Altered Gs and adenylate cyclase activity in human GH-secreting pituitary adenomas

Gs and Gi are guanine nucleotide-binding, heterotrimer proteins that regulate the activity of adenylate cyclase, and are responsible for transferring stimulatory and inhibitory hormonal signals, respectively, from cell surface receptors to the enzyme catalytic unit. These proteins can be directly activated by agents such as GTP and analogues, fluoride and magnesium. Decreased amounts of Gs and Gi, and even the absence of Gs, have been described, whereas an altered Gs has been reported in a cultured cell line (UNC variant of S49 lymphoma cells), but has never been observed in human disease states. We have found a profoundly altered Gs protein in a group of human growth hormone-secreting pituitary adenomas, characterized by high secretory activity and intracellular cyclic AMP levels. In the membranes from these tumours no stimulation of adenylate cyclase activity by growth hormone-releasing hormone, by GTP or by fluoride was observed. Indeed, the last two agents caused an inhibition, probably mediated by Gi. In contrast, adenylate cyclase stimulation by Mg2+ was enormously increased. This altered pattern of adenylate cyclase regulation was reproduced when a cholate extract of the tumour membranes (which contains G proteins) was reconstituted with Gs-free, cyc- S49 cell membranes. Inasmuch as secretion from somatotrophic cells is known to be a cAMP-dependent function, the alteration of Gs could be the direct cause of the high secretory activity of the tumours in which it occurs.     

Kluyveromyces lactis killer toxin inhibits adenylate cyclase of sensitive yeast cells

K1 killer toxin secreted by the K1 strain of Saccharomyces cerevisiae, has been well characterized. It is a simple protein of molecular weight (MW) 11,470 (ref. 3), encoded by a double-stranded, linear RNA plasmid, called M RNA, of MW 1.1-1.7 x 10(6) (refs 4-6). It is lethal to sensitive Saccharomyces cerevisiae which does not carry M RNA. Leakage of K+ and ATP is the first distinct response in sensitive cells, and the toxic action is thought to be due to its action as a protonophore or K+ ionophore. Recently, a further killer toxin has been found in Kluyveromyces lactis IFO 1267, and it is associated with the presence of the double-stranded linear DNA plasmids, pGK1-1 (MW 5.4 x 10(6)) and pGK1-2 (MW 8.4 x 10(6)). It has been shown, by curing pGK1-1 or deletion mapping, that the structural gene for the killer toxin and immunity-determining gene reside on the smaller plasmid. Moreover, the plasmids could be transferred from K. lactis to S. cerevisiae by protoplast fusion and protoplast transformation. As the K. lactis toxin is encoded by a DNA plasmid and has a relatively wider action spectrum than K1 killer toxin, the mode of action of the toxin is highly interesting. Here we report that K. lactis toxin inhibits adenylate cyclase in sensitive yeast cells and brings about arrest of the cells at the G1 stage.     

A nucleotide regulatory site for somatostatin inhibition of adenylate cyclase in S49 lymphoma cells

The cyc- variants of S49 lymphoma cells have served as powerful tools for studying the components and mechanisms of hormone-induced adenylate cyclase stimulation, as these cells are deficient in the guanine nucleotide regulatory site (Ns) mediating hormone, guanine nucleotide, cholera toxin and fluoride-induced stimulations of the enzyme. Because of this deficiency, membranes of these cells have been used for reconstitution of the system by inserting the coupling component derived from other cell types. The hormone-sensitive adenylate cyclase is not only stimulated by hormones but can also be inhibited by a wide variety of hormones and neurotransmitters, and there is some evidence that hormonal inhibition may be mediated by a distinct guanine nucleotide regulatory site. Studies in cyc- cells lacking a functional Ns may therefore answer this unresolved, important question. We have recently observed that stable GTP analogues can inhibit cyc- adenylate cyclase stimulated by purified, preactivated Ns or forskolin, which can activate adenylate cyclase even in the absence of a functional Ns (ref. 10). The data indicated that these Ns-deficient cells contain an inhibitory guanine nucleotide site, Ni. To strengthen this concept, we investigated whether the cyc- adenylate cyclase can be inhibited by a hormone. We report here that somatostatin decreases cyclic AMP levels in cyc- cells, inhibits the forskolin-stimulated adenylate cyclase and causes a concomitant increase in a high affinity GTPase activity in cyc- membranes. The data strongly suggest that both the hormone- and guanine nucleotide-induced adenylate cyclase inhibitions in cyc- cells are mediated by Ni and that the mechanisms of activation and inactivation of Ni are similar to those established for Ns.     

Odorant-sensitive adenylate cyclase may mediate olfactory reception

The mechanism of the sense of smell has long been a subject for theory and speculation. More recently, the notion of odorant recognition by stereospecific protein receptors has gained wide acceptance, but the receptor molecules remained elusive. The recognition molecules are believed to be quite diverse, which would partly explain the unusual difficulties encountered in their isolation by conventional ligand-binding techniques. An alternative approach would be to probe the receptors through transductory components that may be common to all receptor types. Here we report the identification of one such transductory molecular component. This is an odorant-sensitive adenylate cyclase, present in very large concentrations in isolated dendritic membranes of olfactory sensory neurones. Odorant activation of the enzyme is ligand and tissue specific, and occurs only in the presence of GTP, suggesting the involvement of receptor(s) coupled to a guanine nucleotide binding protein (G-protein). The olfactory G-protein is independently identified by labelling with bacterial toxins, and found to be similar to stimulatory G-proteins in other systems. Our results suggest a role for cyclic nucleotides in olfactory transduction, and point to a molecular analogy between olfaction and visual, hormone and neurotransmitter reception. Most importantly, the present findings reveal new ways to identify and isolate olfactory receptor proteins.