Dynamics and time-averaged chemical potential of proteins: importance in oligomer association.

AUTOR(ES)

Xu, G

RESUMO

The chemical potential of a protein is a time-averaged quantity whose value depends upon the fractions of time spent in the different conformations and therefore upon the protein dynamics. If the monomer involved in an association equilibrium undergoes unfolding limited by its lifetime, its chemical potential as well as that of the associated form will not be constant and the free energy of association will be a diminishing function of the degree of dissociation. For a unique free energy of association, the logarithm of the protein concentration must change by 2.86 units to increase the degree of dissociation from 0.1 to 0.9. The dissociation of enolase appears to take place over a significantly smaller range (1.7 units), and dansyl conjugates of enolase show an even narrower range (0.9 unit). A simple descriptive theory is developed, and this shows that the values observed are explained by a difference in free energy of 1-3 kcal/mol (1 cal = 4.18 J) between the conformations present at negligible and almost complete dissociation.

Documentos Relacionados

• Time-averaged chemical potential of proteins and the detailed-balance principle (an alternative viewpoint).
• Hydrogen atoms in proteins: Positions and dynamics
• Measurement of rise time of averaged muscle action potential in normal subjects and patients with myopathy.
• Dynamics and function of proteins: The search for general concepts
• Harmonic dynamics of proteins: normal modes and fluctuations in bovine pancreatic trypsin inhibitor.