Abstract
Recent studies suggest that the second extracellular loop (o2 loop) of bovine rhodopsin and other class I G protein-coupled receptors (GPCRs) targeted by biogenic amine ligands folds deeply into the transmembrane receptor core where the binding of cis-retinal and biogenic amine ligands is known to occur. In the past, the potential role of the o2 loop in agonist-dependent activation of biogenic amine GPCRs has not been studied systematically. To address this issue, we used the M(3) muscarinic acetylcholine receptor (M3R), a prototypic class I GPCR, as a model system. Specifically, we subjected the o2 loop of the M3R to random mutagenesis and subsequently applied a novel yeast genetic screen to identity single amino acid substitutions that interfered with M3R function. This screen led to the recovery of about 20 mutant M3Rs containing single amino acid changes in the o2 loop that were inactive in yeast. In contrast, application of the same strategy to the extracellular N-terminal domain of the M3R did not yield any single point mutations that disrupted M3R function. Pharmacological characterization of many of the recovered mutant M3Rs in mammalian cells, complemented by site-directed mutagenesis studies, indicated that the presence of several o2 loop residues is important for efficient agonist-induced M3R activation. Besides the highly conserved Cys(220) residue, Gln(207), Gly(211), Arg(213), Gly(218), Ile(222), Phe(224), Leu(225), and Pro(228) were found to be of particular functional importance. In general, mutational modification of these residues had little effect on agonist binding affinities. Our findings are therefore consistent with a model in which multiple o2 loop residues are involved in stabilizing the active state of the M3R. Given the high degree of structural homology found among all biogenic amine GPCRs, our findings should be of considerable general relevance.
Highlights
G protein-coupled receptors (GPCRs)3 represent the largest class of cell surface receptors found in nature [1,2,3,4,5,6]
The deletion of residues Ala274–Lys469 leads to a dramatic improvement of M3R expression levels in yeast [27], but it has no significant effect on the ligand binding and G protein-coupling properties of the M3R [12, 33, 34]
The high resolution x-ray structure of bovine rhodopsin suggests that the extracellular regions of class I GPCRs are highly structured [11]
Summary
Materials—Carbamylcholine chloride (carbachol), atropine sulfate, and 3-amino-1,2,4-triazole were obtained from Sigma. The 306-bp PCR fragment (ϳ4 g) generated under error-prone PCR conditions (see previous paragraph) was cotransformed into MPY578q5 with the p416GPD-M3R(⌬i3) yeast expression plasmid (ϳ10 g) that had been linearized with AatII within the region corresponding to the 306-bp PCR fragment This procedure resulted in a yeast expression library consisting of ϳ1 ϫ 105 primary transformants (colonies that were able to grow on plates lacking uracil). The resulting 288-bp PCR product (ϳ3 g) was cotransformed into MPY578q5 with the p416GPD-M3R(⌬i3) yeast expression plasmid (ϳ12 g) linearized with BstXI within the region corresponding to the 288-bp PCR fragment This gap repair protocol [29] yielded a yeast expression library consisting of ϳ1 ϫ 105 primary transformants (colonies that were able to grow on plates lacking uracil). Carbachol IC50 values determined in [3H]NMS/carbachol inhibition binding studies were converted to Ki values by using the Cheng-Prusoff equation [32]
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