The pressure-dependence of two beta-glucosidases with respect to their thermostability.

A comparative study of temperature and pressure effects were carried out by using two homologous enzymes exhibiting different thermostability and oligomery: almond beta-glucosidase and Sulfolobus solfataricus beta-glucosidase. Both the activity and stability were studied using an in-house built bioreactor allowing injection, stirring, sampling and on-line spectrophometric monitoring with retention of pressure up to 2.5 kbar and temperature control possible up to 150 degrees C. Almond beta-glucosidase, the most pressure sensitive enzyme of the two was continuously affected by pressure up to 1.5 kbar. Activation volume changes revealed that the inactivation of almond beta-glucosidase was due to both catalytic step inactivation and enzyme-substrate binding inactivation. Structural modifications generated by pressure, related to a loss of activity did not affect the global conformation of almond beta-glucosidase, after depressurization. In contrast, Sulfolobus solfataricus beta-glucosidase was a highly barostable enzyme. It maintained a half-life of 91 h at 60 degrees C and 2.5 kbar. Moreover, this enzyme appeared to be activated by pressure between atmospheric pressure and 2.5 kbar with a maximal activity at 1.25 kbar. However, this enzyme still displayed the best catalytic efficiency at atmospheric pressure because of a Km value drastically increased by pressure. Activation volume changes indicated that the hydrolysis reaction catalysed by Sulfolobus solfataricus beta-glucosidase, was alternatively favoured and disfavoured by pressure due to the catalytic step activation or inactivation associated with the enzyme-substrate binding step being continuously inactivated by pressure.

Hydrostatic pressure induces conformational and catalytic changes on two alcohol dehydrogenases but no oligomeric dissociation.

A comparison between the pressure effects on the catalysis of Thermoanaerobium brockii alcohol dehydrogenase (TBADH: a thermostable tetrameric enzyme) and yeast alcohol dehydrogenase (YADH: a mesostable tetrameric enzyme) revealed a different behaviour. YADH activity is continuously inhibited by an increase of pressure, whereas YADH affinity seems less sensitive to pressure. TBADH activity is enhanced by pressure up to 100 MPa. TBADH affinity for alcoholic substrates increases if pressure increases, was TBADH affinity for NADP decreases when pressure increases. Hypothesis has been raised concerning the dissociation of oligomeric enzymes under high hydrostatic pressure ( < 200 MPa) [1]. But in the case of these two enzymes, unless the oligomers reassociate very quickly (< 1 min), the activity inhibition of YADH at all pressures and TBADH for pressures above 100 MPa is not correlated to subunit dissociation. Hence we suggest that enzymes under pressure encounter a molecular rearrangement which can either have a positive or a negative effect on activity. Finally, we have observed that the catalytic behaviour of alcohol dehydrogenases under pressure is connected to their thermostability.