利用微生物重组技术促进羰基不对称还原研究进展

手性醇是许多手性药物合成的关键手性砌块,利用微生物细胞催化相应前手性羰基化合物不对称还原,是合成手性醇的重要方法之一。但应用野生微生物催化时,反应的时空产率、立体选择性较低。详细介绍了利用微生物重组技术以促进前手性羰基化合物不对称还原反应合成手性醇的国内外研究进展。从酶的种类、表达系统以及辅酶再生系统3个方面对重组细胞催化反应体系的构建进行了概述。同时按照反应底物的类型,对重组微生物在催化不同类型羰基化合物不对称还原合成手性醇中的应用分别进行了归纳和介绍。     

羰基还原酶及其催化不对称合成大基团手性羟基类化合物的研究进展

手性羟基化合物以其独特的光、热和化学性质广泛应用于医药、农药、精细化工、功能材料等行业.立体专一性羰基还原酶能够直接针对关键手性位点催化不对称还原潜手性底物获得目的手性产物.基于羰基还原酶的底物多样性,具有不同化学结构和功能的醇类、酯类、氨基酸、环氧化合物等重要手性中间体能够通过不对称还原途径实现单一光学活性对映体的高效制备.然而,针对具有应用价值的含有大基团、结构复杂的潜手性羰基化合物,已知的羰基还原酶通常催化活性较低.本文综述了生物催化不对称氧化还原反应的特点和规律及其关键立体选择性羰基还原酶的性质和结构特征,并在此基础上,重点针对大基团手性羟基化合物的不对称合成,总结了羰基还原酶及其催化系统开发和应用的研究进展,并进一步提出解决该关键问题的主要发展策略.     

重组基因工程菌在不对称还原羰基化合物中的应用

手性醇是药物合成的重要手性砌块,利用生物催化剂不对称还原羰基化合物是手性醇制备的重要方法。介绍了生物催化还原羰基化合物的反应原理及特点,综述了重组基因工程菌的构建及其在不对称还原羰基化合物中的应用情况,展望了今后研究发展的方向。     

NAD(P)H依赖型氧化还原酶不对称还原胺化制备手性胺的研究进展

不对称还原胺化反应是制备医药中间体手性胺结构单元的重要反应。目前已有许多不同种类的酶被应用于合成手性胺,其中NAD(P)H依赖型氧化还原酶催化的还原胺化反应最为引人注目,因为其能够一步将潜手性酮化合物完全转化为光学纯的手性胺化合物。文中以亚胺还原酶、氨基酸脱氢酶、冠瘿碱脱氢酶和还原性酮胺化酶为例,从NAD(P)H依赖型氧化还原酶的结构特征、作用机理、分子改造及催化应用等方面,综述了其在不对称还原胺化合成手性胺领域的研究进展。     

一种来源于毕赤酵母的高对映选择性羰基还原酶的性质及底物谱分析

手性醇是一类非常重要的化合物,羰基还原酶催化酮的不对称还原生成对应的手性醇.从毕赤酵母Pichia pastoris GS115基因组数据中找到一个潜在的NADPH依赖的羰基还原酶,研究毕赤酵母 P.pastoris GS115中的羰基还原酶.根据其核酸序列设计引物,从P.pastoris GS115基因组中扩增到目的基因ppcr,大肠杆菌BL21 (DE3)中表达,Ni-NTA纯化,对酶的性质和底物谱进行了研究.PPCR的最适反应温度为35℃,最适反应pH为6.0,低于45℃时有很好的稳定性.对3-甲基-2-羰基丁酸乙酯的Km和kcat分别为9.48 mmol/L和0.12 s-1. PPCR表现出广泛的底物谱和很高的对映选择性,对醛、α-酮酯、芳香族β-酮酯及芳香族酮都表现出了很好的活性,在测定的底物中,除极少数底物外,ee值均达到97％以上.因此,PPCR具有较好的应用前景.     

羰基还原酶不对称还原（R）-6-氰基-5-羟基-3-羰基己酸叔丁酯

选择R-羰基还原酶和葡萄糖脱氢酶双酶,协同催化（R）-6-氰基5-羟基-3-羰基己酸叔丁酯不对称还原制备阿托伐他汀关键手性合成子6-氰基-（3R,5R）-二羟基已酸叔丁酯。转化条件优化结果显示：在不添加外源性辅酶NADP（H）、菌体用量15．0g/L、147．0g/L（R）-6-氰基-5-羟基-3-羰基己酸叔丁酯、128．2g／L葡萄糖,30℃、pH6．5条件下反应6h后,底物转化率达到100％,产物d．e．值大于99．5％。     

响应面法优化羰基还原酶产生菌Cyberlindnera saturnus发酵培养基

(13R,17S)-乙基仲醇是合成甾体类避孕药物左炔诺孕酮的手性中间体,可利用Cyberlindnera saturnus ZJPH1807菌株催化乙基二酮不对称还原制备(13R,17S)-乙基仲醇.为进一步提高该菌株的羰基还原酶活力,采用单因素实验和响应面优化法对其发酵培养基中碳源、氮源及无机盐等主要成分和添加量进行...     

羰基生物还原法合成手性醇的研究进展

手性醇是合成许多光学活性药物、农用化学品及其他精细化学品的关键手性砌块。羰基生物还原法理论上可实现100%转化率,且反应条件温和,对环境十分友好,被普遍认为是生产手性醇的绿色、高效途径。综述了近年来利用生物信息学、高通量筛选和蛋白质工程的发展对新型、高效生物催化剂开发的影响,特别是利用相关技术手段开发羰基还原酶的进展。     

不对称还原前手性芳香酮微生物的筛选及反应特性

含芳香基手性醇是许多手性药物合成的关键手性砌块,生物催化不对称还原前手性酮是合成该类醇的重要方法之一.以4'-氯-苯乙酮为模型底物,从土壤中筛选得到一株能高效催化前手性芳香酮不对称还原合成相应手性醇的菌株,鉴定表明该菌株为白地霉( Geotrichum candid ).进一步考察了其催化4'-氯-苯乙酮不对称还原的反应特性,发现还原4'-氯-苯乙酮的产物主要为 S-4'-氯苯乙醇.在合适的反应条件下,其产率达到35%,对映选择性高于97%.     

融合酶CR2-GDH合成度洛西汀前体的体系与过程调控

以具有高选择性的羰基还原酶(CR2)与可实现辅酶原位循环的葡萄糖脱氢酶(GDH)通过柔性连接肽得到的融合酶CR2-GDH为生物催化剂,催化N,N-二甲基-3-酮-3-(2-噻吩)-1-丙胺(DKTP)不对称还原合成手性药物度洛西汀重要中间体(S)-N,N-二甲基-3-羟基-3-(2-噻吩)-1-丙胺((S)-DHTP)...     

His-tagged Horse Liver Alcohol Dehydrogenase: Immobilization and application in the bio-based enantioselective synthesis of (S)-arylpropanols

The novel histidine-tagged Horse Liver Alcohol Dehydrogenase (His-HLADH-EE) was successfully purified and covalently immobilized onto a solid support in a one-step procedure through a metal-directed technique. A full characterization of the immobilized enzyme was carried out. Effects of pH, temperature and organic co-solvents were deeply investigated and they showed a shift in the optimum pH with respect to the free form as well as increased stability to temperature and solvents. The immobilized His-HLADH-EE proved to be effective as catalyst in the reduction of aliphatic and aromatic aldehydes. Application of the free and immobilized His-HLADH-EE to the chemo-enzymatic synthesis of (S)-Profenols demonstrated enhanced enantioselectivity and high reusability of the immobilized form. The achievement of a robust and effective immobilization of an alcohol dehydrogenase substantiated the use of biocatalytic reduction in the synthesis of primary alcohols and valuable chiral intermediates especially for pharmaceutical industries.     

Post Iron Decoration of Mesoporous Nitrogen‐Doped Carbon Spheres for Efficient Electrochemical Oxygen Reduction

Iron–nitrogen–carbon (Fe–N–C) catalysts are considered as the most promising nonprecious metal catalysts for oxygen reduction reactions (ORRs). Their synthesis generally involves complex pyrolysis reactions at high temperature, making it difficult to optimize their composition, pore structure, and active sites. This study reports a simple synthesis strategy by reacting preformed nitrogen‐doped carbon scaffolds with iron pentacarbonyl, a liquid precursor that can effectively form active sites with the nitrogen sites, enabling more effective control of the catalyst. The resultant catalyst possesses a well‐defined mesoporous structure, a high surface area, and optimized active sites. The catalysts exhibit high ORR activity comparable to that of Pt/C catalyst (40% Pt loading) in alkaline media, with excellent stability and methanol tolerance. The synthetic strategy can be extended to synthesize other metal–N–C catalysts.     

Nanocarbon Electrocatalysts for Oxygen Reduction in Alkaline Media for Advanced Energy Conversion and Storage

Alkaline oxygen electrocatalysis, targeting anion exchange membrane fuel cells, Zn‐air batteries, and alkaline‐based Li‐air batteries, has become a subject of intensive investigation because of its advantages compared to its acidic counterparts in reaction kinetics and materials stability. However, significant breakthroughs in the design and synthesis of efficient oxygen reduction catalysts from earth‐abundant elements instead of precious metals in alkaline media remain in high demand. Carbon composite materials have been recognized as the most promising because of their reasonable balance between catalytic activity, durability, and cost. In particular, heteroatom (e.g., N, S, B, or P) doping can tune the electronic and geometric properties of carbon, providing more active sites and enhancing the interaction between carbon structure and active sites. Importantly, involvement of transition metals appears to be necessary for achieving high catalytic activity and improved durability by catalyzing carbonization of nitrogen/carbon precursors to form highly graphitized carbon nanostructures with more favorable nitrogen doping. Recently, a synergetic effect was found between the active species in nanocarbon and the loaded oxides/sulfides, resulting in much improved activity. This report focuses on these carbon composite catalysts. Guidance for rational design and synthesis of advanced alkaline ORR catalysts with improved activity and performance durability is also presented.     

Light-independent accumulation of chlorophyll a and b and protochlorophyllide in green barley (Hordeum vulgare)

Barley ( Hordeum vulgare L. cvs Clipper, Procter, Astrix) seedlings were transferred from daylight to darkness and changes in chlorophyll a , chlorophyll b , protochlorophyllide and chlorophyllide (μ leaf⁻¹) in either the first or second leaf determined spectrophotometrically after separating the esterified from unesterified pigments by partitioning between ammoniacal acetone and light petroleum ether. Chlorophyll a and b as well as protochlorophyllide accumulated in the dark. The ratio of chlorophyll to protochlorophyllide formed in the absence of light was 18:1. 5-aminolevulinic acid (10 m M ) promoted the synthesis of chlorophyll a and b and protochlorophyllide. Pigment synthesis and response to 5-aminolevulinic acid addition was related to tissue age. Mature tissue in the apical third of the leaf accumulated most chlorophyll, but per μg chlorophyll present at the time of transfer to darkness, was less efficient than immature tissue towards the base of the leaf. Immature tissue was also most responsive to added 5-aminolevulinic acid. Chlorophyll synthesis in the dark was accompanied by chloroplast development. Chloroplasts in immature leaf tissue increased in size and extent of thylakoid development when transferred from daylight to darkness. The results indicate that chlorophyll synthesis and chloroplast membrane development in light-grown barley continue into the dark phase of the diurnal cycle. A light-independent protochlorophyllide reductase in light-grown barley seedlings is postulated.     

马克斯克鲁维酵母羰基还原酶基因的克隆与表达

【目的】研究羰基还原酶基因的克隆、表达及其在不对称生物催化中的应用。【方法】对羰基还原酶氨基酸序列进行BLAST推导出核苷酸序列,设计引物,以马克斯克鲁维酵母(Kluyveromyce marxianus)CGMCC 2.1977全基因组为模板,通过PCR扩增目的片段,与载体pET-28a连接,转化大肠杆菌获得重组菌BL21(DE3)-(pET28a-cMCR)和Rosetta(DE3)-(pET28a-cMCR)。【结果】扩增的序列与已报道的mer序列有100%同源性,全长1 038 bp,共编码345个氨基酸。目的蛋白在Rosetta(DE3)-(pET28a-cMCR)得到了高效表达,大小为42 kD。该酶最适反应温度为40°C,最适反应pH是8,热稳定性与pH稳定性较差。Ca2+对酶活具有明显的激活作用,且浓度为0.5 mmol/L时效果最好。重组菌可还原4-氯乙酰乙酸乙酯(COBE)为(S)-4-氯-3-羟基丁酸乙酯[(S)-CHBE],光学纯度为100%,转化率为81.0%。重组菌在制备度洛西汀关键中间体(S)-氮,氮-二甲基-3-羟基-(2-噻吩)-l-丙胺[(S)-DHTP]中也得到初步应用。【结论】从菌株马克斯克鲁维酵母(Kluyveromyce marxianus)CGMCC 2.1977中克隆获得了羰基还原酶基因,在大肠杆菌中成功表达,并可应用于不对称还原。     

Novel growth characteristics and high rates of nitrate reduction of an Escherichia coli strain, LCB2048, that expresses only a periplasmic nitrate reductase

Escherichia coli strain LCB2048 is a double mutant defective in the synthesis of the two membrane-associated nitrate reductases A and Z. This strain can grow anaerobically on a non-fermentable carbon source, glycerol, in the presence of nitrate even in media supplemented with high concentrations of tungstate. This growth was totally dependent upon a highly active, periplasmic nitrate reductase (Nap). Due to the presence of a previously unreported narL mutation, synthesis of the periplasmic nitrate reductase by this strain was induced during anaerobic growth by nitrate. We have also demonstrated that methyl viologen is an ineffective electron donor to Nap: its use leads to an underestimation of the contribution of Nap activity to the rate of nitrate reduction in vivo.     

β‐Hydroxyamide‐Based Ligands and Their Use in the Enantioselective Borane Reduction of Prochiral Ketones

Hydroxyamide‐based ligands have occupied a considerable place in asymmetric synthesis. Here we report the synthesis of seven β‐hydroxyamide‐based ligands from the reaction of 2‐hydroxynicotinic acid with chiral amino alcohols and test their effect on the enantioselective reduction of aromatic prochiral ketones with borane in tetrahydofuran (THF). They produce the corresponding secondary alcohols with up to 76% enantiomeric excess (ee) and good to excellent yields (86‐99%). Chirality 26:21–26, 2013. © 2013 Wiley Periodicals, Inc.     

Involvement of Fis protein in replication of the Escherichia coli chromosome.

We report evidence indicating that Fis protein plays a role in initiation of replication at oriC in vivo. At high temperatures, fis null mutants form filamentous cells, show aberrant nucleoid segregation, and are unable to form single colonies. DNA synthesis is inhibited in these fis mutant strains following upshift to 44 degrees C. The pattern of DNA synthesis inhibition upon temperature upshift and the requirement for RNA synthesis, but not protein synthesis, for resumed DNA synthesis upon downshift to 32 degrees C indicate that synthesis is affected in the initiation phase. fis mutations act synergistically with gyrB alleles known to affect initiation. oriC-dependent plasmids are poorly established and maintained in fis mutant strains. Finally, purified Fis protein interacts in vitro with sites in oriC. These interactions could be involved in mediating the effect of Fis on DNA synthesis in vivo.     

丹麦森林土壤反硝化作用的动力学分析

本项研究将乙炔和氯霉素抑制技术结合起来 ,对丹麦一森林土壤的反硝化作用进行了研究 ,并考察温度对其还原酶活性的影响 .反硝化还原酶活性和合成过程受O2 的抑制 ,厌氧培养时 ,需要一定时间消耗系统中残余的O2 来解除这种抑制作用 .在无抗生素抑制蛋白质合成时 ,硝酸还原酶只有少量合成 ,而N2 O还原酶却显著地诱导产生 .这一结果对土壤吸收N2 O能力的研究具有重要意义 .在各处理下 ,系统中未发生亚硝酸盐的明显积累 ,表明亚硝酸还原酶活性大于硝酸还原酶 .外加葡萄糖加速了反硝化作用 ,并能促进酶的合成和消除还原过程中的电子竞争 .供试土壤表现出很强的厌氧呼吸作用 ,并受外加C源的促进 .反硝化作用的活化能低于土壤厌氧呼吸的活化能 ,因此反硝化作用的Q1 0值较低 ,CO2 和N2 O的产生比例随温度升高而加大 .