Artículo
Coupling between conformation and proton binding in proteins
Vila, Jorge Alberto
; Ripoll, Daniel R.; Arnautova, Yelena A.; Vorobjev, Yury N.; Scheraga, Harold A.
Fecha de publicación:
12/2005
Editorial:
Wiley-liss, div John Wiley & Sons Inc.
Revista:
Proteins: Structure, Function And Genetics
ISSN:
0887-3585
Idioma:
Inglés
Tipo de recurso:
Artículo publicado
Clasificación temática:
Resumen
Interest centers here on whether the use of a fixed charge distribution of a protein solute, or a treatment that considers proton-binding equilibria by solving the Poisson equation, is a better approach to discriminate native from non-native conformations of proteins. In this analysis of the charge distribution of 7 proteins, we estimate the solvation free energy contribution to the total free energy by exploring the 2ζ possible ionization states of the whole molecule, with ζ being the number of ionizable groups in the amino acid sequence, for every conformation in the ensembles of 7 proteins. As an additional consideration of the role of electrostatic interactions in determining the charge distribution of native folds, we carried out a comparison of alternative charge assignment models for the ionizable residues in a set of 21 native-like proteins. The results of this work indicate that (1) for 6 out of 7 proteins, estimation of solvent polarization based on the Generalized Born model with a fixed charge distribution provides the optimal trade-off between accuracy, with respect to the Poisson equation, and speed when compared to the accessible surface area model; for the seventh protein, consideration of all possible ionization states of the whole molecule appears to be crucial to discriminate the native from non-native conformations; (2) significant differences in the degree of ionization and hence the charge distribution for native folds are found between the different charge models examined; (3) the stability of the native state is determined by a delicate balance of all the energy components, and (4) conformational entropy, and hence the dynamics of folding, may play a crucial role for a successful ab initio protein folding prediction.
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Articulos(IMASL)
Articulos de INST. DE MATEMATICA APLICADA DE SAN LUIS
Articulos de INST. DE MATEMATICA APLICADA DE SAN LUIS
Citación
Vila, Jorge Alberto; Ripoll, Daniel R.; Arnautova, Yelena A.; Vorobjev, Yury N.; Scheraga, Harold A.; Coupling between conformation and proton binding in proteins; Wiley-liss, div John Wiley & Sons Inc.; Proteins: Structure, Function And Genetics; 61; 1; 12-2005; 56-68
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