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RESEARCH PRODUCT
On the polymer physics origins of protein folding thermodynamics
Mark P. TaylorWolfgang PaulKurt Bindersubject
Models Molecular0301 basic medicineProtein FoldingQuantitative Biology::BiomoleculesPolymersProtein ConformationChemistryEnthalpyTemperatureGeneral Physics and AstronomyEnergy landscapeThermodynamicsContact order03 medical and health sciences030104 developmental biologyNative statePolymer physicsProtein foldingDownhill foldingFolding funnelPhysical and Theoretical Chemistrydescription
A remarkable feature of the spontaneous folding of many small proteins is the striking similarity in the thermodynamics of the folding process. This process is characterized by simple two-state thermodynamics with large and compensating changes in entropy and enthalpy and a funnel-like free energy landscape with a free-energy barrier that varies linearly with temperature. One might attribute the commonality of this two-state folding behavior to features particular to these proteins (e.g., chain length, hydrophobic/hydrophilic balance, attributes of the native state) or one might suspect that this similarity in behavior has a more general polymer-physics origin. Here we show that this behavior is also typical for flexible homopolymer chains with sufficiently short range interactions. Two-state behavior arises from the presence of a low entropy ground (folded) state separated from a set of high entropy disordered (unfolded) states by a free energy barrier. This homopolymer model exhibits a funneled free energy landscape that reveals a complex underlying dynamics involving competition between folding and non-folding pathways. Despite the presence of multiple pathways, this simple physics model gives the robust result of two-state thermodynamics for both the cases of folding from a basin of expanded coil states and from a basin of compact globule states.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2016-11-07 | The Journal of Chemical Physics |