Abstract

Molecular dynamic (MD) simulations with both implicit and explicit solvent models have been carried out to study the folding dynamics of HP-36 protein. Starting from the extended conformation, the secondary structure of all three helices in HP-36 was formed in about 50 ns and remained stable in the remaining simulation. However, the formation of the tertiary structure was difficult. Although some intermediates were close to the native structure, the overall conformation was not stable. Further analysis revealed that the large structure fluctuation of loop and hydrophobic core regions was devoted mostly to the instability of the structure during MD simulation. The backbone root-mean-square deviation (RMSD) of the loop and hydrophobic core regions showed strong correlation with the backbone RMSD of the whole protein. The free energy landscape indicated that the distribution of main chain torsions in loop and turn regions was far away from the native state. Starting from an intermediate structure extracted from the initial AMBER simulation, HP-36 was found to generally fold to the native state under the dynamically adjusted polarized protein-specific charge (DPPC) simulation, while the peptide did not fold into the native structure when AMBER force filed was used. The two best folded structures were extracted and taken into further simulations in water employing AMBER03 charge and DPPC for 25 ns. Result showed that introducing polarization effect into interacting potential could stabilize the near-native protein structure.

Highlights

  • Prediction of protein’s native structure from its sequence is still one of the greatest challenges in computational biology

  • Our results showed that the secondary structure formed on the 50 ns time scale while the tertiary structure was hard to fold in the whole Molecular dynamics (MD) simulation

  • We found that the two best folded structures were more stable under dynamically adjusted polarized protein-specific charge (DPPC) than under AMBER charge, indicating the importance of explicit treatment of polarization effect in MD simulation

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Summary

Introduction

Prediction of protein’s native structure from its sequence is still one of the greatest challenges in computational biology. The villin headpiece subdomain, a 36 residues peptide (HP36), has served as a benchmark system for the study of protein folding by all-atom molecular dynamics simulations [4,5,6,7,8,9,10,11]. It is one of the smallest proteins that can fold autonomously without the assistance of disulfide bonds, metal ions, or nonnatural amino acids. Several in silico folding and unfolding studies of HP-36 have been

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