Bulky side chains and non-native salt bridges slow down the folding of a cross-linked helical peptide: A combined molecular dynamics and time-resolved infrared spectroscopy study

TitleBulky side chains and non-native salt bridges slow down the folding of a cross-linked helical peptide: A combined molecular dynamics and time-resolved infrared spectroscopy study
Publication TypeJournal Article
Year of Publication2009
AuthorsPaoli B., Seeber M., Backus E.HG, Ihalainen J.A, Hamm P., Caflisch A.
JournalThe Journal of Physical Chemistry B
Volume113
Issue13
Pagination4435-4442
Date Published2009 Apr 2
Type of ArticleResearch Article
ISSN1520-6106
KeywordsComputer Simulation, Kinetics, Models, Molecular, Mutation, Peptides, Protein Folding, Protein Structure, Secondary, Protein Structure, Tertiary, Salts, Spectrophotometry, Infrared, Time Factors
Abstract

Multiple 4-µs molecular dynamics (MD) simulations are used to study the folding process of the cross-linked α-helical peptide Ac-EACAR5EAAAR10EAACR15Q-NH2 (EAAAR peptide). The folding kinetics are single exponential at 330 K, while they are complex at 281 K with a clear deviation from single-exponential behavior, in agreement with time-resolved infrared (IR) spectroscopy measurements. Network analysis of the conformation space sampled by the MD simulations reveals four main folding channels which start from conformations with partially formed helical structure and non-native salt-bridges in a kinetically partitioned unfolded state. The independent folding pathways explain the comparable quality of models based on stretched exponential and multiexponential fitting of the kinetic traces at low temperature. The rearrangement of bulky side chains, and in particular their reorientation with respect to the cross-linker, makes the EAAAR peptide a slower folder at 281 K than a similar peptide devoid of the three glutamate side chains. On the basis of this simulation result, extracted from a total MD sampling of 1.0 ms, a mutant with additional bulky side chains (three methionines replacing alanines at positions 2, 7, and 12) is suggested to fold slower than the EAAAR peptide. This prediction is confirmed by time-resolved IR spectroscopy.

DOI10.1021/jp810431s
pubindex

0112

Alternate JournalJ. Phys. Chem. B
PubMed ID19256526
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