Enzymatic degradation of nitriles by Klebsiella oxytoca

Klebsiella oxytoca, isolated from cyanide-containing wastewater, was able to utilize many nitriles as sole source of nitrogen. The major objective of this study was to explore the ability of K. oxytoca to utilize some nitriles and then further evaluate the pathways of transformation of cyanide compounds by K. oxytoca. Results from this study indicate that succinonitrile and valeronitrile were the most optimal sources of nitrogen for the growth of K. oxytoca. The biodegradation of acetonitrile proceeded with the formation of acetamide followed by acetic acid. The production of ammonia was also detected in this biodegradation experiment. Similar results were observed in the propionitrile biodegradation experiments. Collectively, this study suggests that the breakdown of acetonitrile or propionitrile by this bacterium was via a two-step enzymatic hydrolysis with amides as the intermediates and organic acids plus with ammonia as the end products.     

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.     

Utilization of acrylonitrile by bacteria isolated from petrochemical waste waters

A bacterium, utilising acrylonitrile as a sole source of carbon and nitrogen, was isolated from Indian Petrochemical Corporation Limited (IPCL) waste waters and identified as Arthrobacter sp. This strain could also utilize acetonitrile, acetamide and acrylamide individually as a source of carbon and nitrogen. The metabolic studies with the whole cells indicated the sequential conversion of the nitrile to the respective amide and then to the respective acid and ammonia. The rate of nitrile hydrolysis was slower than the corresponding amide hydrolysis. Acrylic acid, the end product of acrylonitrile breakdown, did not support the growth when provided as a carbon source.     

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.     

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.     

Utilization of nitriles by yeasts isolated from a Brazilian gold mine

Yeast strains from the genera Candida, Debaryomyces, Aureobasidium, Geotrichum, Pichia, Rhodotorula, Tremella, Hanseniaspora, and Cryptococcus were isolated from samples of a gold mine from liquid extraction circuit. These strains were tested for their ability to utilize acetonitrile at 12 mM as the sole nitrogen source. The yeasts that grew using acetonitrile at 12 mM were tested in the presence of acetonitrile, isobutyronitrile, methacrylnitrile, and propionitrile at concentrations of 12, 24, 48, 97, and 120 mM. One strain was selected for each nitrile and the concentration of nitrile in which the best growth occurred. Cryptococcus sp. strain UFMG-Y28 had a better growth on 120 mM propionitrile and 97 mM acetonitrile, Rhodotorula glutinis strain UFMG-Y5 on 48 mM methacrylnitrile, and Cryptococcus flavus strain UFMG-Y61 on 120 mM isobutyronitrile. The utilization of different nitriles and amides by yeast strains involves hydrolysis in a two-step reaction mediated by both inducible and intracellular nitrile hydratase and amidase.     

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.     

Real-time monitoring of nitrile biotransformations by mid-infrared spectroscopy

In this study mid-infrared spectroscopy was used to follow the enzyme kinetics involved in nitrile biocatalysis using whole cell suspensions of the bacterium Rhodococcus rhodochrous LL100-21. The bacteria were grown on acetonitrile to induce a two-step enzymatic pathway. Acetonitrile was biotransformed to acetamide by a nitrile hydratase enzyme and subsequently to acetic acid (carboxylate ion) by an amidase enzyme. The bacteria were also grown on benzonitrile to induce a one-step enzymatic pathway. Benzonitrile was biotransformed directly to benzoic acid (carboxylate ion) by a nitrilase enzyme. These reactions were followed by React IR using a silicon probe and gave excellent quantitative and qualitative real-time data of both nitrile biocatalytic reactions. This study has shown that this novel technique has potentially useful applications in biocatalysis.     

Remaining acetamide in acetonitrile degradation using nitrile hydratase- and amidase-producing microorganisms

The tandem conversion process involving nitrile hydratase- and amidase-producing microorganisms has potential for use in the treatment of acetonitrile-containing wastes. In that process, the acetamide hydrolysis step catalyzed by amidase is very slow compared with the acetonitrile hydration step catalyzed by nitrile hydratase, and a small amount of acetamide remains in the resulting solution. This study aimed to improve the efficiency of the acetamide hydrolysis step. An amidase-producing microorganism, Rhodococcus sp. S13-4, was newly obtained, whose use enabled rapid acetamide degradation. Though residual acetamide was still detected, it was successfully reduced by the addition of cation/anion mixed ion exchange resin or calcium hydroxide after the acetamide hydrolysis reaction using Rhodococcus sp. S13-4 cells. This result implies that acetamide hydrolysis and acetamide formation are in equilibrium. The incubation of Rhodococcus sp. S13-4 cells with high concentrations of ammonium acetate produced acetamide. The purified amidase from Rhodococcus sp. S13-4 revealed the acetamide formation activity (specific activity of 30.6 U/mg protein). This suggests that the amidase-catalyzed amide formation may cause the remaining of acetamide in the acetonitrile conversion process.     

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.     

Transferase activity of horse blood serum cholinesterase at hydrolysis of 1-methyl-8-acetoxychinolinium iodide in the presence of aliphatic alcohols

The study was performed to check whether the horse blood serum butyrylcholinesterase expresses transferase activity in the presence of several low-molecular aliphatic alcohols, using chromogenic substrate 1-methyl-8-acetoxychinolium iodide whose phenolic hydrolysis product absorbs intensively at 445 nm, whereas the initial ester practically does not absorb within this spectrum area. This allowed measuring simultaneously accumulation of both products of enzymatic hydrolysis: of acetic acid by the potentiometric, while of phenol—by the colorimetric method. Rates of formation of both products of enzymatic hydrolysis are practically equal in experiments with all studied alcohols. This indicates that horse blood serum butyrylcholinesterase under these experimental conditions does not catalyze the transfer of acetyl residue to the studied aliphatic alcohols, i.e. does not have transferase activity.     

Kinetic mechanism of the aliphatic amidase from Pseudomonas aeruginosa.

The kinetic constants for hydrolysis and transfer (with hydroxylamine as the alternate acceptor) of the aliphatic amidase (acylamide amidohydrolase, EC 3.5.1.4) from Pseudomonas aeruginosa were determined for a variety of acetyl and propionyl derivatives. The results obtained were consistent with a ping-pong or substitution mechanism. Product inhibition, which was pH dependent, implicated an acyl-enzyme compound as a compulsory intermediate and indicated that ammonia combined additionally with the free enzyme in a dead-end manner. The uncompetitive activation of acetamide hydrolysis by hydroxylamine and the observation that the partitioning of products between acetic acid and acetohydroxamate was linearly dependent on the hydroxylamine concentration substantiated these conclusions and indicated that deacylation was at least partially rate limiting. With propionamide as the acyl donor apparently anomalous results, which included inequalities in certain kinetic constants and a hyperbolic dependence of the partition ratio on the hydroxylamine concentration, could be explained by postulating a compulsory isomerisation of the acyl-enzyme intermediate prior to the transfer reaction.     

Constitutive acetonitrile hydrolysing activity of Nocardia globerula NHB-2: Optimization of production and reaction conditions

Nocardia globerula NHB-2 exhibited an intracellular acetonitrile hydrolysing activity (AHA) when cultivated in nutrient broth supplemented with glucose (10.0 g/l) and yeast extract (1.0 g/l), at pH 8.0, 30 degrees C for 21 hr. Maximum AHA was recorded in the culture containing 0.1 M of sodium phosphate buffer, (pH 8.8) at 45 degrees C for 15 min with 600 micromol of acetonitrile and resting cells of N. globerula NHB-2 equivalent to 1.0 ml culture broth. This activity was stable up to 40 degrees C and was completely inactivated at or above 60 degrees C. About five-fold increase in AHA was observed after optimization of culture and reaction conditions. Under the optimized conditions, this organism hydrolyzed various nitriles and amides such as propionitrile, benzonitrile. acetamide, and acrylamide to corresponding acids. This nitrile/amide hydrolysing activity of N. globerula NHB-2 has potential applications in enzymatic synthesis of organic acids and bioremediation of nitriles and amides contaminated soil and water system.     

Formation of amino acids from aliphatic nitriles and aliphatic amines by contact glow discharge electrolysis

Contact glow discharge electrolyses (CGDE) were carried out relative to the prebiotic formation of amino acids by amination of aliphatic nitrile in aqueous ammoniacal solution, and by cyanization of aliphatic amine by sodium cyanide. The CGDE of propionitrile by amination followed by hydrolysis resulted in the formation of glycine, alanine and β-alanine. The reaction of ethylamine by cyanization, gave glycine, alanine, β-alanine, aspartic acid, and serine. In these reactions, a relatively high ratio of glycine was observed. This could be explained by the cleavage of the α,β-carbon bond, which was broken easily, due to the strong electron-attracting property of the nitrile group of propionitrile and the resulting α-aminopropionitrile.     

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.     

Characterization and partial purification of an enantioselective arylacetonitrilase from Pseudomonas fluorescens DSM 7155

Pseudomonas fluorescens DSM 7155 after growth on phenylacetonitrile as sole nitrogen source contained an inducible nitrilase which consists of two different functional subunits (40 and 38 kDa). The nitrilase catalysed the exclusive hydrolysis of arylacetonitrile substrates into the equivalent carboxylic acids plus ammonia as major products. The corresponding amides were formed at low levels (<5%) during nitrile hydrolysis but were not substrates for the purified enzyme. The native enzyme, which had a pH optimum of 9 and a temperature optimum of 55°C, was activated (140–160%) by the thiol protectant 2-mercaptoethanol (50–100 mM). The purified nitrilase catalysed the hydrolysis of the two enantiomers of racemic 2-(methoxy)-mandelonitrile to the corresponding acid at significantly different rates: at 50% overall conversion the predominant product was the (R)-acid (enantiomeric excess=92%) whereas at 85% overall conversion the ee% of the (R)-acid had decreased to 27%.     

On the nitrile effect in L-rhamnopyranosylation

It is shown that the use of 5% acetonitrile or propionitrile in dichloromethane functions to increase the beta-selectivity of a number of L-rhamnopyranosylation reactions conducted by the thioglycoside method with activation by the 1-benzenesulfinyl piperidine/trifluoromethanesulfonic anhydride couple. The use of more significant quantities of acetonitrile or propionitrile results in the formation of complex reaction mixtures containing little coupled product, but from which Ritter-type products can be isolated.     

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.     

Amide metabolism of Chlamydomonas reinhardi

Chlamydomonas reinhardi can utilise the lower aliphatic amides (C₁–C₄) as nitrogen sources. Of these only acetamide can serve as a sole carbon source. The acetamide analogue F-acetamide kills cells after conversion to F-acetate and F-citrate. This conversion is controlled by exogenous ammonia and, in part, acetate levels. Only one enzyme and one active site are involved in acetamidase function. Enzymatic analysis indicates an increased substrate range as compared to the growth — supported range, indicating uptake, toxicity or metabolic control restrictions.Abbreviations TCA trichloroacetic acid - TAP tris-acetate-phosphate medium - MIC mimmum inhibitory concentration - BSA bovine serum albumin     

The Bioutilization of Thiodiglycol (a Detoxication Product of Mustard Gas): Isolation of Degrading Strains and Investigation of Degradation Conditions

The Alcaligenes xylosoxydans subsp.denitrificans strain TD1 capable of degrading thiodiglycol (TDG), a product of mustard gas hydrolysis, was isolated from soil contaminated with breakdown products of this chemical warfare agent. The selected stable variant of TD1 (strain TD2) can grow on TDG with a lag phase of 4–8 h and a specific growth rate of 0.04–0.045 h^–1. Optimal conditions for the biodegradation of TDG (pH, the concentration of TDG in the medium, and specific substrate loading) were determined. TDG was found to be degraded with the formation of diglycolsulfoxide and thiodiglycolic acid as intermediate products. The data obtained can be used to develop approaches to the bioremediation of mustard gas–contaminated soils.