Human
G protein-coupled receptors (hGPCRs) are the most frequent
targets of Food and Drug Administration (FDA)-approved drugs. Structural
bioinformatics, along with molecular simulation, can support structure-based
drug design targeting hGPCRs. In this context, several years ago,
we developed a hybrid molecular mechanics (MM)/coarse-grained (CG)
approach to predict ligand poses in low-resolution hGPCR models. The
approach was based on the GROMOS96 43A1 and PRODRG united-atom force
fields for the MM part. Here, we present a new MM/CG implementation
using, instead, the Amber 14SB and GAFF all-atom potentials for proteins
and ligands, respectively. The new implementation outperforms the
previous one, as shown by a variety of applications on models of hGPCR/ligand
complexes at different resolutions, and it is also more user-friendly.
Thus, it emerges as a useful tool to predict poses in low-resolution
models and provides insights into ligand binding similarly to all-atom
molecular dynamics, albeit at a lower computational cost.
Advances in coarse-grained molecular dynamics (CGMD) simulations have extended the use of computational studies on biological macromolecules and their complexes, as well as the interactions of membrane protein and lipid complexes at a reduced level of representation, allowing longer and larger molecular dynamics simulations. Here, we present a computational platform dedicated to the preparation, running, and analysis of CGMD simulations. The platform is built on a completely revisited version of our Martini coarsE gRained MembrAne proteIn Dynamics (MERMAID) web server, and it integrates this with other three dedicated services. In its current version, the platform expands the existing implementation of the Martini force field for membrane proteins to also allow the simulation of soluble proteins using the Martini and the SIRAH force fields. Moreover, it offers an automated protocol for carrying out the backmapping of the coarse-grained description of the system into an atomistic one.
The translocator protein (TSPO) is a transmembrane protein present in the three domains of life. Its functional quaternary structure consists of one or more subunits. In mouse, the dimer-to-monomer equilibrium is shifted in vitro towards the monomer by adding cholesterol, a natural component of mammalian membranes. Here, we present a coarse-grained molecular dynamics study on the mouse protein in the presence of a physiological content and of an excess of cholesterol. The latter turns out to weaken the interfaces of the dimer by clusterizing mostly at the inter-monomeric space and pushing the contact residues apart. It also increases the compactness and the rigidity of the monomer. These two factors might play a role for the experimentally observed incremented stability of the monomeric form with increased content of cholesterol. Comparison with simulations on bacterial proteins suggests that the effect of cholesterol is much less pronounced for the latter than for the mouse protein.
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