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Toward Resolution of Ambiguity for the Unfolded State

Department of Chemical and Materials Engineering, University of Cincinnati, Cincinnati, Ohio

Correspondence: Address reprint requests to Gregory Beaucage, Dept. of Chemical and Materials Engineering, University of Cincinnati, Cincinnati, OH 45221-0012. E-mail: beaucag{at}uc.edu.

The unfolded states in proteins and nucleic acids remain weakly understood despite their importance in folding processes; misfolding diseases (Parkinson's and Alzheimer's); natively unfolded proteins (as many as 30% of eukaryotic proteins, according to Fink); and the study of ribozymes. Research has been hindered by the inability to quantify the residual (native) structure present in an unfolded protein or nucleic acid. Here, a scaling model is proposed to quantify the molar degree of folding and the unfolded state. The model takes a global view of protein structure and can be applied to a number of analytic methods and to simulations. Three examples are given of application to small-angle scattering from pressure-induced unfolding of SNase, from acid-unfolded cytochrome c, and from folding of Azoarcus ribozyme. These examples quantitatively show three characteristic unfolded states for proteins, the statistical nature of a protein folding pathway, and the relationship between extent of folding and chain size during folding for charge-driven folding in RNA.