The thyroid-stimulating hormone receptor (TSHR) transmembrane domain (TMD) is found in the plasma membrane and consists of lipids and water molecules. To understand the role of TSHR-associated water molecules, we used molecular dynamic simulations of the TMD and identified a network of putative receptor-associated transmembrane water channels. This result was confirmed with extended simulations of the full-length TSHR with and without TSH ligand binding. While the transport time observed in the simulations via the TSHR protein was slower than via the lipid bilayer itself, we found that significantly more water traversed via the TSHR than via the lipid bilayer, which more than doubled with the binding of TSH. Using rat thyroid cells (FRTL-5) and a calcein fluorescence technique, we measured cell volumes after blockade of aquaporins 1 and 4, the major thyroid cell water transporters. TSH showed a dose-dependent ability to influence water transport, and similar effects were observed with stimulating TSHR autoantibodies. Small molecule TSHR agonists, which are allosteric activators of the TMD, also enhanced water transport, illustrating the role of the TMD in this phenomenon. Furthermore, the water channel pathway was also mapped across 2 activation motifs within the TSHR TMD, suggesting how water movement may influence activation of the receptor. In pathophysiological conditions such as hypothyroidism and hyperthyroidism where TSH concentrations are highly variable, this action of TSH may greatly influence water movement in thyroid cells and many other extrathyroidal sites where the TSHR is expressed, thus affecting normal cellular function.
Keywords: DPPC; GPCR; TSHR; calcein; molecular dynamics; water channel.
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