First total synthesis of a GPI-anchored peptide

A GPI-anchored dipeptide of sperm CD52 antigen was prepared through a convergent synthesis. First, the dipeptide with its C-terminus free and the GPI with its nonreducing end phosphoethanolamine bearing a free amino group were synthesized separately. Then, the two building blocks were coupled with use of EDC/HOBt as the condensation reagent. Finally, the GPI-anchored peptide was deprotected to give the target molecule 1.     

Synthesis of a malaria candidate glycosylphosphatidylinositol (GPI) structure: a strategy for fully inositol acylated and phosphorylated GPIs

A congener of the glycosylphosphatidylinositol (GPI) membrane anchor present on the cell surface of the malaria pathogen Plasmodium falciparum has been synthesized. This GPI is an example of a small number of such membrane anchors that carry a fatty acyl group at O-2 of the inositol. Although the acyl group plays crucial roles in GPI biosynthesis, it rarely persits in mature molecules. Other notable examples are the mammalian GPIs CD52 and AchE. The presence of bulky functionalities at three contiguous positions of the inositol moiety creates a very crowded environment that poses difficulties for carrying out selective chemical manipulations. Thus installations of the axial long-chain acyl group and neighboring phosphoglyceryl complex were fraught with obstacles. The key solution to these obstacles in the successful synthesis of the malarial candidate and prototype structures involved stereoelectronically controlled opening of a cyclic ortho ester. The reaction proceeds in very good yields, the desired axial diastereomer being formed predominantly, even more so in the case of long-chain acyl derivatives. The myoinositol precursor was prepared from methyl alpha-d-glucopyranoside by the biomimetic procedure of Bender and Budhu. For the glycan array, advantage was taken of the fact that (a). n-pentenyl ortho ester donors are rapidly and chemospecifically activated upon treatment with ytterbium triflate and N-iodosuccinimide and (b). coupling to an acceptor affords alpha-coupled product exclusively. A strategy for obtaining the GPI's alpha-glucosaminide component from the corresponding alpha-mannoside employed Deshong's novel azide displacement procedure. Thus all units of the glycan array were obtained from a beta-d-manno-n-pentenyl ortho ester, this being readily prepared from d-mannose in three easy, high-yielding steps. The "crowded environment" at positions 1 and 2, noted above, could conceivably be relieved by migration of the acyl group to the neighboring cis-O-3-hydroxyl in the natural product. However, study of our synthetic intermediates and prototypes indicate that the O-2 acyl group is quite stable, and that such migration does not occur readily.     

Total synthesis of a glycosylphosphatidylinositol anchor of the human lymphocyte CD52 antigen

The first total synthesis of a glycosylphosphatidylinositol (GPI) anchor bearing a polyunsaturated arachidonoyl fatty acid is reported. This lipid is found in mammalian GPIs that do not undergo lipid remodeling, a process that has important implications in the localization and function of GPI-anchored proteins. Incorporation of the oxidation- and reduction-sensitive arachidonoyl lipid in the target GPI was accomplished by using the para-methoxybenzyl (PMB) group for permanent hydroxyl group protection, which featured a selective, rapid, and efficient global deprotection protocol. The flexibility of this synthetic strategy was further highlighted by the inclusion of two additional GPI core structural modifications present in the GPI anchor of the human lymphocyte CD52 antigen.     

Assembly of a series of malarial glycosylphosphatidylinositol anchor oligosaccharides

We report an efficient and convergent synthesis of a series of oligosaccharides comprised of the malaria GPI glycan (2a), a promising anti-malaria vaccine candidate currently in preclinical trials and several related oligosaccharide sequences (3-8) that are possible biosynthetic precursors of the malarial GPI. A flexible synthetic strategy is disclosed that relies on a late-stage coupling between oligomannosides of varying length and pseudo-disaccharide glycosyl acceptor 11 to readily access various malarial GPI structures. Phosphorylation was accomplished by mild and efficient H-phosphonate chemistry before the final deprotection was carried out by using sodium in ammonia. The direct connection of a thiol group via a phosphate diester linkage to the inositol moiety provides a handle for easy conjugation of the GPI glycan to carrier proteins, immobilization on carbohydrate microarrays and photo-affinity labels identification. These synthetic oligosaccharides will serve as molecular probes.     

糖基磷脂酰肌醇及其锚定蛋白的合成研究进展

在真核生物中,蛋白质的C-末端以共价键形式与糖基磷脂酰肌醇（GPI）相连是一种常见的翻译后修饰,GPI修饰的蛋白质可以通过GPI锚定在细胞膜的外叶.GPI锚及其锚定蛋白的结构复杂、多样,在众多生物学过程中扮演着不可或缺的重要作用.化学合成结合酶催化反应是获得结构明确、纯度高的GPI锚及GPI锚定蛋白的重要方法,为在分子水平上深入探索此类化合物的结构和生物学功能奠定了基础.本文对此合成领域中所涉及的光学纯且差异性保护的肌-肌醇衍生物的制备、天然来源GPI的合成策略、以结构多样性为导向的GPI衍生物的合成,以及GPI锚定蛋白的合成策略进行综述.     

Convergent synthesis of a fully phosphorylated GPI anchor of the CD52 antigen

A fully phosphorylated GPI anchor (1) of the CD52 antigen was synthesized by a highly convergent strategy. After a trimannose and a phospholipidated pseudodisaccharide were prepared separately, they were coupled together to form the GPI core, which was then phosphorylated to introduce two phosphoethanolamine moieties in one step to afford CD52 GPI in its fully protected form. Finally, global deprotection of the product resulted in 1.     

Labeling Cell Surface GPIs and GPI‐Anchored Proteins through Metabolic Engineering with Artificial Inositol Derivatives

Glycosylphosphatidylinositol (GPI) anchoring of proteins to the cell surface is important for various biological processes, but GPI‐anchored proteins are difficult to study. An effective strategy was developed for the metabolic engineering of cell‐surface GPIs and GPI‐anchored proteins by using inositol derivatives carrying an azido group. The azide‐labeled GPIs and GPI‐anchored proteins were then tagged with biotin on live cells through a click reaction, which allows further elaboration with streptavidin‐conjugated dyes or other molecules. The strategy can be used to label GPI‐anchored proteins with various tags for biological studies.     

A convergent, versatile route to two synthetic conjugate anti-toxin malaria vaccines

The synthesis of two glycosylphosphatidyl inositol (GPI) glycans that constitute the malaria toxin and promising anti-toxin vaccine constructs using a scalable route is described.     

A variable concept for the preparation of branched glycosyl phosphatidyl inositol anchors

A variable concept for the synthesis of branched glycosyl phosphatidyl inositol (GPI) anchors was established. Its efficiency could be shown by the successful synthesis of the GPI anchor of rat brain Thy-1 and of the scrapie prion protein both in the water soluble 1c and lipidated form 1a. Retrosynthesis led to building blocks 2-6 of which 5 could be further disconnected to building blocks 7-9. Trichloroacetimidate 5 was built up in a straightforward manner starting from glycosyl acceptor 9 using known glycosyl donors 7 and 8. The carbohydrate backbone was then assembled by glycosylation of pseudodisaccharide acceptor 6 with donor 5. To ensure high stereoselectivity and good yields in the glycosylation reactions, anchimeric assistance was employed. Successive deprotection and introduction of the various phosphate residues gave the fully protected GPI anchors. Catalytic hydrogenation and acid-catalyzed cleavage of the Boc protecting groups afforded the target molecules, which could be fully structurally assigned.     

1,2-Diacetals in synthesis: total synthesis of a glycosylphosphatidylinositol anchor of Trypanosoma brucei

A full account on a total synthesis of GPI anchor 1 employing butanediacetal (BDA) groups and a chiral bis(dihydropyran) is presented. The reactivity of selenium and thio glycosides was tuned by the use of BDA groups. This allowed the assembly of an appropriately protected GPI anchor precursor 2 in just six steps from the six building blocks 5-10 including only one protecting group manipulation. myo-Inositol was desymmetrised with the bis(dihydropyran) derivative 15 and appropriately protected to give inositol acceptor 21 in nine steps and 17% overall yield. The use of common starting materials and BDA-protections give efficient access to building blocks 5, 6, 7 and 8. A new and improved synthesis of the glucosamine donor 28 is included. In summary, a highly convergent and efficient synthesis of GPI anchor 1, which is clearly adaptable to other GPI anchors, has been reported.     

Combinatorial solid-phase synthesis of hapalosin mimetics

The solid-phase synthesis of a small library of mimetics of the cyclic depsipeptide hapalosin is described. 3-Amino-4-hydroxy-5-nitrobenzoic acid was anchored through the anilino moiety to a backbone amide linker (BAL) handle support. Using chemoselective reactions and without the need for protecting group manipulations, the benzoic acid group was first amidated, then the aniline nitrogen was acylated, and finally the nitro group was reduced to an amine and acylated or reductively alkylated, to generate a 12-member library.     

Three New Resin Glycosides and a New Tetrahydropyran Derivative from the Seeds of <i>Quamoclit pennata</i>

Three new resin glycosides, quamoclins V (1), VI (2), and VII (3) and a new tetrahydropyran derivative, quamopyran (4), were isolated from the seeds of Quamoclit pennata BOJER (Convolvulaceae). The chemical structures of these compounds were determined primarily on the basis of spectroscopic data. The carboxyl group of the aglycone, 11S-convolvulinolic acid, of 1 and 2 was linked intermoleculary with a hydroxy group of the sugar moiety to form a macrocyclic ester structure, as in already known jalapins, and 3 was an acylated glycosidic acid methyl ester. All of the sugar moieties of 1-3 were acylated by one 2S-methylbutyric acid. Compound 4 was a diketone having a tetrahydropyran ring.     

Synthesis and biochemical properties of oligodeoxynucleotides acylated by the chemically stable 2-(trimethylsilyl)benzoyl (TMSBz) group at the 5′ or 3′ terminus

Oligodeoxynucleotides acylated with a 2-(trimethylsilyl)benzoyl (TMSBz) group at the 5′ or 3′ terminus were synthesized according to the general method used for DNA synthesis. The acylated DNA oligomers could be easily purified due to the high lipophilicity of the TMSBz group and showed enhanced hybridization ability and resistance to exonucleases.     

Friedel-Crafts chemistry of dieneiron tricarbonyl complexes. Acetylation of 1-silylated and 1,4 disubstituted dienes

In contrast to simple olefinic or to aromatic compounds bearing a silyl group attached to an sp² carbon, trimethyl-silylated dieneiron tricarbonyl complexes, do not undergo ipso-substitution reactions unless there is an alkyl group in the 4 position. This allows synthesis of acylated dienes that still retain the Me₃Si substituent. In one case an unusual 1,1-diacylation was observed during an attempted single acetylation. 1,4-Disubstituted dieneiron tricarbonyl complexes were found to give good yields of stable acylated complexes under the usual Friedel-Crafts conditions.     

Synthesis of Novel,Fluorescently Tagged Analogs of Glycosylphosphatidylinositol (GPI) Anchors

Glycosylphosphatidylinositol (GPI) anchors are a group of complex glycolipids that attach extracellular proteins and glycoproteins to the eukaryotic cell outer membrane. To better understand GPI anchorage, it is necessary to have access to homogeneous, structurally defined, and functionalized GPIs and GPI analogs. In this regard, chemical synthesis is necessary, as GPI anchors are rather scarce and heterogeneous in natural sources. Three GPI analogs with phosphoglycerolipids linked to the pseudodisaccharide core and their fluorescein conjugates were prepared in this work as a small tool set useful for probing how the lipid composition and carbohydrate anomeric configuration may affect the properties of GPI anchors.     

First synthesis of a malarial prototype: a fully lipidated and phosphorylated GPI membrane anchor

A strategy is described for syntheses of a fully lipidated and phosphorylated prototype of the GPI of Plasmodium falciparum, the causative agent of lethal cerebral, drug-resistant malaria. Orthoesters, prepared in four steps from d-mannose, and methyl α-d-glucopyranoside are the key starting materials. The latter furnishes the inositol moiety using Bender’s procedure, while the former gives the other four units of the pseudo-pentasaccharide. The strategy for installing the three biologically important acyl units of the phosphoinositide has been worked out. The critical, biosynthetically important C2-O-acyl group of the inositol is exceptionally stable, showing no tendency to migrate to the cis-related C3-OH in several test substrates.     

Synthesis of the fully phosphorylated GPI anchor pseudohexasaccharide of Toxoplasma gondii.

Retrosynthesis of the fully phosphorylated glycosylphosphatidyl inositol (GPI) anchor pseudohexasaccharide 1a led to building blocks 2-6, of which 5 and 6 are known. The formation of pseudodisaccharide building block 2 is based on readily available building block 7, which gave, via derivative 11 and its glycosylation with known donor 12, the desired compound 2. Building block 3, with the required access to all hydroxy groups being permitted, was prepared from mannose in five steps. From a readily available precursor, building block 4 was obtained, which on reaction with 3 gave disaccharide 23. The synthesis of the decisive pseudohexasaccharide intermediate 32 was based on the reaction of 23 with 5, then with 6, and finally with 2. To obtain high stereoselectivity and good yields in the glycosylation reactions, anchimeric assistance was employed. To enable regioselective attachment of the two different phosphorus esters, the 6f-O-silyl group of 32 was first removed and the aminoethyl phosphate residue was attached. Then the MPM group was oxidatively removed, and the second phosphate residue was introduced. Unprotected 1a was then liberated in two steps: treatment with sodium methanolate removed the acetyl protecting groups, and finally, catalytic hydrogenation afforded the desired target molecule, which could be fully structurally assigned.     

Synthesis of new sugar-based surfactants and evaluation of their hemolytic activities

The synthesis of four sugar-based surfactants derived from glucose and (R)-12-hydroxystearic acid is described. The surfactants have a hydroxy group in the hydrophobic part, which is either free or acylated using acetyl chloride, hexanoyl chloride, or myristoyl chloride. Three of the synthesized surfactants are water-soluble and are evaluated with respect to their CMCs and hemolytic activities. The fourth surfactant has limited water solubility and is not further included in the study. The investigated surfactants are all hemolytic close to their respective CMC indicating that their use in parenteral formulations may be limited. Nevertheless, surfactants having the proposed structure appear as promising alternatives to existing solubilizing agents for pharmaceutical applications.     

Solid-phase synthesis of 7-acylamino-1,4-benzodiazepine-2,5-diones

A method for the synthesis of polymer-bound 7-acylamino-benzodiazepine-2,5-diones is described. The amino group of an alpha-amino acid is linked to polystyrene or TentaGel resin via reductive amination of polymer-bound 4-alkoxy-2,6-dimethoxybenzaldehyde. Acylation with unprotected 5-nitroanthranilic acid is followed by base-catalyzed ring closure. Reduction of the nitro group yields enantiomerically pure 7-aminobenzodiazepin-2,5-dione attached via the N-4 atom to the resin. Acylation of the amino group on the aromatic ring with acid chlorides in N-methylpyrrolidone (no DMF, no base!) followed by cleavage from the resin using TFA/Me(2)S/water (90:5:5) provides the acylated benzodiazepinones in 52-69% (PS resin) and 41-48% (TG resin) yield (based on the theoretical loading) and >70% purity (HPLC, 210 nm). Using Fmoc-protected tyrosine fluoride in NMP gives the amino acid-coupled benzodiazepinones in 24% (PS resin) and 31% (TG resin) yield.     

Electrochemical Deallylation of α‐Allyl Cyclic Amines and Synthesis of Optically Active Quaternary Cyclic Amino Acids

Electrochemical oxidation of α‐allylated and α‐benzylated N‐acylated cyclic amines by using a graphite anode easily affords the corresponding α‐methoxylated products with up to 76 % yield. Ease of oxidation was affected by the type of electrode, the size of cyclic amine, and the nature of the protecting group. This method was successfully applied to the synthesis of optically active N‐acylated α‐alkyl‐α‐amino acid esters with up to 99 % ee.