Adenylate cyclase activity stimulation

As Illustrated in Fig. 7, 3 yM CRF and 1 yM (-)Isoproterenol cause a 190 and 110% stimulation of adenylate cyclase activity In rat pars intermedia particulate fraction, respectively. An additive effect Is observed when both stimulatory agents are present. Dopamine (30 yM), on the other hand, has no significant effect alone. However, In the presence of GXP, the catecholamine causes a 40 to 60% Inhibition of adenylate cyclase activity stimulated by CRF, ISO or CRF + ISO. It can also be seen that while 0.3 mM GXP alone causes a 100% increase In basal adenylate cyclase activity, it leads to a marked potentiation of the effect of ISO and CRF on [ 2P] cyclic AMP accumulation. It should be noticed that In the absence of the guanyl nucleotide, dopamine has no Inhibitory effect on adenylate cyclase activity In any of the groups studied. 

Figure 8.15 Activation of adenylate cyclase by 4-1000nmol PGI2 in control cells ( ), and cells that had been cultured for 16h with 0.01/imolL ( ), 0.10/imolL" (AX 1.00//mol (O) or 10//mol( ) carbacyclin. An Eadie-Hofstee plot of the data is presented, where dv is the increase in adenylate cyclase activity stimulated by PGI2. Data are means of triplicate determinations. (Reproduced from reference 37 with permission)...

Two AT-II receptors, AT and AT2 are known and show wide distribution (27). The AT receptor has been cloned and predominates ia regions iavolved ia the regulation of blood pressure and water and sodium retention, eg, the aorta, Hver, adrenal cortex, and ia the CNS ia the paraventricular nucleus, area postrema, and nucleus of the soHtary tract. AT2 receptors are found primarily ia the adrenal medulla, utems, and ia the brain ia the locus coeruleus and the medial geniculate nucleus. AT receptors are GCPRs inhibiting adenylate cyclase activity and stimulating phosphoHpases C, A2, and D. AT2 receptors use phosphotyrosiae phosphatase as a transduction system. 

A G-protein-mediated effect has an absolute requirement for GTP. Reference has already been made to the requirement for GTP in reconstituting hormone-stimulated adenylate cyclase activity. A similar requirement can be demonstrated when the effector is an ion channel, such as the cardiac atrial inward-rectifier K+ channel which is activated following stimulation of the M2 muscarinic acetylcholine receptor. Thus, in the experiment illustrated in Figure 7.8, the channel recorded with a cell-... 

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. 

Dopamine acts on G-protein-coupled receptors belonging to the D1 -family of receptors (so-called D1-like receptors , or DlLRs, comprised of Dl- and D5-receptors), and the D2-family of receptors ( D2-like receptors , or D2LRs comprised of D2-, D3- and D4-receptors). Dl LRs stimulate adenylate cyclase activity and, possibly, also phosphoinosit-ide hydrolysis, while D2LRs reduce adenylate cyclase activity. In the striatum, DlLRs are predominately associated with medium spiny neurons of the direct pathway, while D2LRs have been found as autoreceptors on dopaminergic terminals, as heteroreceptors on cholinergic interneurons, and on indirect pathway neurons. In the SNr, DlLRs are located on terminals of the direct pathway projection, while D2LRs appear to function as autoreceptors. 

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... 

Li+, at therapeutically relevant concentrations, is a potent inhibitor of norepinephrine-stimulated adenylate cyclase activity ex vivo in both rat [133] and human brain [134], and it inhibits norepinephrine-stimulated cAMP accumulation in Li+-treated patients. Li+ also inhibits dopamine-stimulated cAMP accumulation in rat brain [135]. These inhibitory effects of Li+ have been shown to be region specific within rat brain, a fact that has obvious significance for a therapeutic mechanism of action. It is interesting that other antimanic drugs may also have dampening effects on dopaminergic neurotransmission. 

Li+ also inhibits several hormone-stimulated adenylate cyclases which, in some cases, appear to be related to side effects of Li+ therapy. For instance, Li+ inhibits the hydro-osmotic action of vasopressin, the antidiuretic hormone which increases water resorption in the kidney [136]. This effect is associated with polyuria, a relatively harmless side effect sometimes experienced with Li+ treatment, which arises from the inability of the kidney to concentrate urine. Li+ has been shown to inhibit vasopressin-stimulated adenylate cyclase activity in renal epithelial cells. Additionally, Li+ is reported to enhance the vasopressin-induced synthesis of prostaglandin E2 (PGE2) in vitro in kidney. PGE2 inhibits adenylate cyclase activity by stimulation of Gj, and, therefore, this effect may contribute to the Li+-induced polyuria. 

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+. 

Dopamine-sensitive adenylate cyclase activity was early demonstrated in both the retina and the cervical ganglion of the cow [47] and later in homogenates of the caudate-putamen of the rat brain [48]. Kebabian has recently reviewed the biochemical components of dopamine-sensitive adenylate cyclase and the physiological role of the D1 receptor [49]. D1 and D2 agonists stimulate and inhibit adenylate cyclase activity, respectively. 

Glucagon stimulates adenylate cyclase activity and this increases the concentration of cyclic AMP. Insulin antagonises this effect via an increase in the activity of cyclic AMP phosphodiesterase, which hydrolyses cyclic AMP to AMP, which results in a decrease in the concentration of cyclic AMP (Figure 6.34). 

ADP ribosylation results in inhibition of GTPase activity and hence maintains the a-subunit in the active form. The constant activity of the G-protein results in an increase in adenyl cyclase activity and therefore a chronic increase in the cychc AMP level. This stimulates an ion channel in the enterocyte which results in a loss of Na ions and hence water from the cells into the intestine. This leads to diarrhoea and a massive loss of fluid from the body which can be sufficiently severe to result in death. Since 2000 there have been epidemics in South America and parts of central Africa. Infection is usually caused by drinking water contaminated with faecal matter. Treatment consists of hydration with rehydration fluids (Chapter 5). 

Stimulation of the parasympathetic system releases acetylcholine at the neuromuscular junction in the sinoatrial node. The binding of acetylcholine to its receptor inhibits adenylate cyclase activity and hence decreases the cyclic AMP level. This reduces the heart rate and hence reduces cardiac output. This explains why jumping into very cold water can sometimes stop the heart for a short period of time intense stimulation of the vagus nerve (a parasympathetic nerve) markedly increases the level of... 

Many monoamine neurotransmitters are now thought to work by this receptor-linked second messenger system. In some cases, however, stimulation of the posts)maptic receptors can cause the inhibition of adenylate cyclase activity. For example, D2 dopamine receptors inhibit, while receptors stimulate, the activity of the cyclase. 

Santini F, Vitti P, Mammoli C, Rosellini V, Pelosini C, Marsili A et al (2003) In vitro assay of thyroid disrupters affecting TSH-stimulated adenylate cyclase activity. J Endocrinol Invest 26 950-955... 

Misoprostol is a stable analog of prostaglandin Ei. It reduces acid secretion by inhibiting histamine-stimulated adenyl cyclase activity in the parietal cell. 

Chen F, Bilezikjian LM, Perrin MH, Rivier J, Vale W (1986) Corticotropin releasing factor receptor-mediated stimulation of adenylate cyclase activity in the rat brain. Brain Res 381 49-57... 

Lithium blocks the release of thyroxine (T4) and triiodothyronine (T3) mediated by thyrotropin (Kleiner et ah, 1999). This results in a decrease in circulating T4 and T3 concentrations and a feedback increase in serum thyrotropin concentration. It also inhibits thyrotropin-stimulated adenylate cyclase activity (Kleiner et ah, 1999). Lithium has varying effects on carbohydrate metabolism. Increased and decreased glucose tolerance and decreased sensitivity to insulin have been observed (Van derVelde Gordon, 1969). In animals, lithium decreases hepatic cholesterol and fatty acid synthesis. 

Ebstein R, Belmaker R, Grunhaus L, et al Lithium inhibition of adrenaline-stimulated adenylate cyclase in humans. Nature 259 411-413, 1976 Ebstein RP, Hermoni M, Belmaker RH The effect of lithium on noradrenahne-in-duced cyclic AMP accumulation in rat brain inhibition after chronic treatment and absence of supersensitivity. J Pharmacol Exp Ther 213 161-167, 1980 Ebstein RP, Lerer B, Shlaufman M, et al The effect of repeated electroconvulsive shock treatment and chronic lithium feeding on the release of norepinephrine from rat cortical vesicular preparations. Cell Mol Neurobiol 3 191-201, 1983 Ebstein RP, Moscovich D, Zeevi S, et al Effect of lithium in vitro and after chronic treatment on human platelet adenylate cyclase activity prosreceptor modification or second messenger signal amplification. Psychiatry Res 21 221-228, 1987 Eccleston D, Cole AJ Calcium-channel blockade and depressive illness. Br J Psychiatry 156 889-891, 1990... 

Mork A, Geisler A Mode of action of lithium on the catalytic unit of adenylate cyclase from rat brain. Pharmacol Toxicol 60 241-248, 1987 Mork A, Geisler A Effects of GTP on hormone-stimulated adenylate cyclase activity in cerebral cortex, striatum, and hippocampus from rats treated chronically with lithium. Biol Psychiatry 26 279-288, 1989a Mork A, Geisler A Effects of hthium ex vivo on the GTP-mediated inhibition of calcium-stimulated adenylate cyclase activity in rat brain. Eur J Pharmacol 168 347-354, 1989b... 

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