Two established thermal properties of enzymes are the Arrhenius activation energy and thermal stability. Arising from anomalies found in the variation of enzyme activity with temperature, a comparison has been made of experimental data for the activity and stability properties of five different enzymes with theoretical models. The results provide evidence for a new and fundamental third thermal parameter of enzymes, Teq, arising from a subsecond timescale-reversible temperature-dependent equilibrium between the active enzyme and an inactive (or less active) form. Thus, at temperatures above its optimum, the decrease in enzyme activity arising from the temperature-dependent shift in this equilibrium is up to two orders of magnitude greater t...
The Classical Model describing the effects of temperature on enzyme activity consists of two process...
The increase in enzymatic rates with temperature up to an optimum temperature (Topt) is widely attri...
AbstractThe discovery of an additional step in the progression of an enzyme from the active to inact...
Two established thermal properties of enzymes are the Arrhenius activation energy and thermal stabil...
The two established thermal properties of enzymes are their activation energy and their thermal stab...
Arising from careful measurements of the thermal behaviour of enzymes, a new model, the Equilibrium ...
This thesis describes tests of a new hypothesis describing the effect of temperature on enzyme activ...
Experimental data show that the effect of temperature on enzymes cannot be adequately explained in t...
Traditionally, the dependence of enzyme activity on temperature has been described by a model consis...
The "Equilibrium Model" has provided new tools for describing and investigating enzyme thermal adapt...
The way that enzymes respond to temperature is fundamental to many areas of biotechnology. This has ...
Careful analysis of the dependence of enzyme activity on assay temperature has revealed that some en...
A new, experimentally-validated “Equilibrium Model” describes the effect of temperature on enzymes, ...
The Classical Model describing the effects of temperature on enzyme activity consists of two process...
The increase in enzymatic rates with temperature up to an optimum temperature (Topt) is widely attri...
AbstractThe discovery of an additional step in the progression of an enzyme from the active to inact...
Two established thermal properties of enzymes are the Arrhenius activation energy and thermal stabil...
The two established thermal properties of enzymes are their activation energy and their thermal stab...
Arising from careful measurements of the thermal behaviour of enzymes, a new model, the Equilibrium ...
This thesis describes tests of a new hypothesis describing the effect of temperature on enzyme activ...
Experimental data show that the effect of temperature on enzymes cannot be adequately explained in t...
Traditionally, the dependence of enzyme activity on temperature has been described by a model consis...
The "Equilibrium Model" has provided new tools for describing and investigating enzyme thermal adapt...
The way that enzymes respond to temperature is fundamental to many areas of biotechnology. This has ...
Careful analysis of the dependence of enzyme activity on assay temperature has revealed that some en...
A new, experimentally-validated “Equilibrium Model” describes the effect of temperature on enzymes, ...
The Classical Model describing the effects of temperature on enzyme activity consists of two process...
The increase in enzymatic rates with temperature up to an optimum temperature (Topt) is widely attri...
AbstractThe discovery of an additional step in the progression of an enzyme from the active to inact...