A Comparative Study of Glycosyl Thioimidates as Building Blocks for Chemical Glycosylation

Our results indicate that the reactivity and the activation profile of thioimidate glycosyl donors vary significantly depending on the endocyclic heteroatom (N,O,S). Reactivity diminishes in accordance with the following sequence: O > S > N; and this trend stands for a majority of promoters tested. Acyclic glycosyl thioimidates were found to be generally less reactive than the respective cyclic counterparts. The difference in the reactivity was confirmed in direct competition experiments. These findings made possible a two-step one-pot selective activation using thioimidates as the anomeric leaving group of the glycosyl donor and temporary masking group of the glycosyl acceptor.

Supplemental materials are available for this article. Go to the publisher's online edition of Journal of Carbohydrate Chemistry to view the supplemental file.     

2‐[Dimethyl(2‐naphthylmethyl)silyl]ethoxy Carbonate (NSEC) as a New Mode of Hydroxyl Group Protection*

2‐[Dimethyl(2‐naphthylmethyl)silyl]ethoxy carbonate (NSEC) is a novel protecting group to mask hydroxyl groups. NSECCl is available in three steps from chlorodimethylvinylsilane and 2‐(bromomethyl)naphthalene. Introduction and removal of the NSEC group are performed easily and rapidly in the presence of most protecting groups currently used in carbohydrate chemistry. The removal of NSEC can be carried out under mild conditions in the presence of various ether and ester protecting groups. Additionally, the NSEC group is stable to glycosylation conditions using glycosyl phosphates. The synthesis of disaccharide 18 containing NSEC has been accomplished.     

Promoter-Controlled Synthesis and Conformational Analysis of Cyclic Mannosides up to a 32-mer

Cyclodextrins are widely used as carriers of small molecules for drug delivery owing to their remarkable host properties and excellent biocompatibility. However, cyclic oligosaccharides with different sizes and shapes are limited. Cycloglycosylation of ultra-large bifunctional saccharide precursors is challenging due to the constrained conformational spaces. Herein we report a promoter-controlled cycloglycosylation approach for the synthesis of cyclic α-(1→6)-linked mannosides up to a 32-mer. Cycloglycosylation of the bifunctional thioglycosides and (Z)-ynenoates was found to be highly dependent on the promoters. In particular, a sufficient amount of a gold(I) complex played a key role in the proper preorganization of the ultra-large cyclic transition state, providing a cyclic 32-mer polymannoside, which represents the largest synthetic cyclic polysaccharide to date. NMR experiments and a computational study revealed that the cyclic 2-mer, 4-mer, 8-mer, 16-mer, and 32-mer mannosides adopted different conformational states and shapes.     

O2-2,4-二硝基苯基偶氮二醇盐类化合物的设计、合成及抗肿瘤活性

以O2-2,4-二硝基苯基偶氮二醇盐(PABA/NO)为先导化合物,选择适当的仲胺作为偶氮二醇盐中相应的胺片段,并用碳氮键取代苯环5位的碳氧酯键,设计合成了化合物2a,2b和4a~4j,以期获得活性更强且稳定性好的抗肿瘤药物.目标化合物经1H NMR,13C NMR及HRMS进行了结构确证.生物活性测试结果表明,目标化合物可不同程度地抑制结肠癌HCT-116细胞的增殖,其中化合物4h的活性最强(IC50=7.945±0.421 μmol/L),优于PABA/NO(IC50=12.134±0.675 μmol/L).NO释放实验结果表明,此类化合物的NO释放量与细胞毒性呈正相关.化合物4h在HCT-116细胞中释放NO的量最多,约是正常细胞的2倍.此外,化合物4h在大鼠血浆中的体外稳定性显著优于PABA/NO,值得进一步研究.     

由D-Erythorbic Acid合成新的多官能团C4手性筑块

手性C4筑块是合成许多天然产物 Leukotrienes, Pyrrolizidine alkaloids及前列腺素A2等的重要合成子[1～3]. 然而到目前为止, 手性C4筑块只有从少数几种手性源如酒石酸, L-苏糖, D-赤藓糖等中才能得到[2～7]. 我们在以D-erythorbic acid为原料合成新型手性配体的过程中[8～10], 发现了一种简便获得选择性保护的多官能团手性C4筑块(化合物4, 5)的新途径(Scheme 1).     

用不保护或少保护的糖为原料高区选、高立体选地合成寡糖

用不保护和少保护的糖为原料，用酰基为保护基，通过糖原酸酯的生成与重排，能高区选，高立体选地合成寡糖，合成步骤大为简化，此方法对甘露糖，葡萄糖非常有效，区选主要在3，6位，立体选对甘露糖只得到α-连接，对葡萄糖只是得到β－连接。一些有重要生理活性的寡糖，如植保素激活剂六糖－香菇多糖核心片段都能用此方法方便地合成。     

Regioselective Diastereomeric Michael Adducts as Building Blocks in Heterocyclic Synthesis

The reaction of 4‐(4‐acetylamino/bromophenyl)‐4‐oxobut‐2‐enoic acids with carbon nucleophiles afforded Michael adducts depending on the type of nucleophilic reagents and medium (acidic or basic). The adducts 2 and 3 were used as key starting materials to synthesize some heterocyclic compounds, which include pyridazinone, furanone, 1,2‐oxazin‐5‐one, 1.2‐diazapine, pyrane, and hydroxyl pyridine derivatives. The Steric factor plays an important role in regioselectivity. The structure of newly synthesized compounds was elucidated by elemental analysis and spectroscopic data.     

Synthetic Studies Toward Gangliosides and Their Analogs: Synthesis of Appropriately Protected Core Oligosaccharides as Construction Blocks

Abstract

2-(Trimethylsilyl)ethyl 2, 3, 6, 2′-tetra-O-acetyl-3′-O-benzyl-6′-O-benzyloxymethyl-β-d-lactoside (9) was synthesized starting from acetobromolactose (1) via 2-(trimethylsilyl)ethyl β-d-lactoside (3). Compound 9 was converted to the trisaccharide derivative 17 after coupling with 3,4,6-tri-O-acetyl-2-deoxy-2-phthalimido-α-d-galacto-pyranosyl bromide (11). Coupling of 17 with acetobromogalactose (19) gave the tetrasaccharide 20.     

Synthesis of Diastereomeric 8-Fluoro-ABC-Steroid Building Blocks

An eight-step linear sequence for the preparation of two diastereomers of an 8-fluoro-ABC-steroid building block was developed. Key step was an intramolecular Diels–Alder reaction of an intermediate o-quinodimethane formed from a benzocyclobutene substituted with a 5-fluorohex-5-en-4-one chain. This side chain was prepared from 6-chlorohex-1-ene by bromofluorination, elimination of HBr, Finkelstein reaction and alkylation of a literature-known benzocyclobutene derivative with the thus-formed 6-iodo-2-fluorohex-1-ene. Allylic oxidation of side chain's fluorovinyl moiety to an α-fluoro-α,β-unsaturated ketone completed the preparation of the precursor for the [4+2]-cycloaddition.     

Highly Regio- and Stereoselective Synthesis of Mannose-Containing Oligosaccharides with Acetobromo Sugars as the Donors and Partially Protected Mannose Derivatives as the Acceptors via Sugar Orthoester Intermediates

An orthoester formation/rearrangement sequence , in which 1,2-O-ethylidenated mannose or partially protected mannosides function as the glycosyl acceptors and simple acetobromo sugars as the glycosyl donors (see reaction scheme), provides an efficient and highly regio- and stereoselective route to mannose-containing 1→6, 1→3, and 3,6-branched oligosaccharides with exclusive 1,2-trans linkage.     

Synthesis of Selectively Protected Chitobiose and Chitotriose Derivatives from one Precursor. Versatile Building Blocks for Oligosaccharide Synthesis

Abstract

The inner core region of cell surface N-glycoproteins consists of a chitobiose substructure², containing β-(1,4)-linked disaccharides of glucosamine. Such carbohydrate structures are also found as repeating units of the bacterial cell wall peptidoglycan³ and in novel tetra- and pentasaccharide plant hormones, which are nodulation factors on legume roots.⁴ Since the first synthesis of a chitobiose derivative in 1966 by Paulsen,⁵ approaches to these compounds have relied mainly on the oxazoline method.⁶ The coupling reactions of aminosugar chlorides,⁷ bromides,⁸ acetates⁹ and trichloroacetimidates¹⁰ to suitable glycosyl acceptors have also been described. Most of these syntheses¹¹ require two completely different coupling partners; only in very few examples could the glycosyl donor and acceptor be obtained from the same starting material.¹² During our investigations into the stereocontrolled synthesis of glucosamine oligosaccharides, we required an economical synthetic route to protected derivatives of chitotriose. For the purpose of easy oligomerization, the anomeric protecting group of every building block had to be exchangeable selectively with the activating group for the next glycosylation. In this paper, we report an efficient approach to chitobiose and chitotriose from a single precursor. Furthermore, the hydroxyl groups at C-1, C-3, C-4, C-6 of these oligosaccharides are differentially protected. This protecting group scenario allows a specific access to any of these functionalities by regioselective deblocking. The N-phthalimide group was chosen out of several possible amino protecting groups to ensure β-selectivity and simultaneous activation in the coupling.¹³     

Syntheses of N-aryl-protected glucosamines and their stereoselectivity in chemical glycosylations

N-Aryl-protecting groups were introduced in glucosamines to achieve β-selective glycosylation. Various N-aryl aminosugars were synthesized via Buchwald–Hartwig reaction. Glycosylation using glycosyl trichloroacetimidates of N-aryl aminosugars smoothly proceeded in the presence of trimethylsilyl trifluoromethanesulfonate. Use of a glycosyl donor comprising an electron-donating 2,4-dimethoxyphenyl (DMP) group led to the glycosylation proceeding with high β selectivity. This stereoselectivity seemed to be derived from the formation of an aziridine intermediate. The DMP-protecting group can be removed immediately by using ammonium hexanitratocerate (IV).     

Heterometallic Rings: Their Physics and use as Supramolecular Building Blocks

An enormous family of heterometallic rings has been made. The first were Cr₇M rings where M=Ni^II, Zn^II, Mn^II, and rings have been made with as many as fourteen metal centers in the cyclic structure. They are bridged externally by carboxylates, and internally by fluorides or a penta‐deprotonated polyol. The size of the rings is controlled through templates which have included a range of ammonium or imidazolium ions, alkali metals and coordination compounds. The rings can be functionalized to act as ligands, and incorporated into hybrid organic–inorganic rotaxanes and into molecules containing up to 200 metal centers. Physical studies reported include: magnetic measurements, inelastic neutron scattering (including single crystal measurements), electron paramagnetic resonance spectroscopy (including measurements of phase memory times), NMR spectroscopy (both solution and solid state), and polarized neutron diffraction. The rings are hence ideal for understanding magnetism in elegant exchange‐coupled systems.     

Phosphaketenes as Building Blocks for the Synthesis of Triphospha Heterocycles

Unsaturated phosphorus compounds, such as phosphaalkenes and phosphaalkynes, show a versatile reactivity in cycloadditions. Although phosphaketenes (R?P?C?O) have been known for three decades, their chemistry has remained limited. Herein, we show that heteroatom‐substituted phosphaketenes, R₃E?P?C?O (E=Si, Sn), are building blocks for silyl‐ and stannyl‐substituted five‐membered heterocycles containing three phosphorous atoms. The structure of the heterocyclic anion depends on the nature of the tetrel atom involved. Although the silyl analogue [P₃C₂(OSiR₃)₂]^? is an aromatic 1,2,4‐triphospholide, the stannyl compound [P(CO)₂(PSnR₃)₂]^? is a 1,2,4‐triphosphacyclopenta‐3,5‐dionate with a delocalized OCPCO fragment. Because of their anionic character, these compounds can easily be used as building blocks, for example, in the preparation of a silyl‐functionalized hexaphosphaferrocene or the parent 1,2,4‐triphosphacyclopenta‐3,5‐dionate [P(CO)₂(PH)₂]^?. NMR spectroscopic investigations and computations have shown that the heterocycle‐formation reactions presented herein are remarkably complex.     

Efficient and Convenient One-Pot Synthesis of Dioxadiazaphophepines

The reaction of vicinal dioxime with sodium hydride in dry THF followed by addition of dichlorophosphates or dichlorothiophosphates yields 2-oxo-1,3,4,7-dioxadiazaphosphepines and 2-thioxo-1,3,4,7-dioxodiazaphosphepines in moderate to good overall yields. The products are characterized by elemental analyses, molecular weights and spectral (IR, ¹H, ¹³C and ³¹P NMR) studies. A salt elimination route is used for the synthesis of titled heterocycles.     

Efficient stereoselective synthesis of oligosaccharides of Streptococcus pneumoniae serotypes 6A and 6B containing multiple 1,2-cis glycosidic linkages

The synthesis of the repeating units of pneumococcal polysaccharide serotypes 6A and 6B and derivatives thereof is described. Application of S-benzoxazolyl and S-thiazolinyl glycosides allowed rapid oligosaccharide assembly and provided complete stereoselectivity in challenging 1,2-cis glucosylations and galactosylations. The oligosaccharide assembly was accomplished in an efficient manner by selective activation of thioimidoyl leaving groups over thioglycosides.     

Synthesis of Tetrapeptides Containing Dehydroalanine,Dehydrophenylalanine and Oxazole as Building Blocks for Construction of Foldamers and Bioinspired Catalysts

The incorporation of dehydroamino acid or fragments of oxazole into peptide chain is accompanied by a distorted three-dimensional structure and additionally enables the introduction of non-typical side-chain substituents. Thus, such compounds could be building blocks for obtaining novel foldamers and/or artificial enzymes (artzymes). In this paper, effective synthetic procedures leading to such building blocks—tetrapeptides containing glycyldehydroalanine, glycyldehydrophenylalanine, and glycyloxazole subunits—are described. Peptides containing serine were used as substrates for their conversion into peptides containing dehydroalanine and aminomethyloxazole-4-carboxylic acid while considering possible requirements for the introduction of these fragments into long-chain peptides at the last steps of synthesis.     

Design,Synthesis and Pharmacological Evaluation of Novel 4-Phenoxyquinoline Derivatives as Potential Antitumor Agents

A series of novel 4-phenoxyquinoline derivatives containing 3-amino-2-cyano-acrylamide framework was designed and synthesized, and the in vitro cytotoxic activities of them against five cancer cell lines(HT-29, H460, A549, MKN-45, and U87MG) were evaluated. Most of the compounds exhibited moderate-to-significant cytotoxicity and high selectivity against one or more cell lines as compared with Foretinib. The studies of their preliminary structure-activity relationships(SARs) indicate that the compounds containing methyl groups, especially methyl groups at 4-position of the phenyl ring(moiety B) are more effective. Among them, compound 36 shows the most potent antitumor activities with IC₅₀ values of 0.04, 0.09, 0.67, 0.39 and 1.10 μmol/L against HT-29, H460, A549, MKN-45 and U87MG cell lines, respectively.