Amino Acid 49 Polymorphisms of the Human &bgr; 1 -Adrenergic Receptor Affect Agonist-Promoted Trafficking

The signaling impact of a human &bgr; 1 -adrenergic receptor (&bgr; 1 AR) polymorphism at residue 49 of the aminoterminus (Ser-to-Gly substitution) was studied by recombinantly expressing each receptor. The two receptors displayed identical agonist and antagonist binding affinities. Furthermore, basal and agonist-stimulated adenylyl cyclase activities were the same for these receptors as assessed in both cell types. Although short-term agonist exposure resulted in similar degrees of receptor internalization, long-term agonist-promoted downregulation was greater for Gly49 compared with Ser49. The Gly49 receptor underwent a 24 ± 3% loss of receptor density after exposure to isoproterenol for 18 h, whereas Ser49 underwent no such loss. In studies in which receptor synthesis was inhibited, agonist-promoted downregulation for Gly49 was 55 ± 3% compared with 36 ± 5% for Ser49. In the absence of agonist, degradative turnover of each receptor was the same. Immunoblotting revealed that some of the Ser49 receptor exists as a highly N-glycosylated form (≈105-kD molecular mass), which is not present with Gly49. Thus the phenotype of the Gly49 polymorphic receptor is that of wild-type coupling with enhanced agonist-promoted downregulation, which is associated with altered N-glycosylation. Based on this cellular phenotype, the &bgr; 1 AR Gly49 polymorphism may impart a beneficial effect in chronic heart failure.

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