利用温控载体构建碱性果胶酯裂解酶工程菌

从筛选出的Bacillus subtilisWSHB04-02菌株中扩增出编码碱性果胶酯裂解酶的结构基因PL,将其插入载体pET22b( )多克隆位点,得到带有前导序列PelB重组质粒pET22b( )PL。以pET22b( )PL为模板扩增出带前导序列的碱性果胶酯裂解酶的结构基因PL,将其插入温控载体pHsh,重组载体在大肠杆菌JM109中得到表达。其表达量与以T7为启动子的重组菌BL21DE3[(pET22b( )PL]相比,表达量相近。SDS-PAGE分析显示表达产物的分子量均为43kDa,同核酸序列测定所推导的值相符。研究表明利用pHsh构建的JM109(pHsh PL)诱导表达好,诱导方式简单廉价,这对该酶的大规模发酵具有重要意义。     

极耐热性b-葡萄糖醛酸酶的高效表达和酶学性质及其 应用

从海栖热袍菌克隆出编码热稳定性b-葡萄糖醛酸酶基因, 以热激载体pHsh为表达质粒, 在大肠杆菌中得到高效表达。基因表达产物通过一步热处理后, 酶纯度达电泳均一。纯化重组酶酶学性质研究表明, b-葡萄糖醛酸酶的最适反应温度为80oC, 最适反应pH为5.0, pH 5.8~ 8.2之间酶的稳定性较好, 80oC的半衰期为2 h, SDS-PAGE结果显示分子量为65.9 kD, 与理论推算值相吻合。以对硝基苯-b-葡萄糖醛酸苷(pNPG)为底物时, 其动力学参数Km值0.18 mmol/L, Vmax值为312 u/mg。初步的应用分析表明, 该重组酶能催化甘草酸转化为甘草次酸。     

极端耐热纤维素酶Cel74的表达、纯化与特性

从海栖热袍菌中克隆出编码热稳定性的纤维素酶基因,以热激载体pHsh为表达质粒,构建重组质粒phsh—Ceff4,并转化至大肠杆菌中进行表达。基因表达产物通过热处理和离子交换层析,重组酶纯度达电泳纯。对纯化的重组酶酶学性质研究表明,最适反应温度85℃,最适反应pH4．6,pH4．5—6．0之间酶的相对酶活在80％以上。Co^2＋对酶活性有促进作用,Ca^2＋、Mg^2＋、Zn^2＋不影响酶活性,而Cu^2＋、Ni^2＋、Mn^2＋对酶活性有抑制作用。     

极耐热性乳酸脱氢酶高效表达、纯化及酶学性质

从海栖热袍菌扩增出编码乳酸脱氢酶的基因并将其插入热激载体pHsh构建表达质粒,在大肠杆菌Escherichia coli中进行表达产生极耐热性乳酸脱氢酶Tm-LDH。基因表达产物通过热处理,可以一步获得接近电泳纯的重组酶。酶学性质研究表明,Tm-LDH的最适反应温度为95℃,最适pH 7.0;纯酶在90℃的半衰期为2 h,在pH 5.5–8.0之间最稳定;SDS-PAGE结果显示分子量为33 kDa,与理论推算值相吻合。以丙酮酸和NADH为底物时,相对于丙酮酸的Km值1.7 mmol/L,Vmax为3.8×104 U/mg;相对于NADH的Km值7.2 mmol/L,Vmax值为1.1×105 U/mg。Tm-LDH基因在T7载体中未能实现高效表达,但是在热激载体pHsh中得到了可溶性超量表达,表达水平达到340 mg/L。该酶在65℃反应条件下,活性达到最高活性的50%,并能保持活性不变,这使该酶能够与常温酶匹配,在辅酶NAD再生体系的建立中具有广泛的用途。     

极耐热性β-葡萄糖醛酸酶的高效表达和酶学性质及其应用

从海栖热袍菌克隆出编码热稳定性β-葡萄糖醛酸酶基因,以热激载体pHsh为表达质粒,在大肠杆菌中得到高效表达。基因表达产物通过一步热处理后,酶纯度达电泳均一。纯化重组酶酶学性质研究表明,β-葡萄糖醛酸酶的最适反应温度为80℃,最适反应pH为5．0,pH5．8～8．2之间酶的稳定性较好,80℃的半衰期为2h,SDS—PAGE结果显示分子量为65.9kD,与理论推算值相吻合。以对硝基苯-β-葡萄糖醛酸苷（pN/PG）为底物时,其动力学参数Km值0.18mmol／L,Vmax值为312u／mg。初步的应用分析表明,该重组酶能催化甘草酸转化为甘草次酸。     

麻类脱胶高效菌株果胶裂解酶基因克隆与表达

【目的】克隆麻类脱胶高效菌株Dickeya sp.DCE-01的果胶裂解酶基因并进行原核表达,对表达产物进行纯化和酶学性质研究。【方法】根据该菌株全基因组序列预测的果胶裂解酶基因Q59419设计引物,PCR扩增后将该基因连接到pEASY-E1和pACYCDuet-1载体上,导入E.coli BL21(DE3)进行表达。选择酶活力高的阳性克隆子进行大量诱导表达后,采用超滤和Sephadex G-100凝胶层析两步法纯化出果胶裂解酶,研究其酶学性质。【结果】克隆到果胶裂解酶基因pel(GenBank登录号:JX964997),其序列全长1 128 bp,编码375个氨基酸。pACYCDuet-1-pel-BL表达胞外果胶裂解酶活力最高,发酵液粗酶活达298.8 IU/mL。其最适反应温度为50°C,最适pH为9.0;保温1 h,酶活稳定温度≤45°C,稳定pH为9.0?10.0。酶催化作用依赖于Ca2+,其最适作用浓度为2 mmol/L;Zn2+、Ca2+和NH4+促进酶活力,Fe3+和Pb2+严重抑制酶活力;聚半乳糖醛酸钠为该酶的最适底物。【结论】从麻类脱胶高效菌株中发掘到碱性果胶裂解酶基因,其表达产物在生物质加工过程中具有重要工业化应用前景。     

采用pHsh载体克隆与表达N-乙酰鸟氨酸脱乙酰基酶基因

利用质粒pHsh为表达载体,构建高效表达N-乙酰鸟氨酸脱乙酰基酶的基因工程菌E.coli DH10B/argE-pHsh.为提高酶活并降低生产成本,优化了诱导条件.结果表明:NAOase可在pHsh系统中高活性表达,诱导起始OD600为0.6,在空气摇床中42℃热激诱导5h重组菌比酶活达到152U/mL.     

类芽胞杆菌碱性果胶裂解酶的纯化与酶学性质表征

从类芽胞杆菌Paenibacillus sp.WZ008的发酵上清液中纯化得到一个高活力碱性果胶裂解酶,经SDS-PAGE电泳估算其亚基相对分子质量为4.5×104。通过对该酶进行酶学性质研究发现：该酶能催化裂解果胶酸、低酯果胶和高酯果胶;酶催化反应最适温度范围为55～60℃,最适pH为9.6,在最适条件下以低酯果胶为底物酶的比酶活达3 021.6 U/mg;Ca2＋能增强该酶的活力,而Mn2＋,Ba2＋和EDTA强烈抑制该酶活力;当没有Ca2＋存在时,高度酯化的果胶是该酶的最适底物,在4 mmol/L Ca2＋存在时,该酶以果胶酸为底物比酶活最高（25 467 U/mg）。该酶N端序列比对分析发现与类芽胞杆菌Paenibacillus amylolyticus strain 27c64果胶裂解酶高度同源。     

宏基因组来源果胶酸裂解酶在毕赤酵母中的表达及应用

果胶酸裂解酶可用于含果胶废水的处理、纸浆漂白以及棉麻纺织品的生物精炼等。基于高通量宏基因组测序技术,从富含果胶土壤宏基因组中挖掘得到一个果胶酸裂解酶基因pela。将pela连接表达载体pPIC9转化毕赤酵母Pichia pastoris GS115。在3 L发酵罐水平,甲醇诱导10 h后,培养基中果胶酸裂解酶活力达到10.8 U/mL。重组PELA的最适温度为45℃,最适pH为9.0,在pH 7.5~11.0具有良好的稳定性。PELA的比活力为244.12 U/mg,以聚半乳糖醛酸为底物时催化反应的Km和Vmax分别为0.26 mg/mL和488.40 μmol/min·mg。EDTA及金属离子Cd2+、Zn2+、Mn2+、Cu2+、Fe3+能够高度抑制酶的活性,1 mmol/L Ca2+和2 mmol/L K+对酶活力有促进作用。将重组PELA作用于苎麻纤维4 h后,纤维质量损失率达到9.2%,苎麻纤维分散度和白度都明显提高。结果表明从宏基因组来源的果胶酸裂解酶PELA在苎麻脱胶中具有良好的应用潜力。     

超耐热酸性α-淀粉酶基因的克隆及其在酵母细胞中的表达

用PCR方法扩增来源于极端嗜热厌氧古菌Pyrococcus furiosus中的超耐热酸性α-淀粉酶的结构基因,将该结构基因引入载体pPIC9K中,将重组质粒pPIC9K-Amy转化大肠杆菌DH5α细胞,测序结果表明,克隆到的α-淀粉酶结构基因为1305bp,其编码的成熟肽为435个氨基酸。将正确构建的重组质粒转化毕赤酵母GS115细胞,得到酵母工程菌株。在酵母α-Factor及AOX1基因启动子和终止信号的调控下,超耐热酸性α-淀粉酶在甲醇酵母中大量表达并分泌到胞外,该酶的表达受甲醇的严格调控和诱导,随着诱导培养时间的增加,在培养基上清液中的单位体积酶活力相应上升,在诱导培养7d后酶活力达到最大值。该酶最适反应温度为90~100℃,最适反应pH值为4.5~5.5。该酶具有非常好的温度稳定性,在100℃条件下热处理5h,仍具有60%以上的酶活力。该酶的这些优点使其非常适于在工业生产上应用。     

果胶裂解酶基因PelC表达载体的构建及原核表达分析

从实验室分离保存的1株产果胶酶的菌株（BTC105）中克隆果胶裂解酶基因（PelC）完整开放阅读框,通过载体构建,将目的基因连接到表达载体pET28a上,转化大肠埃希茵BL21（DE3）进行融合表达,在LB（Luria—Bertani）中进行摇瓶发酵,1mmol／LIPTG（异丙基－β－D－硫代半乳糖苷）诱导。结果表明,拘建了表达载俸pET28a－felC,果胶裂解酶主要在胞内表达,酶活最适pH为5．4,最适温度为50℃,Ca^2＋对酶活促进作用最为明显,Cu^2＋完全抑制了酶的活性。     

Comparative analysis of the five major Erwinia chrysanthemi pectate lyases: enzyme characteristics and potential inhibitors.

In Erwinia chrysanthemi 3937, pectate lyase activity mainly results from the cumulative action of five major isoenzymes, PelA to PelE. Comparison of their amino acid sequences revealed two families, PelB-C and PelA-D-E. Molecular cloning permitted expression of the different pel genes in Escherichia coli and the isolation of each Pel independently from the other isoenzymes. We used similar experimental conditions to overproduce and purify the five Pels in a one-step chromatography method. We analyzed some of the basic enzymatic properties of these five isoenzymes. PelA has a low specific activity compared to the other four enzymes. PelB and PelC have a high affinity for their substrate: about 10-fold higher than the enzymes of the PelA-D-E group. The optimum pH is more alkaline for PelB and PelC (about 9.2) than for PelA, PelD, and PelE (from 8 to 8.8). Below pH 7, activity was negligible for PelB and PelC, while PelA, PelD, and PelE retained 25 to 30% of their activities. The temperature optima were determined to be 50 degrees C for PelD and PelE, 55 degrees C for PelA, and 60 degrees C for PelB and PelC. Enzymes of the PelB-C group are more stable than those of the PelA-D-E group. Use of substrates presenting various degrees of methylation revealed that PelA, PelD, and PelE are active only for very low levels of methylation, while PelB and PelC are more active on partially methylated pectins (up to 22% for PelC and up to 45% for PelB). Pectate lyases have an absolute requirement for Ca2+ ions. For the five isoenzymes, maximal activity was obtained at a Ca2+ concentration of 0.1 mM. None of the tested cations (Ba2+, Co2+, Cu2+, Mg2+, Mn2+, Sr2+, Zn2+) can substitute for Ca2+. At a high concentration (1 mM), most of the divalent cations inhibited pectate lyase activity. In addition, we demonstrated that two compounds present in plant tissues, epicatechin and salicylic acid, inhibit the pectate lyases at a concentration of 0.2 mM.     

Expression of a Bacillus subtilis pectate lyase gene in Pichia pastoris

The methylotrophic yeast Pichia pastoris is an attractive heterologous protein expression host, mainly for genes from higher eukaryotes. However, no successful examples for the expression of bacterial gene encoding pectate lyase in P. pastoris have been reported. The present study reports for the first time the cloning and functional expression of the bacterial Bacillus subtilis gene encoding alkaline pectate lyase in P. pastoris. A molecular weight of 43,644 Da was calculated from the deduced amino acid sequence. A pectate lyase activity as high as 100 U/ml was attained in the fermentation broth of P. pastoris GS 115, which was about 10 times higher than when the gene is expressed in Escherichia coli. The recombinant pectate lyase was purified to homogeneity and maximal activity of the enzyme was observed at 65 °C, and pH 9.4. The recombinant enzyme showed a wider pH and thermal stability spectrum than the purified pectate lyase from B. subtilis WSHB04-02. Pectate lyase activity slightly increased in the presence of Mg²⁺ (ion) but decreased in the presence of other metal ions. Analysis of polygalacturonic acid degradation products by electrospray ionization-mass spectrometry revealed that the degradation products were unsaturated trigalacturonic acid and unsaturated bigalacturonic acid, which confirms that the enzyme catalyzes a trans-elimination reaction.     

海栖热袍菌葡萄糖异构酶基因xylA的克隆、表达及酶学性质

海栖热袍菌(Thermotoga maritima)是嗜极端高温的厌氧细菌,其产生的葡萄糖异构酶由于其出色的耐热性有着潜在的工业应用价值.由于海栖热袍菌苛刻的培养条件导致其葡萄糖异构酶产量较低.通过PCR方法克隆编码T. maritima MSB8葡萄糖异构酶基因xylA,构建重组质粒pHsh-xylA,转入Escherichia coli JM109,通过热激诱导表达.通过热处理和离子交换层析纯化两步得到电泳纯的酶制品,纯化倍数和回收率分别为8.02和49.02.对酶学性质研究表明,该重组酶为金属离子激活性酶,Mg2 ,Co2 对相对酶活有很强的激活作用,其最适pH为7.0,最适反应温度为95℃,且在pH 6～8之间有着较好的稳定性,在95℃下半衰期长达5 h以上.以葡萄糖为底物时的表观Km和Vmax分别为105 mmol/L和45.2 mol/min·mg.     

Characterization and implications of Ca2+ binding to pectate lyase C

Ca(2+) is essential for in vitro activity of Erwinia chrysanthemi pectate lyase C (PelC). Crystallographic analyses of 11 PelC-Ca(2+) complexes, formed at pH 4.5, 9.5, and 11.2 under varying Ca(2+) concentrations, have been solved and refined at a resolution of 2.2 A. The Ca(2+) site represents a new motif for Ca(2+), consisting primarily of beta-turns and beta-strands. The principal differences between PelC and the PelC-Ca(2+) structures at all pH values are the side-chain conformations of Asp-129 and Glu-166 as well as the occupancies of four water molecules. According to calculations of pK(a) values, the presence of Ca(2+) and associated structural changes lower the pK(a) of Arg-218, the amino acid responsible for proton abstraction during catalysis. The Ca(2+) affinity for PelC is weak, as the K(d) was estimated to be 0.132 (+/-0.004) mm at pH 9.5, 1.09 (+/-0.29) mm at pH 11.2, and 5.84 (+/-0.41) mm at pH 4.5 from x-ray diffraction studies and 0.133 (+/-0.045) mm at pH 9.5 from intrinsic tryptophan fluorescence measurements. Given the pH dependence of Ca(2+) affinity, PelC activity at pH 4.5 has been reexamined. At saturating Ca(2+) concentrations, PelC activity increases 10-fold at pH 4.5 but is less than 1% of maximal activity at pH 9.5. Taken together, the studies suggest that the primary Ca(2+) ion in PelC has multiple functions.     

弗氏柠檬酸细菌酪氨酸酚解酶基因在大肠杆菌中的克隆与表达

以基因组DNA为模板,利用PCR技术从弗氏柠檬酸细菌（Citrobacter freundii)中扩增得到含有酪氨酸酚解酶基因的DNA片段,定向连续到质粒pUC118上,得到重组质粒pTPL,将此重组质粒转化到受体菌E.colXL-1-Blue MRF′中,通过蓝白斑鉴定挑出阳性菌株。从此阳性菌株中提取质粒pTPL并将此质粒转入到E.coliJM109中,用E.coliJM109（pTPL)制备高活性的酪氨酸酚解酶。对质粒稳定性的研究表明,E.coliJM109（pTPL)在无选择压力下37℃连续培养50代以上,质粒丢失率仅有15％,说明质粒基本稳定。     

Enhanced Soluble Expression of a Thermostable Cellulase from <Emphasis Type="Italic">Clostridium thermocellum</Emphasis> in <Emphasis Type="Italic">Escherichia coli</Emphasis>

In this study, the cellulase gene celD from Clostridium thermocellum was cloned into expression vectors pET-20b(+) and pHsh. While high expression can be achieved by means of both these expression systems, only the pHsh expression system gives soluble proteins. By weakening the mRNA secondary structure and replacing the rare codons for the N-terminal amino acids of the target protein, the expression level of CelD was increased from 4.1 ± 0.3 to 6.4 ± 0.4 U ml⁻¹ in LB medium. Recombinant CelD was purified by heat treatment followed by Ni–NTA affinity. The purified CelD exhibited the highest activity at pH 5.4 and 60°C, and retained more than 50% activity after incubation at 70°C for 1 h. The cellulase activity of CelD was significantly enhanced by Ca²⁺ but inhibited by EDTA. The favorable properties of CelD offer the potential for genetic modification of strains for biomass degradation. Presently, one of the major bottlenecks for industrial cellulase users is the high cost of enzyme production. The high level expression of soluble enzymes from the pHsh expression system offers a novel approach for the production of cellulases to be used in various agro-industrial processes such as chemical, food and textile.     

Enhanced expression of an endoglucanase in Bacillus subtilis by using the sucrose-inducible sacB promoter and improved properties of the recombinant enzyme

An endoglucanase from Bacillus akibai I-1 was successfully overexpressed in Bacillus subtilis 168 and the expression level of the recombinant enzyme was greatly enhanced by using the sucrose-inducible sacB promoter. The endoglucanase activity in the culture supernatant of recombinant B. subtilis by using itself promoter (HpaII) in plasmid pMA5 was 3U/ml. Interestingly, with the addition of sacB promoter at downstream from the HpaII promoter or the replacement of HpaII promoter by the sacB promoter, the endoglucanase activities reached 62 and 60U/ml, respectively, under the optimal culture conditions. These results demonstrated that the sacB promoter might be more efficient for the expression of the endoglucanase than the HpaII promoter. More interestingly, the purified native enzyme had broad pH stability, good thermostability and resistibility to various metal ions and chelating agents examined, while the recombinant enzyme had improved resistibility to SDS, which was stable in 0.2% (w/v) laundry detergent and thus showed great potential in detergents industry.