Multiple G protein signaling pathways operate in individual cells to maintain homeostasis and to bring about responses to external stimuli such as growth and differentiation. An important, but unresolved issue is how the specificity of these pathways is maintained among so much complexity. 23 G protein ␣ subunits, 5  subunits, and 12 ␥ subunits have been identified in mammals (1), which could give rise to more than 1300 combinations. However, inactivation of specific G protein subunits in vivo using antisense (2-6) and ribozyme (7,8) strategies has demonstrated a remarkable specificity of interaction between receptors, ␣␥ combinations, and effectors. For instance, ribozyme-mediated suppression of ␥ 7 in HEK-293 cells specifically reduces expression of  1 and disrupts activation of G s by -adrenergic and D 1 dopamine receptors, but not by prostaglandin E 1 and D 5 dopamine receptors (8, 9). Moreover, knockout of ␥ 7 in the mouse results in behavioral changes and reductions in the level of ␣ olf in the striatum (10).One mechanism by which signaling specificity appears to be regulated is at the level of subcellular compartmentalization, which can facilitate or impair interactions between proteins expressed in the same cell (11,12). However, in the case of protein complexes such as G s , for which the localization patterns of the ␣ and ␥ subunits have been reported to change upon activation, it is not clear how specificity can be maintained. The G s subunits associate with the plasma membrane as a result of fatty acid modifications and association with each other. Targeting of  subunits to the plasma membrane requires association with prenylated ␥ subunits (13) and is facilitated by association with ␣ subunits (14). Similarly, ␣ s attaches to the plasma membrane as a result of amino-terminal palmitoylation (15, 16) and association with ␥ (17). Activation of G s results in depalmitoylation of ␣ s (18), and studies using immunohistochemistry (19) and an ␣ s -GFP 1 fusion protein (20) have demonstrated activation-dependent movement of ␣ s from the plasma membrane to the cytoplasm. Activation-dependent changes in ␥ localization have not been imaged in cells, but subcellular fractionation indicated that ␥ redistributed from the plasma membrane to low density microsomes upon stimulation of -adrenergic receptors (21). In the face of these localization changes, it is not clear how specific ␣ s ␥ combinations can be preserved throughout multiple signaling cycles.To address this issue, we have performed real time imaging of a G s heterotrimer, ␣ s  1 ␥ 7 , which mediates signaling from the  2 AR to adenylyl cyclase (7,8), in isoproterenol-stimulated HEK-293 cells. ␣ s was visualized using an internally tagged ␣ s -CFP fusion protein that has comparable activity to that of ␣ s , whereas  1 and ␥ 7 were imaged exclusively in the form of  1 ␥ 7 complexes using the strategy of BiFC (22). BiFC involves the production of a fluorescent signal by two nonfluorescent fragments of YFP when they are brought together by int...
