Protein Stability in Mixed Solvents: A Balance of Contact Interaction and Excluded Volume

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Protein Stability in Mixed Solvents: A Balance of Contact Interaction and Excluded Volume

John A. Schellman

Institute of Molecular Biology, University of Oregon, Eugene, Oregon 97405

Correspondence: Address reprint requests to John A. Schellman, 65 W. 30th Ave., Eugene, OR 97405. Tel.: 541-346-6093; Fax: 541-346-5891; E-mail: john{at}molbio.uoregon.edu.

Changes in excluded volume and contact interaction with thesurface of a protein have been suggested as mechanisms for thechanges in stability induced by cosolvents. The aim of the presentpaper is to present an analysis that combines both effects ina quantitative manner. The result is that both processes arepresent in both stabilizing and destabilizing interactions andneither can be ignored. Excluded volume was estimated usingaccessible surface area calculations of the kind introducedby Lee and Richards. The change in excluded volume on unfolding, ${Delta}$ X, is quite large. For example, ${Delta}$ X for ribonuclease is 6.7 Lin urea and $~$ 16 L in sucrose. The latter number is greater thanthe molar volume of the protein. Direct interaction with theprotein is represented as the solvent exchange mechanism, whichdiffers from ordinary association theory because of the weaknessof the interaction and the high concentrations of cosolvents.The balance between the two effects and their contribution tooverall stability are most simply presented as bar diagramsas in Fig. 3. Our finding for five proteins is that excludedvolume contributes to the stabilization of the native structureand that contact interaction contributes to destabilization.This is true for five proteins and four cosolvents includingboth denaturants and osmolytes. Whether a substance stabilizesa protein or destabilizes it depends on the relative size ofthese two contributions. The constant for the cosolvent contactwith the protein is remarkably uniform for four of the proteins,indicating a similarity of groups exposed during unfolding.One protein, staphylococcus nuclease, is anomalous in almostall respects. In general, the strength of the interaction withguanidinium is about twice that of urea, which is about twicethat of trimethylamine-N-oxide and sucrose. Arguments are presentedfor the use of volume fractions in equilibrium equations andthe ignoring of activity coefficients of the cosolvent. It isshown in the Appendix that both the excluded volume and thedirect interaction can be extracted in a unified way from theMcMillan-Mayer formula for the second virial coefficient.

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