posted on 2018-04-04, 00:00authored byYuta Kajiwara, Satoshi Yasuda, Simon Hikiri, Tomohiko Hayashi, Mitsunori Ikeguchi, Takeshi Murata, Masahiro Kinoshita
The G protein-coupled
receptors (GPCRs) form a large, physiologically
important family of membrane proteins and are currently the most attractive
targets for drug discovery. We investigate the physical origin of
thermostabilization of the adenosine A2a receptor (A2aR) in the active state, which was experimentally achieved
by another research group using the four point mutations: L48A, A54L,
T65A, and Q89A. The investigation is performed on the basis of our
recently developed physics-based free-energy function (FEF), which
has been quite successful for the thermodynamics of GPCRs in the inactive
state. The experimental condition for solving the wild-type and mutant
crystal structures was substantially different from that for comparing
their thermostabilities. Therefore, all-atom molecular dynamics simulations
are necessitated, which also allows us to account for the structural
fluctuations of the membrane protein. We show that the quadruple mutation
leads to the enlargement of the solvent–entropy gain upon protein
folding. The solvent is formed by hydrocarbon groups constituting
nonpolar chains within the lipid bilayer, and the entropy is relevant
to the thermal motion of the hydrocarbon groups. From an energetic
point of view (e.g., in terms of protein intramolecular hydrogen bonds),
the mutation confers no improvement upon the structural stability
of A2aR. The reliability of our FEF and the crucial importance
of the solvent-entropy effect have thus been demonstrated for a GPCR
in the active state. We are now ready to identify thermostabilizing
mutations of GPCRs not only in the inactive state but also in the
active one.