A concise synthesis of arabinogalactan with β-(1→6) galactopyranose backbone and α-(1→2) arabinofuranose side chains

Penta- and octasaccharides composed of β-(1→6)-linked galactose backbone with α-(1→2)-linked arabinose branches were synthesized through coupling of α-(1→5)-linked arabinofuranosyl disaccharide donor with a tri- and tetrasaccharide backbone at C-2, respectively.     

固相载体法合成低聚糖

固相载体法合成低聚糖;固相载体;合成;低聚糖;偶联剂     

Studies on the Total Synthesis of the Repeat Unit of Candida kefyr IFO 0586 Strain

Ithasrecentlybeenreportedthatthea-linkedoligo-D-mannosylsidechainsofacell-wallD-marmanofthepathogenicyeastalbicansareinlargepartresponsiblefortheyeastcellbindingtothemarginalzoneofmousespleen',andthealkali-releaseda-linkedD-manno-oligosaccharidesisolatedfromaCandidaalbicanscell-wallD-mannanwerepotentinhibitorsoflymphoproliferationinducedbytheparentD-mannan'.Thesefactsseemofinterestfromtheviewpointofbothhost-parasiteinteractionsandthebiologicalrolesofcarbohydrates.StructuralanalysisoftheD-man…     

Total Synthesis of a Partial Structure from Arabinogalactan and Its Application for Allergy Prevention

Arabinogalactan, a microheterogeneous polysaccharide occurring in plants, is known for its allergy-protective activity, which could potentially be used for preventive allergy treatment. New treatment options are highly desirable, especially in a preventive manner, due to the constant rise of atopic diseases worldwide. The structural origin of the allergy-protective activity of arabinogalactan is, however, still unclear and isolation of the polysaccharide is not feasible for pharmaceutical applications due to a variation of the activity of the natural product and contaminations with endotoxins. Therefore, a pentasaccharide partial structure was selected for total synthesis and subsequently coupled to a carrier protein to form a neoglycoconjugate. The allergy-protective activity of arabinogalactan could be reproduced with the partial structure in subsequent in vivo experiments. This is the first example of a successful simplification of arabinogalactan with a single partial structure while retaining its allergy-preventive potential.     

寡糖合成中的“预活化”策略

寡糖及其缀合物因其重要的生物学功能而日益受到人们的关注,由于糖链结构的复杂性与多样性,寡糖的化学合成具有很大的挑战性。为了减少合成及分离步骤,提高寡糖合成的效率,糖基化策略十分重要。"一釜合成法"由于进行多个连续的糖基化反应但不需分离中间体而具有很大优势,但传统"一釜法"在设计单糖模块时需要进行精细复杂的保护基操作和离去基调整而影响其合成效率。"预活化"寡糖合成策略不依赖于糖基供体与糖基受体的活性差异,无需复杂的保护基操作,所有偶联反应在同一条件下一釜完成,实现了寡糖的高效、快速合成。本文在简要介绍传统"一釜合成法"的基础上,对"预活化"策略的研究进展进行综述,重点介绍"预活化"策略的基本原理,发展过程及其在生物活性寡糖合成上的应用。     

寡糖的立体选择性合成策略

研究寡糖及缀合物的生物活性日益显现出重要的生物学意义, 采用化学合成方法研究特定的或糖苷键的构建对复杂寡糖及缀合物的合成极其重要. 到目前为止, 寡糖及其缀合物化学偶联立体选择性设计与合成策略是糖化学领域中十分活跃和引人注目的热点, 受到特别的关注. 综述了多年来高立体选择性寡糖的合成的研究进展.     

Synthesis of β-（ 1→6）-Branched （ 1→3）-Glucononaoside with Alter-nate β- and α-Bonds in the Backbone

Lauryl glycoside of β-D-Glcp-(1→3)-[β-D-Glcp-(1→6)-]α-D-Glcp-(1→3)-β-D-Glcp-(1→3)-[β-D-Glcp-(1→6)-]α-D-Glcp-(1→3)-β-D-Glcp-(1→3)-[β-D-Glcp-(1→6)-]β-D-Glcp was synthesized through 3 3 3 strategy. 3-O-Allyl-2,4,6-tri-O-benzoyl-β-D-glucopyranosyl-(1→3)- -[2, 3, 4, 6-tetra-O-benzoyl-β-D-glucopyranosyl-(1→6)-] 1,2-O-isopropylidene-α-D-glucofuranose was used as the key intermediate which was converted to the corresponding trisaccharide donor and acceptor readily.     

Synthesis of Analogues of the Antitumor （1→6）-Branched （1→3）-Glucohexaose

β-D-Glcp-(1→）3-[β-D-Glcp-(1→6)-]α-D-Manp-(1→3)-β-D-Glcp-(1→3)-[β-D-Glcp(1→6)-]D-Glcp(18)and β-D-Glcp(1→3)-[β-D-Glcp(1→6)-]α-D-Manp-(1→3)-β-D-Glcp(1→3)-[β-D-Glcp(1→6)-]β-D-Glcp-D-(1→3)-Glcp-1→OM3(29)were synthesized as the analogues of the immunomodulator β-D-Glcp-(1→3)-[β-D-Glcp(1→6)-]α-D-Glcp(1→3)-β-D-Glcp(1→63)-[β-D-Glcp(1→6)-]D-Glcp through coupling of trisaccharide donors 9 with trisaccharide acceptor 16 and tetrasaccharide acceptor 27 followed by deprotection,respectively.     

具有β-(1→6)-半乳吡喃糖骨架和α-L-(1→3)-阿拉伯呋喃糖侧链的阿拉伯半乳寡糖的简易合成

4-Methoxyphenyl glycoside of β-D-Galp-(1→6)-[α-L-Araf-(1→3)-]β-D-Galp-(1→6)-β-D-Galp-(1→6)-{β-D-Galp-(1→6)-[α-L-Araf-(1→3)-]β-D-Galp-(1→6)-β-D-Galp-(1→6)-}2β-D-Galp-(1→6)-[α-L-Araf-(1→)3)-]β-D-Galp-(1→)6)-β-D-Galp was synthesized with 2,3,4,6-tetra-O-benzoyl-α-D-galactopyranosyl trichloroacetimidate (1), 6-O-acetyl-2,3,4-tri-O-benzoyl-α-D-galactopyranosyl trichloroacetimidate (11), 4-methoxyphenyl 3-O-allyl-2,4-tri-O-benzoyl-β-D-galactopyranoside (2),isopropyl 3-O-allyl-2,4-tri-O-benzoyl--thio-β-D-galactopyranoside (12),4-methoxyphenyl 2,3,4-tri-O-benzoyl-β-D-galactopyranoside (5), and 2,3,5-tri-O-benzoyl-α-L-arabinofuranosyl trichloroacetimidate (8) as the key synthons.     

Facile and Effective Synthesis of Glucopyranosyl Oligosacchardes with Alternative (1→3)-α- and -β-Linkages in the Presence of C-2 Ester Capable of Neighboring Group Participation

β (1→ 3) Ｌｉｎｋｅｄｇｌｕｃａｎｓｏｃｃｕｒｉｎａｖａｒｉｅｔｙｏｆｂｉｏ ｌｏｇｉｃａｌｌｙｉｍｐｏｒｔａｎｔｎａｔｕｒａｌｐｒｏｄｕｃｔｓ ,ｓｕｃｈａｓａｎｔｉｔｕｍｏｒｓｃｈｉｚｏｐｈｙｌｌａｎ ,ｓｃｅｒｏｇｌｕｃａｎａｎｄｌｅｎｔｉｎａｎ ,1ｗｈｉｌｅα (1→3) ｌｉｎｋｅｄｇｌｕｃａｎｓｅｘｉｓｔｉｎｓｏｍｅｍｅｄｉｃａｌｌｙｉｍｐｏｒｔａｎｔｆｕｎｇｉｓｕｃｈａｓＣｒｙｐｈｏｎｅｃｔｒｉｎｉｐａｒａｓｉｔｉｃａａｎｄＧａｎｏｄｅｒｍａｌｕ ｃｉｄｕｍ .2 Ｆｏｒａｓｔｕｄｙｏｎｔｈｅ…     

Studies Related to Norway Spruce Galactoglucomannans: Chemical Synthesis,Conformation Analysis,NMR Spectroscopic Characterization,and Molecular Recognition of Model Compounds

Galactoglucomannan (GGM) is a polysaccharide mainly consisting of mannose, glucose, and galactose. GGM is the most abundant hemicellulose in the Norway spruce (Picea abies), but is also found in the cell wall of flax seeds, tobacco plants, and kiwifruit. Although several applications for GGM polysaccharides have been developed in pulp and paper manufacturing and the food and medical industries, attempts to synthesize and study distinct fragments of this polysaccharide have not been reported previously. Herein, the synthesis of one of the core trisaccharide units of GGM together with a less‐abundant tetrasaccharide fragment is described. In addition, detailed NMR spectroscopic characterization of the model compounds, comparison of the spectral data with natural GGM, investigation of the acetyl‐group migration phenomena that takes place in the polysaccharide by using small model compounds, and a binding study between the tetrasaccharide model fragment and a galactose‐binding protein (the toxin viscumin) are reported.     

A New and Practical Procedure for the Preparation of the Glucohexatose Phytoalexin Elicitor

The phytoalexin elicitor β-(1→3)-branched β-( 1→6)-linked glucohexatose has been regio- and stereospecifically synthesized by coupling of the 3, 6-branched gluco-trisaccharide Schmidt reagent 10 with a mixture of multiol 3,6-branched gluco-trisaccharides 13 which consists of free 5,6‘-OH trisaccharide, free 5,2‘ ,6‘-OH trisaccharide, free 5,3‘ ,6‘-OH trisaccharide and so on. The compounds 10 and 13 were prepared from 1,2:5,6-di-O-isopropylidene-α-D-glucofuranose , 2, 3, 4, 6-tetra-O-ben-zoyi-a-D-glucopyranosyl trichioroacetimldate, and 2,3,4, 6-tetra-O-acetyl-α-D-glucopyranosyl trichloreacetimidate through regio- and stereoselective manners.     

脱水糖苷化方法合成肝素酶底物寡糖

乙酰肝素酶（Heparanase,Hpa）是哺乳动物体内的内切葡萄糖醛酸苷水解酶,通过水解葡萄糖醛酸（GlcA）与己胺糖（GlcN）之间的β-糖苷键,选择性地降解肝素和硫酸肝素糖胺聚糖,从而释放多功能的肝素寡糖.本文报道一条高效的肝素酶底物寡糖的合成路线：采用苯甲酰基保护待硫酸化的羟基,苄基保护羧基和裸露的羟基,叠氮基保护氨基,应用脱水糖苷化方法高效地构建关键的a-GlcN-（1→4）-GlcA糖苷键.然后通过标准化的保护基脱除和硫酸化操作,获得肝素酶底物三糖和四糖1-4.最后五步反应的总收率超过52%.肝素酶底物寡糖的合成为研究肝素酶的底物选择性和活性检测打下了基础.     

CHEMOENZYMATIC SYNTHESIS OF NeuAcα-(2→3)-Galβ-(1→3)-[NeuAcα-(2→6)]-GalNAcα1- O-(Z)-Serine (N-PROTECTED MUC II OLIGOSACCHARIDE–SERINE)

An efficient synthesis of NeuAcα-(2→3)-Galβ-(1→3)-[NeuAcα-(2→6)]-GalNAcα1- O-(Z)-Serine (N-protected MUC II oligosaccharide–serine, 14) by a chemoenzymatic strategy is described. The enzymatic reaction of GalNAcα1- O-(Z)-Ser- OAll 7 with pNP-β-Gal in the presence of recombinant β1,3-galactosidase from Bacillus circulans gave Galβ-(1→3)-GalNAcα1- O-(Z)-Ser- OAll 3 in 68%. The introduction of two sialic acids into 3 was accomplished by a stepwise method. The branched Galβ-(1→3)-[NeuAcα-(2→6)]-GalNAcα1- O-(Z)-Ser- OAll 11 was constructed by a chemical method. Sialylation at the C-3 position of the terminal Gal residue on Galβ-(1→3)-[NeuAcα-(2→6)]-GalNAcα1- O-(Z)-Serine 2 using α2,3-(O)-sialyltransferase from rat liver gave a target compound 14 in a practical yield.     

Automated solid-phase synthesis of protected oligosaccharides containing beta-mannosidic linkages

For automated oligosaccharide synthesis to impact glycobiology, synthetic access to most carbohydrates has to become efficient and routine. Methods to install "difficult" glycosidic linkages have to be established and incorporated into the overall synthetic concept. Described here is the first automated solid-phase synthesis of oligosaccharides containing the challenging beta-mannosidic linkage. Carboxybenzyl mannoside building blocks proved effective beta-mannosylation agents and resulted in excellent conversion and good to moderate selectivities. [(Triisopropylsilyl)oxy]-methyl ether (Tom), served as an orthogonal, minimally intrusive, and readily cleavable protecting group for the elongation of the C3 position of mannose. The desired oligosaccharide products were readily separated from by-products containing unwanted stereoisomers using reverse-phase HPLC. The methods described here expand the scope of carbohydrates currently accessible by automation as many oligosaccharides of biological interest contain beta-mannosidic linkages.     

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.     

固相合成寡糖的进展

固相法是一种非常有前途的合成寡糖的方法。本文综述了固相法合成寡糖的进展。论述了固相合成寡糖的原理、所用的聚合物载体、合成过程的检测、偶联和拆解的方法等。