Glycosidases reactions

The dependences, such as Eq. 2.47, are known as compensation effect, and coefficient (3C is denoted as isokinetic temperature at which all reactions of given series have the same rate constant. An example of compensation effect for for catalytic rate constant of the Sulfolobus solfataricus p-glycosidase reaction with different substrates is shown in Fig. 2.19. Similar relationships were reported for many other prosesses, involving the binding ligands to hemoglobin, the oxidation of alcohols by catalase, the hydroxylation of substrates by cytochrome c, etc. 

Polyhydroxyalkaloids have potential as research tools for probing the chemistry and biology of glycosidase reactions. 

Triazoline imino sugar derivatives 297 that are prospective glycosidase inhibitors have been prepared as single diastereomers in high yield via an lAOC reaction of in situ generated azido alkene 296 (Eq. 32) [78]. m-CPBA oxidation of the dithioacetal groups in the 0-acetylated 5-azido-5-deoxydibenzyl dithio-acetal of o-xylose or D-ribose 294 to the bis-sulfone 295, followed by loss of HOAc between C-1 and C-2 provided the lAOC precursor 296. 

Several possible models can be discussed for the molecular basis of slow inhibition, but experimental evidence in support of one or the other is still lacking for glycosidases. A reversible chemical reaction at the active site, for example, formation of the cyclic imine 3 or a diffusion-controlled association with a trace of 3 in equilibrium with the 5-araino-5-deoxypyranose 1 can be precluded, because slow inhibition is also observed with 1-deoxynojirimycin and its analogs and with acarbose (see Section II,2,d) and indoli-... 

The term pseudosubstrate as used in this article will comprise sugar-related compounds that are chemically transformed by glycosidases, often forming long-lived intermediates and thereby acting as reversible inhibitors. Even in cases of weak inhibition, where the intermediate is too short-lived for chemical or physical characterization, the type of reaction catalyzed by the... 

Scheme 6. — Reaction of ConduritoJ Epoxide (Anhydro-inositol, Hydroxyl groups omitted) with / - and a-Specific Glycosidase, Respectively.

The principle of active-site-directed inactivation of glycosidases by gly-con-related epoxides can be extended to compounds having an exocyclic oxirane ring, either directly attached to the six-membered ring (32) or at some distance (33,34). Studies with -o-glucosidase from sweet almonds and intestinal sucrase-isomaltase revealed that, in spite of the higher intrinsic reactivity of these epoxides, this shift of the position of the epoxide function causes a 10- to 30-fold decrease of kj(max)/Ki, an effect which probably reflects the limited flexibility of the catalytic groups involved in the epoxide reaction. 

Evidence for a glycosyl-enzyme intermediate of finite lifetime with inverting a-D-glycosidases, and details of its reaction, came from studies with 2,6-anhydro-l-deoxyhept-l-enitols and glycosyl fluorides. - Analysis of hydration and hydrolysis products on the one hand, and of glycosyla-tion products on the other, indicated an intermediate that could be approached by water from the yff-face only of the ring, and by other glycosyl acceptors only from the a-face (see Schemes 4 and 5 This can be considered a proof of the principle of microscopic reversibility of chemical reactions. 

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