Techniques: GPCR assembly, pharmacology and screening by flow cytometry.

Flow cytometers are well known for their ability to analyze and sort cells at high rates based on physiological responses and expression of protein markers. The potential for flow cytometry in G-protein-coupled receptor (GPCR) research, however, is less well appreciated. Potential applications include: (i) the homogenous discrimination of free and bound ligands or proteins in both cellular and microsphere-based assays; and (ii) multiplexed ('suspension array') analysis of cell responses and protein-protein interactions. Innovative sample-handling systems also provide sub-second resolution of interaction kinetics and 1 second per well throughput of microliter-sized samples from multiwell plates. Flow cytometric methods using microspheres for analysis of GPCRs that interact with intracellular and extracellular binding partners such as ligands, G proteins and kinases have been established. These analyses can produce quantitative pharmacological data analogous to radioligand assays, and, in some cases, the probes can be integrated into the assembly as fluorescent fusion proteins.

Real-time analysis of ternary complex on particles: direct evidence for partial agonism at the agonist-receptor-G protein complex assembly step of signal transduction.

We developed a novel and generalized approach to investigate G protein-coupled receptor molecular assemblies. We solubilized a fusion protein consisting of the beta(2)-adrenergic receptor and green fluorescent protein (GFP) for bead-based flow cytometric analysis. beta(2)-Adrenergic receptor GFP bound to dihydroalprenolol-conjugated beads, providing a K(d) for the fusion protein and, in competition with beta(2)-adrenergic receptor ligands, K(d) values for agonists and antagonists. Beads displaying chelated nickel bound purified hexahistidine-tagged G protein heterotrimers and, subsequently, the binary complex of agonist with beta(2)-adrenergic receptor GFP. The dose-response curves of ternary complex formation revealed maximal assembly for ligands previously classified as full agonists and reduced assembly for ligands previously classified as partial agonists. Guanosine 5'-3-O-(thio)triphosphate-induced dissociation rates of the ternary complex were the same for full and partial agonists. Soluble G protein, competing with ternary complexes on beads provided an affinity estimate of agonist-receptor complexes to G protein. When performed simultaneously, the two assemblies discriminated between agonist, antagonist or inactive molecule in a manner appropriate for high throughput, small volume drug discovery. The assemblies can be further generalized to other G protein coupled receptor protein-protein interactions.