脂肪酶催化合成生物柴油的瓶颈问题及其对策研究进展

生物柴油,一种新型的清洁能源燃料,具有可再生、可生物降解、环境友好等优良的品性,可部分或全部替代石化柴油。碱催化法、脂肪酶催化法及超临界法是合成生物柴油的主要工艺,其中脂肪酶催化法是一种节能型、环保型工艺,在节能和环保方面,有着碱催化法无可比拟的优越性,具有良好的工业应用前景。但目前在实现产业化的进程中仍存在如酶成本高、稳定性较差、甲醇对酶的失活效应及反应时间长等瓶颈问题。通过固定化技术和全细胞催化剂的采用、甲醇流加方式的改进、溶剂工程的改善及酰基受体和耐醇酶的开发等技术手段,结合固定床生物反应器,较好地解决了这些瓶颈问题,从而推进了酶催化法合成生物柴油的工业化进程。本文主要对酶法合成生物柴油工艺存在的主要问题及相应对策研究进展进行概括介绍,并对其工业化发展前景进行讨论。     

几种离子液体的微波法合成及其对脂肪酶催化效果的影响

采用微波法合成9种目标离子液体,对中间体[Bmim]Br的合成条件及其离子液体对全细胞催化剂催化效果的影响进行考察.直接将产脂肪酶真菌粗状假丝酵母(Candida valida) T2细胞固定在聚氨酯颗粒中,制备固定化细胞催化剂,将其应用于合成离子液体介质中催化甲醇与大豆油酯交换反应制备生物柴油.结果表明:微波功率200 W下间隙照射100 s,中间体[Bmim]Br的收率达95.16%,有效地提高了离子液合成产率;在[Bmim]PF6离子液中固定化细胞酶催化转酯化反应30 h,大豆油的转化率达42%,反应效果较其他8种合成离子液体好;固定化细胞颗粒和[Bmim]PF6重复使用4次,其油脂转化率和酶活保持率分别达到29%和69%,表现出较好的催化反应稳定性.     

游离细胞催化法生产丙烯酰胺的菌株改造策略

丙烯酰胺是一种重要的酰胺类化合物,其聚合产物——聚丙烯酰胺被广泛应用于三次采油、水处理、造纸、冶金等领域。以腈水合酶为核心的生物催化法,尤其是游离细胞催化法,具有转化效率高、产物纯度高以及环境友好等优点,是目前丙烯酰胺生产的主要方法;而腈水合酶及其生产菌株的性能在丙烯酰胺生产工艺中起着至关重要的作用。分别从细胞层次和酶层次对常用的生产菌株性能改造策略进行了简介,并重点阐述了目前用于腈水合酶生产菌株改造的基因重组策略。最后介绍了腈水合酶和产酶细胞的协同改造策略及改造效果。其中,通过对产腈水合酶红球菌R.ruber TH在酶和细胞层面的协同改造,重组游离细胞TH8实现了工业规模约500g/L高浓丙烯酰胺的三批次水合制备。     

固定化全细胞催化可再生油脂合成生物柴油的稳定性

酶法合成生物柴油具有反应条件温和、醇用量小、无污染物排放、产物易分离回收等优点,越来越得到关注。全细胞催化剂,无需酶的提取和纯化,减少了酶活损失,有望大幅降低生产成本;Rhizopus oryzae IFO4697全细胞可以有效催化植物油脂合成生物柴油,进一步提高全细胞在催化植物油脂甲醇解制备生物柴油过程中的稳定性,对于工业放大具有重要意义。本实验对固定化全细胞Rhizopus oryzae IFO4697催化植物油脂合成生物柴油的稳定性进行了系统地研究,结果表明:反应体系水含量对于全细胞催化剂的反应活性和催化稳定性有重要影响,5%～15%含水量适宜;研究范围内,载体粒度及干燥方式对稳定性影响不显著;经过戊二醛交联后,全细胞催化油脂甲醇解反应的稳定性显著提高,1200h反应后,仍然可以保持75%的生物柴油得率;真空抽滤直接回用的方式有利于稳定性的保持。在优化条件下,回用20个批次,生物柴油得率可维持在80%。     

华根霉脂肪酶有机相合成酶活的研究

通过比较7种微生物脂肪酶的有机相合成酶活、水相水解酶活及在正庚烷中催化己酸乙酯合成的能力,证明了合成酶活与水解酶活相关性不高,合成酶活比水解酶活更能反映脂肪酶的合成能力。通过比较两株华根霉(Rhizopus chinensis)脂肪酶酶活,发现合成酶活相差较大,表明相同种属微生物的脂肪酶合成酶活存在不同。对．Rhizopus chinensis-2液态发酵产脂肪酶进程研究发现,水解酶活高峰先于合成酶活高峰大约12h。将不同培养时间的Rhizopus chinensis-2全细胞脂肪酶用于催化己酸乙酯合成,具有高合成酶活的全细胞脂肪酶催化己酸乙酯合成反应较快。因此,全细胞脂肪酶用于催化有机相酯合成反应时,具有高脂肪酶合成酶活的菌体具有较好的催化酯合成能力。     

重组大肠杆菌全细胞催化合成莱鲍迪苷D

莱鲍迪苷D(Rebaudioside D,RD)是一种稀有具有高甜度的甜菊糖苷类化合物。本文实现了重组大肠杆菌全细胞催化莱鲍迪苷A(Rebaudioside A,RA)合成RD。以水稻c DNA为模板,扩增得到葡萄糖基转移酶基因eugt11,构建了重组菌株E.coli BL21(p ETDuet-eugt11),并成功表达了重组蛋白6His-EUGT11。通过Ni柱亲和层析纯化并在体外酶催化反应表征了其催化活性。将重组菌BL21(p ETDuet-eugt11)应用于催化合成RD研究。探讨了反应体系pH、温度、柠檬酸钠浓度、菌体密度、二价金属离子、二甲苯体积分数、UDPG添加浓度对反应效率的影响。单因素考察结果显示,在菌体密度0.16 g湿细胞/m L反应液,底物RA浓度为1.0 mmol/L,pH 8.0,60 mmol/L柠檬酸钠,1%二甲苯,0.1 mmol/L Zn Cl2,12.0 mmol/L UDPG,反应温度42℃,反应时间24 h的条件下,RD产量为123.6 mg/L(约0.1 mmol/L)。     

脂肪酶催化制备生物柴油的研究进展

生物柴油作为一种可再生的清洁能源,以其良好的环境效应受到越来越多的关注。酶法生产生物柴油具有化学催化法不可比拟的优越性,是工业化生产的发展方向。本文综述了利用固定化脂肪酶、游离酶、全细胞生物催化剂制备生物柴油的研究与应用进展,并探讨了我国生物柴油产业化发展的困境和对策。     

生物催化不对称还原制备氟代手性醇

由于氟原子的特殊性质，化合物中引入氟原子可显著改变其物理化学性质。因此，氟原子在药物中的应用越来越广。此外，80%药物分子结构属于手性分子。其中，氟代手性醇常见于手性药物结构中，该类结构的合成方法研究具有重要的意义。不对称还原含氟酮是合成此结构的常见方法。与化学还原方法相比，生物催化还原具有对映选择性强、产率高和易于分离纯化等优点。生物催化，特别是酶催化还原含氟酮类化合物成为手性药物合成领域的研究热点。本文从纯化酶催化和全细胞催化两个方面，综述了近年来含氟酮生物催化还原合成氟代手性醇的研究进展，并分析总结了氟代对酮生物催化还原的影响，最后对生物催化还原法未来的发展进行了展望。     

南沙链霉菌来源细胞色素P450酶CYP154C34的表征及生物转化

【目的】P450酶作为一种多功能生物催化剂,可在温和条件下高区域和立体选择性地催化复杂化合物中未活化的C-H键,因此P450酶在化工原料合成、环境污染物降解及药物合成等领域都具有重要作用。本文对南沙链霉菌基因组中的一个新颖的P450酶CYP154C34进行研究,通过构建异源表达和全细胞生物转化重组菌探究其功能。【方法】构建2种全细胞生物转化BL21(DE3)重组菌(含p ET28a-CYP154C34-RhFRED和pET28a-CYP154C34+pACYCDuet-Pdx/PdR)和1种异源表达BL21(DE3)重组菌(含pET28a-CYP154C34)。通过全细胞生物转化的方式筛选底物,分析催化功能及产物结构。比较2种全细胞生物转化重组菌和体外酶反应对底物的转化率。分析CYP154C34和不同底物及底物类似物的亲和力。【结果】通过底物筛选和产物鉴定发现CYP154C34可催化包括孕酮、睾酮、雄烯二酮在内的9种甾体化合物16α位羟基化。通过2种不同还原伴侣的全细胞体系及体外酶反应对底物转化率的比较,发现含有pET28a-CYP154C34-RhFRED的BL21(DE3)重组菌的...     

组合生物催化

自然界最有效的分子是由酶催化的反应所产生,并对这些产物进行自然选择,使其具有优化的生理活性,组合生物催化（Combinatorial Biocatalysis)利用酶反应的多样性,完成有机库（Organic Library)的反复合成,这些反复的反应,可以用分离的酶或全细胞,在天然或非天然的环境中、在溶液或固相中与底物进行反应。组合生物催化是组合方法的在药物发现和发展中产生和优化先导化合物（LeadCompound)的一个有力补充。     

非水相体系酶催化反应研究进展

非水相酶催化反应是酶催化反应中的一个重要方面。非水相溶剂通常可增加底物溶解度,减少水相中的副反应,加快生物催化的速率和效率,在药物及药物中间体和食品等方面具有较大的应用价值。以下探讨了非水相体系对酶活力及酶促反应速率的影响因素,并阐述酶的化学修饰、固定化及定点突变对酶活力的影响,进一步分析无溶剂系统、反胶束、超临界流体及离子液体的不同溶剂体系对酶反应速率及催化效率的影响。此外,还列举一些非水相酶催化反应的应用实例。     

High yielding one-pot enzyme-catalyzed synthesis of UDP-glucose in gram scales.

Uridine diphosphoglucose is an important cofactor of glucosylating enzymes. A simple and high yielding one-pot enzymatic synthesis of UDPG on a gram scale from glucose via hexokinase, phosphoglucomutase and UDPG pyrophosphorylase (UGPase) is described. Repetitive addition of substrate was used to avoid inhibition of UGPase. The approach allows recovery of active enzymes and their re-use. The synthesis of UDP-[4-(13)C]-glucose on a 0.5 g scale resulted in a final yield of 70% and a purity of >95% after chromatographic purification.     

Isolation and characterization of mutations affecting UDPG pyrophosphorylase activity in Dictyostelium discoideum

A procedure for screening large numbers of clones for an enzyme activity was used to isolate mutations which affect UDPG pyrophosphorylase activity (EC 2.7.7.9) in the cellular slime mold Dictyostelium discoideum. Five strains were recovered which have little or no UDPG pyrophosphorylase activity. Ten other strains were found which have significant activity in vivo which is rapidly inactivated upon cell lysis. These strains have permitted us to evaluate the role of UDPG pyrophosphorylase during growth and development. The enzyme affects the growth rate of the cells but is not essential for growth. However, during development the lack of enzyme activity leads to cell death and lysis. Strains which lack UDPG pyrophosphorylase accomplish early developmental events but are unable to culminate. However, certain biochemical and cytological differentiations associated with late stages were observed.     

Cellulose synthesis by Acetobacter xylinum III. Matrix,primer and lipid requirements and heat stability of the cellulose-forming enzymes

The addition of soluble cellodextrins of increasing size to a cell envelope preparation of Acetobacter xylinum stimulated cellulose synthesis from UDPG. This stimulation was attributed to both acceptor and activator effects. Enzymes required for cellulose synthesis were found to be heat-unstable and those required for synthesis of glycosylated lipid components from UDPG, heat-stable. Both heat-inactivated envelope fragments and supernatant fluid from whole cells were necessary for cellulose synthesis from UDPG. Cellulose was not formed from UDPG in the presence of either supernatant fluid alone or heat-inactivated envelopes alone.The combined results of this and previous studies suggest that either the cell envelope is necessary for synthesis of a more immediate precursor to cellulose than UDPG, or that the synthesis from UDPG requires a matrix. The former suggestion and its possible link with lipid intermediate involvement was strengthened by the observation of inefficient glycoxylated lipid formation by a celluloseless mutant strain of A. xylinum. The possible locations of various enzyme activities required for the synthesis of the cellulose precursor are indicated and a possible microfibril nucleation process is discussed.     

Proton transfer at carbon

The viability of living systems requires that C--H bonds of biological molecules be stable in water, but that there also be a mechanism for shortening the timescale for their heterolytic cleavage through enzymatic catalysis of a variety of catabolic and metabolic reactions. An understanding of the mechanism of enzymatic catalysis of proton transfer at carbon requires the integration of results of studies to determine the structure of the enzyme-substrate complex with model studies on the mechanism for the non-enzymatic reaction in water, and the effect of the local protein environment on the stability of the transition state for this reaction. A common theme is the importance of electrostatic interactions in providing stabilization of bound carbanion intermediates of enzyme-catalyzed proton-transfer reactions.     

Correlated conformational fluctuations during enzymatic catalysis: Implications for catalytic rate enhancement

Correlated enzymatic conformational fluctuations are shown to contribute to the rate of enhancement achieved during catalysis. Cytidine deaminase serves as a model system. Crystallographic temperature factor data for this enzyme complexed with substrate analog, transition-state analog, and product are available, thereby establishing a measure of atomic scale conformational fluctuations along the (approximate) reaction coordinate. First, a neural network-based algorithm is used to visualize the decreased conformational fluctuations at the transition state. Second, a dynamic diffusion equation along the reaction coordinate is solved and shows that the flux velocity through the associated enzymatic conformation space is greatest at the transition state. These results suggest (1) that there are both dynamic and energetic restrictions to conformational fluctuations at the transition state, (2) that enzymatic catalysis occurs on a fluctuating potential energy surface, and (3) a form for the potential energy. The Michaelis-Menten equations are modified to describe catalysis on this fluctuating potential energy profile, leading to enhanced catalytic rates when fluctuations along the reaction coordinate are appropriately correlated. This represents a dynamic tuning of the enzyme for maximally effective transformation of the ES complex into EP.     

Partial purification, properties, and kinetic studies of UDP-glucose:p-hydroxybenzoate glucosyltransferase from cell cultures of Lithospermum erythrorhizon.

A glucosyltransferase, which catalyzed the transfer of glucose from UDP-glucose (UDPG) to p-hydroxybenzoate (PHB) in cell cultures of Lithospermum erythrorhizon Sieb. et Zucc., Boraginaceae, was purified 219-fold by ammonium sulfate fractionation and chromatography on DEAE-Sephacel, Sephadex G-150, and phenyl-Sepharose Cl-4B. p-Hydroxybenzoic acid O-beta-D-glucoside (PHB-glc) was identified as a product of the enzymatic reaction. This glucosyltransferase has a molecular weight of 47,500 Da, an isoelectric point at pH 5.0, and a pH optimum of 7.8. The enzyme does not sediment at 100,000g. Enzyme activity did not require metal cofactors. The enzyme was highly specific for p-hydroxybenzoate (Km 0.264 mM) and UDP-glucose (Km 0.268 mM). Initial velocity studies suggest that the enzyme reaction mechanism is a sequential rather than a ping-pong mechanism. Product inhibition patterns are consistent with an ordered sequential bi-bi mechanism, where UDPG is the first substrate to bind to the enzyme and UDP the final product released. The data indicate the formation of a dead-end complex between PHB-glc and the enzyme. Uncompetitive inhibition by the substrate PHB can be put down to the formation of an abortive complex between E-UDP and PHB.     

极端酶的研究进展

极端酶具有超常的生物学稳定性,能够在极端温度、pH、压力和离子强度下表现出生物学活性,因此极端酶为生物催化和生物转化提供了良机.新的极端物种的发现、基因组序列的确定及基因工程技术的应用,加快了发现和制备新酶的进程.蛋白质工程和定向进化技术进一步改善酶的活性和特异性,促进了极端酶的工业应用.对极端酶的研究加深了人们对酶稳定性机制的理解,丰富了分子进化理论.     

UDP-Glucose level as a limiting factor for IAA-induced cell elongation in Avena coleoptile segments

The effects of galactose on IAA-induced elongation and endogenous level of UDP-glucose (UDPG) in oat ( Avena sativa L. cv. Victory) coleoptile segments were examined under various growth conditions to see if there was a correlation between the level of UDPG and auxin-induced growth. The following results were obtained:

• (1)

  Galactose (10 m M ) inhibited the auxin-induced cell elongation of oat coleoptile segments after a lag of ca 2 h. Determinations of cell wall polysaccharides and UDP-sugars indicated that galactose, when inhibiting the cell wall polysaccharide synthesis, decreased the level of UDPG but caused an increase in the levels of Gal-1-P and UDP-Gal.
• (2)

  When coleoptile segments treated with IAA and galactose were transferred to galactose-free IAA-solution, the segment elongation was restored and the amounts of cell wall polysaccharides increased. During this period, the amount of UDPG increased and the levels of Gal-1-P and UDP-Gal slightly decreased or leveled off. The UDP-pentoses changed similarly as UDPG did.
• (3)

  Addition of sucrose (30 m M ) enhanced IAA-induced cell elongation and removed growth inhibition by 1 m M galactose. Sucrose increased the amounts of the cell wall polysaccharides and the level of UDPG in the presence or absence of IAA and also counteracted the decrease in UDPG caused by galactose.

These results indicate that the level of UDPG is an important limiting factor for cell wall biosynthesis and, thus, for auxin-induced elongation.