Abstract
Two regions on the α subunits of heterotrimeric GTP-binding proteins (G-proteins), the Switch II/α2 helix (which changes conformation upon GDP-GTP exchange) and the α3 helix, have been shown to contain the binding sites for their effector proteins. However, how the binding of Gα subunits to their effector proteins is translated into the stimulation of effector activity is still poorly understood. Here, we took advantage of a reconstituted rhodopsin-coupled phototransduction system to address this question and identified a distinct surface and an essential residue on the α subunit of the G-protein transducin (α(T)) that is necessary to fully activate its effector enzyme, the cGMP phosphodiesterase (PDE). We started with a chimeric G-protein α subunit (α(T)*) comprising residues mainly from α(T) and a short stretch of residues from the G(i1) α subunit (α(i1)), which only weakly stimulates PDE activity. We then reinstated the α(T) residues by systematically replacing the corresponding α(i1) residues within α(T)* with the aim of fully restoring PDE stimulatory activity. These experiments revealed that the αG/α4 loop and a phenylalanine residue at position 283 are essential for conferring the α(T)* subunit with full PDE stimulatory capability. We further demonstrated that this same region and amino acid within the α subunit of the G(s) protein (α(s)) are necessary for full adenylyl cyclase activation. These findings highlight the importance of the αG/α4 loop and of an essential phenylalanine residue within this region on Gα subunits α(T) and α(s) as being pivotal for their selective and optimal stimulation of effector activity.