Applications of BRET to study dynamic G-protein coupled receptor interactions in living cells

Protein-protein interactions are fundamental processes for manybiological systems including those involving the superfamily ofG-protein coupled receptors (GPCRs). When addressing keyquestions concerning the regulation of GPCR-protein complexes andtheir functional significance, the development and refinement ofnon-invasive techniques to study these interactions will be ofgreat value. One such technique, bioluminescence resonanceenergy transfer (BRET), is a recently described biophysicalmethod that represents a powerful tool with which to measureprotein-protein interactions in live cells, in real time. Thisminireview highlights the impact that evolving techniques such asBRET have had on the study of dynamic protein interactionsinvolving GPCRs. In particular, the application of BRET to thestudy of protein interactions involving the receptors forhypothalamic peptide hormones, thyrotropin-releasing hormone(TRH) and gonadotropin-releasing hormone (GnRH), will bediscussed. Using these receptors, BRET has successfully beenused to demonstrate formation of both agonist-dependent andindependent GPCR-GPCR complexes (oligomerization) and theagonist-dependent interaction of GPCRs with their intracellularadaptor protein partners, the arrestins. In summary, BRET is ahighly sensitive method that will not only aid in advancing ourunderstanding of GPCR signalling and trafficking but could alsopotentially lead to the development of novel therapeutics thattarget these GPCR-protein complexes.