Synthesis of a Glucose‐Derived Tetrazole as a New β‐Glucosidase Inhibitor. A New Synthesis of 1‐Deoxynojirimycin

Myrosinase, an S-glycosidase, hydrolyzes plant anionic 1-thio-␤-D-glucosides (glucosinolates) considered part of the plant defense system. Although O-glycosidases are ubiquitous, myrosinase is the only known Sglycosidase. Its active site is very similar to that of retaining O-glycosidases, but one of the catalytic residues in O-glycosidases, a carboxylate residue functioning as the general base, is replaced by a glutamine residue. Myrosinase is strongly activated by ascorbic acid. Several binary and ternary complexes of myrosinase with different transition state analogues and ascorbic acid have been analyzed at high resolution by x-ray crystallography along with a 2-deoxy-2-fluoro-glucosyl enzyme intermediate. One of the inhibitors, D-gluconhydroximo-1,5-lactam, binds simultaneously with a sulfate ion to form a mimic of the enzyme-substrate complex. Ascorbate binds to a site distinct from the glucose binding site but overlapping with the aglycon binding site, suggesting that activation occurs at the second step of catalysis, i.e. hydrolysis of the glycosyl enzyme. A water molecule is placed perfectly for activation by ascorbate and for nucleophilic attack on the covalently trapped 2-fluoroglucosyl-moiety. Activation of the hydrolysis of the glucosyl enzyme intermediate is further evidenced by the observation that ascorbate enhances the rate of reactivation of the 2-fluoro-glycosyl enzyme, leading to the conclusion that ascorbic acid substitutes for the catalytic base in myrosinase.Glucosinolates are anionic ␤-D-S-glucosides found prominently in plants of the genus Brassica (cabbage, mustard, rapeseed, and other Cruciferae). They constitute a large family of S-glucosides that differ by their aglycon (Ref. 1 and Fig. 1a). The same plants produce myrosinase (thioglucoside glucohydrolase, EC 3.2.3.1), an S-glucosidase hydrolyzing glucosinolates. Myrosinase and glucosinolates are stored in different compartments of the plant, especially in the seeds. Mixing of enzyme and substrate (for example through mastication) induces glucosinolate hydrolysis. The biological function of myrosinase and glucosinolates is only partly elucidated; it has been suggested that they represent a defense system of the plant. Glucosinolates may as well serve to store inactive precursors of hormones such as 3-indolylacetic acid. 3-Indolyl acetonitrile and related indoles (2) are released from indolyl glucosinolates by myrosinase (3). Cleavage of indol-3-ylmethyl glucosinolate (glucobrassicin) by myrosinase in the presence of ascorbic acid produces ascorbigen, a condensation product of ascorbic acid with 3-hydroxymethylindole (4). Thus, the myrosinase system could be involved in the storage and in the inactivation of ascorbic acid. A detailed review on myrosinase is given by Bones and Rossiter (3).Myrosinase hydrolyzes the S-glycosides with retention of the anomeric configuration (5). Retaining glycosidases operate by a double displacement at the anomeric center promoted by two carboxylic residues acting as acid/base and as nucleophile, respec...

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“…1d) and gluco-hydroximolactam (Fig. 1e) were synthesized as described (9,11). C-GTL, the C-glycosidic analogue of glucotropaeolin (Fig.…”

Section: Reagents-2-f-gtlmentioning

confidence: 99%

High Resolution X-ray Crystallography Shows That Ascorbate Is a Cofactor for Myrosinase and Substitutes for the Function of the Catalytic Base

Burmeister¹,

Cottaz²,

Rollin³

et al. 2000

Journal of Biological Chemistry

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174

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“…Neither compound showed a CN absorption in their IR spectra, like other nitriles described in this work, and similarly to what has been previously observed for α-alkoxynitriles. [25,26] The structures of compounds 4a,b were confirmed by correlation with products obtained by known methods (Scheme 2). Starting from 5a, available from the O-benzyl derivative of -xylal [15,16] and in accordance with the reaction sequence depicted in Scheme 2, a compound identical to 4a, already prepared from 1a (see Scheme 1), was obtained.…”

Section: Resultsmentioning

confidence: 89%

Neighboring‐Group Participation in Nitrile‐Forming Beckmann Fragmentation Reactions: Synthesis of Enantiopure (E)‐2,3‐Di‐O‐substituted‐5‐methoxy‐ pent‐4‐enenitriles and Their Conversion into Pyranosylamines

et al. 2004

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The selective Beckmann fragmentations of multifunctionalised ketoximes have been proven to proceed effectively to give the corresponding nitriles. The chiral (E)-1,3,4-tri-Osubstituted-6-methoxy-hex-5-en-2-one oxime derivatives, available from glycals and glycosyl glycals, gave enantiopure (E)-2,3-di-O-substituted-5-methoxypent-4-enenitriles by treatment with mesyl chloride and triethylamine. The C1−C2 heterolytic fragmentation was completely controlled and directed by the adjacent C1 ether oxygen, which generates a

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“…[14] Initial attempts to convert the oxime 5 into the nitrile 1 under the conditions described by Vasella et al (PPh 3 , CBr 4 ) [15] failed. Under these conditions, the removal of the labile 4,5-O-isopropylidene protecting group occurred, due to the effect of HBr formed in situ.…”

Section: Resultsmentioning

confidence: 99%

Ti‐Mediated Synthesis of Aminocyclopropyl‐Substituted Carbohydrates

et al. 2005

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Synthesis of a Glucose‐Derived Tetrazole as a New β‐Glucosidase Inhibitor. A New Synthesis of 1‐Deoxynojirimycin

Cited by 116 publications

References 42 publications

High Resolution X-ray Crystallography Shows That Ascorbate Is a Cofactor for Myrosinase and Substitutes for the Function of the Catalytic Base

High Resolution X-ray Crystallography Shows That Ascorbate Is a Cofactor for Myrosinase and Substitutes for the Function of the Catalytic Base

Neighboring‐Group Participation in Nitrile‐Forming Beckmann Fragmentation Reactions: Synthesis of Enantiopure (E)‐2,3‐Di‐O‐substituted‐5‐methoxy‐ pent‐4‐enenitriles and Their Conversion into Pyranosylamines

Ti‐Mediated Synthesis of Aminocyclopropyl‐Substituted Carbohydrates

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