Prediction of protein-folding mechanisms from free-energy landscapes derived from native structures.

Guided by recent experimental results suggesting that protein-folding rates and mechanisms are determined largely by native-state topology, we develop a simple model for protein folding free-energy landscapes based on native-state structures. The configurations considered by the model contain one or two contiguous stretches of residues ordered as in the native structure with all other residues completely disordered; the free energy of each configuration is the difference between the entropic cost of ordering the residues, which depends on the total number of residues ordered and the length of the loop between the two ordered segments, and the favorable attractive interactions, which are taken to be proportional to the total surface area buried by the ordered residues in the native structure. Folding kinetics are modeled by allowing only one residue to become ordered/disordered at a time, and a rigorous and exact method is used to identify free-energy maxima on the lowest free-energy paths connecting the fully disordered and fully ordered configurations. The distribution of structure in these free-energy maxima, which comprise the transition-state ensemble in the model, are reasonably consistent with experimental data on the folding transition state for five of seven proteins studied. Thus, the model appears to capture, at least in part, the basic physics underlying protein folding and the aspects of native-state topology that determine protein-folding mechanisms.

[1]  Homer Jacobson,et al.  Intramolecular Reaction in Polycondensations. I. The Theory of Linear Systems , 1950 .

[2]  F. Young Biochemistry , 1955, The Indian Medical Gazette.

[3]  J. Schellman,et al.  The Factors Affecting the Stability of Hydrogen-bonded Polypeptide Structures in Solution , 1958 .

[4]  A. D. McLachlan,et al.  Solvation energy in protein folding and binding , 1986, Nature.

[5]  K. Dill,et al.  The effects of internal constraints on the configurations of chain molecules , 1990 .

[6]  P. Kraulis A program to produce both detailed and schematic plots of protein structures , 1991 .

[7]  L Serrano,et al.  The folding of an enzyme. III. Structure of the transition state for unfolding of barnase analysed by a protein engineering procedure. , 1992, Journal of molecular biology.

[8]  L Serrano,et al.  The folding of an enzyme. IV. Structure of an intermediate in the refolding of barnase analysed by a protein engineering procedure. , 1992, Journal of molecular biology.

[9]  Kenneth M. Merz,et al.  Rapid approximation to molecular surface area via the use of Boolean logic and look‐up tables , 1993, J. Comput. Chem..

[10]  R A Sayle,et al.  RASMOL: biomolecular graphics for all. , 1995, Trends in biochemical sciences.

[11]  J. Onuchic,et al.  Funnels, pathways, and the energy landscape of protein folding: A synthesis , 1994, Proteins.

[12]  A. Fersht,et al.  The structure of the transition state for folding of chymotrypsin inhibitor 2 analysed by protein engineering methods: evidence for a nucleation-condensation mechanism for protein folding. , 1995, Journal of molecular biology.

[13]  A. Fersht,et al.  Characterizing transition states in protein folding: an essential step in the puzzle. , 1995, Current opinion in structural biology.

[14]  J. Onuchic,et al.  Toward an outline of the topography of a realistic protein-folding funnel. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[15]  Serrano,et al.  Structure of the transition state for folding of the 129 aa protein CheY resembles that of a smaller protein, CI-2. , 1995, Folding & design.

[16]  V. Hilser,et al.  The magnitude of the backbone conformational entropy change in protein folding , 1996, Proteins.

[17]  J. Onuchic,et al.  DIFFUSIVE DYNAMICS OF THE REACTION COORDINATE FOR PROTEIN FOLDING FUNNELS , 1996, cond-mat/9601091.

[18]  P. Wolynes,et al.  Folding funnels and energy landscapes of larger proteins within the capillarity approximation. , 1997, Proceedings of the National Academy of Sciences of the United States of America.

[19]  A V Finkelstein,et al.  Rate of protein folding near the point of thermodynamic equilibrium between the coil and the most stable chain fold. , 1997, Folding & design.

[20]  L. Serrano,et al.  Loop length, intramolecular diffusion and protein folding , 1997, Nature Structural Biology.

[21]  A. Fersht,et al.  Glutamine, alanine or glycine repeats inserted into the loop of a protein have minimal effects on stability and folding rates. , 1997, Journal of molecular biology.

[22]  D Baker,et al.  Contrasting roles for symmetrically disposed beta-turns in the folding of a small protein. , 1997, Journal of molecular biology.

[23]  V. Muñoz,et al.  Folding dynamics and mechanism of β-hairpin formation , 1997, Nature.

[24]  L Regan,et al.  An inverse correlation between loop length and stability in a four-helix-bundle protein. , 1997, Folding & design.

[25]  Terrence G. Oas,et al.  The energy landscape of a fast-folding protein mapped by Ala→Gly Substitutions , 1997, Nature Structural Biology.

[26]  D. Baker,et al.  Functional rapidly folding proteins from simplified amino acid sequences , 1997, Nature Structural Biology.

[27]  Mohamed A. Marahiel,et al.  Conservation of rapid two-state folding in mesophilic, thermophilic and hyperthermophilic cold shock proteins , 1998, Nature Structural Biology.

[28]  D Baker,et al.  The sequences of small proteins are not extensively optimized for rapid folding by natural selection. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[29]  T. Oas,et al.  Protein folding dynamics: quantitative comparison between theory and experiment. , 1998, Biochemistry.

[30]  D. Baker,et al.  Contact order, transition state placement and the refolding rates of single domain proteins. , 1998, Journal of molecular biology.

[31]  David Baker,et al.  Important role of hydrogen bonds in the structurally polarized transition state for folding of the src SH3 domain , 1998, Nature Structural &Molecular Biology.

[32]  L. Serrano,et al.  Obligatory steps in protein folding and the conformational diversity of the transition state , 1998, Nature Structural &Molecular Biology.

[33]  Shoji Takada,et al.  Variational Theory for Site Resolved Protein Folding Free Energy Surfaces , 1998, cond-mat/9805366.

[34]  V. Pande,et al.  Pathways for protein folding: is a new view needed? , 1998, Current opinion in structural biology.

[35]  A. Finkelstein,et al.  A theoretical search for folding/unfolding nuclei in three-dimensional protein structures. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[36]  D. Baker,et al.  Matching theory and experiment in protein folding. , 1999, Current opinion in structural biology.

[37]  V. Muñoz,et al.  A simple model for calculating the kinetics of protein folding from three-dimensional structures. , 1999, Proceedings of the National Academy of Sciences of the United States of America.