Baptista_2008_Biopolymers_89_538

Reference

Title : Thermodynamics and mechanism of cutinase stabilization by trehalose - Baptista_2008_Biopolymers_89_538
Author(s) : Baptista RP , Pedersen S , Cabrita GJ , Otzen DE , Cabral JM , Melo EP
Ref : Biopolymers , 89 :538 , 2008
Abstract :

Trehalose has been widely used to stabilize cellular structures such as membranes and proteins. The effect of trehalose on the stability of the enzyme cutinase was studied. Thermal unfolding of cutinase reveals that trehalose delays thermal unfolding, thus increasing the temperature at the midpoint of unfolding by 7.2 degrees . Despite this stabilizing effect, trehalose also favors pathways that lead to irreversible denaturation. Stopped-flow kinetics of cutinase folding and unfolding was measured and temperature was introduced as experimental variable to assess the mechanism and thermodynamics of protein stabilization by trehalose. The main stabilizing effect of trehalose was to delay the rate constant of the unfolding of an intermediate. A full thermodynamic analysis of this step has revealed that trehalose induces the phenomenon of entropy-enthalpy compensation, but the enthalpic contribution increases more significantly leading to a net stabilizing effect that slows down unfolding of the intermediate. Regarding the molecular mechanism of stabilization, trehalose increases the compactness of the unfolded state. The conformational space accessible to the unfolded state decreases in the presence of trehalose when the unfolded state acquires residual native interactions that channel the folding of the protein. This residual structure results into less hydrophobic groups being newly exposed upon unfolding, as less water molecules are immobilized upon unfolding.

PubMedSearch : Baptista_2008_Biopolymers_89_538
PubMedID: 18213692

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Citations formats

Baptista RP, Pedersen S, Cabrita GJ, Otzen DE, Cabral JM, Melo EP (2008)
Thermodynamics and mechanism of cutinase stabilization by trehalose
Biopolymers 89 :538

Baptista RP, Pedersen S, Cabrita GJ, Otzen DE, Cabral JM, Melo EP (2008)
Biopolymers 89 :538