N-terminal amino acid sequence of Brevibacterium sp. R312 wide-spectrum amidase

Summary A wide-spectrum amidase from Brevibacterium sp. R312 was partially purified. The enzyme subunit was purified by reversed phase HPLC and the N-terminal amino acid sequence was found to be identical to that of Pseudomonas aeruginosa aliphatic amidase. Offprint requests to: A. Arnaud     

Regulation of nitrile-hydratase synthesis in a Brevibacterium species

The regulation of nitrile-hydratase biosynthese was studied in Brevibacterium sp R 312. Enzyme biosynthesis was not influenced by any carbon and nitrogen source used in the growth medium. It was, however, repressed by amide and amide analogues. Acetamide repressed nitrile-hydratase biosynthesis and induced the wide-spectrum amidase. Therefore, it appeared reasonable to hypothesize a single repressor gene for the nitrile-hydratase/wide-spectrum amidase system.     

Sizing of theRhodococcus sp. R312 genome by pulsed-field gel electrophoresis. Localization of genes involved in nitrile degradation

The two restriction enzymesAsnI andDraI were found to produce DNA fragment sizes that could be used for mapping theRhodococcus sp. R312 (formerlyBrevibacterium sp. R312) genome by pulsed-field gel electrophoresis.AsnI produced 24 fragments (4 to 727 kb) andDraI yielded 15 fragments (8.5 to 2400 kb). The fragment lengths in each digest were summed, indicating that the size of the chromosome ranged from 6.31 to 6.56 Mb, with a mean of 6.44 Mb. In addition, the wide-spectrum amidase gene (amiE) and the operon containing the enantiomer-selective amidase gene (amdA) and the nitrile hydratase structural gene (nthA, nthB) were localized on theAsnI andDraI fragments.     

Detoxification of cassava pulp using Brevibacterium sp. R312

Summary Brevibacterium sp. strain R312 has an endocellular -glucosidase, a nitrile hydratase and an amidase that can break down some cyanoglucosides. Nonsterile cassava pulp suspensions were fermented using this strain and 70%–80% reduction of nitrile compounds, in particular cyanoglucosides and -hydroxynitriles, was observed. This type of nitrile-hydratase-active microorganism could be a solution for the detoxification of cassava. Experiments conducted with the yeast Candida molischiana and C. wickkerhamii showed no improvement in detoxification. Offprint requests to: A. Arnaud     

The use of neural networks to aid in microorganism identification: a case study ofHaemophilus species identification

The adipamidase of a mutant strainBrevibacterium sp. R312 involved in the degradation of adiponitrile to adipic acid was purified. Its N-terminal amino acid sequence was shown to be identical toBrevibacterium sp. R312 enantio-selective amidase andRhodococcus sp. N-774 amidase.     

A Study of the Mechanism of the Reactions Catalyzed by the Amidase Brevibacterium sp. R312

Besides its amide hydrolase activity, the amidase from Brevibacterium sp. R312 also exhibits an acyl-transferase activity.

The mechanism of the transfer reaction of the acyl from acetamide to hydroxylamine was studied. This is a “Bi Bi Ping Pong” type reaction. The kinetic parameters of the reaction were determined:

– Apparent V_m = 135 μmol · min ^–1 · mg^–1

– Acetamide K_m = 18.2 mM

– Hydroxylamine K_m = 131 mM     

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).     

Amide hydrolyzing potential of amidase from halotolerant bacterium Brevibacterium sp. IIIMB2706

Till date, amidases from halophiles and halotolerant micro-organisms have not been much explored. In the present study, Brevibacterium sp. IIIMB2706 strain was isolated from salt fields of Gujarat, India, using propionitrile as a nitrogen source in the mineral base media and explored for its amidase activity. Amidase from Brevibacterium sp. IIIMB2706 exhibited substrate affinity towards isobutyramide, propionamide and butyramide. The optimum temperature and pH required for its maximum activity was 45?°C and 7.0, respectively. Effect of salt concentration on amidase activity was also studied and maximum activity was observed in presence of 50?g L^?1 NaCl with significant activity up to 200?g L^?1 NaCl which justifies its halotolerant nature. Various organic solvents compatibility profile showed that the enzyme was highly active in presence of 10% methyl alcohol. Henceforth, halotolerant enzymes may find application in industrial processes where substrate requires organic solvents for solubilization.     

Cloning the amidase gene from Rhodococcus rhodochrous M8 and its expression in Escherichia coli

The amidase gene from Rhodococcus rhodochrous M8 was cloned by PCR amplification with primers developed by use of peptide amino acid sequences obtained after treating amidase with trypsin. Nucleotide sequence analysis of this gene revealed high homology with aliphatic amidases from R. erythropolis R312 and Pseudomonas aeruginosa. Considering the substrate specificity and the results of DNA analysis, amidase from R. rhodochrous M8 was assigned to the group of aliphatic amidases preferentially hydrolyzing short-chain aliphatic amides. The amidase gene was expressed in cells of Escherichia coli from the self promoter and from the lac promoter. To clone a fragment of R. rhodochrous M8 chromosome (approximately 9 kb), containing the entire structural gene and its flanking regions, plasmid pRY1 that can be integrated into the chromosome via homology regions was used. No sequences of the nitrile hydratase gene, the second key gene of nitrile degradation in strain R. rhodochrous M8, were detected. Thus, genes encoding amidase and nitrile hydratase in strain R. rhodochrous M8 are not organized into a single operon despite their common regulation.     

Amidase activity of some bacteria

The amidase activity of bacteria possessing a high nitrilase activity was found to display the same spectrum although the bacteria may belong to different taxonomic groups,Bacillus, Bacteridium, Micrococcus, Brevibacterium. The spectrum of amidase activity, although very broad, is more restricted than that of nitrilase activity. Internal amides as well as vinyl-bound amides are not hydrolyzed.     

A study of the inhibition of an amidase with a wide substrate spectrum and its consequences for the bioconversion of nitriles

Summary TheBrevibacterium sp. R 312 strain possesses a nitrile-hydratase and an amidase, both with a wide substrate spectrum. These two enzymes can be used for the bioconversion of nitriles into the corresponding organic acids: the actions of three types of compounds (nitriles, amides and acids) on the activity of the amidase are reported in the present work.     

The superiority of the third-generation catalyst,Rhodococcus rhodochrous J1 nitrile hydratase,for industrial production of acrylamide

As the third-generation biocatalyst for industrial production of acrylamide, the superiority of Rhodococcus rhodochrous J1 nitrile hydratase was demonstrated in comparison with other acrylamide-producing bacteria. R. rhodochrous J1 enzyme is much more heat stable and more tolerant to a high concentration of acrylonitrile than Pseudomonas chlororaphis B23 and Brevibacterium R312 enzymes. The J1 enzyme is peculiar in its extremely high tolerance to acrylamide. The hydration reaction of acrylonitrile catalysed by J1 cells proceeded even in the presence of 50% (w/v) acrylamide. The tolerance of J1 enzyme to various organic solvents such as n-propanol and isopropanol was prominent. Using R. rhodochrous J1 resting cells, the accumulation reaction was carried out by feeding acrylonitrile to maintain a level of 6%. After 10 h incubation, the accumulation of acrylamide was approximately 65.6% (w/v) at 10°C, 56.7% (w/v) at 15°C, and 56.0 (w/v) at 20°C. The high stability, high catalytic efficiency and other outstanding features of the J1 enzyme are analysed and discussed. Correspondence to: T. Nagasawa     

Identification and characterization of an aliphatic amidase in Helicobacter pylori

We report, for the first time, the presence in Helicobacter pylori of an aliphatic amidase that, like urease, contributes to ammonia production. Aliphatic amidases are cytoplasmic acylamide amidohydrolases (EC 3.5.1.4) hydrolysing short-chain aliphatic amides to produce ammonia and the corresponding organic acid. The finding of an aliphatic amidase in H. pylori was unexpected as this enzyme has only previously been described in bacteria of environmental (soil or water) origin. The H. pylori amidase gene amiE (1017 bp) was sequenced, and the deduced amino acid sequence of AmiE (37 746 Da) is very similar (75% identity) to the other two sequenced aliphatic amidases, one from Pseudomonas aeruginosa and one from Rhodococcus sp. R312. Amidase activity was measured as the release of ammonia by sonicated crude extracts from H. pylori strains and from recombinant Escherichia coli strains overproducing the H. pylori amidase. The substrate specificity was analysed with crude extracts from H. pylori cells grown in vitro; the best substrates were propionamide, acrylamide and acetamide. Polymerase chain reaction (PCR) amplification of an internal amiE sequence was obtained with each of 45 different H. pylori clinical isolates, suggesting that amidase is common to all H. pylori strains. A H. pylori mutant (N6-836) carrying an interrupted amiE gene was constructed by allelic exchange. No amidase activity could be detected in N6-836. In a N6–urease negative mutant, amidase activity was two- to threefold higher than in the parental strain N6. Crude extracts of strain N6 slowly hydrolysed formamide. This activity was affected in neither the amidase negative strain (N6-836) nor a double mutant strain deficient in both amidase and urease activities, suggesting the presence of an independent discrete formamidase in H. pylori. The existence of an aliphatic amidase, a correlation between the urease and amidase activities and the possible presence of a formamidase indicates that H. pylori has a large range of possibilities for intracellular ammonia production.     

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.     

The Enzymatic Production of Adipic Acid

Mutants of Brevibacterium sp. R312 were isolated for the production of adipic acid from 1,4-dicyanobutane (adiponitrile). One mutant (Ad), with a modified cell wall showed activity against adipamide three times greater than the wild type. Another mutant (ACV2) derived from the Ad strain had 30 times more activity on 5-cyanovaleric acid, and 7 times more on adipamide than the wild type.

The nitrile hydratase from the mutant strain ACV2 was purified and compared to that from the wild type R312. The nitrile hydratase of the mutant strain is different from that of the wild type by its pHi, optimum activity pH, and its rates of hydrolysis of 5-cyanovaleramide and 5-cyanovaleric acid which were 30 and 15 folds greater.

The presence of a new amidase named “adipamidase” acting on amide intermediates in the hydrolysis of dinitriles to organic acids was demonstrated in this mutant ACV2.     

Esterase Activities of Brevihacterium sp. R312 and Brevihacterium linens 62

Esterase activity of Brevihacterium linens 62 and Brevibacterium sp. R312 was detected. Each strain had esterase activities that hydrolyzed p-nitrophenyl acetate and α-naphthyl acetate. Biosynthesis and optimum pH and temperature of the two esterase activities showed that the latter were caused by different esterases. The influence of the culture medium and the growth substrate on biosynthesis of the esterase systems were studied. Hydrolysis of methylthioacetate and phenethyl acetate by cell extracts of the two strains was done. No enzymatic ester synthesis reaction was observed. However, transfer reactions by cell extracts of the two strains were done.     

短杆菌属海洋环境适应机制的泛基因组学

[目的]为了探究短杆菌属对海洋环境的适应机制.[方法]本研究通过对6株分离自不同洋区、属于不同分类单元的短杆菌菌株进行测序、拼接和注释,结合23株从美国国家生物技术信息中心(NCBI)下载的短杆菌属模式菌株及非模式菌株的基因组数据,进行泛基因组学分析和物种进化分析.[结果]泛基因组学分析表明短杆菌属具有开放型泛基因组,...     

Enhanced production of amidase from <Emphasis Type="Italic">Rhodococcus erythropolis</Emphasis> MTCC 1526 by medium optimisation using a statistical experimental design

In the present work, statistical experimental methodology was used to enhance the production of amidase from Rhodococcus erythropolis MTCC 1526. R. erythropolis MTCC 1526 was selected through screening of seven strains of Rhodococcus species. The Placket–Burman screening experiments suggested that sorbitol as carbon source, yeast extract and meat peptone as nitrogen sources, and acetamide as amidase inducer are the most influential media components. The concentrations of these four media components were optimised using a face-centred design of response surface methodology (RSM). The optimum medium composition for amidase production was found to contain sorbitol (5 g/L), yeast extract (4 g/L), meat peptone (2.5 g/L), and acetamide (12.25 mM). Amidase activities before and after optimisation were 157.85 units/g dry cells and 1,086.57 units/g dry cells, respectively. Thus, use of RSM increased production of amidase from R. erythropolis MTCC 1526 by 6.88-fold.     

Overexpression of a recombinant amidase in a complex auto-inducing culture: purification,biochemical characterization,and regio- and stereoselectivity

Rhodococcus erythropolis AJ270 metabolizes a wide range of nitriles via the two-step nitrile hydratase/amidase pathway. In this study, an amidase gene from R. erythropolis AJ270 was cloned and expressed in Escherichia coli BL21 (DE3). The activity reached the highest level of 22.04 U/ml in a complex auto-inducing medium using a simplified process of fermentation operation. The recombinant amidase was purified to more than 95% from the crude lysate using Ni-NTA affinity chromatography and Superose S10-300 gel filtration. The V _max and K _m values of the purified enzyme with acetamide (50 mM) were 6.89 μmol/min/mg protein and 4.12 mM, respectively, which are similar to those of the enzyme from the wild-type cell. The enzyme converted racemic α-substituted amides, O-benzylated β-hydroxy amides, and N-benzylated β-amino amides to the corresponding (S)-acids with remarkably high enantioselectivity. The ionic liquid [BMIm][PF₆] (1-butyl-3-methylimidazolium hexafluorophosphate) enhanced the activity by 1.5-fold compared with water. The adequate expression of the enzyme and excellent enantioselectivity of the recombinant amidase to a broad spectrum of amides suggest that the enzyme has prospective industrial-scale practical applications in pharmaceutical chemistry.