Studies on Nucleotide and Receptor Regulation of GiProteins: Effects of Pertussis Toxin

Abstract

In intact membranes as well as after reconstitution into phospholipid vesicles, pertussis toxin (PT)-mediated ADP-ribosylation of G proteins causes loss of receptor-mediated regulation of effectors and/or G protein-mediated regulation of receptor binding. Studies were carried out to test which of several discrete steps known to constitute the basal and receptor-stimulated regulatory cycles of G_i proteins are affected by PT. Experiments with the G_s-deficient G_i-regulated adenylyl cyclase of cyc⁻ S49 cell membranes indicated that PT blocks G_i activation by GTP without affecting GDP dissociation or GTP binding to a major extent. This suggested that the block lies in the transition of inactive GTP-G_i to active GTP-G_i (G to G* transition). Experiments with purified G_i in solution and after incorporation into phospholipid vesicles showed that PT does not increase or decrease the intrinsic GTPase activity of G_i. Experiments in which G_i was incorporated into phospholipid vesicles with rhodopsin, a receptor that interacts with G_i to stimulate the rate of guanosine 5′-O-(3-thio)triphosphate binding and GTP hydrolysis, indicated that PT does not affect the basal GTPase activity of G_i, but blocks its activation by the photoreceptor. Taken together the results indicate that PT-mediated ADP ribosylation has two separate effects, one to block the interaction of receptor with G_i and another to impede the GTP-induced activation reaction from occurring, or that PT has only one effect, that of blocking interaction with receptors. In this latter case the present results add to a mounting series of data that are consistent with the hypothesis that unoccupied receptors are not inactive, but exhibit a basal agonist-independent activity responsible for the various effects of GTP observed on G protein-coupled effector functions in intact membranes.