Molecular dynamics simulations of bromodomains reveal binding-site flexibility and multiple binding modes of the natural ligand acetyl-lysine

TitleMolecular dynamics simulations of bromodomains reveal binding-site flexibility and multiple binding modes of the natural ligand acetyl-lysine
Publication TypeJournal Article
Year of Publication2014
AuthorsSpiliotopoulos D., Caflisch A.
JournalIsrael Journal of Chemistry
Volume54
Issue8-9
Pagination1084–1092
Date PublishedAug 2014
Type of ArticleReview Article
ISSN1869-5868
Keywordsatomistic simulations, computational chemistry, Drug Design, epigenetics, protein-protein interactions
Abstract

Experimental protein structures provide spatial information at the atomic level. A further dimension, time, is supplemented by molecular dynamics. Since the pioneering work on the 58-residue inhibitor of bovine pancreatic trypsin in the group of Martin Karplus in the seventies, molecular dynamics simulations have shown that the intrinsic flexibility of proteins is essential for their function. Here, we review simulation studies of bromodomains. These protein modules are involved in the recognition of acetylated lysine side chains, a post-translational modification frequently observed in histone tails. The molecular dynamics simulations have unmasked: (i) the large plasticity of the loops lining the acetyl-lysine binding site (coupled to its self-occlusion), and (ii) multiple binding modes of acetyl-lysine. These simulation results suggest that recognition of histone tails by bromodomains is modulated by their intrinsic flexibility, and further corroborate the utility of molecular dynamics in understanding (macro)molecular recognition.

URLhttp://dx.doi.org/10.1002/ijch.201400009
DOI10.1002/ijch.201400009
pubindex

0188

Alternate JournalIsr. J. Chem.