Lind_2004_Biochim.Biophys.Acta_1702_103

Reference

Title : Esterase catalysis of substrate vapour: enzyme activity occurs at very low hydration - Lind_2004_Biochim.Biophys.Acta_1702_103
Author(s) : Lind PA , Daniel RM , Monk C , Dunn RV
Ref : Biochimica & Biophysica Acta , 1702 :103 , 2004
Abstract :

It has been generally accepted that enzyme activity requires a minimal hydration of about 0.2 g H2O g(-1) protein. This fits well with evidence that hydration above this level is associated with the onset of intramolecular motions. The influence of enzyme hydration on the hydrolysis of substrate by Candida rugosa Lipase B and pig liver esterase was investigated. Each enzyme was studied as a powder at various hydration levels, using vapour phase ethyl butyrate as substrate. This procedure allows the separation of those effects that are due to hydration from those arising from diffusional constraints. We found hydrolytic activity in both enzymes at all hydration levels above zero (between 0.054-0.47 and 0.029-0.60 g H2O g(-1) protein, respectively) that were investigated. The lowest hydration level investigated, <0.03 g H2O g(-1) enzyme, corresponded to a water/enzyme mole ratio of 100 and a coverage of about 10% of the enzyme surface by water molecules. The hydrolytic activity of both enzymes was dependent on protein hydration. However, since the hydrolysis of ethyl butyrate requires water as a second substrate, the absence of activity at zero hydration does not rule out the possibility of enzyme activity in the absence of water. These results suggest that the properties conferred on proteins by water, at least above 10% surface coverage (in this case corresponding to a hydration level of 0.03 g H2O g(-1) protein), are not a requirement for enzyme catalysis.

PubMedSearch : Lind_2004_Biochim.Biophys.Acta_1702_103
PubMedID: 15450854

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Citations formats

Lind PA, Daniel RM, Monk C, Dunn RV (2004)
Esterase catalysis of substrate vapour: enzyme activity occurs at very low hydration
Biochimica & Biophysica Acta 1702 :103

Lind PA, Daniel RM, Monk C, Dunn RV (2004)
Biochimica & Biophysica Acta 1702 :103