Publications

The molecular basis of receptor/G protein coupling selectivity was studied by using the m2 muscarinic receptor, a prototypical G(i/o)-coupled receptor as a model system. We could recently show that the m2 receptor can efficiently interact with mutant G protein alpha(q) subunits in which the last five amino acids were replaced with alpha(i2) or alpha(o) sequence [Liu, J., Conklin, B. R., Blin, N., Yun, J., & Wess, J. (1995) Proc. Natl. Acad. Sci. U.S.A. 92, 11642-11646]. Additional mutagenesis studies led to the identification of a four-amino-acid motif on the m2 receptor (Val385, Thr386, Ile389, and Leu390) that is predicted to functionally interact with the C-terminal portion of alpha(i/o) subunits. To further investigate the structural requirements for this interaction to occur, these four m2 receptor residues were replaced, either individually or in combination, with the corresponding residues present in the G(q/11)-coupled muscarinic receptors (m1, m3, and m5). The ability of the resulting mutant m2 receptors to interact with a mutant alpha(q) subunit (qo5) in which the last five amino acids were replaced with alpha(o) sequence was investigated in co-transfected COS-7 cells [studied biochemical response: stimulation of phosphatidyl inositol (PI) hydrolysis]. Our data suggest that the presence of three of the four targeted m2 receptor residues (Val385, Thr386, and Ile389) is essential for efficient recognition of C-terminal alpha(i/o) sequences. To study which specific amino acids within the C-terminal segment of alpha(i/o) subunits are critical for this interaction to occur, the wild type m2 receptor was co-expressed with a series of mutant alpha(q) subunits containing single or multiple alpha(q) --> alpha(i1,2) point mutations at their C-terminus. Remarkably, the wild type m2 receptor, while unable to efficiently stimulate wild type alpha(q), gained the ability to productively interact with three alpha(q) single-point mutants, providing the first example that the receptor coupling selectivity of G protein alpha subunits can be switched by single amino acid substitutions. Given the high degree of structural homology among different G protein-coupled receptors and among different classes of G protein alpha subunits, our results should be of broad general relevance.

Treatment of allergic disease by decreasing circulating IgE with anti-IgE Abs is currently under clinical study. Based on previous unrelated studies, it appeared likely that Fc(epsilon)RI expression on basophils and mast cells might also be regulated by levels of circulating IgE Ab. Therefore, the expression of IgE and Fc(epsilon)RI on human basophils was examined in 15 subjects receiving humanized anti-IgE mAb intravenously. Treatment with the anti-IgE mAb decreased free IgE levels to 1% of pretreatment levels and also resulted in a marked down-regulation of Fc(epsilon)RI on basophils. Median pretreatment densities of Fc(epsilon)RI were approximately 220,000 receptors per basophil and after 3 mo of treatment, the densities had decreased to a median of 8,300 receptors per basophil. Flow cytometric studies, conducted in parallel, showed similar results and also showed in a subset of 3 donors that receptors decreased with a t1/2 of approximately 3 days. The responsiveness of the cells to IgE-mediated stimulation using anti-IgE Ab was marginally decreased (approximately 40%) while the response of the same cells to stimulation with dust mite Ag, Dermatophagoides farinae, was reduced by approximately 90%. One possible explanation for these results is that Fc(epsilon)RI density is directly or indirectly regulated by plasma-free IgE levels.