Human m1 muscarinic acetylcholine receptor mutants were screened to determine receptor domains and cellular pathways relevant to down-regulation. Mutations in the second intracellular loop and the junctions of the third intracellular loop of the receptor, where a role for receptor activation or internalization had been previously demonstrated in HEK293 cells, were selected for this study. To assess receptor down-regulation, the m1 receptor mutants were transfected into Chinese hamster ovary cells. Because receptor internalization is expected to precede down-regulation, mutants displaying intact internalization were selected to permit interpretation of mutational effects on down-regulation alone. Four mutations were identified that specifically impaired down-regulation without altering receptor internalization: V127A, I211A, E360A, and K362A. The results define new receptor domains in the second intracellular loop and the junctions of the third intracellular loop that are involved in down-regulation. These same four mutants were also defective in signaling via the phospholipase C and the adenylyl cyclase pathways and in G protein activation, as measured by [35S]GTP gamma S binding. However, the level of second messenger stimulation correlated poorly with the extent of down-regulation. In summary, several mutations of the m1 receptor selectively affect down-regulation, demonstrating that internalization and down-regulation represent distinct events driven by different cellular mechanisms.
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