Abstract
Using action-derived molecular dynamics (ADMD), we study the dynamic folding pathway models of the Trp-cage protein by providing its sequential conformational changes from its initial disordered structure to the final native structure at atomic details. We find that the numbers of native contacts and native hydrogen bonds are highly correlated, implying that the native structure of Trp-cage is achieved through the concurrent formations of native contacts and native hydrogen bonds. In early stage, an unfolded state appears with partially formed native contacts (~40%) and native hydrogen bonds (~30%). Afterward, the folding is initiated by the contact of the side chain of Tyr3 with that of Trp6, together with the formation of the N-terminal α-helix. Then, the C-terminal polyproline structure docks onto the Trp6 and Tyr3 rings, resulting in the formations of the hydrophobic core of Trp-cage and its near-native state. Finally, the slow adjustment processes of the near-native states into the native structure are dominant in later stage. The ADMD results are in agreement with those of the experimental folding studies on Trp-cage and consistent with most of other computational studies.
Highlights
The understanding of the folding dynamics of a protein from its one-dimensional amino-acid sequence into the threedimensional native structure is a long-standing challenge in modern science
The goal of this study is to investigate the dynamic folding pathway models of the Trp-cage protein by providing its sequential conformational changes from its initial disordered structure to the final native structure, at atomic details
We have studied the dynamic folding pathway models of the 20-residue Trp-cage protein into the native structure at all-atom resolution by using action-derived molecular dynamics (ADMD) and parallel computation with the AMBER force field and the GB/SA solvation potential
Summary
The understanding of the folding dynamics of a protein from its one-dimensional amino-acid sequence into the threedimensional native structure is a long-standing challenge in modern science. The 20-residue Trp-cage protein [1] with a fast folding rate [2] has attracted many researchers, both experimentalists [1,2,3,4,5,6,7,8,9,10,11] and theoreticians [12,13,14,15,16,17,18,19,20,21,22,23,24], in the protein-folding research community. The Trp-cage protein has the amino-acid sequence of NLYIQ WLKDG GPSSG RPPPS (PDB code: 1L2Y). The salt bridge between Asp and Arg is important for the Trp-cage stability
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