Abstract
Coarse-grained, self-contained polymer models are powerful tools in the study of protein folding. They are also essential to assess predictions from less rigorous theoretical approaches that lack an explicit-chain representation. Here we review advances in coarse-grained modeling of cooperative protein folding, noting in particular that the Levinthal paradox was raised in response to the experimental discovery of two-state-like folding in the late 1960s, rather than to the problem of conformational search per se. Comparisons between theory and experiment indicate a prominent role of desolvation barriers in cooperative folding, which likely emerges generally from a coupling between local conformational preferences and nonlocal packing interactions. Many of these principles have been elucidated by native-centric models, wherein nonnative interactions may be treated perturbatively. We discuss these developments as well as recent applications of coarse-grained chain modeling to knotted proteins and to intrinsically disordered proteins.
Original language | English |
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Pages (from-to) | 301-326 |
Journal | Annual Review of Physical Chemistry |
Volume | 62 |
DOIs | |
Publication status | Published - 2011 |
Subject classification (UKÄ)
- Biophysics
Free keywords
- native topology
- Levinthal paradox
- folding funnel
- energy landscape
- desolvation
- enthalpic barrier