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Literature DB >> 7549881

Domains in folding of model proteins.

V I Abkevich¹, A M Gutin, E I Shakhnovich.

Abstract

By means of Monte Carlo simulation, we investigated the equilibrium between folded and unfolded states of lattice model proteins. The amino acid sequences were designed to have pronounced energy minimum target conformations of different length and shape. For short fully compact (36-mer) proteins, the all-or-none transition from the unfolded state to the native state was observed. This was not always the case for longer proteins. Among 12 designed sequences with the native structure of a fully compact 48-mer, a simple all-or-none transition was observed in only three cases. For the other nine sequences, three states of behavior-the native, denatured, and intermediate states-were found. The contiguous part of the native structure (domain) was conserved in the intermediate state, whereas the remaining part was completely unfolded and structureless. These parts melted separately from each other.

Mesh：

Substances：
Proteins

Year: 1995 PMID： 7549881 PMCID： PMC2143143 DOI： 10.1002/pro.5560040615

Source DB: PubMed Journal: Protein Sci ISSN： 0961-8368 Impact factor: 6.725

21 in total

Review 1. Dynamic Monte Carlo simulations of a new lattice model of globular protein folding, structure and dynamics.

Authors: J Skolnick; A Kolinski
Journal: J Mol Biol Date: 1991-09-20 Impact factor: 5.469

2. Theory of cooperative transitions in protein molecules. I. Why denaturation of globular protein is a first-order phase transition.

Authors: E I Shakhnovich; A V Finkelstein
Journal: Biopolymers Date: 1989-10 Impact factor: 2.505

Domains in folding of model proteins.

Review 1. Dynamic Monte Carlo simulations of a new lattice model of globular protein folding, structure and dynamics.

2. Theory of cooperative transitions in protein molecules. I. Why denaturation of globular protein is a first-order phase transition.

3. How does a protein fold?

Review 4. Why are the same protein folds used to perform different functions?

5. Three-state thermodynamic analysis of the denaturation of staphylococcal nuclease mutants.

6. Specific nucleus as the transition state for protein folding: evidence from the lattice model.

Review 7. Protein folding dynamics: the diffusion-collision model and experimental data.

Review 8. Stability of proteins. Proteins which do not present a single cooperative system.

9. Study of the "molten globule" intermediate state in protein folding by a hydrophobic fluorescent probe.

10. Spin glasses and the statistical mechanics of protein folding.

1. Folding pathway of a lattice model for proteins.

2. An entropy criterion to detect minimally frustrated intermediates in native proteins.

3. Foldons, protein structural modules, and exons.

4. Optimization of rates of protein folding: the nucleation-condensation mechanism and its implications.