction was performed, and the metabolites of THF were analyzed. In the resting cell reaction, 5 mM THF was completely degraded within 5 h. Cells were harvested at 2, 3, and 4 h after the initiation of the reaction; the intermediates accumulated in the cells were extracted using methanol and were derivatized using phenyl boronate. Gas chromatography–mass spectrometry (GC–MS) analysis of the derivatized products showed 4-hydroxybutyrate accumulating in the resting cells. This result suggests that R. aetherivorans strain M8 degrades THF via the oxidation pathway.     

Production of acrylamide using immobilized cells of<Emphasis Type="Italic">Rhodococcus rhodochrous</Emphasis> M33

The cellsof Rhodococcus rhodochrous M33, which produce a nitrile hydratase enzyme, were immobilized in acrylamide-based polymer gels. The optimum pH and temperature for the activity of nitrile hydratase in both the free and immobilized cells were 7.4 and 45°C, respectively, yet the optinum temperature for acrylamide production by the immobilized cells was 20°C. The nitrile hydratase of the immobilized cells was more stable with acrylamide than that of the free cells. Under optimal conditions, the final acrylamide concentration reached about 400 g/L with a conversion yield of almost 100% after 8 h of reaction when using 150 g/L of immobilized cells corresponding to a 1.91 g-dry cell weight/L. The enzyme activity of the immobilized cells rapidly decreased with repeated use. However, the quality of the acrylamide produced by the immobilized cells was much better than that produced by the free cells in terms of color, salt content, turbidity, and foam formation. The quality of the aqueous acrylamide solution obtained was found to be of commercial use without further purification.     

Hydration of cyanopyridine to nicotinamide by whole cell nitrile hydratase

Summary 3-cyanopyridine was hydrated to nicotinamide by whole cells ofBrevibacterium R-312 containing nitrile hydratase. Cells used for kinetic studies had an initial activity of 0.30 mg nicotinamide/mg cells(dry)-min and storage half-lives (pH 8) of approximately 100 days, 10 days, 5 days and less than 1 day at 4°C, 10°C, 25°C, and 30°C respectively. Temperature and pH maxima were 35°C and 8.0, respectively. Fermentations gave a maximum total hydratase activity of 1.25 mg nicotinamide/min, but at this maximum the amidase activity was unacceptably high (25% of the hydratase activity): nicotinamide was converted too rapidly to nicotinic acid. But systematic fermentation studies (7 1) showed that harvesting at mid-log phase (18–20 h) prior to the attainment of maximum total activity gave reasonably high levels of hydratase (0.3 mg nicotinamide/mg cells-min) and acceptable levels of amidase (0.03 mg nicotinic acid/mg cells-min).     

Mild hydrolysis of nitriles by the immobilized nitrilase from Aspergillus niger K10

The cell free extract from the nitrile-hydrolyzing strain Aspergillus niger K10 (0.25 mg of protein) was adsorped onto a 1 mL HiTrap Butyl Sepharose column. The benzonitrile-hydrolyzing activity of the immobilized enzyme (about 1.6 U/mg of protein) was stable at pH 8 and 35 °C within the examined period (4 h). The enzyme load on the above column was increased 18 times in order to achieve high nitrile conversion. This enzyme preparation was used for the conversion of 3-cyanopyridine and 4-cyanopyridine under the above conditions. The initial substrate conversion was nearly quantitative. The activity was fairly stable; the conversion of 3-cyanopyridine decreased to 70% after 15 h, while the conversion of 4-cyanopyridine was 60% of the initial value after 39 h. The former substrate was converted into nicotinic acid and nicotinamide (molar ratio approximately 16:1) and the latter one into isonicotinic acid and isonicotinamide (molar ratio approximately 3:1).     

Cyanide hydratase from Aspergillus niger K10: Overproduction in Escherichia coli,purification, characterization and use in continuous cyanide degradation

A cyanide hydratase from Aspergillus niger K10 was expressed in Escherichia coli and purified. Apart from HCN, it transformed some nitriles, preferentially 2-cyanopyridine and fumaronitrile. V_max and K_m for HCN were ca. 6.8 mmol min⁻¹ mg⁻¹ protein and 109 mM, respectively. V_max for fumaronitrile and 2-cyanopyridine was two to three orders of magnitude lower than for HCN (ca. 18.8 and 10.3 μmol min⁻¹ mg⁻¹, respectively) but K_m was also lower (ca. 14.7 and 3.7 mM, respectively). Both cyanide hydratase and nitrilase activities were abolished in truncated enzyme variants missing 18–34 C-terminal aa residues. The enzyme exhibited the highest activity at 45 °C and pH 8–9; it was unstable at over 35 °C and at below pH 5.5. The operational stability of the whole-cell catalyst was examined in continuous stirred membrane reactors with 70-mL working volume. The catalyst exhibited a half-life of 5.6 h at 28 °C. A reactor loaded with an excess of the catalyst was used to degrade 25 mM KCN. A conversion rate of over 80% was maintained for 3 days.     

Solvent free biocatalytic synthesis of isoniazid from isonicotinamide using whole cell of Bacillus smithii strain IITR6b2

A biocatalytic route for the synthesis of isoniazid, an important first-line antitubercular drug, in aqueous system is presented. The reported bioprocess is a greener method, does not involve any hazardous reagent and takes place under mild reaction conditions. Whole cell amidase of Bacillus smithii strain IITR6b2 having acyltransferase activity was utilized for its ability to transfer acyl group of isonicotinamide to hydrazine–2HCl in aqueous medium. B. smithii strain IITR6b2 possessed 3 folds higher acyltransferase activity as compared to amide hydrolase activity and this ratio was further improved to 4.5 by optimizing concentration of co-substrate hydrazine–2HCl. Various key parameters were optimized and under the optimum reaction conditions of pH (7, phosphate buffer 100 mM), temperature (30 °C), substrate/co-substrate concentration (100/1000 mM) and resting cells concentration (2.0 mg_dcw/ml), 90.4% conversion of isonicotinamide to isoniazid was achieved in 60 min. Under these conditions, a fed batch process for production of isoniazid was developed and resulted in the accumulation of 439 mM of isoniazid with 87.8% molar conversion yield and productivity of 6.0 g/h/g_dcw. These results demonstrated that enzymatic synthesis of isoniazid using whole cells of B. smithii strain IITR6b2 might present an efficient alternative route to the chemical synthesis procedures without the involvement of organic solvent.