Alpha 2-adrenergic receptor subtypes: subtle mutation of the alpha 2A-adrenergic receptor in vivo by gene targeting strategies reveals the role of this subtype in multiple physiological settings.

Alpha 2-adrenergic receptors (alpha 2AARs) are coupled by pertussis-toxin sensitive G proteins to various effectors, including adenylyl cyclase and ion channels. The alpha 2AARs respond to endogenous norepinephrine and epinephrine to elicit a variety of physiological responses, including inhibition of neurotransmitter release, suppression of insulin release from pancreatic beta cells, activation of platelet aggregation, and contraction of arteriolar smooth muscle. Three distinct alpha 2AR subtypes (alpha 2A, alpha 2B, alpha 2C) have been characterized by both pharmacological and molecular biological approaches; however, the lack of subtype-specific ligands has precluded an understanding of the physiological relevance of each subtype. Previous studies demonstrated that mutation of a conserved aspartate residue in the alpha 2AAR to asparagine (D79N alpha 2AAR) resulted in a receptor that retained its ability to inhibit voltage-gated Ca2+ channels and cAMP production but was unable to activate K+ currents in AtT20 cells (Surprenant et al., 1992). To explore the physiological role of the alpha 2AAR subtype and to evaluate the selectivity of alpha 2AAR effects with respect to various signal transduction pathways, we used gene targeting in embryonic stem cells to create a mouse line that expresses the mutant D79N alpha 2AAR instead of the wild-type alpha 2AAR. We established a D79N alpha 2AAR mouse line and characterized various alpha 2AAR-mediated physiological functions in these mutant mice. Because the in vivo D79N alpha 2AAR is expressed at a reduced density relative to wild-type alpha 2A and is not selectively uncoupled from a single signal transduction pathway, our findings of losses of alpha 2AAR-mediated functions in the D79N mice reflect a requirement for the alpha 2AAR subtype but do not reveal the importance of a specific signal transduction pathway. The alpha 2AAR subtype appears to mediate reduction in blood pressure following alpha 2A agonist administration as well as sedative, anesthetic-sparing, and analgesic responses to alpha 2AAR agonists. Therefore, the alpha 2AAR subtype appears to mediate a majority of the clinically relevant responses associated with alpha 2AAR agonist treatment.