Protein adenylate cyclase

This transmembrane signaling system involves a complex consisting of several functional proteins (Figure 7) stimulatory (e.g. P-adrenergic, dopamine Dp serotonin, vasopressin) [124] and inhibitory (e.g. a2-adrenergic, dopamine D2, opiod, and muscarinic) [125] receptors, stimulatory (Gs) and inhibitory (G ) G-proteins, and the catalytic protein, adenylate cyclase. On stimulation of a receptor, an associated G-protein binds GTP and the resulting receptor/G-protein/GTP complex then activates, or inhibits, adenylate cyclase in the catalysis of the synthesis... 

When epinephrine occupies its receptor it activates the ligand binding/ G-protein/ adenylate cyclase cascade. This in turn phosphorylates the muscle enzyme, phosphorylase. This form of the enzyme is the active form which cleaves glucose 1-phosphate unit from glycogen, eventually depleting it... 

Marzo, K.P., Frey, M.J., Wilson, J.R., Liang, B.T., Manning, D.R., Lanoce, V., and Mohnoff, RB. 1991. P-adrenergic receptor-G protein-adenylate cyclase complex in experimental canine congestive heart failure produced by rapid ventricular pacing. Circ. Res. 69 1546-1556. 

The GTP-bound subunit of G activates the transmembrane protein adenylate cyclase. This enzyme catalyzes the formation of the second messenger cyclic AMP from ATP. 

Vanadium. Vanadium is essential in rats and chicks (85,156). Estimated human intake is less than 4 mg/d. In animals, deficiency results in impaired growth, reproduction, and Hpid metaboHsm (157), and altered thyroid peroxidase activities (112). The levels of coen2yme A and coen2yme Q q in rats are reduced and monoamine oxidase activity is increased when rats are given excess vanadium (157). Vanadium may play a role in the regulation of (NaK)—ATPase, phosphoryl transferases, adenylate cyclase, and protein kinases (112). 

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...

FIGURE 2.6 Production of cyclic AMP from ATP by the enzyme adenylate cyclase. Cyclic AMP is a ubiquitous second messenger in cells activating numerous cellular pathways. The adenylate cyclase is activated by the a subunit of Gs-protein and inhibited by the a-subunit of Gj-protein. Cyclic AMP is degraded by phosphodiesterases in the cell. 

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. 

Two AR subtypes, Ax and A3, couple through G to inhibit adenylate cyclase, while the other two subtypes, A2a and A2B, stimulate adenylate cyclase through Gs or G0if (for A2a). The A2BAR is also coupled to the activation of PLC through Gq. Furthermore, each of these receptors may couple through the (3,y subunits of the G proteins to other effector systems, including ion channels and phospholipases. Levels of intracellular... 

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). 

Acyl-CoA Synthetase Adaptive Immunity Adaptor Proteins Addiction Addison s Disease Additive Interaction Adenosine Adenosine Receptors Adenoviruses Adenylate Cyclase Adenylyl Cyclases ADH ADHD... 

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. 

It is appreciated that certain ion channels appear to be directly regulated by various G-proteins [126]. The cardiac and skeletal muscle L channels appear to be capable of being directly activated by Gs (the heterotrimeric G-protein that stimulates adenylate cyclase), in a manner that appears to be independent of second messenger... 

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