Fabien Ribes scite author profile

Butyrylcholinesterase is a serine esterase, closely related to acetylcholinesterase. Both enzymes employ a catalytic triad mechanism for catalysis, similar to that used by serine proteases such as a-chymotrypsin. Enzymes of this type are generally considered to be inactive at pH values below 5, because the histidine member of the catalytic triad becomes protonated. We have found that butyrylcholinesterase retains activity at pH £ 5, under conditions of excess substrate activation. This low-pH activity appears with wildtype butyrylcholinesterase as well as with all mutants we examined: A328G, A328I, A328F, A328Y, A328W, E197Q, L286W, V288W and Y332A (residue A328 is at the bottom of the active-site gorge, near the p-cation-binding site; E197 is next to the active-site serine S198; L286 and V288 form the acyl-binding pocket; and Y332 is a component of the peripheral anionic site). For example, the k cat value at pH 5.0 for activity in the presence of excess substrate was 32 900 ± 4400 min )1 for wild-type, 55 200 ± 1600 min )1 for A328F, and 28 700 ± 700 min )1 for A328W. This activity is titratable, with pK a values of 6.0-6.6, suggesting that the catalytic histidine is protonated at pH 5. The existence of activity when the catalytic histidine is protonated indicates that the catalytic-triad mechanism of butyrylcholinesterase does not operate for catalysis at low pH. The mechanism explaining the catalytic behaviour of butyrylcholinesterase at low pH in the presence of excess substrate remains to be elucidated.

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Pressure- and heat-induced inactivation of butyrylcholinesterase: evidence for multiple intermediates and the remnant inactivation process

Weingand-Ziadé¹,

Ribes²,

Renault³

et al. 2001

Biochem. J.

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The inactivation process of native (N) human butyrylcholinesterase (BuChE) by pressure and/or heat was found to be multi-step. It led to irreversible formation of an active intermediate (I) state and a denatured state. This series-inactivation process was described by expanding the Lumry-Eyring [Lumry, R. and Eyring, H. (1954) J. Phys. Chem. 58, 110-120] model. The intermediate state (I) was found to have a K(m) identical with that of the native state and a turnover rate (k(cat)) twofold higher than that of the native state with butyrylthiocholine as the substrate. The increased catalytic efficiency (k(cat)/K(m)) of I can be explained by a conformational change in the active-site gorge and/or restructuring of the water-molecule network in the active-site pocket, making the catalytic steps faster. However, a pressure/heat-induced covalent modification of native BuChE, affecting the catalytic machinery, cannot be ruled out. The inactivation process of BuChE induced by the combined action of pressure and heat was found to continue after interruption of pressure/temperature treatment. This secondary inactivation process was termed 'remnant inactivation'. We hypothesized that N and I were in equilibrium with populated metastable N' and I' states. The N' and I' states can either return to the active forms, N and I, or develop into inactive forms, N(')(in) and I(')(in). Both active N' and I' intermediate states displayed different rates of remnant inactivation depending on the pressure and temperature pretreatments and on the storage temperature. A first-order deactivation model describing the kinetics of the remnant inactivation of BuChE is proposed.

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Fabien Ribes

Butyrylcholinesterase-catalyzed hydrolysis of N-methylindoxyl acetate: analysis of volume changes upon reaction and hysteretic behavior

Substrate activation in acetylcholinesterase induced by low pH or mutation in the π-cation subsite

Capillary zone electrophoresis with optimized temperature control for studying thermal denaturation of proteins at various pH

High activity of human butyrylcholinesterase at low pH in the presence of excess butyrylthiocholine

Pressure- and heat-induced inactivation of butyrylcholinesterase: evidence for multiple intermediates and the remnant inactivation process

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