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展示南极假丝酵母脂肪酶B的毕赤酵母全细胞催化合成短链芳香酯 被引量:11

Synthesis of flavor esters catalyzed by CALB-displaying Pichia pastoris whole-cells in non-aqueous phase
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摘要 展示酶的酵母细胞作为全细胞催化剂,既具有固定化酶的优点,又有制备简单、成本较低的特点。本研究将细胞表面展示南极假丝酵母脂肪酶B(Candida antarctica lipase B,CALB)的重组毕赤酵母用于非水相中催化合成短链芳香酯,通过滴定和气相色谱的方法测定底物酸的转化率,从底物的碳链长度、醇的结构、酵母冻干粉的添加量、底物浓度及底物的酸醇摩尔比等方面考察了展示CALB的毕赤酵母全细胞催化合成短链芳香酯的特性。研究结果表明:该全细胞催化剂可催化C10以下的酸和醇直接酯化合成多种短链芳香酯,酸的转化率达到90%以上;其中己酸和乙醇为酶的最适底物;酵母冻干粉的添加量20g/L(306.0U/g-drycell)、己酸浓度0.8mol/L、酸醇摩尔比1:1.1是合成己酸乙酯的最佳条件。在此条件下反应1.5h,己酸的转化率达到97.3%。在现有的关于脂肪酶非水相催化合成短链芳香酯的报道中,该全细胞催化剂显示出较好的底物耐受性以及较高的催化反应速率。因此,展示CALB的毕赤酵母全细胞催化剂在合成短链芳香酯方面具有较大的商业化应用潜能。 An enzyme-displaying yeast as a whole-cell biocatalyst seemed an alternative to immobilized enzyme,due to its low-cost preparation and simple recycle course.Here,we tried to use a recombinant Pichia pastoris displaying Candida antarctica lipase B (CALB) to catalyze the synthesis of short chain flavor esters in n-heptane.We studied some major influential factors of esterification reactions,such as carbon chain length of the substrates,alcohol structure,enzyme concentration,substrates concentration,molar ratio of the substrates. The acid conversions were determined by titration and gas chromatography analysis. About ten kinds of esters were synthesized successfully, and the acid conversions of eight esters reached as high as 90% after reaction for 6 h. The result also indicated that ethanol and hexanoic acid were the most suitable substrates for this whole-cell catalyst. Under the optimal reaction conditions (the amount of lipase 20 g/L (306.0 U/g-dry cell), hexanoic acid concentration 0.8 mol/L, the molar ratio of hexanoic acid to ethanol 1:1.1), hexanoic acid conversion reached 97.3% after reaction for 1.5 h. To our knowledge, the CALB-displaying P. pastoris whole-cell biocatalyst showed good tolerance for high substrates concentration and exhibited high reaction rate on esterification of short chain flavor esters among the present enzyme/cell reported. Thus, CALB-displaying P. pastoris whole-cell biocatalyst was promising in commercial application for flavor esters synthesis in non-aqueous phase.
作者 金子 林影 黄登峰 苏国栋 韩双艳
机构地区 华南理工大学生物科学与工程学院
出处 《生物工程学报》 CAS CSCD 北大核心 2009年第12期1927-1932,共6页 Chinese Journal of Biotechnology
基金 广东省科技攻关项目(Nos.2007A010900001 2008A010900002)资助~~
关键词 酵母表面展示 南极假丝酵母脂肪酶B 全细胞催化 短链芳香酯 yeast surface display Candida antarctica lipase B whole-cell biocatalyst short chain flavor esters
分类号 Q789 [生物学—分子生物学]
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参考文献19

  • 1Leon R, Fernandes P, Pinheiro HM, et al. Whole-cell biocatalysis in organic media. Enzyme Microb Technol, 1998, 23(7/8): 483-500.
  • 2Larios A, Garcia HS, Oliart RM, et al. Synthesis of flavor and fragrance esters using Candida antarctica lipase. Appl Microbiol Biotechnol, 2004, 65(4): 373-376.
  • 3Villeneuve P, Muderhwa JM, Graille J, et al. Customizing lipases for biocatalysis: a survey of chemical, physical and molecular biological approaches. J Mol Catal B: Enzym, 2000, 9(4/6): 113-148.
  • 4Gitlesen T, Bauer M, Adlercreutz P, et al. Adsorption of lipase on polypropylene powder. Biochim Biophys Acta, 1997, 1345(2): 188-196.
  • 5De Oliveira PC, Alves GM, De Castro HF, et al. Immobilization studies and catalytic properties of microbial lipase onto styrene-divinylbenzene copolymer. Biochem Eng J, 2000, 5(1): 63-71.
  • 6Soares CMF, De Castro HE De Moraes FF, et al. Characterization and utilization of Candida rugosa lipase immobilized on controlled pore silica. Appl Biochem Biotechnol, 1999, 79(1/3): 745-757.
  • 7Keeling-Tucker T, Rakic M, Spong C, et al. Controlling the material properties and biological activity of lipase within sol-gel derived bioglasses via organosilane and polymer doping. Chem Mater, 2000, 12(12): 3695-3704.
  • 8Reetz MT, Zonta A, Simpelkamp J. Efficient immobilization of lipases by entrapment in hydrophobic sol-gel materials. Biotechnol Bioeng, 1996, 49(5 ): 527-534.
  • 9Kato M, Fuchimoto J, Tanino T, et al. Preparation of a whole-cell biocatalyst of mutated Candida antarctica lipase B (mCALB) by a yeast molecular display system and its practical properties. Appl Microbiol Biotechnol, 2007, 75(3): 549-555.
  • 10Tanino T, Ohno T, Aoki T, et al. Development of yeast cells displaying Candida antarctica lipase B and their application to ester synthesis reaction. Appl Microbiol Biotechnol, 2007, 75(6): 1319-1325.

二级参考文献21

  • 1[1]Yan X,Dong W,et al.Biosynthesis of ethyl esters of short-chain fatty acids using whole-cell lipase from Rhizopus chinesis CCTCC M201021 in non-aqueous phase[J].Journal of Molecular Catalysis B:Enzymatic,2002,18:29-37
  • 2[2]Michael J.H,Robert V,Brian M,et al.Enzymatic Hydrolysis of a Pruchiral 3-Substituted Glutarate Ester,an Intermediate in the Synthesis of an NK1/NK2 Dual Antagonist[J].Adv.Synth.Catal.,2001,343:744-749
  • 3[3]Senanayake S,Shahidi E Incorporation of docosahexaenoic acid (DHA) into evening primrose (Oenothera biennis L.) oil via lipase-catalyzcd transesterification[J],Food Chemistry,2004,85(4):489-496
  • 4[4]Gotor-Fernández V,Busto E,Gotor V.Candida antarctica Lipase B:An Ideal Biocatalyst for the Preparation of Nitrogenated Organic Compounds[J].Advanced synthesis & catalysis,2006,348:797-812
  • 5[5]Kondo A,Udea M.Yeast cell-surface disphy--applications of molecular display[J].Appl Microbiol Biotechnol,2004,64:28-40
  • 6[6]Kordel M,Hofrnann B,Schomburg D,et al.Extraccllular Lipase of Pseudomonas sp.Strain ATCC 21808:Purification,Characterization,Crystallization,and Preliminary X-Ray Diffraction Data[j].Journal of Bacteriology,1991,173(15):4836-4841.
  • 7[7]Ole Kirk,Morten Wurtz Christensen.Lipases from Candida antarctica:Unique Biocatalysts from a Unique Origin[J].Organic Process Research & Development,2002,6:446-451
  • 8[9]Mitsuyoshi U,Atsuo T.Genetic immobilization of proteins on the yeast cell surfacr[J].Biotechnology Advances,2000,18:121-140
  • 9[10]Kuroda K,Ueda M,Shibasaki S,et al.Cell surface-engineered yeast with ability to bind,and self-aggregate in response to copperion[J].Applied Microbiology and Biotechnology,2002,59 (2):259-264
  • 10[11]Hisayori S,Yasuya F,Jun K,et al.Energy-saving direct ethanol production from low-temperature-cooked corn starch using a cell-surface engineered yeast strain co-displaying glueoamylase and α-amylase[J].Biochemical Engineering Journal,2004,18:149-153

共引文献11

同被引文献148

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二级引证文献51

生物工程学报
2009年 第12期

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