other ‘closed’, and that the role of glutamate is to stabilise the closed, active form.
In contrast, the GABABreceptor is a heterodimer involving two receptors from family
B. The explanation for the importance of this dimerisation of GPCRs is a topic of
current research but a number of points have emerged so far:- Firstly, it appears to occur early in the biosynthetic pathway of the receptors,
specifically in the endoplasmic reticulum, and is essential for the trafficking of the
receptors into the membrane. - Secondly, molecular modelling studies with the rhodopsin receptor have
demonstrated that it can only effectively interact with subunits of a G-protein if it is a
homodimer emphasising the importance of molecular size and conformation in
receptor activity. - Thirdly, the formation of heterodimers facilitates the opportunity for crosstalk
between the two protomers. Such crosstalk has been demonstrated for a number of
receptors including histamine H 1 receptors and GABABreceptors and there is growing
evidence of the general importance of such receptor crosstalk in maintaining
specificity from signal to cellular response.
(a) IRABLigand I leads to Gicoupling
Coupling to Gi–leads to
effector response Ab bai aqg g(b)RABLigand II leads to Gq coupling
Coupling to Gq–leads to
effector response BIIb bai aqg gFig. 17.9Functional selectivity. GPCRs often couple to multiple G-proteins. Functional selectivity is seen
when ligand binding influences which G-protein associates with the receptor by promoting distinct coupling
efficiencies. For example, binding of a distinct ligand (I) leads to activation of Giand effector responses initiated
through this G protein (a), whereas binding of a different ligand (II) to the same GPCR leads to activation of Gq
and to an alternative set of effector responses driven through this G-protein (b). (Reproduced from Gilchrist, A.
(2007). Modulating G-protein-coupled receptors: from traditional pharmacology to allosterics.Trends in
Pharmacological Sciences, 28 , 431–437, by permission of Elsevier Science.)695 17.4 Mechanisms of signal transduction