阿魏酸酯酶基因工程菌研究进展

阿魏酸酯酶能水解阿魏酸、多聚阿魏酸与木聚糖以及木质素之间形成的酯键,有利于植物细胞壁的降解。介绍阿魏酸酯酶的微生物来源、阿魏酸酯酶基因工程菌构建和阿魏酸酯酶与其他酶相互协同作用等的研究进展。     

阿魏酸酯酶A的基因克隆与表达及其水解产物的纯化

为在毕赤酵母中表达来源于米曲霉Aspergillus oryzae的A型阿魏酸酯酶并研究其水解功能,探讨大孔树脂对其水解产物阿魏酸的纯化条件及纯化效果,以米曲霉A.oryzae CICC 40186总RNA为模板,通过RT-PCR技术克隆出了米曲霉阿魏酸酯酶A(AorFaeA)成熟肽的编码基因AorfaeA,并借助pPIC9K质粒实现了其在毕赤酵母GS115中的异源表达。SDS-PAGE分析结果显示纯化后的重组阿魏酸酯酶(reAorFaeA)为单一条带,其表观分子质量约39.0 kDa。以阿魏酸甲酯为底物,经高效液相色谱法测得该酶的最高酶活为58.35 U/mg。利用reAorFaeA和木聚糖酶复合酶水解去淀粉麦麸制备阿魏酸,用大孔树脂纯化小麦麸皮阿魏酸粗提液,所测树脂中HPD-300型大孔树脂的吸附量和解吸率较高,以50%的乙醇为洗脱液,当流速为1.0 mL/min时洗脱效果较好。在该纯化条件下,阿魏酸的回收率为92%,质量分数由原材料中的0.13%富集提高到10.55%。这些研究为阿魏酸的酶法"绿色生产"及应用奠定了坚实的理论基础。     

阿魏酸酯酶基因克隆表达调控及其应用进展

阿魏酸酯酶作为微生物降解植物多糖的酶系的一部分,其从细胞壁中降解多糖获得芳香酸和单多糖的能力越来越受到重视.主要介绍了阿魏酸酯酶研究进展,包括阿魏酸酯酶的研究现状,酶-底物分子对接模型、阿魏酸酯酶基因克隆表达、重组与调控以及应用.     

来自桔青霉的阿魏酸酯酶的分离纯化、理化性质

【目的】从桔青霉的发酵液中分离纯化了胞外阿魏酸酯酶(PcFAE)并进行了酶学性质的研究,初步探讨了PcFAE对麦糟的酶解作用。【方法】利用(NH4)2SO4沉淀、DEAE-Sepharose Fast Flow离子交换层析、Phenyl Sepharose6Fast Flow疏水层析纯化得到电泳纯的阿魏酸酯酶。【结果】从该菌株的发酵液中获得一阿魏酸酯酶,该酶亚基分子量约为31kDa,全酶分子量约为58kDa。其最适pH为6.0,最适温度为45℃-65℃,在pH5.0-6.0及25℃-55℃之间,酶保持了较好的稳定性。Mg2+、Fe2+、Mn2+、Ca2+和Na+对酶活有一定的促进作用,Zn2+对PcFAE酶活有一定的抑制作用,而Cu2+、亮抑肽素、抑肽酶有显著的抑制作用,Hg2+、苯甲基磺酰氟几乎完全抑制了酶活。EDTA对PcFAE活性无明显影响。PcFAE的kcat/Km对香豆酸甲酯、芥子酸甲酯、阿魏酸甲酯、咖啡酸甲酯的值分别为823、416、103、0,PcFAE对MpCA的催化效率最高。PcFAE作用于麦糟,当5U PcFAE/g麦糟时,其阿魏酸的释放量为7.2%。【结论】获得了一阿魏酸酯酶,其理化性质与至今报道的阿魏酸酯酶有所不同,为阿魏酸酯酶的开发提供了重要的实验依据。     

一组厌氧真菌菌系产阿魏酸酯酶的初步研究

利用玉米秸秆粉为唯一碳源的筛选培养基,从肉牛瘤胃液中筛选构建了一组厌氧真菌菌系,研究了该菌系产阿魏酸酯酶的特征.阿魏酸酯酶的最适pH为8.0,最适温度为40℃,最高酶活力为19.1 mU/mL,在pH 6.0 ～8.0及35～45℃之间,酶活性保持相对稳定.Mg2+对酶活力具有激活作用,Fe2、Cu2+、Fe3+等均抑制酶活力.     

阿魏酸酯酶和纤维素酶在水解汽爆稻草中的协同作用

利用阿魏酸酯酶, 水解天然木质纤维素原料中半纤维素与木质素之间的阿魏酸酯键, 从破坏两者共价键连接的角度, 探索阿魏酸酯酶促进纤维素酶水解汽爆稻草中纤维素的可行性。结果显示, 当阿魏酸酯酶加入量为240 mu/g底物、水解72 h时, 汽爆稻草纤维素的酶解率、不溶性底物失重率较不加阿魏酸酯酶分别增加了32.00%、32.77%; 阿魏酸酯酶(300 mu/g底物)作用120 min后, 纤维素酶对汽爆稻草纤维素的酶解率、不溶性底物失重率分别增加了29.85%、32.48%。通过比较不同酶法处理后的汽爆稻草的可及度和红外光谱图发现, 阿魏酸酯酶能有效地水解原料中的酯键, 提高原料可及度50%以上。由此表明, 阿魏酸酯酶和纤维素酶之间存在较大的协同作用, 添加阿魏酸酯酶能够提高纤维素酶对天然木质纤维素的酶解效率。     

黑曲霉h408阿魏酸酯酶基因的克隆及在毕赤酵母中的高效表达

【目的】实现在巴斯德毕赤酵母(Pichia pastoris)中高效表达黑曲霉(Aspergillus niger)h408阿魏酸酯酶A基因(AnfaeA),并对重组酶特性进行表征。【方法】采用重叠延伸PCR扩增黑曲霉h408的阿魏酸酯酶A基因。将AnfaeA基因和毕赤酵母表达载体pPIC9K连接,成功构建重组质粒pPIC9K-Anfae,经线性化后电转化P.pastoris GS115,透明圈法筛选活性高的转化子后进行诱导表达。利用紫外吸收法测定温度及pH对重组阿魏酸酯酶活性的影响。【结果】成功从A.niger h408中克隆得到阿魏酸酯酶A的cDNA基因(GenBank:KF911349),并实现了其在P.pastoris GS115中的高效表达。该基因长度为783bp,含有1个开放阅读框架(ORF),编码260个氨基酸,Blast分析显示该基因和GenBank中黑曲霉阿魏酸酯酶序列同源性为99%。翻译的氨基酸序列含有脂酶典型的活性盖子和催化三联体结构。从转化板上获得1株编号为pPIC9K-Anfae5的转化子阿魏酸酯酶活性最高,酶活达24.72 U/mL,比活力为40.84 U/mg,比黑曲霉出发菌株(22.1 mU/mL)提高了1100倍左右。重组阿魏酸酯酶的最适pH为5.0,且在pH 4.0-9.0稳定性较好;最适反应温度50℃,在40-60℃时较稳定。【结论】阿魏酸酯酶在毕赤酵母中的高效分泌表达为其在饲料工业和造纸工业等工业化应用提供了前提,也为后续改进酶学特性的定向进化奠定实验基础。     

黑曲霉阿魏酸酯酶基因密码子优化及在毕赤酵母中的高效表达

【目的】对黑曲霉(Aspergillus niger)阿魏酸酯酶基因进行克隆和密码子优化,使其在毕赤酵母(Pichia pastoris X-33)中高效表达。【方法】以黑曲霉基因组为模板,经重叠延伸PCR扩增得到阿魏酸酯酶基因(Anfae A),并对Anfae A基因进行毕赤酵母密码子偏好性"随机优化"和"一对一优化",全基因合成后分别与表达载体pPICZαA连接,构建表达载体pPICZαA-Anfae A、pPICZαA-op Anfae A I和pPICZαA-op Anfae A II。经Sac I线性化后电转化至P.pastoris X-33中,筛选阳性转化子。摇瓶发酵4.5 d后,测定并比较重组阿魏酸酯酶(re Anfae A)酶活。【结果】密码子优化前阿魏酸酯酶酶活为6.8±0.1 U/m L,基因"一对一优化"和"随机优化"后的重组酶酶活分别为5.2±0.1 U/m L和39.9±0.1 U/m L,"随机优化"后酶活比优化前提高了近6倍,而"一对一优化"后酶活仅为优化前酶活的76.5%。重组阿魏酸酯酶的最适p H为5.5,且在pH 4.5-7.0稳定性较好;最适反应温度50°C,在45-50°C较稳定。【结论】阿魏酸酯酶基因经密码子"随机优化"后进行重组表达,酶活显著提高,对研究阿魏酸酯酶在毕赤酵母及其它宿主中的高效表达具有一定的借鉴意义,也为大规模工业化应用奠定了基础。     

1株阿魏酸酯酶产生菌的筛选鉴定及发酵条件优化

从浙江绍兴鉴湖附近土样中分离筛选到1株产阿魏酸酯酶(ferulic acid esterase,FAE)的菌株FD-8,通过菌落形态、分生孢子梗形态对比和ITS/18S rDNA分子生物学同源性分析,鉴定该菌株为溜曲霉,命名为Aspergillus tamarii FD-8。FD-8生长最适碳源和氮源分别为蔗糖和酵母浸提物,最适生长温度和pH分别为32℃和5.0,最适产酶条件为32℃、pH 6.0,发酵周期为120 h。在最适培养基中、分阶段控制pH培养条件下,FAE比酶活达到231.34 mU/mg。去淀粉麸皮可诱导FAE的合成,在发酵48 h添加20.0 g/L去淀粉麸皮,FAE最高比酶活可达到573.61 mU/mg,比对照提高1.48倍。     

黑曲霉阿魏酸酯酶在毕赤酵母中的组成型表达

【目的】实现黑曲霉来源的阿魏酸酯酶在毕赤酵母(Pichia pastoris GS115)中的组成型表达。【方法】以黑曲霉(Aspergillus niger)基因组为模板,经重叠延伸PCR扩增得到阿魏酸酯酶基因(AnfaeA),将其与载体pGAP9K相连,构建重组表达载体p GAP9KAnfae A,经SalI线性化后电转入毕赤酵母GS115中,得到重组菌株。高效液相色谱法测定发酵液中阿魏酸酯酶活力,并对重组菌进行了发酵优化。【结果】克隆得到783 bp的阿魏酸酯酶编码基因并实现了其在毕赤酵母中的组成型表达。重组菌发酵84 h后,上清液中酶活达5.72±0.10 U/m L。重组酶(reAnfaeA)经分离纯化后比酶活为59.75 U/mg,大小约为40 k D。发酵优化结果为:葡萄糖40.0 g/L,蛋白胨10.0 g/L,酵母膏30.0 g/L,CaCO_3 0.2 g/L,种龄28 h,接种量3%(体积比),装液量50 m L/250 m L。在此条件下发酵培养,酶活达15.60±0.23 U/m L。【结论】阿魏酸酯酶在毕赤酵母中的组成型表达,对研究毕赤酵母组成型表达系统和阿魏酸酯酶的发酵生产具有一定的借鉴意义。     

Measurement of feruloyl/p-coumaroyl esterase by capillary zone electrophoresis

Ferulic andp-coumaric acid can be separated from their corresponding aliphatic methyl esters by capillary zone electrophoresis, which allows the convenient determination of feruloyl andp-coumaroyl esterase activities using synthetic esters as substrates. A feruloyl-containing sugar ester from wheat bran was also efficiently separated and used as substrate for the enzyme assays.Penicillium expansum was shown to produce feruloyl/p-coumaroyl esterase activity when grown on wheat bran in solid-state culture.The authors are with the Food Microbiology Research Division, Department of Agriculture for Northern Ireland, Newforge Lane, Belfast BT9 5PX, UK; A.M. McKay is also affiliated with the Department of Food Science (Microbiology), The Queen's University of Belfast, Newforge Lane, Belfast BT9 5PX, UK.     

Xylanase and feruloyl esterase from actinomycetes cultures could enhance sugarcane bagasse hydrolysis in the production of fermentable sugars

The addition of enzymes that are capable of degrading hemicellulose has a potential to reduce the need for commercial enzymes during biomass hydrolysis in the production of fermentable sugars. In this study, a high xylanase producing actinomycete strain (Kitasatospora sp. ID06-480) and the first ethyl ferulate producing actinomycete strain (Nonomuraea sp. ID06-094) were selected from 797 rare actinomycetes, respectively, which were isolated in Indonesia. The addition (30%, v/v) of a crude enzyme supernatant from the selected strains in sugarcane bagasse hydrolysis with low-level loading (1 FPU/g-biomass) of Cellic® CTec2 enhanced both the released amount of glucose and reducing sugars. When the reaction with Ctec2 was combined with crude enzymes containing either xylanase or feruloyl esterase, high conversion yield of glucose from cellulose at 60.5% could be achieved after 72 h-saccharification.     

Administration of Lactobacillus fermentum CRL1446 increases intestinal feruloyl esterase activity in mice

Aims: To evaluate the effect of oral administration of Lactobacillus fermentum CRL1446 on the intestinal feruloyl esterase (FE) activity and oxidative status of mice. Methods and Results: Adult Swiss albino mice received Lact. fermentum CRL1446 at the doses 10⁷ and 10⁹ cells per day per mouse for 2, 5, 7 and 10 days. Intestinal FE activity, intestinal microbiota counts, plasmatic thiobarbituric acid‐reactive substances (TBARS) percentage and glutathione reductase (GR) activity were determined. Mice that received Lact. fermentum CRL1446 at the dose 10⁷ cells per day for 7 days showed a twofold increase in total intestinal FE activity, compared to the nontreated group. In large intestine content, FE activity increased up to 6·4 times. No major quantitative changes in colonic microbiota were observed in treated animals. Administration of this strain produced an approx. 30–40% decrease in the basal levels of plasmatic TBARS and an approx. twofold increase in GR activity from day 5 of feeding with both doses. Conclusions: Oral administration of Lact. fermentum CRL1446 to mice increases total intestinal FE activity, decreases the basal percentage of plasmatic lipoperoxides and increases GR activity. Significance and Impact of the Study: Lactobacillus fermentum CRL1446 could be orally administered as a dietary supplement or functional food for increasing the intestinal FE activity to enhance the bioavailability of ferulic acid, thus improving oxidative status.     

Synthesis of pentylferulate by a feruloyl esterase from Aspergillus niger using water-in-oil microemulsions

Pentylferulate synthesis was achieved at high yields (50–60%) with Aspergillus niger feruloyl esterase using a water-in-oil microemulsion system. The initial rate of synthesis decreased by 15–20% when the water content of the microemulsion was increased from 1.8 to 2.4% (v/v), although a concomitant decrease in conversion was not observed. The enzyme stability was significantly higher in the microemulsion than in an aqueous solution.     

The crystal structure of feruloyl esterase A from Aspergillus niger suggests evolutive functional convergence in feruloyl esterase family

As a component of the array of enzymes produced by micro-organisms to deconstruct plant cell walls, feruloyl esterases hydrolyze phenolic groups involved in the cross-linking of arabinoxylan to other polymeric structures. This is important for opening the cell wall structure, making material more accessible to glycosyl hydrolases. Here, we describe the first crystal structure of the non-modular type-A feruloyl esterase from Aspergillus niger (AnFaeA) solved at 2.5A resolution. AnFaeA displays an alpha/beta hydrolase fold similar to that found in fungal lipases and different from that reported for other feruloyl esterases. Crystallographic and site-directed mutagenesis studies allow us to identify the catalytic triad (Ser133-His247-Asp194) that forms the catalytic machinery of this enzyme. The active-site cavity is confined by a lid (residues 68-80), on the analogy of lipases, and by a loop (residues 226-244) that confers plasticity to the substrate-binding site. The lid presents a high ratio of polar residues, which in addition to a unique N-glycosylation site stabilises the lid in an open conformation, conferring the esterase character to this enzyme. A putative model for bound 5,5'-diferulic acid-linked arabinoxylan has been built, pointing to the more relevant residues involved in substrate recognition. Comparison with structurally related lipases reveals that subtle amino acid and conformational changes within a highly conserved protein fold may produce protein variants endowed with new enzymatic properties, while comparison with functionally related proteins points to a functional convergence after evolutionary divergence within the feruloyl esterases family.     

Characterization of four esterase genes and esterase activity from the gut of the termite Reticulitermes flavipes

Four esterase genes and general esterase activity were investigated in the gut of the termite Reticulitermes flavipes. Two genes (RfEst1 and RfEst2) share significant translated identity with a number of insect JH esterases. The two remaining genes (RfEst3 and RfEst4) apparently code for much shorter proteins with similarity to fungal phenolic acid esterases involved in hemicellulose solubilization. All four genes showed consistently high midgut expression. This result was further supported by colorimetric activity assays and Native polyacrylamide gel electrophoresis, which showed significant esterase activity and a number of isoforms in the midgut. The greatest esterase activity and isoform composition were detected when α‐naphthyl propionate was used as a substrate. Moreover, esterase activity and diverse isoforms were present in gut mitochondrial, microsomal, and cytosolic sub‐cellular protein fractions, as well as in the hindgut lumen. These findings reveal an agreement between gut esterase gene expression and activity distributions, and support the idea that R. flavipes gut esterase activity is host (not symbiont)‐derived. In addition, these findings support the hypotheses that termite gut esterases may play important roles in lignocellulose digestion and caste differentiation. This study provides important baseline data that will assist ongoing functional‐genomic efforts to identify novel genes with roles in semiochemical, hormone, and lignocellulose processing in the termite gut. © 2009 Wiley Periodicals, Inc.     

Structure of the catalytic domain of glucuronoyl esterase Cip2 from Hypocrea jecorina

The structure of the catalytic domain of glucuronoyl esterase Cip2 from the fungus H. jecorina was determined at a resolution of 1.9 ?. This is the first structure of the newly established carbohydrate esterase family 15. The structure has revealed the residues Ser278-His411-Glu301 present in a triad arrangement as the active site. Ser278 is present in the novel consensus sequence GCSRXG reported earlier in the members of CE-15 family. The active site is exposed on the surface of the protein which has implications for the ability of the enzyme to hydrolyze ester bonds of large substrates. Efforts are underway to obtain crystals of Cip2_GE complexed with inhibitor and synthetic substrates. The activity of the glucuronoyl esterase could play a significant role in plant biomass degradation as its expected role is to separate the lignin from hemicelluloses by hydrolysis of the ester bond between 4-O-methyl-D-glucuronic acid moieties of glucuronoxylans and aromatic alcohols of lignin.     

Crystal structure of a feruloyl esterase belonging to the tannase family: A disulfide bond near a catalytic triad

Feruloyl esterase (FAE) catalyzes the hydrolysis of the ferulic and diferulic acids present in plant cell wall polysaccharides, and tannase catalyzes the hydrolysis of tannins to release gallic acid. The fungal tannase family in the ESTHER database contains various enzymes, including FAEs and tannases. Despite the importance of FAEs and tannases in bioindustrial applications, three‐dimensional structures of the fungal tannase family members have been unknown. Here, we determined the crystal structure of FAE B from Aspergillus oryzae (AoFaeB), which belongs to the fungal tannase family, at 1.5 Å resolution. AoFaeB consists of a catalytic α/β‐hydrolase fold domain and a large lid domain, and the latter has a novel fold. To estimate probable binding models of substrates in AoFaeB, an automated docking analysis was performed. In the active site pocket of AoFaeB, residues responsible for the substrate specificity of the FAE activity were identified. The catalytic triad of AoFaeB comprises Ser203, Asp417, and His457, and the serine and histidine residues are directly connected by a disulfide bond of the neighboring cysteine residues, Cys202 and Cys458. This structural feature, the “CS‐D‐HC motif,” is unprecedented in serine hydrolases. A mutational analysis indicated that the novel structural motif plays essential roles in the function of the active site. Proteins 2014; 82:2857–2867. © 2014 Wiley Periodicals, Inc.