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Current Physical Chemistry

Editor-in-Chief

ISSN (Print): 1877-9468
ISSN (Online): 1877-9476

Complexity in Protein Folding: Simulation Meets Experiment

Author(s): Amedeo Caflisch and Peter Hamm

Volume 2, Issue 1, 2012

Page: [4 - 11] Pages: 8

DOI: 10.2174/1877946811202010004

Price: $65

Abstract

We review our joint experimental-theoretical effort on the folding of photo-switchable α-helices. The folding kinetics of these peptides is profoundly non-exponential, which is attributed to a partitioning of the unfolded state into several misfolded traps. These traps are connected to the folded state in a hub-like fashion with folding barriers of different heights. Molecular dynamics simulations reveal a semi-quantitative agreement with the complex response observed in the experiment, allowing one to discuss the process in unprecedented detail. It is found that the nonexponential response is to a large extent introduced by the photo-linker used to initiate folding. Hence, folding of these cross-linked peptides emulates formation of a helical segment in the context of a globular protein rather than folding of an isolated peptide.

Keywords: Molecular dynamics simulations, Time-resolved infrared spectroscopy, Protein folding, Cross-linked alpha-helix, Misfolded traps, Free energy surface of folding, Kinetic Partitioning, Steric Encumbrance, peptide, Backbone


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