Origin of Initial Burst in Activity for Trichoderma reesei endo-Glucanases Hydrolyzing Insoluble Cellulose.

Bibliographic Details
Title:	Origin of Initial Burst in Activity for Trichoderma reesei endo-Glucanases Hydrolyzing Insoluble Cellulose.
Authors:	Murphy, Leigh^1,2, Cruys-Bagger, Nicolaj¹, Damgaard, Heidi Delcomyn¹, Baumann, Martin J.², Olsen, Søren Nymand², Borch, Kim², Lassen, Søren Flensted², Sweeney, Matt³, Tatsumi, Hirosuke⁴, Westh, Peter¹ pwesth@ruc.dk
Superior Title:	Journal of Biological Chemistry. 1/6/2012, Vol. 287 Issue 2, following p1252-1260. 15p.
Subject Terms:	CELLULOSE, HYDROLYSIS, ENZYMES, TRICHODERMA reesei, *CALORIMETRY
Abstract:	The kinetics of cellulose hydrolysis have longbeen described by an initial fast hydrolysis rate, tapering rapidly off, leading to a process that takes days rather than hours to complete. This behavior has been mainly attributed to the action of cellobiohydrolases and often linked to the processive mechanism of this exo-acting group of enzymes. The initial kinetics of endo-glucanases (EGs) is far less investigated, partly due to a limited availability of quantitative assay technologies.Wehave used isothermal calorimetry to monitor the early time course of the hydrolysis of insoluble cellulose by the three main EGs from Trichoderma reesei (Tr): TrCel7B (formerly EG I), TrCel5A (EG II), and TrCel12A (EG III). These endo-glucanases show a distinctive initial burst with a maximal rate that is about 5-fold higher than the rate after 5 min of hydrolysis. The burst is particularly conspicuous for TrCel7B, which reaches a maximal turnover of about 20 s-1 at 30°C and conducts about 1200 catalytic cycles per enzyme molecule in the initial fast phase. For TrCel5A and TrCel12A the extent of the burst is 2-300 cycles per enzyme molecule. The availability of continuous data on EG activity allows an analysis of the mechanisms underlying the initial kinetics, and it is suggested that the slowdown is linked to transient inactivation of enzyme on the cellulose surface. We propose, therefore, that the frequency of structures on the substrate surface that cause transient inactivation determine the extent of the burst phase. [ABSTRACT FROM AUTHOR]
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