The thermodynamics of protein stability: Cold destabilization as a general phenomenon

A theoretical analysis of the temperature/stability profiles of proteins shows that, where a two-state model represents the denaturation, and where the free energy of denaturation Δ G( T) shows a strong temperature dependence, then the protein becomes subject to both high- and low-temperature destab...

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Bibliographic Details
Published in:Biophysical chemistry 1988-09, Vol.31 (3), p.307-315
Main Authors: Franks, F., Hatley, R.H.M., Friedman, H.L.
Format: Article
Language:English
Subjects:
Analytical, structural and metabolic biochemistry
Biological and medical sciences
Calorimetry
cold
Cold denaturation
Cold Temperature
Denaturation
Drug Stability
Fundamental and applied biological sciences. Psychology
General aspects, investigation methods
Mathematics
Models, Theoretical
Protein Conformation
Protein Denaturation
Protein stability
Proteins
Thermodynamics
thermostability
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Summary:A theoretical analysis of the temperature/stability profiles of proteins shows that, where a two-state model represents the denaturation, and where the free energy of denaturation Δ G( T) shows a strong temperature dependence, then the protein becomes subject to both high- and low-temperature destabilization. In the simplest case Δ G( T) is parabolic, therefore the high temperature T H, where Δ( G( T H) = 0, is complemented by a low temperature T L, where Δ G( T L) = 0. It is generally stated that the partial molal heat capacity change Δ C accompanying the heat denaturation is positive and independent of the temperature. This implies that heating the protein through T L results in a negative Δ C which seems physically unsatisfactory. The constant Δ C model is explored and a physically more realistic model is advanced which allows for a temperature-dependent Δ C which changes sign at some temperature within the range of stability of the native protein; Δ G( T) then has the form of a skewed parabola. Experimental heat capacity data for native lysozyme and for a flexible polymer lend support to this model. The molecular basis of cold inactivation of proteins is discussed in the light of the thermodynamic analysis.
ISSN:0301-4622
1873-4200
DOI:10.1016/0301-4622(88)80037-1