Activation of adenylate cyclase activity

As mentioned earlier, guanyl nucleotides have been found to play an important role In the activation of adenylate cyclase activity by many hormones (90, 91). The present observations show that in pars Intermedia tissue, GXP causes an almost doubling of the stimulatory effect of CRF while that of the B-adrenerglc ago-... 

Figure 13.3 G protein-mediated activation of adenylate cyclase by hormone binding. Hormone binding on the extracellular side of a receptor such as the P adrenergic receptor activates a G protein on the cytoplasmic ATP side. The activated form of the G protein...

Group II assays consist of those monitoring cellular second messengers. Thus, activation of receptors to cause Gs-protein activation of adenylate cyclase will lead to elevation of cytosolic or extracellularly secreted cyclic AMP. This second messenger phosphorylates numerous cyclic AMP-dependent protein kinases, which go on to phosphorylate metabolic enzymes and transport and regulatory proteins (see Chapter 2). Cyclic AMP can be detected either radiometrically or with fluorescent probe technology. 

Cholera toxin, heat labile coli toxins Gs proteins ADP-ribosylation Activation of adenylate cyclase (cholera, traveler -d iarrhea)... 

The OP group of receptois share common effector mechanisms. All receptois couple via pertussis toxin-sensitive Go and Gi proteins leading to (i) inhibition of adenylate cyclase (ii) reduction of Ca2+ currents via diverse Ca2+ channels (hi) activation of inward rectifying K+ channels. In addition, the majority of these receptors cause the activation of phospholipase A2 (PLA2), phospholipase C 3 (PLC 3), phospholipase D2 and of MAP (mitogen-activated protein) kinase (Table 3). 

It is perhaps not surprising that DA produces such mixed effects. The Di receptor is primarily linked to the activation of adenylate cyclase and then protein kinase A. The response to its activation will therefore depend on the ion channels and other proteins modulated by the kinase which can vary from one neuron to another. Since the D2 receptor is not so closely associated with just one G-protein, this gives it the potential for even more effects (see Greenhoff and Johnson 1997). 

Histamine receptors were first divided into two subclasses Hi and H2 by Ash and Schild (1966) on the basis that the then known antihistamines did not inhibit histamine-induced gastric acid secretion. The justification for this subdivision was established some years later when Black (see Black et al. 1972) developed drugs, like cimetidine, that affected only the histamine stimulation of gastric acid secretion and had such a dramatic impact on the treatment of peptic ulcers. A recently developed H2 antagonist zolantidine is the first, however, to show significant brain penetration. A further H3 receptor has now been established. It is predominantly an autoreceptor on histamine nerves but is also found on the terminals of aminergic, cholinergic and peptide neurons. All three receptors are G-protein-coupled but little is known of the intracellular pathway linked to the H3 receptor and unlike Hi and H2 receptors it still remains to be cloned. Activation of Hi receptors stimulates IP3 formation while the H2 receptor is linked to activation of adenylate cyclase. 

Ehlert FJ. Gallamine allosterically antagonizes muscarinic receptor-mediated inhibition of adenylate cyclase activity in the rat myocardium. J Pharmacol Exp Ther 1988 247 596-602. 

Here, the agonist-receptor complex (AR) combines with a G-protein (G) to form a ternary complex (ARG ), which can initiate further cellular events, such as the activation of adenylate cyclase. However, this simple scheme (the ternary complex model) was not in keeping with what was already known about the importance of isomerization in receptor activation (see Sections 1.2.3 and 1.4.3), and it also failed to account for findings that were soon to come from studies of mutated receptors. In all current models of G-protein-coupled receptors, receptor activation by isomerization is assumed to occur so that the model becomes ... 

FIGURE 7.1 Martin Rodbell s conception of the role of the G-protein transducer in the activation of adenylate cyclase by glucagon. (From Birnbaumer, L., FASEB J., 4, 3178, 1990. With permission.)... 

The effect of stimulation of cardiac adrenoceptors is even more leisurely because several more steps follow activation of the Gs protein by the p-adrenoceptor. For example, to increase the force of cardiac contraction, we have (1) activation of adenylate cyclase by Gas-GTP, (2) formation of cAMP, (3) activation of protein kinase A by the cAMP, then (4) phosphorylation of the calcium channel protein by the kinase. As a result, it takes about 5 to 6 sec from the time the receptors are... 

RJ Walkenbach, RD LeGrand. (1982). Inhibition of adenylate cyclase activity in the corneal epithelium by anti-inflammatory steroids. Exp Eye Res 34 161-168. 

Moss J, Vaughan M Activation of adenylate cyclase by choleragen. Annu Rev Biochem 1979 48 581-600. 

H2 receptors are associated with adenylate cyclase, and stimulation of these receptors increases the cytosolic concentration of cAMP and activation of cAMP-dependent protein kinase. Although inhibition of adenylate cyclase has been suggested as the intracellular signaling mechanism associated with H receptors, this has not been completely substantiated. 

Mg2+ is competitive with the Li+ inhibition of both postreceptor G-protein stimulation [140], and direct stimulation of adenylate cyclase [141]. Li+ inhibits Mn2+-stimulated adenylate cyclase activity in membranes in the presence, but not in the absence, of calmodulin. Since, Mn2+ can replace Ca2+ in activating calmodulin, it is likely that the observed inhibition is that of the Mn2+-dependent calmodulin stimulation of the enzyme. In the absence of calmodulin, stimulation of adenylate cyclase is probably due to substitution of Mn2+ for Mg2+ in the substrate, MnATP2+ and this is unaffected by Li+. 

The effects of Li+ upon hematopoiesis have been proposed to be due to two different systems modification of the activity of the membrane Na+/K+-ATPase, and the inhibition of adenylate cyclase. Monovalent cation flux, in particular Na+ transport, is known to influence the differentiation and proliferation of hematopoietic stem cells. For instance, ouabain, an effective inhibitor of the membrane Na+/K+-ATPase, blocks the proliferation of lymphocytes and has been shown to attenuate the Li+-induced proliferation of granulocyte precursors [208]. Conversely, Li+ can reverse the actions of amphotericin and monensin, which mediate Na+ transport and which inhibit CFU-GM, CFU-E, and CFU-MK colony formation in the absence of Li+ [209]. Therefore, the influence of Li+ upon normal physiological cation transport—for example, its influence upon Na+/K+-ATPase activity—may be partly responsible for the observed interference in hematopoiesis. 

Hill, D. R. (1985) GABAb receptor modulation of adenylate cyclase activity in rat brain... 

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