Reductive Ring‐Opening Reaction of 1,2‐O‐Benzylidene and 1,2‐O‐p‐Methoxybenzylidene‐α‐D‐glucopyranose Using Diisobutyl Aluminum Hydride

Abstract

Regioselectivity in the reductive ring‐opening reaction of 3,4,6‐tri‐O‐benzyl‐1,2‐O‐benzylidene and 3,4,6‐tri‐O‐benzyl‐1,2‐O‐p‐methoxybenzylidene‐α‐D‐glucopyranose using diisobutyl aluminum hydride (DIBAH) was examined. The ratio of the 1‐O‐ and 2‐O‐p‐methoxybenzyl ethers, which were generated from endo‐type 1,2‐O‐p‐methoxybenzylidene, was variable by the change of solvent.     

Synthesis of C‐Nucleoside Analogues Starting from 1‐(Methyl 3‐O‐benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐D‐altropyranosid‐2‐yl)‐4‐phenyl‐but‐3‐yn‐2‐one

Abstract

1‐(Methyl 3‐O‐benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐D‐altropyranosid‐2‐yl)‐4‐phenyl‐but‐3‐yn‐2‐one (4) was synthesized by the reaction of (methyl 3‐O‐benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐D‐altropyranosid‐2‐yl)ethanal (2) with lithium phenylethynide and following oxidation. Compound 4 and hydrazine hydrate provided the 3(5)‐(methyl 3‐O‐benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐D‐altropyranosid‐2‐yl‐methyl)‐5(3)‐phenyl‐1H‐pyrazole (5). The reactions of 4 with amidinium salts and a S‐methyl‐isothiouronium salt, respectively, furnished the pyrimidine C‐nucleoside analogues 6a–6c. Treatment of 4 with 2‐aminobenzimidazole afforded 2‐(methyl 3‐O‐benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐D‐altropyranosid‐2‐ylmethyl)‐4‐phenyl‐benzo [4,5]imidazo[1,2‐a]pyrimidine (7a). Compound 4 and sodium azide yielded 2‐(methyl 3‐O‐benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐D‐altropyranosid‐2‐yl)‐1‐[5(4)‐phenyl‐1H(2H)‐1,2,3‐triazole‐4(5)‐yl]ethanone (8).     

Synthesis of (Methyl 3‐O‐Benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐d‐altropyranosid‐2‐yl)thiophene Derivatives as Precursors of New Iso‐C‐nucleoside Analogues

Treatment of 2‐(methyl 3‐O‐benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐d‐altropyranosid‐2‐yl)ethanal (3) with malononitrile in the presence of aluminium oxide provided 2‐cyano‐4‐(methyl 3‐O‐benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐d‐altropyranosid‐2‐yl)crotononitrile (4). Starting from 4, cyclization with sulphur and triethylamine yielded 2‐amino‐5‐(methyl 3‐O‐benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐d‐altropyranosid‐2‐yl)thiophene‐3‐carbonitrile (5). Further cyclization could be achieved with triethyl orthoformate/ammonia to furnish 4‐amino‐6‐(methyl 3‐O‐benzyl‐4,6‐O‐benzylidene‐2‐deoxy‐α‐d‐altropyranosid‐2‐yl)thieno[2.3‐d]pyrimidine (8).     

Preparation of Methyl 6‐O‐p‐Nitrobenzoyl‐β‐d‐Glucoside

Methyl 6‐O‐p‐nitrobenzoyl‐β‐d‐glucoside was synthesized by reacting methyl 4,6‐O‐p‐nitrobenzylidine‐β‐d‐glucoside with N‐bromosuccinimide (NBS). First, methyl β‐d‐glucoside was converted into methyl 4,6‐O‐p‐nitrobenzylidine‐β‐d‐glucoside with p‐nitrobenzaldehyde. Later, methyl 4,6‐O‐p‐nitrobenzylidine‐β‐d‐glucoside was opened oxidatively with NBS to give methyl 6‐O‐p‐nitrobenzoyl‐β‐d‐glucoside.     

Synthesis of Tetra‐O‐acetyl‐1‐thio‐α‐d‐glucopyranose by Reaction of Tetra‐O‐acetyl‐α‐d‐glucopyranosyl Bromide with N,N‐Dimethylthioformamide

A reaction system was found to prepare tetra‐O‐acetyl‐1‐thio‐d‐glycopyranose in both α and β‐forms. Methanolysis of the adduct prepared from the reaction of tetra‐O‐acetyl‐α‐d‐glucopyranosyl bromide with N,N‐dimethylthioformamide afforded the corresponding tetra‐O‐acetyl‐1‐thio‐d‐glucopyranose with an anomer ratio α/β of 52:48 in 98% yield. The anomer mixture was easily separated by column chromatography to obtain the product of α‐form. This synthetic method is very convenient to proceed by one‐pot reaction under ordinary conditions.     

A Facile,One‐Step Conversion of 6‐O‐Trityl and 6‐O‐TBDMS Monosaccharides into the Corresponding Formate Esters

A convenient method has been developed for a facile and high‐yield conversion of 6‐O‐tert‐butyldimethylsilyl and 6‐O‐trityl protected monosaccharides to their formate esters, which may serve as useful intermediates for the replacement of the primary hydroxyl group of sugars by other functional groups.     

Syntheses of Acyclo‐C‐nucleoside Analogs from 2,3:4,5‐Di‐O‐isopropylidene‐D‐xylose

Treatment of 1,2‐dideoxy‐4,5:6,7‐di‐O‐isopropylidene‐D‐xylo‐hept‐1‐yn‐3‐uloses 4a,b with hydrazine hydrate and amidines yielded the 3‐(1,2:3,4‐di‐O‐isopropylidene‐D‐xylo‐1,2,3,4‐tetrahydroxy‐butyl)‐5‐phenyl‐1H(2H)‐pyrazole 5 and the substituted 4‐(1,2:3,4‐di‐O‐isopropylidene‐D‐xylo‐1,2,3,4‐tetrahydroxy‐butyl)pyrimidines 7a–f, respectively. Reaction of 4a,b with 2‐amino‐benzimidazol afforded the 2‐(1,2:3,4‐di‐O‐isopropylidene‐D‐xylo‐1,2,3,4‐tetrahydroxy‐butyl)benzo[4,5]imidazo[1,2‐a]pyrimidines 9a,b. Compound 4a and 5‐amino‐pyrazole‐4‐carbonic acid derivatives yielded the 5‐(1,2:3,4‐di‐O‐isopropylidene‐D‐xylo‐1,2,3,4‐tetrahydroxy‐butyl)pyrazolo[1,5‐a]pyrimidines 11a–d. Deprotection of pyrazole 5, pyrimidine 7a, and pyrazolo[1,5‐a]pyrimidine 11b yielded the acyclo‐C‐nucleosides 6, 8, and 12, respectively.     

Synthesis of O‐β‐D‐Glucopyranosides of 7‐Hydroxy‐3‐(imidazol‐2‐yl)‐4H‐chromen‐4‐ones

The 7‐hydroxy‐3‐formyl‐4H‐chromen‐4‐one 1 reacted with various cyclic 1,2‐dicarbonyl compounds in the presence of ammonium acetate to furnish 7‐hydroxy‐3‐([4,5‐fused] imidazol‐2‐yl)‐4H‐chromen‐4‐ones 2a–f, which on glucosylation with α‐acetobromoglucose affords 2,3,4,6‐tetra‐O‐acetyl‐β‐D‐glucopyranosyloxy‐3‐([4,5‐fused] imidazol‐2‐yl)‐4H‐chromen‐4‐ones 3a–f. 7‐O‐β‐D‐Glucopyranosyloxy‐3‐([4,5‐fused] imidazol‐2‐yl)‐4H‐chromen‐4‐ones 4a–f were prepared by deacetylation with anhydrous zinc acetate in absolute methanol. The structure of these new O‐β‐D‐glucosides was established on the basis of chemical, elemental, and spectral analysis. These compounds were evaluated for their in vitro biological activity.

     

Application of Dichlorovinyl Xyloside for the Novel Synthesis of 2,3,4‐Tri‐O‐methyl‐D‐xylono‐1,5‐lactone

A novel synthesis of 2,3,4‐tri‐O‐methyl‐D‐xylopyranose, 4, and its oxidation product 2,3,4‐tri‐O‐methyl‐D‐xylono‐1,5‐lactone, 5, are reported. The new synthesis applies a regioselective Wittig‐like reaction of tetra-O-acetyl-D-xylopyranase, 1, with triphenylphosphine and carbon tetrachloride to yield an O‐dichlorovinyl xyloside protected at C‐1, 2. The protecting group facilitates the permethylation of xylose and is removed under the methylation conditions, to yield tetra-O-acetyl-D-xylopyranase, 3. The anomeric methyl group was removed under mildly acidic conditions to give 2,3,4‐tri‐O‐methyl‐D‐xylopyranose, 4, in good yield. Compound 4 was oxidized using pyridinium chlorochromate to give the title compound, 5, in 95% yield.     

Selective Reductions of C‐(4,6‐O‐Benzylidene‐β‐d‐glucopyranosyl) Nitromethane

Abstract

The nitromethyl group of C‐(4,6‐O‐benzylidene‐β‐d‐glucopyranosyl) nitromethane was manipulated by various reduction and oxidation methods and further functionalizations into –CH₂NHOH, –CH?NOH, –CN, –CH?O, and –CH₂NHCONH₂, all with retention of the 4,6‐O‐benzylidene group. Certain reduction methods gave rise to a novel secondary amine via an unusual dimeric aminal.     

Synthesis of Heteroanellated Pyranosides Starting from Methyl 4,6‐O‐benzylidene‐2,3‐dideoxy‐α‐d‐erythro‐hexopyranosid‐2‐ylidenemalononitrile

The hexopyranosid‐2‐ylidenemalononitrile 1 reacted with phenyl isothiocyanate in the presence of triethylamine to furnish (2R,4aR,6S,10bS)‐8‐amino‐4a,6,10,10b‐tetrahydro‐6‐methoxy‐2‐phenyl‐10‐phenylimino‐4H‐thiopyrano[3′,4′:4,5]pyrano[3,2‐d][1,3]dioxine‐7‐carbonitrile (2). Starting from 1, cyclization with sulphur and diethylamine yielded (2R,4aR,6S,9bR)‐8‐amino‐4,4a,6,9b‐tetrahydro‐6‐methoxy‐2‐phenylthieno[2′,3′:4,5]pyrano[3,2‐d][1,3]dioxine‐7‐carbonitrile (3), which could be transformed into the corresponding aminomethylenamino derivative 4 by treatment with triethyl orthoformate and ammonia. Intramolecular cyclization of 4 to yield (2R,4aR,6S,11bR)‐4,4a,6,11b‐tetrahydro‐6‐methoxy‐2‐phenyl[1,3]dioxino[4″,5″:5′,6′]pyrano[3′,4′:4,5]thieno [2,3‐d]pyrimidin‐7‐amine (5) was achieved by using NaH as base. (2R,4aR,6S,9bS)‐8‐Amino‐4a,6,9,9b‐tetrahydro‐6‐methoxy‐9‐(4‐methylphenyl‐sulfonyl)‐2‐phenyl‐4H‐[1,3]dioxino[4′,5′:5,6]pyrano[4,3‐b]pyrrole‐7‐carbonitrile (6) was prepared by treatment of compound 1 with tosylazide and triethylamine.     

Lanthanum Trifluoromethane-sulfonate‐Catalyzed Facile Synthesis of Per‐O‐acetylated Sugars and Their One‐Pot Conversion to S‐Aryl and O‐Alkyl/Aryl Glycosides†

Lanthanum trifluoromethanesulfonate‐catalyzed solvent‐free per‐O‐acetylation with stoichiometric acetic anhydride proceeds in high yield (95%–99%) to afford exclusively pyranose products as anomeric mixtures. Subsequent anomeric substitution employing borontrifluoride etherate and thiols or alcohols furnished the corresponding 1,2‐trans‐linked thioglycosides and O‐glycosides, respectively, in good to excellent overall yield (75%–85%). Alternatively, reaction of free sugars in neat alcohol employing the same catalyst at elevated temperature gives the corresponding 1,2‐cis‐linked O‐glycosides (along with 1,2‐trans‐linked glycosides as minor product) in good yield (73%–80%). Anomeric mixtures of compounds thus produced were characterized as their per‐O‐acetylated derivatives.      

MM3 Conformational Analysis and X‐ray Crystal Structure of 2,3,4,5‐Tetra‐O‐Acetyl‐N,N′‐Dimethyl‐D‐Glucaramide as a Conformational Model for the d‐Glucaryl Unit of Poly(Alkylene 2,3,4,5‐Tetra‐O‐Acetyl‐d‐Glucaramides)

This report describes the MM3 conformational analysis and X‐ray crystal structure of tetra‐O‐acetyl‐N,N′‐dimethyl‐d‐glucaramide as a conformational model for the D‐glucaryl monomer unit of poly(alkylene tetra‐O‐acyl‐d‐glucaramides). The driving force for this study was to determine the conformational preferences for the diacid unit as a function of the increasing steric bulk of pendant O‐acyl groups: acetyl, propanoyl, 2‐methylpropanoyl, and 2,2‐dimethylpropanoyl. The model dialkyl d‐glucaramides all displayed a large vicinal proton coupling between the central backbone glucaryl hydrogens, indicating an essentially fixed anti conformational arrangement of these protons. The MM3 molecular mechanics program was then applied to calculate the corresponding low‐energy conformations of the structurally simplest of these molecules, tetra‐O‐acetyl‐N,N′‐dimethyl‐d‐glucaramide (4). Given the large number of dihedral angles to be considered and the apparent rigidity of these molecules around the central carbons of the glucaryl backbone, a number of conformational approximations based upon model compounds were applied regarding the rotameric disposition of the pendant O‐acetyl and terminal N‐methyl groups. The calculated, and dominant, lowest energy conformer has a sickle structure very similar to the global minimum conformation previously calculated for unprotected d‐glucaramide. The x‐ray crystal structure data from 4 indicated an extended conformation in the solid state and gave solid‐state torsion angle information that was comparable to that obtained computationally.     

Synthesis of Novel Anellated Pyranosides as Precursors of C‐Nucleoside Analogues Using Isopropyl 6‐O‐Acetyl‐3‐deoxy‐4‐S‐ethyl‐4‐thio‐α‐D‐threo‐hexopyranosid‐2‐ulose

Abstract

Isopropyl 6‐O‐acetyl‐3‐deoxy‐4‐S‐ethyl‐4‐thio‐α‐D‐threo‐hexopyranosid‐2‐ulose (3) was converted to the corresponding 3‐[bis(methylthio)methylene] derivative 4 with a push–pull activated C–C double bond. Treatment of 4 with hydrazine and methylhydrazine afforded the pyrano[3,4‐c]pyrazol‐5‐ylmethyl acetates 5a and 5b, respectively. Desulfurization of compound 4 with sodium boron hydride yielded the 3‐[(methylthio)methylene]hexopyranosid‐2‐ulose 7. Compound 7 was reacted with amines to furnish 3‐aminomethylene‐hexopyranosid‐2‐uloses 8, 9. Reaction of 7 with hydrazine hydrate, hydrazines, hydroxylamine, and benzamidine afforded the pyrazolo, isoxazalo, and pyrimido anellated pyranosides (10–13).     

Regioselectivity in Alkylation Reactions of 1,2‐O‐Stannylene Acetals of d‐Arabinofuranose

The synthesis of β‐arabinofuranosides via alkylation of 1,2‐O‐stannylene acetal intermediates has been studied. With reactive alkyl halides (benzyl bromide, allyl bromide, and p‐methoxybenzyl chloride), the method provides a mixture of β‐arabinofuranosides and 2‐O‐alkylated lactols in ratios of 4:1 to 1:1.5. However, with carbohydrate‐derived electrophiles, no alkylated products are produced. It appears, therefore, that the method is limited to the preparation of β‐arabinofuranosides of simple alcohols. Through the use of computational chemistry, we have explored the conformational properties of one of these stannylene acetals and propose that these species exist in more than one conformation in solution and that this contributes to the relatively poor regioselectivity in these reactions.     

Synthesis and Antimicrobial Activity of 4‐Aryl‐5‐phenyl‐imino‐3‐(tetra‐O‐benzoyl‐β‐D‐glucopyranosylimino)‐1,2,4‐dithiazolidines (Hydrochlorides)

Abstract

Synthesis of 4‐aryl‐5‐phenylimino‐3‐(tetra‐O‐benzoyl‐β‐D‐glucopyranosylimino)‐1,2,4‐dithiazolidines (hydrochlorides) is described. These compounds were screened for their antibacterial and antifungal activity against Escherichia coli, Staphylococcus aureus, P. vulgaris, Pseudomonas, Bacillus, Salomonella sp., Aspergilus niger, and Fusarium. The identities of these new N‐glucosides have been established on the basis of usual chemical transformation IR, NMR, and mass spectral studies.     

A Novel,Convenient Synthesis of the 3‐O‐β‐D‐ and 4′‐O‐β‐D‐Glucopyranosides of trans‐Resveratrol

Abstract

trans‐Resveratrol‐3‐O‐β‐D‐glucupyranoside (trans‐piceid, 2) and trans‐resveratrol‐4′‐O‐β‐D‐glucupyranoside (trans‐resveratroloside 3) are the naturally occurring O‐glucoside conjugates of the polyphenolic stilbenoid trans‐resveratrol 1. Recently, attention has been drawn towards the interesting biological properties of the glucoside conjugates 2 and 3 as well as those of the aglycone 1. The fact that only limited quantities can be obtained by extraction from natural sources has prompted the development of novel syntheses of 2 and 3, based on a convergent Heck‐coupling strategy, which now conveniently allows for the preparation of multi‐milligram to gram quantities of each.     

Synthesis and Structure of 2‐Hydroxy‐2‐Methyl‐1,3‐Bis‐(Methyl 3′,4′,6′‐Tri‐O‐Acetyl‐β‐D‐Glucopyranosid‐2‐yl)‐Imidazolidine‐4,5‐Dione

The title compound was synthesized starting from methyl 3,4,6‐tri‐O‐acetyl‐2‐acetamido‐2‐deoxy‐β‐D‐glucopyranoside, oxalyl chloride, and methyl 3,4,6‐tri‐O‐acetyl‐2‐amino‐2‐deoxy‐β‐D‐glucopyranoside. The crystal and molecular structure of the obtained imidazolidine‐4,5‐dione have been determined by X‐ray analysis as well as ¹H and ¹³C NMR spectroscopy.     

From Tri‐O‐Acetyl‐D‐Glucal to (2R,3R,5R)‐2,3‐Diazido‐5‐Hydroxycyclohexanone Oxime

Abstract

Methyl 3‐azido‐2,3‐dideoxy‐α/β‐D‐arabino‐ and ‐α/β‐D‐ribo‐hexopyranosides were transformed into 6‐iodo analogues via p‐tolylsulfonyl compounds. Elimination of hydrogen iodide from 6‐iodo glycosides provided methyl 4‐O‐acetyl‐3‐azido‐2,3,6‐trideoxy‐α‐ and ‐β‐D‐threo‐hex‐5‐eno‐pyranosides or 3‐azido‐4‐O‐p‐tolylsulfonyl‐2,3,6‐trideoxy‐α‐D‐threo‐ and ‐β‐D‐erythro‐hex‐5‐eno‐pyranosides. Ferrier's carbocyclization of 4‐O‐acetyl‐3‐azido‐2,3,6‐trideoxy‐α‐ and ‐β‐D‐threo‐hex‐5‐eno‐pyranosides gave (2S,3R,5R)‐2‐acetoxy‐3‐azido‐5‐hydroxycyclohexanone, which was converted into oxime. The 2‐OAc group in oxime was substituted by azide ion to yield (2R,3R,5R)‐2,3‐diazido‐5‐hydroxycyclohexanone oxime. The configuration and conformation of all products are widely discussed on the basis of the ¹H and ¹³C NMR.     

An Exceptionally Simple Chemical Synthesis of O‐Glycosylated d‐Glucosamine Derivatives by Heyns Rearrangement of the Corresponding O‐Glycosyl Fructoses

2‐N‐Acetyl‐4‐O‐(β‐d‐galactopyranosyl)‐d‐glucosamine (N‐acetyl‐d‐lactosamine), a very important building block of biologically relevant oligosaccharides such as sialyl Lewis^x, is easily accessible via the Heyns rearrangement of the corresponding O‐glycosylated ketohexose, d‐lactulose. This approach can also be extended to other glucosamine derivatives employing suitable O‐glycosylated ketoses many of which are commercially available. For example, nigerosamine (3‐O‐α‐d‐glucopyranosyl‐d‐glucosamine) was prepared from turanose (3‐O‐α‐d‐glucopyranosyl‐d‐fructose). In combination with a recently introduced vinylogous amide type N‐protecting group, [1,3‐dimethyl‐2, 4, 6 (1H, 3H, 5H)‐trioxopyrimidine‐5‐ylidene] methyl (DTPM), this access is clearly superior to other routes and eminently suitable for scaling up.