Metabolism of benzonitrile and butyronitrile by Klebsiella pneumoniae.

A strain of Klebsiella pneumoniae that used aliphatic nitriles as the sole source of nitrogen was adapted to benzonitrile as the sole source of carbon and nitrogen. Gas chromatographic and mass spectral analyses of culture filtrates indicated that K. pneumoniae metabolized 8.4 mM benzonitrile to 4.0 mM benzoic acid and 2.7 mM ammonia. In addition, butyronitrile was metabolized to butyramide and ammonia. The isolate also degraded mixtures of benzonitrile and aliphatic nitriles. Cell extracts contained nitrile hydratase and amidase activities. The enzyme activities were higher with butyronitrile and butyramide than with benzonitrile and benzamide, and amidase activities were twofold higher than nitrile hydratase activities. K. pneumoniae appears promising for the bioremediation of sites contaminated with aliphatic and aromatic nitriles.     

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     

Degradation of Acetonitrile by Pseudomonas putida

A bacterium capable of utilizing high concentrations of acetonitrile as the sole source of carbon and nitrogen was isolated from soil and identified as Pseudomonas putida. This bacterium could also utilize butyronitrile, glutaronitrile, isobutyronitrile, methacrylonitrile, propionitrile, succinonitrile, valeronitrile, and some of their corresponding amides, such as acetamide, butyramide, isobutyramide, methacrylamide, propionamide, and succinamide as growth substrates. Acetonitrile-grown cells oxidized acetonitrile with a K_m of 40.61 mM. Mass balance studies with [¹⁴C]acetonitrile indicated that nearly 66% of carbon of acetonitrile was released as ¹⁴CO₂ and 14% was associated with the biomass. Metabolites of acetonitrile in the culture medium were acetic acid and ammonia. The acetate formed in the early stages of growth completely disappeared in the later stages. Cell extracts of acetonitrile-grown cells contained activities corresponding to nitrile hydratase and amidase, which mediate the breakdown of actonitrile into acetic acid and ammonia. Both enzymes were intracellular and inducible and hydrolyzed a wide range of substrates. The specific activity of amidase was at least 150-fold higher than the activity of the enzyme nitrile hydratase.     

Studies on utilization of acetonitrile by Rhodococcus erythropolis A10

A petrochemical wastewater isolate, capable of utilizing high concentrations of acetonitrile and acetamide as the sole source of carbon and nitrogen was identified as Rhodococcus erythropolis A10. Cell-free extracts of acetonitrile-grown cells exhibited activities corresponding to nitrile hydratase (EC 4.2.1.84) and amidase (EC 3.5.1.4), which mediate the two-step breakdown of acetonitrile into acetic acid and ammonia. Studies indicated that both these enzymes in R. erythropolis A10 are intracellular, inducible and capable of hydrolysing a wide range of nitriles, including simple (acetonitrile, propionitrile), branched-chain (isobutyronitrile) and dinitrile (succinonitrile). The specific activity of the amidase was found to be several-fold higher than nitrile hydratase.     

Enzymatic degradation of nitriles by a Candida guilliermondii UFMG-Y65

Candida guilliermondii UFMG-Y65, isolated from a gold mine, was able to utilize different nitriles and the corresponding amides as sole source of nitrogen, at concentrations up to 2 M. Resting cells cultivated on YCB-acetonitrile medium showed nitrile hydrolyzing enzyme activities against acrylonitrile and benzonitrile. These enzymes were inducible and intracellular; the optimum pH was 7.0-8.0, and the optimum temperature 25 degrees C-30 degrees C. Liquid chromatographic analysis indicated that C. guilliermondii UFMG-Y65 metabolized 12 mM benzonitrile to 11 mM benzoic acid and 10 mM acrylonitrile to 7.9 mM acrylic acid. The results suggest that C. guilliermondii UFMG-Y65 may be useful for the bioproduction of amides and acids, and for the bioremediation of environments contaminated with nitriles.     

Simultaneous degradation of acetonitrile and biphenyl by Pseudomonas aeruginosa

A bacterium capable of utilizing either acetonitrile as the sole source of carbon and nitrogen or biphenyl as the sole source of carbon was isolated from soil and identified as Pseudomonas aeruginosa. The bacterium also utilized other nitriles, amides, and polychlorinated biphenyls (PCBs) as growth substrates. Acetonitrile- or biphenyl-grown cells oxidized these substrates without a lag. In studies with [14C]acetonitrile, nearly 74% of the carbon was recovered as 14CO2 and 8% was associated with the biomass. In studies with [14C]biphenyl, nearly 68% of the carbon was recovered as 14CO2 and nearly 6% was associated with the biomass. Although higher concentrations of acetonitrile as the sole sources of nitrogen inhibited the rates of [14C]biphenyl mineralization, lower concentrations (0.05%, w/v) gave a 77% stimulation in 14CO2 recovery. Pseudomonas aeruginosa metabolized acetonitrile to ammonia and acetic acid and biphenyl to benzoic acid. The bacterium also simultaneously utilized biphenyl as the sole carbon source and acetonitrile as the sole nitrogen source. However, biphenyl utilization increased only after the depletion of acetonitrile. Metabolites of the mixed substrate were ammonia and benzoic acid, which completely disappeared in the later stages of incubation. Nitrile hydratase and amidase were responsible for the transformation of acetonitrile to acetic acid and ammonia.     

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 of a novelAgrobacteriun spp capable of degrading a range of nitrile compounds

Summary Using soil enrichment techniques we have isolated micro-organisms capable of degrading simple nitrile compounds. One species identified as anAgrobacterium spp. was examined in detail. This isolate was capable of utilising a range of aliphatic and aromatic nitriles as sole sources of carbon and nitrogen. Assays for enzymes involved in nitrile degradation and growth/production studies with this organism growing on acetonitrile indicated that breakdown occurred via a two step mechanism firstly to the amide and then via the production of the corresponding acid with the subsequent release of ammonia. Our studies indicate that the system of nitrile breakdown is inducible and levels of the amidase are 170 times that of the nitrile hydratase in crude extracts.     

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.     

Nitrile- and Amide-hydrolysing Activity in Kluyveromyces thermotolerans MGBY 37

Summary Forty yeast strains were screened for nitrile-hydrolysing activity. Among them Kluyveromyces thermotolerans MGBY 37 exhibited highest nitrile-hydrolysing activity (0.030 μmol/h/mg dry cell weight). This yeast contained a two-enzyme system i.e. nitrile hydratase (NHase, EC 4.2.1.84) and amidase (EC 3.5.1.4) for the hydrolysis of nitriles/amides to corresponding acids and ammonia. However, these enzymes had more affinity for N-heterocyclic aromatic and aromatic nitriles/amides rather than unsaturated and saturated aliphatic nitriles/amides. The NHase–amidase activity was constitutively produced by K. thermotolerence MGBY 37. Addition of acetonitrile in the medium enhanced the production of this activity while other nitriles and amides lowered the production of NHase–amidase activity. This organism thus exhibited two types of amidase i.e. a constitutive amidase having affinity for N-heterocyclic aromatic, unsaturated and saturated aliphatic amides and another inducible amidase with affinity for aromatic amides. Formamide proved to be the best inducer of the latter amidase activity. This is the first report on nitrile- and amide-hydrolysing activity in Kluyveromyces.     

Utilization of aliphatic nitriles under haloalkaline conditions by Bacillus alkalinitrilicus sp. nov. isolated from soda solonchak soil

Enrichment with isobutyronitrile as the sole carbon, energy and nitrogen source at pH 10, using soda solonchak soils as an inoculum, resulted in the selection of a binary culture consisting of two different spore-forming phenotypes. One of them, strain ANL-iso4, was capable of growth with isobutyronitrile as a single substrate, while the other phenotype only utilized products of isobutyronitrile hydrolysis, such as isobutyroamide and isobutyrate. Strain ANL-iso4 is an obligate alkaliphile and a moderately salt-tolerant bacterium. Apart from isobutyronitrile, it grew on other (C3-C6) aliphatic nitriles at pH 10. Resting cells of ANL-iso4 actively hydrolyzed a number of aliphatic and arylaliphatic nitriles and their corresponding amides. The latter, together with the intermediate formation of amides during nitrile hydrolysis, indicated the presence of a nitrile hydratase/amidase system in the novel bacterium. Although present in an alkaliphilic bacterium, both nitrile- and amide-hydrolyzing activities had a pH optimum within the neutral range, probably due to their intracellular localization. On the basis of phenotypic and phylogenetic analyses, strain ANL-iso4 is proposed as a new species Bacillus alkalinitrilicus sp. nov.     

Utilization of acetonitrile and other aliphatic nitriles by a Candida famata strain

Abstract A variant of a yeast strain identified as Candida famata isolated from gold mine effluent was able to grow on acetonitrile, acrylonitrile, butyronitrile, isobutyronitrile, methacrylnitrile, propionitrile, succinonitrile, valeronitrile, acetamide, isobutyamide, and succinamide as sole nitrogen source, after acclimatization. The yeast grew on acetonitrile and acetamide at concentrations up to 4%. The utilisation of acetonitrile and acetamide by the C. famata strain probably involves hydrolysis in a two-step reaction mediated by both inducible and intracellular nitrile hydratase and amidase.     

Expression and purification of a recombinant enantioselective amidase

Microbacterium sp. AJ115 metabolises a wide range of nitriles using the two-step nitrile hydratase/amidase pathway. In this study, the amidase gene of Microbacterium sp. AJ115 has been inserted into the pCal-n-EK expression vector and expressed in Escherichia coli BL21(DE3)pLysS. The expressed protein is active in E. coli and expression of the amidase gene allows E. coli to grow on acetamide as sole carbon and/or nitrogen source. Expression of active amidase in E. coli was temperature dependent with high activity found when cultures were grown between 20 and 30 degrees C but no activity at 37 degrees C. On induction, the amidase represents 28% of the total soluble protein in E. coli. The expressed amidase has been purified in a single step from the crude lysate using the calmodulin-binding peptide (CBP) affinity tag. The V(max) and K(m) of the purified enzyme with acetamide (50 mM) were 4.4 micromol/min/mg protein and 4.5mM, respectively. The temperature optimum was found to be 50 degrees C. Purified enzyme demonstrated enantioselectivity with the ability to preferentially act on the S enantiomer of racemic (R,S)-2-phenylpropionamide. S-2-phenylpropionic acid is produced with an enantiomeric excess of >82% at 50% conversion of the parent amide.     

A plate method for screening of bacteria capable of degrading aliphatic nitriles

A novel indicator plate method was developed for screening of aliphatic-nitrile-degrading bacteria. Isolated bacteria were tested for utilization of acetonitrile as sole source of carbon and nitrogen with the release of ammonia. The released ammonia causes increase of the pH of the medium. Phenol red indicator is used for detection of ammonia based on colour change of the indicator dye from red to pink. The liberation of ammonia from aliphatic-nitrile-utilizing bacteria is also studied in plates containing other indicators such as bromothymol blue and phenolphthalein. The usefulness of the indicator plate is demonstrated for bacteria that degrade certain aliphatic nitriles. Bacteria degrading nitriles as a nitrogen source can also be isolated with a medium containing additional carbon source. This plate method would be useful in isolation and screening of bacteria for degradation of aliphatic nitriles and also for production of nitrile-hydrolyzing enzymes.     

Utilization of aliphatic nitrile by Paracoccus sp. SKG isolated from chemical waste samples

A bacterial strain Paracoccus sp. SKG capable of utilizing acetonitrile as a sole source of carbon and nitrogen was isolated from the chemical waste samples. The molecular phylogram generated using the complete sequence of 16S rDNA of the strain SKG showed close links to the bacteria grouped under Brucellaceae family, that belongs to the class alphaproteobacteria. Specifically, the 16S rDNA sequence of strain SKG has shown 99% similarity to Paracoccus sp. This bacterium has also shown impressive growth on aliphatic nitriles like acetonitrile, propionitrile, acrylonitrile, valeronitrile and their corresponding amides. The nitriles degradation has led to the accumulation of ammonia and respective carboxylic acids. The acetonitrile grown cells showed the release of ammonia that contributes to the increase in pH of the medium. However, glucose grown cells failed to produce ammonia, thus indicating the inducible nature of acetonitrile degrading enzymes in Paracoccus sp. SKG. Nitrile hydratase and amidase are the two key enzymes involved in the degradation of acetonitrile. Degradation of acetonitrile in Paracoccus sp. SKG follows the bi-enzymatic pathway. Further, this strain is capable of degrading acetonitrile in the presence of other organic solvents such as methanol, ethanol and dimethylformamide. Therefore, this strain is efficiently used for the treatment of HPLC waste stream containing acetonitrile in the presence of other organic solvents.     

Ferrous and ferric ions-based high-throughput screening strategy for nitrile hydratase and amidase

Rapid and direct screening of nitrile-converting enzymes is of great importance in the development of industrial biocatalytic process for pharmaceuticals and fine chemicals. In this paper, a combination of ferrous and ferric ions was used to establish a novel colorimetric screening method for nitrile hydratase and amidase with α-amino nitriles and α-amino amides as substrates, respectively. Ferrous and ferric ions reacted sequentially with the cyanide dissociated spontaneously from α-amino nitrile solution, forming a characteristic deep blue precipitate. They were also sensitive to weak basicity due to the presence of amino amide, resulting in a yellow precipitate. When amino amide was further hydrolyzed to amino acid, it gave a light yellow solution. Mechanisms of color changes were further proposed. Using this method, two isolates with nitrile hydratase activity towards 2-amino-2,3-dimethyl butyronitrile, one strain capable of hydrating 2-amino-4-(hydroxymethyl phosphiny) butyronitrile and another microbe exhibiting amidase activity against 2-amino-4-methylsulfanyl butyrlamide were obtained from soil samples and culture collections of our laboratory. Versatility of this method enabled it the first direct and inexpensive high-throughput screening system for both nitrile hydratase and amidase.     

Enantioselective hydrolysis of racemic 2-phenylpropionitrile and other (R,S)-2-arylpropionitriles by a new bacterial isolate,Agrobacterium tumefaciens strain d3

Bacteria were enriched from soil samples with succinate as carbon source and racemic 2-phenylpropionitrile as sole source of nitrogen. One of the isolates, strain d3, converted (R,S)-2-phenylpropionitrile with high enantioselectivity to (S)-2-phenylpropionic acid. Strain d3 was identified as Agrobacterium tumefaciens. Resting cells hydrolysed 2-phenylpropionitrile via 2-phenylpropionamide to 2-phenylpropionic acid. Racemic 2-phenylpropionitrile as well as 2-phenylpropionamide were converted to (S)-2-phenylpropionic acid with an enantiometric excess above 96%. The nitrile hydratase and the amidase were both shown to convert preferentially the S enantiomer of their respective substrate. These two enzymes were induced in the presence of (R,S)-2-phenylpropionitrile but only in the absence of ammonia. In addition to 2-phenylpropionitrile strain d3 could utilize various aliphatic and aromatic nitriles as nitrogen sources. Resting cells of strain d3 also converted (R,S)-2-phenylbutyronitrile, ibuprofen nitrile, ketoprofen nitrile and -aminophenylacetonitrile with high enantioselectivity. The nitrile- and amide-converting enzyme activities were also found in cell-free extracts.     

Pseudomonas marginalis: its degradative capability on organic nitriles and amides

Pseudomonas marginalis, capable of utilizing acetonitrile as the sole source of carbon and nitrogen, was isolated from an industrial waste site. P. marginalis metabolized acetonitrile into ammonia and acetate. The minimal inhibitory concentration values of different nitriles and amides for P. marginalis were in the range 5–300 mM. The bacterium was able to transform high-molecular-mass nitrile compounds and their respective amides into ammonia. The data from substrate-dependent kinetics showed that the K _m and V _max values of P. marginalis for acetonitrile were 33 mM and 67 nmol oxygen consumed min^–1 (ml cell suspension)^–1 respectively. The study with [¹⁴C]acetonitrile indicated that nearly 66% of the carbon was released as ¹⁴CO₂ and 12% was associated with the biomass. The enzyme system involved in the hydrolysis of acetonitrile was shown to be intracellular and inducible. The specific activities of the enzymes nitrile aminohydrolase and amidase were determined in the cell-free extracts of P. marginalis. Both the enzymes could hydrolyze a wide range of nitriles and amides. The present study suggests that the biodegradation of organic nitriles and the bioproduction of organic acids may be achieved with the cells of P. marginalis.     

Biodegradation of Nitriles in Shale Oil

Enrichment cultures were obtained, after prolonged incubation on a shale oil as the sole source of nitrogen, that selectively degraded nitriles. Capillary gas chromatographic analyses showed that the mixed microbial populations in the enrichments degraded the homologous series of aliphatic nitriles but not the aliphatic hydrocarbons, aromatic hydrocarbons, or heterocyclic-nitrogen compounds found in this oil. Time course studies showed that lighter nitriles were removed more rapidly than higher-molecular-weight nitriles. A Pseudomonas fluorescens strain isolated from an enrichment, which was able to completely utilize the individual nitriles undecyl cyanide and undecanenitrile as sole sources of carbon and nitrogen, was unable to attack stearonitrile when provided alone as the growth substrate. A P. aeruginosa strain, also isolated from one of the enrichments, used nitriles but not aliphatic or aromatic hydrocarbons when the oil was used as a sole nitrogen source. However, when the shale oil was used as the sole source of carbon, aliphatic hydrocarbons in addition to nitriles were degraded but aromatic hydrocarbons were still not attacked by this P. aeruginosa strain.