Conformational flexibility of the leucine binding protein examined by protein domain coarse-grained molecular dynamics

Autor:	Lea Thøgersen, Iwona Siuda
Rok vydání:	2013
Předmět:	Models Molecular Chemistry Protein Conformation Organic Chemistry Protein domain Membrane Transport Proteins Molecular Dynamics Simulation DNA-binding protein Catalysis Force field (chemistry) Computer Science Applications Protein Structure Tertiary Inorganic Chemistry Microsecond Molecular dynamics Crystallography Protein structure Computational Theory and Mathematics Leucine Leucine binding Periplasmic Binding Proteins Biophysics Physical and Theoretical Chemistry Apoproteins
Zdroj:	Siuda, I & Thøgersen, L 2013, ' Conformational flexibility of the leucine binding protein examined by protein domain coarse-grained molecular dynamics ', Journal of Molecular Modeling, vol. 19, no. 11, pp. 4931-4945 . https://doi.org/10.1007/s00894-013-1991-9
ISSN:	0948-5023
DOI:	10.1007/s00894-013-1991-9
Popis:	Periplasmic binding proteins are the initial receptors for the transport of various substrates over the inner membrane of gram-negative bacteria. The binding proteins are composed of two domains, and the substrate is entrapped between these domains. For several of the binding proteins it has been established that a closed-up conformation exists even without substrate present, suggesting a highly flexible apo-structure which would compete with the ligand-bound protein for the transporter interaction. For the leucine binding protein (LBP), structures of both open and closed conformations are known, but no closed-up structure without substrate has been reported. Here we present molecular dynamics simulations exploring the conformational flexibility of LBP. Coarse grained models based on the MARTINI force field are used to access the microsecond timescale. We show that a standard MARTINI model cannot maintain the structural stability of the protein whereas the ELNEDIN extension to MARTINI enables simulations showing a stable protein structure and nanosecond dynamics comparable to atomistic simulations, but does not allow the simulation of conformational flexibility. A modification to the MARTINI-ELNEDIN setup, referred to as domELNEDIN, is therefore presented. The domELNEDIN setup allows the protein domains to move independently and thus allows for the simulation of conformational changes. Microsecond domELNEDIN simulations starting from either the open or the closed conformations consistently show that also for LBP, the apo-structure is flexible and can exist in a closed form.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::40b540bea9615eff2ac9e72e7c5a23d5 https://pubmed.ncbi.nlm.nih.gov/24048570 Zobrazit plný text záznamu Full text from SpringerLink