N-氨甲酰基-D-氨基酸酰胺水解酶的快速纯化及性质

通过硫酸铵分级沉淀、疏水层析及阴离子交换层析等三步 ,有效地从一菌株NO .2 2 6 2中纯化了N 氨甲酰基 D 氨基酸酰胺水解酶。结果表明 ,酶活性回收约 2 0 %,纯化了 8 4倍。天然PAGE与SDS PAGE分析表明 ,该酶分子为同源四聚体 ,单体分子量约为 3 5kD。酶催化反应的最适pH为 7 7～ 8 0 ,最适温度为 45℃。以N 氨甲酰 DL 丙氨酸为底物时 ,Km =1 3×1 0 - 3 mol L ,Vmax=0 .3 3mol min。二价金属离子Ni2 + 有激活作用 ,Zn2 + 有明显的抑制作用 ,而Co2 + 对酶活无影响。该酶N 末端 8个氨基酸残基依次为TRQKILAF。     

节杆菌BT801 N-氨甲酰氨基酸水解酶基因的克隆与表达

通过PCR从质粒pUC18 16 9中扩增得到N 氨甲酰氨基酸水解酶基因 (hyuC) ,置于原核表达载体pQE6 0的T5启动子下游构成表达质粒pQE6 0 hyuC ,并在大肠杆菌M15中实现了该基因的高表达。SDS PAGE检测表达产物 ,在相对分子量 44kD处有一表达带 ,经薄层扫描分析目的蛋白占全菌蛋白的 40 % ,主要以可溶性形式存在。酶活性分析结果表明 ,工程菌M15 pQE6 0 hyuC的N 氨甲酰氨基酸水解酶的比活分别比原始菌株ArthrobacterBT80 1和亚克隆DH5α pUC18 16 9提高了 5 2倍和 72倍。在节杆菌BT80 1和大肠杆菌DH5α pUC18 16 9的反应体系中加入等量菌体的工程菌M15 pQE6 0 hyuC ,可使乙内酰脲酶总比活分别提高 8 1倍和 3 0倍。     

节杆菌BT801 N-氨甲酰氨基酸水解酶基因的克隆与表达

通过PCR从质粒pUC18-169中扩增得到N-氨甲酰氨基酸水解酶基因（hyuC）,置于原核表达载体pQE60的T5启动子下游构成表达质粒pQE60-hyuC,并在大肠杆菌M15中实现了该基因的高表达。SDS-PAGE检测表达产物,在相对分子量44kD处有一表达带,经薄层扫描分析目的蛋白占全菌蛋白的40%,主要以可溶性形式存在。酶活性分析结果表明,工程菌M15/pQE60-hyuC的N氨甲酰氨基酸水解酶的比活分别比原始菌株Arthrobacter BT801和亚克隆DH5α/pUC18-169提高了52倍和72倍。在节杆菌BT801和大肠杆菌DH5α/pUC18-169的反应体系中加入等量菌体的工程菌M15/pQE60-hyuC,可使乙内酰脲酶总比活分别提高8.1倍和3.0倍。     

N-氨甲酰基-D-氨基酸酰胺水解酶的快速纯化及性质

通过硫酸铵分级沉淀、疏水层析及阴离子交换层析等三步 ,有效地从一菌株NO .2 2 6 2中纯化了N 氨甲酰基 D 氨基酸酰胺水解酶。结果表明 ,酶活性回收约 2 0 %,纯化了 8 4倍。天然PAGE与SDS PAGE分析表明 ,该酶分子为同源四聚体 ,单体分子量约为 3 5kD。酶催化反应的最适pH为 7 7～ 8 0 ,最适温度为 45℃。以N 氨甲酰 DL 丙氨酸为底物时 ,Km =1 3×1 0 - 3 mol L ,Vmax=0 .3 3mol min。二价金属离子Ni2 + 有激活作用 ,Zn2 + 有明显的抑制作用 ,而Co2 + 对酶活无影响。该酶N 末端 8个氨基酸残基依次为TRQKILAF。     

N-氨甲酰基氨基酸水解酶在毕赤酵母中的表达

N-氨甲酰氨基酸水解酶是乙内酰脲酶系的组成部分,催化N-氨甲酰氨基酸水解为相应氨基酸。节杆菌BT801的N-氨甲酰氨基酸水解酶是该菌乙内酰脲酶系中惟一具立体专一性的酶,也是整个反应体系的限速酶。通过PCR从携带乙内酰脲酶系完整操纵子的亚克隆质粒pUC18-169上扩增得到N-氨甲酰氨基酸水解酶基因(hyuC)片段,连接到载体pPIC3.5K上,经BglⅡ酶切线性化,通过PEG法转化导入毕赤酵母GS115感受态细胞,利用G418抗性筛选得到插入多拷贝目的基因的转化子。酶活性分析表明所得转化子具     

异源D-海因酶和N-氨甲酰水解酶共表达重组枯草芽孢杆菌的构建

【目的】构建异源D-海因酶和N-氨甲酰水解酶共表达的重组枯草芽孢杆菌,探讨其作为全细胞催化剂合成D-对羟基苯甘氨酸的可行性。【方法】采用P_(aco)表达盒表达D-海因酶基因hyd或sd1,采用P_(AE)表达盒表达N-氨甲酰水解酶基因adc。分别以质粒pHP13和pUB110为载体,构建D-海因酶和N-氨甲酰水解酶共表达质粒pHCS、pHCY和pUCS。在受体菌中整合表达了acoR和sigL基因,敲除了skf和sdp基因。将共表达质粒分别转化不同的受体菌,通过测定全细胞催化活性,表征D-海因酶和N-氨甲酰水解酶共表达的效果。【结果】带有质粒pHCY和pHCS的重组菌,全细胞催化活性分别为0.21 U/mL和0.31 U/mL。整合表达acoR和sigL基因以及高拷贝质粒pUCS,使全细胞催化活性达到1.0 U/mL。【结论】异源D-海因酶和N-氨甲酰水解酶在枯草芽孢杆菌中能够正确表达。基因拷贝数、acoR和sigL基因表达水平,及skf和sdp基因缺失对重组菌的催化活性具有显著影响。     

N-氨甲酰基-D-氨基酸酰胺水解酶的固定化工艺

以TJS环氧基树脂作为载体对N-氨甲酰基-D-氨基酸酰胺水解酶进行固定化,最佳工艺条件为：1g树脂载体大约对应133U酶液,蛋白质量浓度0.35mg/mL,固定时间15h,温度28℃,pH7.5,固定化酶活达到58.5U。蛋白固定率可达97.4%,酶活回收率达到49.3%,得到的固定化酶使用半衰期达到26批。     

定点突变提高D-氨甲酰水解酶的可溶性表达

采用定点突变的方法对皮氏伯克霍尔德氏菌(Burkholderia pickettii)来源的D-氨甲酰水解酶(D-carbamoylase,DCase)编码基因的3个位点A18、Y30、K34进行突变,并将获得的突变体基因片段构建入高表达载体pET-28b中,转化E coli BL21( DE3),获得带有组合三突变(A18E/Y30D/K34E)的DCase-SM表达菌株BL21/pET-DCSM.当以IPTG诱导目的蛋白表达时,发现突变菌株(DCase-SM)与出发菌株(DCase)菌株相比,目的蛋白的可溶性表达显著提高,其可溶蛋白比例约为64％;与出发菌株相比,其单位菌体酶活增加427％;另外,与本实验室前期构建的高可溶性三叠加突变体菌株DCase-M3相比,单位菌体酶活亦增加7.9％.     

海因酶与氨甲酰水解酶产生菌的鉴定及分布

利用Biolog微生物鉴定系统和16S rDNA序列分析相结合的方法对自行筛选的24株海因酶和氨甲酰水解酶产生菌进行了鉴定。海因酶与氨甲酰水解酶产生菌主要分布在Bacillus,Geobacillus,Brevibacillus,Aneurinibacillus,Microbacterium,Pseudomonas,Kurthia和Empedobacter等菌属,特别的是,Kurthia和Empedobacter是新的海因酶和氨甲酰水解酶产生菌属,说明海因酶和氨甲酰水解酶产生菌在细菌中分布较广泛。进一步分析比较发现,D-海因酶产生菌主要分布于Pseudomonas,Agrobacterium等菌属中,而大部分L-海因酶产生菌分布于Bacillus,Geobacillus,Microbacterium等菌属中,说明D-海因酶产生菌与L-海因酶产生菌分布特点具有一定的种属倾向性。这些工作不仅提供了多种海因酶和N-氨甲酰水解酶的生物材料,而且对双酶的结构与功能及分子进化研究等具有重要意义。     

四季豆幼苗尿囊酸酰胺水解酶的纯化和性质研究(简报)

从四季豆幼苗提取、部分纯化尿囊酸酰胺水解酶,分离出两个同功酶：一分子量同功酶（尿圳酸酰胺水解酶Ⅰ）,另一为小分子量同功酶（尿囊酸酰胺水解酶Ⅱ）,并对后者的性质进行研究。     

Structural basis for catalysis and substrate specificity of Agrobacterium radiobacter N-carbamoyl-D-amino acid amidohydrolase

N-Carbamoyl-d-amino acid amidohydrolase is an industrial biocatalyst to hydrolyze N-carbamoyl-d-amino acids for producing valuable d-amino acids. The crystal structure of N-carbamoyl-d-amino acid amidohydrolase in the unliganded form exhibits a alpha-beta-beta-alpha fold. To investigate the roles of Cys172, Asn173, Arg175, and Arg176 in catalysis, C172A, C172S, N173A, R175A, R176A, R175K, and R176K mutants were constructed and expressed, respectively. All mutants showed similar CD spectra and had hardly any detectable activity except for R173A that retained 5% of relative activity. N173A had a decreased value in kcat or Km, whereas R175K or R176K showed high Km and very low kcat values. Crystal structures of C172A and C172S in its free form and in complex form with a substrate, along with N173A and R175A, have been determined. Analysis of these structures shows that the overall structure maintains its four-layer architecture and that there is limited conformational change within the binding pocket except for R175A. In the substrate-bound structure, side chains of Glu47, Lys127, and C172S cluster together toward the carbamoyl moiety of the substrate, and those of Asn173, Arg175, and Arg176 interact with the carboxyl group. These results collectively suggest that a Cys172-Glu47-Lys127 catalytic triad is involved in the hydrolysis of the carbamoyl moiety and that Arg175 and Arg176 are crucial in binding to the carboxyl moiety, hence demonstrating substrate specificity. The common (Glu/Asp)-Lys-Cys triad observed among N-carbamoyl-d-amino acid amidohydrolase, NitFhit, and another carbamoylase suggests a conserved and robust platform during evolution, enabling it to catalyze the reactions toward a specific nitrile or amide efficiently.     

Purification and some properties of 1-aspartamido-beta-N-acetylglucosamine amidohydrolase from human liver.

Human liver 1-aspartamido-beta-N-acetylglucosamine amidohydrolase (aspartylglucosylaminase, EC 3.5.1.26) was purified 17 500-fold to apparent homogeneity as judged from polyacrylamide-gel disc electrophoresis. A pH optimum of 7.7-9.0 was found. The Km value was pH- and temperature-dependent. At 37 degrees C and pH 7.7, Km was 0.16 mM and it increased to 0.29 at pH 6.0 and 0.23 at pH 9.0. At 25 degrees C and pH 7.7, a Km value of 0.99 mM was obtained. When the substrate concentration was varied, apparent Michaelis-Menten kinetics were obtained. p-Hydroxymercuribenzoate, glutathione or cysteine had no effect on the enzyme activity; 5 mM-N-acetylcysteine inhibited about 47% of the total enzyme activity. Apart from Cu2+, other bivalent ions were virtually ineffective at 1 mM. The kinetic study differentiates this enzyme from aspartylglucosylaminase from other sources.     

Production of -amino acids by N-acyl- -amino acid amidohydrolase and its structure and function

-Amino acids have been widely used as synthetic materials for various compounds such as pharmaceuticals and agrochemicals. The manufacture of -amino acids by fermentation is difficult, and enzymatic methods are mainly employed. At present, the optical resolution method using N-acyl- -amino acid amidohydrolase is the most useful and convenient. In this review, the application of N-acyl- -amino acid amidohydrolase to the production of -amino acids and recent progress in the study of structure–function relationships from the standpoint of improving this enzyme for industrial application are discussed.     

Efficient production of the industrial biocatalysts hydantoinase and N-carbamyl amino acid amidohydrolase: Novel non-metabolizable inducers

Abstract The biosynthesis of the hydantoin-hydrolysing enzymes hydantoinase and N -carbamyl amino acid amidohydrolase from Agrobacterium sp. IP I-671, a Gram-negative bacterium used as a biocatalyst for the production of enantiomerically pure ( R ) amino acids, was found to be highly inducible by the addition to the cultivation medium of different non-metabolizable thiolated hydantoins or pyrimidines. Among these inducers the hexacyclic pyrimidine thioderivatives were more potent than all the pentacyclic thiohydantoin compounds. Addition of 2,4-thiouracil to the cultures, at a rate of 0.1 g (g cell dry mass)⁻¹, led to no appreciable growth inhibition and yielded a biocatalyst exhibiting a 40-fold higher hydantoinase and a 15-fold higher N -carbamyl amino acid amidohydrolase activity than the corresponding inducer-free cultures.     

Purification and some properties of camel carboxypeptidase B

A carboxypeptidase B-like enzyme was purified 116-fold with a recovery of activity of 29% from a crude extract of camel pancreas by a four-step procedure consisting of two anion exchange chromatographies in succession, gel filtration and hydrophobic interaction chromatography. The enzyme was homogeneous on SDS and non-denaturing gel electrophoresis and on gel isoelectric focusing. Its molecular mass was found to be 31.5 kDa and its isoelectric point was estimated as 6.1. It was active towards a number of substrates that are cleaved by carboxypeptidases B from other species and was also susceptible to inhibition by inhibitors of such enzymes. The camel enzyme showed a pH optimum of 8.0 and it was seen to be a relatively potent kinase in vitro. The enzyme purified in this study was very similar to carboxypeptidases B isolated from other species in size, charge, substrate specificity and susceptibility to inhibition and thus it can be identified as camel carboxypeptidase B.     

Directed evolution and structural analysis of N-carbamoyl-D-amino acid amidohydrolase provide insights into recombinant protein solubility in Escherichia coli

One of the greatest bottlenecks in producing recombinant proteins in Escherichia coli is that over-expressed target proteins are mostly present in an insoluble form without any biological activity. DCase (N-carbamoyl-D-amino acid amidohydrolase) is an important enzyme involved in semi-synthesis of beta-lactam antibiotics in industry. In the present study, in order to determine the amino acid sites responsible for solubility of DCase, error-prone PCR and DNA shuffling techniques were applied to randomly mutate its coding sequence, followed by an efficient screening based on structural complementation. Several mutants of DCase with reduced aggregation were isolated. Solubility tests of these and several other mutants generated by site-directed mutagenesis indicated that three amino acid residues of DCase (Ala18, Tyr30 and Lys34) are involved in its protein solubility. In silico structural modelling analyses suggest further that hydrophilicity and/or negative charge at these three residues may be responsible for the increased solubility of DCase proteins in E. coli. Based on this information, multiple engineering designated mutants were constructed by site-directed mutagenesis, among them a triple mutant A18T/Y30N/K34E (named DCase-M3) could be overexpressed in E. coli and up to 80% of it was soluble. DCase-M3 was purified to homogeneity and a comparative analysis with wild-type DCase demonstrated that DCase-M3 enzyme was similar to the native DCase in terms of its kinetic and thermodynamic properties. The present study provides new insights into recombinant protein solubility in E. coli.     

灵芝EIM-40漆酶的分离纯化及酶学性质

采用冻干浓缩、（NH4）2S04盐析、HiTrapphenyl（FF）疏水层析和QSepharose FastFlow离子交换层析对灵芝EIM-40发酵液进行分离纯化,获得纯化漆酶,纯化倍数为14．6,回收率为5．3％。SDS-PAGE银染的结果为单一条带,相对分子质量约为6．53×104。以愈创木酚和2,2-联氮-二（3-乙基-苯并噻唑-6-磺酸）二铵盐（ABTS）为催化底物进行酶学性质研究,最适pH分别为4．8和4．5,最适温度分别为55和50℃,2种底物在pH4．0。5．0范围内,温度低于50℃时,酶的稳定性都很好。以愈创木酚为底物,Km=645．0umol／L;以ABTS为底物,Km=22．2txmol／L。Cu2＋对该酶起激活作用,Fe2＋、Ca2＋、Ba2＋则完全抑制酶的活性。     

Production,IMAC purification,and molecular modeling of N-carbamoyl-D-amino acid amidohydrolase C-terminally fused with a six-his peptide

A six-His peptide was genetically engineered to the C-terminus of Agrobacterium radiobacter N-carbamoyl-D-amino acid amidohydrolase monomer to facilitate the protein purification with immobilized metal affinity chromatography (IMAC). The fusion enzyme, named as DCaseH, was overexpressed in Escherichia coli and one-step IMAC-purified. The production study showed that DCaseH was optimally produced at 15 degrees C for 25 h by the induction of 0.05 mM IPTG. Both Co(2+)-chelated TANOL gels and Ni(2+)-chelated nitriloacetic acid agarose gels efficiently purified DCaseH, with the former yielding purer enzyme than the latter. Highly pure DCaseH was obtained in the former purification with the addition of 5 mM imidazole in the washing buffer, and the specific enzyme activity was increased more than 11-fold. Denaturing IMAC purification successfully purified DCaseH from inclusion bodies that were mostly composed of the overexpressed DCaseH, while the attempt to refold the purified enzyme by either dialysis or solid-state refolding was not achieved. The purified native enzyme was optimally active at pH 6.5 and 50 degrees C, and the presence of 10% glycerol increased the activity. The molecular modeling of dimeric DCaseH indicated that the six-His tags were freely exposed to the protein surface, resulting in the selective and effective IMAC purification of DCaseH.