G-PROTEIN COUPLING OF RECEPTORS TO IONIC CHANNELS AND OTHER EFFECTOR SYSTEMS

1. Four questions raised by previous studies that had shown activation of K+ channels by alpha subunits of the type 3 Gi protein are addressed in the present communication: a) are K+ channels specific for one Gi? b) are there more ionic channels under direct G protein control? c) can we confirm using recombinant G alpha s the results obtained with biochemically resolved G alpha s and continue ascribing the regulatory effector to this part of the alpha beta gamma holo‐G protein? and d) can we confirm that a single G alpha, Gs alpha in this case, is able to affect more than one type of effector function? 2. We found Gi alpha s are isoforms, that there exist also Gi‐insensitive, Go‐responsive K+ channels and that G alpha s can be multifunctional. Thus, a single receptor will elicit cellular responses that will depend on the endogenous G protein as well as the type of effector function expressed in it. 3. In another set of experiments we found that G beta gamma s, be they derived from human erythrocytes, human placenta, bovine brain or bovine retina, all inhibit Gk‐gated K+ channel activity as seen in inside out membrane patches with GTP as the driving nucleotide. In addition we noted that inhibition was much more effective under basal (no agonist in the pipette) than agonist stimulated conditions, as reported in earlier experiments in which beta‐adrenoceptors, Gs and catalytic unit of adenylyl cyclase had been incorporated into phospholipid vesicles. 4. We propose that one of the roles of G beta gamma s in membranes is to quench ligand independent G protein activation by unoccupied receptors. Other roles of G beta gamma s are: a) by re‐associating with GDP‐G alpha s, to promote interaction with receptors, and b) by dissociating from activated R.G alpha *GTP.beta gamma, to allow for receptor dissociation from GTP‐activated G alpha s, which is required to satisfy the catalytic mode of receptor action. 1990 The British Pharmacological Society