3-氰基吡啶水合酶产生菌的筛选及其酶形成条件

应用富集培养和梯度底物浓度定向筛选技术,从长期被腈化物污染的土壤中筛选到一株产 3-氰基吡啶水合酶(3-cyanopyridine hydratase)活性较高的马红球菌(Rhodococcus e-qui)SHB-121.研究了该菌3-氰基吡啶水合酶的最适形成条件.在最适条件下,酶的比活力达5.3u/mg干细胞,比在初筛条件下的酶活力提高95倍,而在其细胞内共存的尼克酰胺(烟酰胺)水解酶活力很低.     

3-氰基吡啶水合酶的纯化及性质

马红球菌(Rhodococcus equi)SHB-121胞内3-氰基吡啶水合酶经硫酸铵分级沉淀、DEAE-cellulose DE52和羟基磷灰石柱层析并经过Sephadex G-25处理,得到了聚丙烯酰胺凝胶电泳均一的3-氰基吡啶水合酶,纯化了31倍。该酶由一条肽链组成,其分子量为30kD,等电点为4.1。3-氰基吡啶水合酶能催化3-氰基吡啶水合生成尼克酰胺。酶反应最适pH为8.0,最适温度为30℃。Ag~+、Hg~(2+)、Cu~(2+)及NH_4~+对酶活力有强烈抑制作用。当以3-氰基吡啶为底物时,其K_m为0.1mol/L。NaCN为该酶反竞争性抑制剂,其K_I为5mmol/L。     

3-氰基吡啶水合酶的反应条件及影响因子

研究了芳腈水合酶催化水合3-氰基吡啶生成尼克酰胺的反应条件及影响因子.酶反应的最适pH为8.0,最适温度为25℃.酶在pH8.5于25℃保温4小时或在25—30℃于pH8.0保温3小时是稳定的.反应液中加入Fe~(3 )(1.5 mmol/L)可使酶活力增加 50%,而加入NH_4~ (300 mmol/L)则使酶活降低了67%.Ag~ 和 Hg(2 )”强烈地抑制酶反应活性,在浓度均为 5mmol/L时,抑制率分别为99.7%和100%.NaCN(50 mmol/L)和苯甲腈(100 mmol/L)对酶活性的抑制率分别为78%和85%.该酶作用于 3-氰基吡啶的Km为62.5 mmol/L,V_(max)为85.8 μmol·min~(-1)·mg~(-1).     

3-氰基吡啶水合酶的反应条件及影响因子

研究了芳腈水合酶催化水合3-氰基吡啶生成尼克酰胺的反应条件及影响因子.酶反应的最适pH为8.0,最适温度为25℃.酶在pH8.5于25℃保温4小时或在25—30℃于pH8.0保温3小时是稳定的.反应液中加入Fe~(3+)(1.5 mmol/L)可使酶活力增加 50%,而加入NH_4~+(300 mmol/L)则使酶活降低了67%.Ag~+和 Hg(2+)”强烈地抑制酶反应活性,在浓度均为 5mmol/L时,抑制率分别为99.7%和100%.NaCN(50 mmol/L)和苯甲腈(100 mmol/L)对酶活性的抑制率分别为78%和85%.该酶作用于 3-氰基吡啶的Km为62.5 mmol/L,V_(max)为85.8 μmol·min~(-1)·mg~(-1).     

3-氰基吡啶水合酶的纯化及性质

马红球菌ＳＨＢ－１２１胞内３－氰基吡啶水合酶经硫酸铵分级沉淀、ＤＥＡＥ－ｃｅｌｌｕｌｏｓｅ ＤＥ５２和羟基磷灰石柱层析并经过Ｓｅｐｈａｄｅｘ Ｇ－２５处理,得到了聚丙烯酰胺凝胶电泳均一的３－氰基吡啶水合酶,纯化了３１倍。该酶由一条肽链组成,棋 分子量为３０ｋＤ,等电点４．１,３－氰基吡啶水合酶能催化３－氰基吡啶水合生成尼克酰胺。酶反应最适ＰＨ为８．０,最适温度为３０℃,Ａｇ＾＋、Ｈｇ＾２＋、Ｃｕ＾     

棒状杆菌腈水合酶的形成条件

本文研究了棒状杆菌(cORYNEBACTERIUM)ZBB-2l腈水合酶形成的最适条件。在培养基中加入Fe2+、维生素B1和L-谷氨酸等,并以n-丁腈做诱导物,可明显促进该菌腈水合酶的生物合成。ZBB-21菌在选定的培养基中,于28℃培养64小时,其腈水合酶比活力可达83．1u／mg,而酰胺酶的比活力只有1．1u／mg。腈水合酶比活力比以前报道的提高9倍。     

腈水解酶psn基因工程菌的发酵及产酶条件优化

来自恶臭假单胞菌的腈水解酶具有高效催化3-氰基吡啶产烟酸的能力,对表达该酶的基因psn进行发酵和产酶条件优化,通过对C源、N源、磷酸盐、金属离子、温度、诱导剂浓度和诱导时间进行单因素考察,获得最适培养基条件(g/L):葡萄糖5、蛋白胨15、酵母粉5、(NH4)2SO45、K2HPO424.5、KH2PO45.76、MgSO40.48;最佳诱导条件:培养2.5 h后添加IPTG诱导,浓度0.2 mmol/L,诱导温度30℃。在该条件下培养,重组大肠杆菌的腈水解酶比酶活可达到45.67 U/mL,比优化前提高了2.26倍。在此基础上,于5 L发酵罐上进行C、N源的补料研究,获得最适分批补料策略,发现其腈水解酶活力可达到75.40 U/mL,是优化前的3.74倍。     

一类生物催化剂——氰基耐受型腈水合酶

氰基耐受型腈水合酶是一类生物催化剂。与普通腈水合酶相比,它能够耐受体系中较高浓度的氰基而不受抑制,从而为α-羟(氨)基酰胺的工业化合成开辟了崭新途径。研究腈水合酶的氰基耐受性机理及提高其耐受能力是目前需要解决的关键问题。综述了腈水合酶受氰基抑制的机制,氰基耐受型腈水合酶的发现以及其在蛋氨酸和2-羟基异丁酰胺生物合成中的应用。同时,对今后氰基耐受型腈水合酶基础、应用研究的思路进行了探讨。     

漆酶高产工程菌构建及漆酶对RBBR的脱色作用

研究提取产漆酶白腐菌 (Fomelignosus)的总RNA ,利用RT PCR克隆到漆酶的cDNA ,并将其克隆到表达载体pGAPZA ,重组质粒经线性化、电激转化PichiapastorisGS115、通过底物显色反应筛选漆酶生产工程菌株 ,在最适培养条件下该菌株产酶活力高达 9 0 3U·mL-1。纯化得到漆酶对RBBR(RemazolbrilliantblueR)有很好的脱色作用 ,该酶的最适脱色pH为 5 0 ,最适脱色温度为 30℃。当溶液中漆酶活力为 1 0U·mL-1,在最适脱色条件下作用12h ,10 0mg·L-1RBBR溶液脱色率可达 90 %以上。     

具有差向选择性还原(R)-6-氰基-5-羟基-3-羰基己酸叔丁酯活性的微生物菌株筛选和鉴定

从土样中分离得到一株具有差向选择性还原(R)-6-氰基-5-羟基-3-羰基己酸叔丁酯活性的微生物菌株ZJB-09225,经生理生化特征鉴定和18S rDNA测序后鉴定为卡里比克毕赤酵母(Pichia caribbic ZJB-09225)。研究结果发现,在最适发酵条件下培养32 h,生物量为8.8 g/L,体积酶活达7.2 U/L;P.caribbic ZJB-09225最适作用温度、最适作用pH值分别为35℃和7.5。在最适的催化条件下,P.caribbic ZJB-09225细胞催化50.0 g/L(R)-6-氰基-5-羟基-3-羰基己酸叔丁酯3 h后,产物6-氰基-(3R,5R)-二羟基己酸叔丁酯得率3.4%,产物d.e.值99.5%以上。     

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.     

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.     

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.     

Efficient inducible expression of nitrile hydratase in Corynebacterium glutamicum

Nitrile hydratases are important industrial catalysts to produce valuable amides. In this study, we describe a comprehensive and systematic approach to the development of an inducible expression system for enhanced nitrile hydratase expression in Corynebacterium glutamicum. Through promoter engineering, codon optimization and design of ribosome binding site sequences, the nitrile hydratase activity toward 3-cyanopyridine was improved from 0.33 U/mg DCW to 12.03 U/mg DCW in shake-flask culture. By introduction of the novel inducible mmp expression system, the nitrile hydratase activity was further elevated to 14.97 U/mg DCW. Finally, a high nitrile hydratase yield of 1432 U/mL was achieved in a fed-batch fermentation process and used for nicotinamide production. These results provide new insights for the development of heterologous protein expression systems in C. glutamicum.     

Isolation and characterization of a bacterium possessing a novel aldoxime-dehydration activity and nitrile-degrading enzymes

A bacterial strain capable of utilizing E-pyridine-3-aldoxime as a nitrogen source was isolated from soil after a 4-month acclimation period and was identified as Rhodococcus sp. The strain contained a novel aldoxime dehydration activity that catalyzed a stoichiometric dehydration of E-pyridine-3-aldoxime to form 3-cyanopyridine. The enzyme activity was induced by various aldoximes and nitriles. The strain metabolized the aldoxime as follows: E-pyridine-3-aldoxime was dehydrated to form 3-cyanopyridine, which was converted to nicotinamide by a nitrile hydratase, and the nicotinamide was successively hydrolyzed to nicotinic acid by an amidase. Received: 21 January 1998 / Accepted: 12 May 1998     

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.     

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).     

Optimum culture conditions for the production of cobalt-containing nitrile hydratase by Rhodococcus rhodochrous J1

Summary We sought the optimum conditions for production of nitrile hydratase by Rhodococcus rhodochrous J1. The addiiion of both cobalt ions and an aliphatic nitrile or amide as an inducer was indispensable for the appearance of nitrile hydratase activity in R. rhodochrous J1 cells. Crotonamide was an efficient inducer and, moreover, urea was found to be the most powerful inducer for the production of nitrile hydratase. When R. rhodochrous J1 was cultivated under optimal conditions, the enzyme activity in the culture broth and the specific activity was approximately 32,000 and 512 times higher than the initially obtained levels, respectively. The nitrile hydratase formed corresponded to more than 45% of the total soluble protein in urea-induced cells, as judged by quantitative evaluation of the gel track.Offprint requests to: T. Nagasawa     

Expression of nitrile hydratase gene of mutant 4D strain of Rhodococcus rhodochrous PA 34 in Pichia pastoris

The nitrile hydratase (NHase) gene of Rhodococcus rhodochrous PA-34 mutant 4D has been amplified by PCR, cloned and expressed in Pichia pastoris KM-71 using pHIL-D2 expression vector. The recombinant P. pastoris KM-71 exhibited active expression of the nitrile hydratase gene of the mutant 4D and has shown very good potential for the transformation of 3-cyanopyridine to nicotinamide. The recombinant P. pastoris KM-71 exhibited maximum NHase activity when cultivated in YPD medium was supplemented with 0.4?mM cobalt ions. The recombinant P. pastoris KM-71 showed maximum nitrile hydratase enzyme production, when incubated at 30?°C for 15?h.     

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.