TY - JOUR T1 - The Role of a Conserved Inter-Transmembrane Domain Interface in Regulating α<sub>2a</sub>-Adrenergic Receptor Conformational Stability and Cell-Surface Turnover JF - Molecular Pharmacology JO - Mol Pharmacol SP - 929 LP - 938 DO - 10.1124/mol.59.4.929 VL - 59 IS - 4 AU - Matthew H. Wilson AU - Hilary A. Highfield AU - Lee E. Limbird Y1 - 2001/04/01 UR - http://molpharm.aspetjournals.org/content/59/4/929.abstract N2 - Functional and structural data from G protein-coupled receptors (GPCR) predict that transmembrane-domain (TM)2 is adjacent to TM7 within the GPCR structure, and that within this interface a conserved aspartate in TM2 and a conserved asparagine in TM7 exist in close proximity. Mutation at this D79(TM2)-N422(TM7) interface in the α2A-adrenergic receptor (α2AAR) affects not only receptor activation but also cell-surface residence time and conformational stability. Mutation at TM2(D79N) reduces allosteric modulation by Na+ and receptor activation more dramatically than affecting cell-surface receptor turnover and conformational stability, whereas mutation at TM7(N422D) creates profound conformational instability and more rapid degradation of receptor from the surface of cells despite receptor activation and allosteric modulation properties that mirror a wild-type receptor. Double mutation of TM2 and 7(D79N/N422D) reveals phenotypes for receptor activation and conformational stability intermediate between the wild-type and singly mutated α2AAR. Additionally, the structural placement of a negative charge at this TM2/TM7 interface is necessary but not sufficient for receptor structural stability, because mislocalization of the negative charge in either the D79Eα2AAR (which extends the charge out one methylene group) or the D79N/N422Dα2AAR (placing the charge in TM7 instead of TM2) results in conformational lability in detergent solution and more rapid cell-surface receptor clearance. These studies suggest that this interface is important in regulating receptor cell-surface residence time and conformational stability in addition to its previously recognized role in receptor activation. ER -