Literature DB >> 15731383

A directed essential dynamics simulation of peptide folding.

Changjun Chen1, Yi Xiao, Linsen Zhang.   

Abstract

We present a directed essential dynamics (DED) method for peptide and protein folding. DED is a molecular dynamics method based on the essential dynamics sampling and the principal component analysis. The main idea of DED is to use principal component analysis to determine the direction of the most active collective motion of peptides at short intervals of time (20 fs) during the folding process and then add an additional force along it to adjust the folding direction. This method can make the peptides avoid being trapped in the local minima for a long time and enhance the sampling efficiency in conformational space during the simulation. An S-peptide with 15 amino acids is used to demonstrate the DED method. The results show that DED can lead the S-peptide to fold quickly into the native state, whereas traditional molecular dynamics needs more time to do this.

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Year:  2005        PMID: 15731383      PMCID: PMC1305476          DOI: 10.1529/biophysj.104.046904

Source DB:  PubMed          Journal:  Biophys J        ISSN: 0006-3495            Impact factor:   4.033


  38 in total

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4.  Molecular dynamics simulations of the unfolding of an alpha-helical analogue of ribonuclease A S-peptide in water.

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5.  Structure-based thermodynamic scale of alpha-helix propensities in amino acids.

Authors:  I Luque; O L Mayorga; E Freire
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Authors:  A Amadei; A B Linssen; B L de Groot; D M van Aalten; H J Berendsen
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7.  Essential dynamics from NMR clusters: dynamic properties of the Myb DNA-binding domain and a hinge-bending enhancing variant.

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10.  Estimation of changes in side chain configurational entropy in binding and folding: general methods and application to helix formation.

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