Transferability of different classical force fields for right and left handed alpha-helices constructed from enantiomeric amino acids

TitleTransferability of different classical force fields for right and left handed alpha-helices constructed from enantiomeric amino acids
Publication TypeJournal Article
Year of Publication2016
AuthorsBiswas, S, Sarkar, S, Pandey, PRaj, Roy, S
JournalPhysical Chemistry Chemical Physics
Volume18
Issue7
Pagination5550-5563
Date PublishedFEB
ISSN1463-9076
Abstract

Amino acids can form D and L enantiomers, of which the L enantiomer is abundant in nature. The naturally occurring L enantiomer has a greater preference for a right handed helical conformation, and the D enantiomer for a left handed helical conformation. The other conformations, that is, left handed helical conformations of the L enantiomers and right handed helical conformations of the D enantiomers, are not common. The energetic differences between left and right handed alpha helical peptide chains constructed from enantiomeric amino acids are investigated using quantum chemical calculations (using the M06/6-311g(d,p) level of theory). Further, the performances of commonly used biomolecular force fields (OPLS/AA, CHARMM27/CMAP and AMBER) to represent the different helical conformations (left and right handed) constructed from enantiomeric (D and L) amino acids are evaluated. 5- and 10-mer chains from D and L enantiomers of alanine, leucine, lysine, and glutamic acid, in right and left handed helical conformations, are considered in the study. Thus, in total, 32 a-helical polypeptides (4 amino acids x 4 conformations of 5-mer and 10-mer) are studied. Conclusions, with regards to the performance of the force fields, are derived keeping the quantum optimized geometry as the benchmark, and on the basis of phi and psi angle calculations, hydrogen bond analysis, and different long range helical order parameters.

DOI10.1039/c5cp06715d
Type of Journal (Indian or Foreign)

Foreign

Impact Factor (IF)4.449
Divison category: 
Physical and Materials Chemistry