Visualizing signal transduction: receptors, G-proteins, and adenylate cyclases.

1. The first glimpses of heterotrimeric G-proteins came with the discoveries of the ubiquitous adenylate cyclase activator, Gs, and the specialized retinal cGMP phosphodiesterase activator, Gi or transducin. The model that evolved for regulation of adenylate cyclase activity by G-proteins soon proved to be a general paradigm for a large number of signalling pathways. Although many different G-proteins interact with a diverse array of receptors and effectors, each is composed of a guaninenucleotide-binding alpha-subunit and a tightly associated complex of a beta- and a gamma-subunit. 2. Receptors catalyse the activation of G-proteins by promoting exchange of GDP for GTP, while G-proteins catalyse their own deactivation as a result of their intrinsic GTPase activity. Crystallographic analysis has described several of the various conformational states that G-proteins undergo as they are activated and deactivated and has provided great insight into the kinetic models of G-protein-mediated signal transduction. 3. The regulation of adenylate cyclase has proven to be intriguing and complex. Gsx activates all forms of mammalian adenylate cyclase; other G-proteins (Gi, Go and Gz) inhibit certain isoforms of the enzyme. The discovery of new isoforms of adenylate cyclase has revealed synergistic and conditional mechanisms of regulation. These include activation or inhibition by the G-protein beta gamma-subunit complex, activation by Ca(2+)-calmodulin, and phosphorylation by protein kinases. The large number of receptors, G-proteins and adenylate cyclases provides a complex signalling network that integrates and interprets a multitude of convergent inputs.