有机锡化合物在天然产物合成中的应用

综述了有机锡化合物在不同对称合成天然产物中的应用。有机锡化合物应用于天然产物的不对称合成,反应条件温和、活性高,有很高的立体选择性和区域选择性,有广阔的应用前景。     

生物催化在绿色化学和新药开发中的应用

近年来生物技术领域有了突破性进展,如: 公共基因数据库(GenBank)和蛋白质数据库(PDB)中序列的指数增长,高效基因克隆和表达平台的建立,可有效改进生物催化剂专一性、选择性和稳定性的酶定向进化技术的应用。这些进展使生物催化在化学合成中日趋重要[1]。本文综述了生物催化在如下领域的成功应用：在药物生产中用于开发经济的化学酶法合成工艺,在绿色化学领域中最大程度的减少废物的产生和危险试剂的应用,在天然化学领域中对天然产物进行修饰以发现具有更好生物活性的新药物。     

生物催化在高分子合成中的应用

生物催化剂已被越来越多地用于高分子学中,产生了许多新的反应、工艺和商业用途.酶和全细胞工艺都引起了众多关注,生物催化剂的立体选择性是它们的主要优势之一,新的或改良的方法层出不穷.生物催化的进程主要集中在几个方面上:聚合反应、聚合物修饰反应、聚合物降解反应以及单体和低聚物的合成.在这篇文章中,我们总结了生物催化在高分子合成中的最新应用.     

环钯化合物合成及其在催化中的应用

环钯化合物由于丰富的结构、高度的稳定性和卓越的催化性能,已成为钯化学研究的热点之一。迄今已开发出了C-H键活化、氧化加成、转金属化、亲核加成和配体交换等多种方法,可制备出从三元环到十一元环的CY型环钯化合物和多种YCY型环钯化合物。环钯化合物目前已应用于偶联、烯烃氢化和不对称催化等反应中。本文简单介绍了环钯化合物的种类,重点介绍了环钯化合物的合成方法和催化应用情况,最后提出了环钯化合物在今后合成研究和催化应用中的发展建议。     

面包酵母在催化不对称合成中的应用

介绍了当前国内外在以面包酵母为催化剂不对称催化合成手性化合物的研究情况,重点介绍了面包酵母催化各类潜手性羰基的不对称还原、潜手性碳一碳双键的不对称加成和碳一碳键形成的反应情况,讨论了各种提高酵母催化不对称合成反应立体选择性的方法,对酵母催化不对称合成有关生物学方面的研究进行了简单的介绍。     

用不保护或少保护的糖基受体合成寡糖*

用不保护或少保护的葡萄糖、甘露糖、鼠李糖作为糖基受体,经由糖原酸酯的中间体,能高区选和立体选地合成寡糖. α-(1→6)-连接的甘露寡糖、β-(1→6)-连接的葡萄寡糖、3,6-支化的甘露寡糖及葡萄寡糖用此方法能用很简单步骤合成,如具有重要生物活性的寡糖植保素激活剂葡萄六糖、具有抗肿瘤活性的香菇多糖的活性片段,以及一些具有重要生理功能的多糖的重复单元等.本文同时简述了用少保护的半乳糖和氨基葡萄糖为糖基受体合成寡糖的进展.     

酶催化在聚合物合成中的应用进展

酶催化聚合反应条件温和、选择性高,引起了众多学者的关注。本文综述了酶催化方法在多糖、聚酯、聚碳酸酯、聚苯胺、聚烯烃和酚聚合物合成中的应用进展,并介绍了其在合成特殊结构聚合物方面的优势。虽然酶催化聚合反应具有良好的应用前景,但该类反应尚存在一些需要解决的问题,本文对此也进行了探讨。     

杂多化合物膜在乙酸乙酯合成中的催化性能

乙酸乙酯是一种重要的有机物,有着广泛应用。杂多酸作催化剂具有催化活性高、选择性好、用量少、产品质量高、对设备无腐蚀、对环境无污染等优点[1-6]。本文从膜催化[7-9]、多相催化的角度、采用多孔钛片载磷钨酸膜研究杂多化合物在乙酸乙酯合成中的催化性能,探讨反应温度、酸醇比对酯收率的影响。1　实验部分1.1　主要仪器与试剂ＧＣ102-Ｎ气相色谱仪(上海分析仪器厂);Ｎ2000色谱数据工作站(浙江大学智能信息工程研究所);ＸＭＴ数显调节仪,ＺＫ-1可控硅电压调整器(联泰仪表有限公司);ＡＢ204电子天平(ＭＥＬＥＲＴＯＬＥＤＯＣＯＭＰＡ…     

甘油在微生物代谢合成及生物催化中的应用

生物柴油是一种可再生能源,因其可替代石油来源的柴油而日益受到重视。随着生物柴油工业的蓬勃发展,其制备过程中的主要副产物甘油出现明显的产能过剩。作为一种廉价的清洁资源,甘油的深度开发和利用既是发展生物柴油工业的关键,也符合绿色化学的发展要求。近年来,甘油不仅作为重要的起始原料用于一些高附加值化学品的制备,而且因其独特的理化性质和易降解、生物相容性好等特性,在生物催化和绿色溶剂领域的应用研究日趋活跃。本文主要综述了甘油在工业微生物发酵、生物合成和绿色溶剂领域的研究进展,并就其应用中存在的一些问题,如甘油原料品质和微生物利用效率等进行分析,同时展望了甘油在生物催化领域的应用前景。     

天然-合成高分子生物杂化材料在生物医学领域中的应用

综述了天然—合成高分子生物杂化材料在生物医学领域中的应用，并分析了它作为组织工程基质和药物载体的优点，指出生物杂化材料是生物医用材料的发展趋势。     

Modular synthesis of heparin oligosaccharides

A general, modular strategy for the first completely stereoselective synthesis of defined heparin oligosaccharides is described. Six monosaccharide building blocks (four differentially protected glucosamines, one glucuronic and one iduronic acid) were utilized to prepare di- and trisaccharide modules in a fully selective fashion. Installation of the alpha-glucosamine linkage was controlled by placing a conformational constraint on the uronic acid glycosyl acceptors thereby establishing a new concept for stereochemical control. Combination of disaccharide modules to form trans-uronic acid linkages was completely selective by virtue of C2 participating groups. Coupling reactions between disaccharide modules exhibited sequence dependence. While the union of many glucosamine uronic acid disaccharide modules did not meet any problems, certain sequences proved not accessible. Elaboration of glucosamine uronic acid disaccharide building blocks to trisaccharide modules by addition of either one additional glucosamine or uronic acid allowed for stereoselective access to oligosaccharides as demonstrated on the example of a hexasaccharide resembling the ATIII-binding sequence. Final deprotection and sulfation yielded the fully synthetic heparin oligosaccharides.     

Enzymatic synthesis of prebiotic oligosaccharides

Prebiotic oligosaccharides are nondigestible carbohydrates that can be obtained by enzymatic synthesis. Glucosyltransferases can be used to produce these carbohydrates through an acceptor reaction synthesis. When maltose is the acceptor a trisaccharide composed of one maltose unit and one glucose unit linked by an alpha-1,6-glycosidic bond (panose) is obtained as the primer product of the dextransucrase acceptor reaction. In this work, panose enzymatic synthesis was evaluated by a central composite experimental design in which maltose and sucrose concentration were varied in a wide range of maltose/sucrose ratios in a batch reactor system. A partially purified enzyme was used in order to reduce the process costs, because enzyme purification is one of the most expensive steps in enzymatic synthesis. Even using high maltose/sucrose ratios, dextran and higher-oligosaccharide formation were not avoided. The results showed that intermediate concentrations of sucrose and high maltose concentration resulted in high panose productivity with low dextran and higher-oligosaccharide productivity.     

Construction of N-glycan microarrays by using modular synthesis and on-chip nanoscale enzymatic glycosylation

An effective chemoenzymatic strategy is reported that has allowed the construction, for the first time, of a focused microarray of synthetic N-glycans. Based on modular approaches, a variety of N-glycan core structures have been chemically synthesized and covalently immobilized on a glass surface. The printed structures were then enzymatically diversified by the action of three different glycosyltransferases in nanodroplets placed on top of individual spots of the microarray by a printing robot. Conversion was followed by lectin binding specific for the terminal sugars. This enzymatic extension of surface-bound ligands in nanodroplets reduces the amount of precious glycosyltransferases needed by seven orders of magnitude relative to reactions carried out in the solution phase. Moreover, only those ligands that have been shown to be substrates to a specific glycosyltransferase can be individually chosen for elongation on the array. The methodology described here, combining focused modular synthesis and nanoscale on-chip enzymatic elongation, could open the way for the much needed rapid construction of large synthetic glycan arrays.     

A Glycan Array‐Based Assay for the Identification and Characterization of Plant Glycosyltransferases

Growing plants with modified cell wall compositions is a promising strategy to improve resistance to pathogens, increase biomass digestibility, and tune other important properties. In order to alter biomass architecture, a detailed knowledge of cell wall structure and biosynthesis is a prerequisite. We report here a glycan array‐based assay for the high‐throughput identification and characterization of plant cell wall biosynthetic glycosyltransferases (GTs). We demonstrate that different heterologously expressed galactosyl‐, fucosyl‐, and xylosyltransferases can transfer azido‐functionalized sugar nucleotide donors to selected synthetic plant cell wall oligosaccharides on the array and that the transferred monosaccharides can be visualized “on chip” by a 1,3‐dipolar cycloaddition reaction with an alkynyl‐modified dye. The opportunity to simultaneously screen thousands of combinations of putative GTs, nucleotide sugar donors, and oligosaccharide acceptors will dramatically accelerate plant cell wall biosynthesis research.     

A Glycan Array-Based Assay for the Identification and Characterization of Plant Glycosyltransferases

Growing plants with modified cell wall compositions is a promising strategy to improve resistance to pathogens, increase biomass digestibility, and tune other important properties. In order to alter biomass architecture, a detailed knowledge of cell wall structure and biosynthesis is a prerequisite. We report here a glycan array-based assay for the high-throughput identification and characterization of plant cell wall biosynthetic glycosyltransferases (GTs). We demonstrate that different heterologously expressed galactosyl-, fucosyl-, and xylosyltransferases can transfer azido-functionalized sugar nucleotide donors to selected synthetic plant cell wall oligosaccharides on the array and that the transferred monosaccharides can be visualized “on chip” by a 1,3-dipolar cycloaddition reaction with an alkynyl-modified dye. The opportunity to simultaneously screen thousands of combinations of putative GTs, nucleotide sugar donors, and oligosaccharide acceptors will dramatically accelerate plant cell wall biosynthesis research.     

硫代糖苷在糖化学合成中的应用

介绍了近几年来有关硫代糖苷在一些复杂寡糖及其缀合物合成中的应用。     

Prompt chemoenzymatic synthesis of diverse complex-type oligosaccharides and its application to the solid-phase synthesis of a glycopeptide with Asn-linked sialyl-undeca- and asialo-nonasaccharides

We describe herein the preparation of 24 pure asparagine-linked oligosaccharides (Asn-oligosaccharides) from asparagine-linked biantennary complex-type sialylundecasaccharide [(NeuAc-alpha-2,6-Gal-beta-1,4-GlcNAc-beta-1,2-Man-alpha-1,6/1,3-)(2)-Man-beta-1,4-GlcNAc-beta-1,4-GlcNAc-beta-1-asparagine, 2] obtained from egg yolk. Our synthetic strategy aimed at adapting branch specific exo-glycosidases digestion (beta-D-galactosidase, N-acetyl-beta-D-glucosaminidase and alpha-D-mannosidase) of the individual asialo-branch after preparation of monosialyloligosaccharides obtained from 2 by acid hydrolysis of NeuAc. In order to perform branch specific exo-glycosidase digestion, isolation of pure monosialyloligosaccharides obtained was essential. However, isolation of two kinds of monosialyloligosaccharides are difficult by HPLC due to their highly hydrophilic nature. Therefore, we examined chemical protection with hydrophobic protecting (Fmoc and benzyl) groups. These chemical protection enabled us to separate the monosialyloligosaccharides by use of a HPLC column (ODS) on synthetic scales. Using these pure monosialiloligosaccharides enable us to obtain 24 Asn-linked oligosaccharides (100 mg scale) within a few weeks by branch specific exo-glycosidase digestions (alpha-D-neuraminidase, beta-D-galactosidase, N-acetyl-beta-D-glucosaminidase and alpha-D-mannosidase). In addition, solid-phase synthesis of glycopeptide having Asn-linked sialyl-undeca- and asialo-nonasaccharides thus obtained, was also performed on an acid labile HMPA-PEGA resin.