Spin glasses and the statistical mechanics of protein folding.

Bryngelson, Joseph D.; Wolynes, Peter G.

doi:10.1073/pnas.84.21.7524

Cited by 1,525 publications

(1,328 citation statements)

References 28 publications

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“…This is a natural starting assumption for thinking about heteropolymer dynamics since one expects this behavior generically for heterogeneous systems. The implications of the roughness of heteropolymer energy landscapes for protein folding were first discussed by Bryngelson and Wolynes who postulated that the energies of the states of a random heteropolymer could be approximately modeled by a set of random, independent energies [4]. This model is known as the random energy model in the theory of spin glasses [45][46][47].…”

Section: Smoothness Roughness and The Topography Of Energy Landscmentioning

confidence: 99%

Funnels, pathways, and the energy landscape of protein folding: A synthesis

et al. 1995

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The understanding, and even the description of protein folding is impeded by the complexity of the process. Much of this complexity can be described and understood by taking a statistical approach to the energetics of protein conformation, that is, to the energy landscape. The statistical energy landscape approach explains when and why unique behaviors, such as specific folding pathways, occur in some proteins and more generally explains the distinction between folding processes common to all sequences and those peculiar to individual sequences. This approach also gives new, quantitative insights into the interpretation of experiments and simulations of protein folding thermodynamics and kinetics. Specifically, the picture provides simple explanations for folding as a two‐state first‐order phase transition, for the origin of metastable collapsed unfolded states and for the curved Arrhenius plots observed in both laboratory experiments and discrete lattice simulations. The relation of these quantitative ideas to folding pathways, to uniexponential vs. multiexponential behavior in protein folding experiments and to the effect of mutations on folding is also discussed. The success of energy landscape ideas in protein structure prediction is also described. The use of the energy landscape approach for analyzing data is illustrated with a quantitative analysis of some recent simulations, and a qualitative analysis of experiments on the folding of three proteins. The work unifies several previously proposed ideas concerning the mechanism protein folding and delimits the regions of validity of these ideas under different thermodynamic conditions. © 1995 Wiley‐Liss, Inc.

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Section: Smoothness Roughness and The Topography Of Energy Landscmentioning

confidence: 99%

Funnels, pathways, and the energy landscape of protein folding: A synthesis

et al. 1995

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“…In addition, the comparison to experiments requires an accumulation of folding events to gain a enough large statistics further narrowing the route to the to full-atom techniques. These limitations suggest resorting to minimalist models which adopt a less accurate description of protein chains, residue-residue and residue-solvent interactions [3,4,5,6,7]. Approximate representations reduce the computational costs and, with a certain amount of uncertainty, allow to follow all the stages which bring a protein into its native fold.…”

Section: Introductionmentioning

confidence: 99%

Analysis of PIN1 WW domain through a simple statistical mechanics model

Bruscolini

Cecconi

2005

Biophysical Chemistry

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We have applied a simple statistical-mechanics Gō-like model to the analysis of the PIN1 WW domain, resorting to Mean Field and Monte Carlo techniques to characterize its thermodynamics, and comparing the results with the wealth of available experimental data. PIN1 WW domain is a 39-residues protein fragment which folds on an antiparallel β-sheet, thus representing an interesting model system to study the behavior of these secondary structure elements. Results show that the model correctly reproduces the two-state behavior of the protein, and also the trends of the experimental φT -values. Moreover, there is a good agreement between Monte Carlo results and the Mean-Field ones, which can be obtained with a substantially smaller computational effort.

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“…This conclusion corresponds to the consistency principle of G6 (1983) or the principle of minimum frustration of Bryngelson and Wolynes (1987). These concepts state that the shortrange interactions governing secondary structure propensities are consistent (or not in conflict) with the long-range interactions.…”

Section: Resultsmentioning

confidence: 75%

Determinants of protein side‐chain packing

1994

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The problem of protein side-chain packing for a given backbone trace is investigated using 3 different prediction models. The first requires an exhaustive search of all possible combinations of side-chain conformers, using the dead-end elimination theorem. The second considers only side-chain-backbone interactions, whereas the third neglects side-chain-backbone interactions and instead keeps side-chain-side-chain interactions. Predictions of sidechain conformations for 11 proteins using all 3 models show that removal of side-chain-side-chain interactions does not cause a large decrease in the prediction accuracy, whereas the model having only side-chain-side-chain interactions still retains a significant level of accuracy. These results suggest that the 2 classes of interactions, sidechain-backbone and side-chain-side-chain, are consistent with each other and work concurrently to stabilize the native conformations. This is confirmed by analyses of energy spectra of the side-chain conformations derived from the fourth prediction model, the Independent model, which gives almost the same quality of the prediction as the dead-end elimination. The analyses indicate that the 2 classes of interactions simultaneously increase the energy difference between the native and nonnative conformations.Keywords: consistency in side-chain packing; dead-end elimination; energy spectra; Independent model; prediction of side-chain conformation; side-chain packing; side-chain rotamer Individual proteins are characterized by their native backbone folds and side-chain arrangements. Because more than half of the degrees of freedom are required in defining the latter, the problem of side-chain packing is an important subproblem in protein folding. To tackle this problem of side-chain packing, it has often been assumed that the main-chain atoms are fixed at their native coordinates ( The number of possible combinations of side-chain conformations (c, and cj in E 2 ) is still too large to be enumerated exhaustively, but due to the simplicity of Equation 2, various heuristic approaches have successfully predicted side-chain con-

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Spin glasses and the statistical mechanics of protein folding.

Cited by 1,525 publications

References 28 publications

Funnels, pathways, and the energy landscape of protein folding: A synthesis

Funnels, pathways, and the energy landscape of protein folding: A synthesis

Analysis of PIN1 WW domain through a simple statistical mechanics model

Determinants of protein side‐chain packing

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