The role of cyclic AMP in aldosterone production by isolated zona glomerulosa cells.

The role of cyclic AMP in the regulation of aldosterone production by adrenocorticotropic hormone (ACTH), angiotensin II (A II), potassium, and serotonin was examined in collagenase-dispersed adrenal glomerulosa cells. The ability of 8-bromo cyclic AMP and choleragen to stimulate maximum aldosterone production indicated that cyclic AMP could act as second messenger for certain of the aldosterone-stimulating factors. The actions of ACTH and choleragen on aldosterone and cyclic AMP production were correlated in dog and rat cells, and a similar relation was seen during stimulation of rat cells by serotonin. In contrast, A II and potassium did not cause changes in cyclic AMP formation while stimulating aldosterone production. Intracellular and receptor-bound cyclic AMP were increased 3-fold by 10(-7) M ACTH but not by A II. Addition of a phosphodiesterase inhibitor increased the magnitude of the cyclic AMP response to ACTH but did not change the lack of stimulation by A II or potassium. In dog cells, the effects of A II and potassium on aldosterone production were partially additive to those of ACTH, choleragen, and 8-bromo cyclic AMP. In contrast, no additivity was observed between A II and potassium, or between combinations of the cyclic AMP-dependent stimuli. These results indicate that the actions of ACTH on aldosterone secretion are mediated by cyclic AMP formation, whereas A II and potassium stimulate aldosterone production through an independent mechanism. The lack of additivity between steroid responses to A II and potassium suggests that these factors could share a common mode of action on steroidogenesis in zona glomerulosa cells.     

The effect of diamide on cyclic AMP levels and cyclic nucleotide phosphodiesterase in human peripheral blood lymphocytes

The effect of diamide (diazene dicarboxylic acid bis[N,N'-dimethylamide) on cyclic AMP levels and cyclic nucleotide phosphodiesterase in human peripheral blood lymphocytes was examined. In the absence of mitogenic lectins, 5 . 10(-3)-1 . 10(-4) M diamide markedly increased intracellular cyclic AMP with variable effects at higher levels. In the presence of phytohemagglutinin or concanavalin A, 5 . 10(-4) M or higher diamide concentrations consistently decreased cyclic AMP levels, usually to control levels or below, while 1 . 10(-4)-1 . 10(-5) M diamide augmented the lectin-induced rise in cyclic AMP. When intact lymphocytes were incubated with diamide, phosphodiesterase activity against both cyclic AMP and cyclic GMP, assayed in homogenates of these cells, was inhibited at concentrations as low as 1 . 10(-6) M. In contrast, when diamide was incubated with phosphodiesterase extracted from lymphocytes there was a dual effect. At low substrate concentrations and high diamide concentrations diamide was a non-competitive inhibitor of phosphodiesterase with a Ki of 1.3--2.5 mM for cyclic AMP and 3.3--10 mM for cyclic GMP. In contrast, at high substrate concentrations diamide was an 'uncompetitive' activator of phosphodiesterase activity for both cyclic AMP and cyclic GMP. The effects of diamide could be largely or completely blocked by glutathione or dithiothreitol, indicating that sulfhydryl reactivity was involved in diamide's action on lymphocyte phosphodiesterase activity and intracellular cyclic AMP levels. These data demonstrate that diamide is a phosphodiesterase inhibitor both on phosphodiesterase extracted from lymphocytes and when incubated with intact lymphocytes and that diamide may increase or decrease intracellular cyclic AMP levels depending on the concentration of diamide used.     

Relationship between cyclic AMP production and lipolysis induced by forskolin in rat fat cells.

Forskolin (7 beta-acetoxy-8, 13-epoxy-1 alpha,6 beta,9 alpha-trihydroxy-labd-14-ene-11-one) induced both cyclic AMP production and lipolysis in intact fat cells, but stimulated lipolysis without increasing cyclic AMP at a concentration of 10(-5) M. Homogenization of fat cells elicited lipolysis without elevation of cyclic AMP. Forskolin did not stimulate lipolysis in the homogenate. Forskolin stimulated both cyclic AMP production and lipolysis in a cell-free system consisting of endogenous lipid droplets and a lipoprotein lipase-free lipase fraction prepared from fat cells. However, at a concentration of 10(-6) M, it induced lipolysis without increase in the cyclic AMP content in this cell-free system. In the cell-free system, homogenization of the lipid droplets resulted in marked increase in lipolysis to almost the same level as that with 10(-4) M forskolin without concomitant increase in cyclic AMP. Addition of forskolin to a cell-free system consisting of homogenized lipid droplets and lipase did not stimulate lipolysis further. Phosphodiesterase activities were found to be almost the same both in the presence and absence of forskolin in these reaction mixtures. Although 10(-3) M forskolin produced maximal concentrations of cyclic AMP: 6.7 x 10(-7) M in fat cells and 2.7 x 10(-7) M in the cell-free system, 10(-4) M cyclic AMP did not stimulate lipolysis in the cell-free system. In a cell-free system consisting of lipid droplets and the lipase, pyrophosphate inhibited forskolin-induced cyclic AMP production, but decreased forskolin-mediated lipolysis only slightly. Based on these results, mechanism of lipolytic action of forskolin was discussed.     

Adenosine 3′:5′-cyclic monophosphate production and steroidogenesis by isolated rat adrenal glomerulosa cells. Effects of angiotensin II and [Sar1,Ala8]angiotensin II

Angiotensin II effects on cyclic AMP production and steroid output were studied in a sensitive preparation of isolated rat adrenal glomerulosa cells. With increasing concentrations of angiotensin II logarithmic dose-response curves for aldosterone and cyclic AMP production were similar. The minimum effective dose (0.2nm) for stimulation of aldosterone production also significantly (P<0.001) increased cyclic AMP output. For both aldosterone and cyclic AMP production, the peptide hormone concentration eliciting maximal response (0.2mum) and the ED(50) (median effective dose) values (1nm) were the same; this is consistent with cyclic AMP acting as an intracellular mediator for angiotensin II-stimulated aldosterone production by glomerulosa cells. The angiotensin II antagonist [Sar(1),Ala(8)]angiotensin II inhibited angiotensin II-stimulated corticosterone and aldosterone production in these cells. An equimolar concentration of antagonist halved the response to 20nm-angiotensin II, and complete inhibition was observed with 0.2mum-antagonist. In contrast, [Sar(1),Ala(8)]angiotensin II had no effect on maximally stimulated steroidogenesis induced by serotonin and a raised extracellular K(+) concentration. Increasing concentrations of [Sar(1),Ala(8)]angiotensin II alone decreased corticosterone and aldosterone outputs significantly (P<0.05) at concentrations of 20nm and 2nm of antagonist respectively. A significant (P<0.001) decrease in cyclic AMP production occurred with 2mum antagonist and this was comparable with the decrease in aldosterone production. It is concluded that [Sar(1),Ala(8)]angiotensin II can independently affect glomerulosa-cell steroidogenesis, possibly by modulating adenylate cyclase activity.     

Evidence for a cyclic AMP system highly sensitive to secretin in gastric glands isolated from the rat fundus and antrum

The effects of secretin and vasointestinal peptide (VIP) on the production of cyclic AMP have been studied in gastric glands isolated by means of EDTA from rat fundic and antral mucosa. (1) In gastric fundus, secretin and VIP caused a time- and temperature-dependent stimulation of cyclic AMP production that was maximal when the test agents were incubated for 60 min at 20 degrees C in the presence of 0.5 mM 3-isobutyl-1-methylxanthine as a phosphodiesterase inhibitor. The dose-response curve was monophasic for both peptides, the production of cyclic AMP being sensitive to 10(-10) M secretin and to 5 . 10(-8) M VIP. Half-maximal stimulation was obtained with 2.9 10(-9) M secretin or 2 . 10(-7) M VIP and the maximal stimulation represented a 21-fold and a 19-fold increase above control for secretin and VIP, respectively. Histamine also stimulated cyclic AMP production, with a Km of about 5 . 10(-4) M. No additive effect on cyclic AMP production was oberved when secretin and VIP were simultaneously added at maximally active concentrations, while an additive effect was observed when secretin and histamine were added together. (2) In gastric antrum, the characteristics of the secretin- and VIP-stimulated cyclic AMP production were similar to those observed in gastric fundus. Histamine nevertheless failed to stimulate the formation of cyclic AMP in antral mucosa. (3) These data demonstrate the existence of a cyclic AMP system highly sensitive to secretin in gastric glands isolated from the rat fundus and antrum and suggest that VIP operates through this system. (4) It is proposed that the pepsinogen- and/or mucous-secreting cells are implicated in the regulation of cyclic AMP production by secretin in gastric glands of the rat.     

Relationship between endogenous cyclic AMP production and steroid hormone secretion in chick adrenal cells

Dispersed chick adrenal cells were incubated with either ACTH, cholera toxin or forskolin. All three agents stimulated cyclic AMP accumulation and secretion of corticosterone and aldosterone by the dispersed cells. The dose-response to ACTH was similar for cyclic AMP and corticosterone but aldosterone secretion appeared to be more sensitive to ACTH stimulation. Concentrations higher than 10(-8) M of ACTH caused suppression of corticosterone output but not of cyclic AMP accumulation or aldosterone secretion. A significant cyclic AMP accumulation occurred within 30 min of exposure to ACTH whereas significant increases in steroid secretion were observed only after 30 min. An early increase (within 30 min) in cyclic AMP accumulation with both cholera toxin and forskolin was not accompanied by any significant stimulation of steroid secretion, which occurred only after 120 min. The results with the avian adrenal cells are consistent with the thesis that steroid production in the adrenocortical cells is stimulated by cyclic AMP-dependent pathways, whereas steroid release may be modulated by others.     

Induction of glomerulopressin production by cyclic AMP

Isolated rat livers were perfused with gassed Krebs-Ringer-Bicarbonate and different doses of theophylline and dibutyryl cyclic AMP were added to the perfusing solution. The perfusates were ultrafiltrated through Diaflo UM-05 membranes. The glomerulopressin activity of the ultrafiltrates were assayed in the tonic tension contraction (TTC) of isolated stomach fundus from rats. As glomerulopressin is known to be a glucuronide, it was inactivated with beta-glucuronidase to confirm that the effect on the stomach fundus was due to the glomerulopressin and not to another substance. It was observed that doses of theophylline between 2 x 10(-3) M and 2 x 10(-5) M enhanced glomerulopressin production. However, there was no relationship between dose of theophylline and the response, and a dose of theophylline 2 x 10(-6) M has no activity. The perfusion with dibutyryl cyclic AMP at 5 x 10(-8) M increased the amount of glomerulopressin produced by the liver. This was a log-dose response of glomerulopressin production to dibutyryl cyclic AMP between 5 x 10(-8) M and 5 x 10(-4) M. Theophylline (2 x 10(-6) M) potentiated the activity of cyclic AMP (5 x 10(-8) M). These results support the view that cyclic AMP is intracellular mediator of the hepatic production of glomerulopressin.     

Enhancing effects of angiotensin I on the vasopressin-stimulated water flow of toad bladder through increased cyclic AMP in mucosal cells

The effects of angiotensins I and II on 10 mU/ml vasopressin-stimulated water flow across toad bladder were examined. Angiotensin I at concentrations of 10(-6) and 10(-7) M enhanced the water flow, but angiotensin II failed to do so at these concentrations. Angiotensin I had no effect on 5 mM cyclic AMP-stimulated water flow. After being preincubated for 30 min with angiotensin II, angiotensin I failed to have any stimulatory effect on vasopressin-stimulated water flow. At 10(-6) M angiotensin I significantly enhanced vasopressin-stimulated cyclic AMP content in bladder mucosal cells. These results indicate that angiotensin I enhances vasopressin-stimulated water flow by increasing cyclic AMP production in bladder cells and that angiotensin II may possibly interfere with angiotensin I in a competitive manner.     

Inhibition by cyclic AMP of lactose production in lactating guinea pig mammary gland slices.

Addition of the cyclic AMP phosphodiesterase inhibitors theophylline (10- minus 2 M) or papaverine (10- minus 4 M) leads to a complete inhibition of lactose synthesis in incubated guinea pig mammary gland slices. Addition of 10- minus 5 M cyclic AMP or dibutyryl cyclic AMP results in 1 30-40% inhibition of the synthesis, which effect is not increased by applying higher concentrations of these compounds. A 30-40% inhibition can also be obtained with epinephrine (5 - 10- minus 5 M), or isoproterenol (10- minus 4 M), but the polypeptide hormones glucagon (10- minus 7 M), insulin (1 munit/ml) and relaxin (10 mug/ml) do not significantly affect lactose synthesis. Cytochalasin B (5 mug/ml) inhibits lactose production by 58and colchicine (10- minus 5 M) by 25%. These experiments suggest that an increase in the intracellular level of cyclic AMP either through its addition, through hormonal stimulation of its synthesis, or through inhibition of its intracellular breakdown, leads to an inhibition of lactose production in lactating mammary gland. This effect of cyclic AMP is similar to that of progesterone, which is known to inhibit lactation in vivo and the withdrawal of which at parturition has been postulated to initiate lactogenesis.     

Evidence for a tonic inhibitory role of nifedipine-sensitive calcium channels in aldosterone biosynthesis.

This study investigated the effects of the calcium channel blockers nifedipine (a dihydropyridine) and verapamil (a papaverine derivative), on aldosterone production utilizing isolation of the early and late phases of aldosterone biosynthesis. Pregnenolone production (the early phase of aldosterone biosynthesis) was assessed in trilostane-treated bovine glomerulosa cells, used to inhibit the conversion of pregnenolone onwards to aldosterone. Conversion of exogenous corticosterone to aldosterone, an index of late phase activity, was assessed using aminoglutethimide to inhibit endogenous aldosterone production. Low concentrations of nifedipine, 10(-11)-10(-9) M, stimulated basal total aldosterone biosynthesis by enhancing the late phase although the early phase was inhibited. In the presence of 12 mM potassium (K+), which is less effective in stimulating aldosterone production than lower K+ concentrations, aldosterone production was enhanced by nifedipine, 10(-8) M, by an effect on the late phase. At K+ 6 and 8 mM, nifedipine, 10(-4) M, inhibited the early phase. Nifedipine 10(-5) inhibited angiotensin II (AII)-stimulated total aldosterone biosynthesis by independent effects on the early and late phases. Verapamil, 10(-4) M, inhibited total and early phase aldosterone production at K+, 4 mM and inhibited both phases at K+, 8 mM, stimulation was not observed using verapamil. Verapamil, 10(-4) M, also inhibited AII-stimulated aldosterone production. Basal and AII-stimulated pregnenolone production were inhibited by verapamil, 10(-4) M (basal) and 10(-6) M (AII-stimulated). These studies using nifedipine have revealed subtle calcium-dependent mechanisms involved in the tonic inhibition of activity in the late phase of aldosterone biosynthesis and the reversal of the inhibitory effect of high K+ concentrations also on the late phase. In addition, the data reported indicate that both AII and K+ independently enhance activity in the early and late phases of aldosterone production by calcium-dependent mechanisms.     

Possible involvement of a cyclic AMP-dependent mechanism in PACAP-induced proliferation and ERK activation in astrocytes

In cultured astrocytes, PACAP activates extracellular signal-regulated kinase (ERK) and induces cell proliferation at picomolar concentrations. Here, we examined the role of cyclic AMP signaling underlying the effects of PACAP. PACAP38 induced accumulation of cyclic AMP in astrocytes at concentrations as low as 10(-12)M. PACAP38 (10(-12)-10(-9)M)-stimulated cell proliferation was completely abolished by the cyclic AMP antagonist Rp-cAMP, whereas the protein kinase A (PKA) inhibitor H89 had no effect. This PACAP38-mediated effect was also abolished by the ERK kinase inhibitor PD98059, suggesting the involvement of ERK in PACAP-induced proliferation. PACAP38 (10(-12)M)-stimulated phosphorylation of ERK lasted for at least 60 min. This effect was completely abolished by Rp-cAMP but not by H89. Dibutyryl cyclic AMP maximally stimulated the incorporation of thymidine and activation of ERK at 10(-10)M. These results suggest that PACAP-mediated stimulation of ERK activity and proliferation of astrocytes may involve a cyclic AMP-dependent, but PKA-independent, pathway.     

Effect of 1,25-dihydroxyvitamin D-3 on phosphate uptake into chick intestinal brush border membrane vesicles

The production of collagenase by human skin explants in culture is prevented by 10(-8) M dexamethasone, 5 . 10(-4) M dibutyryl cyclic AMP, or 2.5 . 10(-3) M theophylline. Decreases in collagenase activity are paralleled by reductions in the degradation of explant collagen during the culture period. Progesterone, which effectively inhibits collagenase production in rat uterine explant cultures, has no effect on human skin explants. The inhibition by cyclic AMP is nucleotide specific. When partially inhibitory concentrations of dexamethasone and dibutyryl cyclic AMP, or dexamethasone and theophylline, are added to culture medium together, the resultant inhibition is that predicted by additivity. Synergistic inhibition, as observed in rat uterus between progesterone and dibutyryl cyclic AMP, fails to occur. Dexamethasone inhibits the production of collagenase by cultured explants of rat uterus, with complete inhibition occurring at 10(-7) M steroid. Synergism between glucocorticoids and dibutyryl cyclic AMP or between dexamethasone and progesterone could not be demonstrated in the uterine culture system. These results suggest the existence of three regulatory systems for the control of collagenase production in mammalian tissues, and that cooperativity between systems may occur on a tissue-specific basis.     

Polyamine Regulation of the Microtubule-Associated Protein Kinase

Microtubule protein prepared by cycles of assembly-disassembly contains a cyclic AMP-dependent protein kinase that phosphorylates the high-molecular-weight microtubule-associated protein MAP-2. The polyamine spermine at 2mM affected the phosphorylation of MAP-2 in a manner that depended on the cyclic AMP concentration. At cyclic AMP concentrations below 10(-6) M, spermine increased the rate of phosphorylation, while at cyclic AMP concentrations above 10(-6) M, spermine decreased the rate of phosphorylation. Spermine also decreased the final extent of cyclic AMP-dependent phosphorylation but did not affect the protein substrate specificity of the microtubule-associated protein kinase. MAP-2 was the principal substrate both in the presence and in the absence of spermine. Because of these results, we propose that microtubule protein phosphorylation may be regulated in vivo by spermine as well as by cyclic AMP levels.     

Mechanism of action of aldosterone release by prostaglandin E in isolated rat adrenal glomerulosa cells

The effect of prostaglandin E (PGE) on aldosterone release and the mechanism of action of PGE in mediating the release of aldosterone were studied using isolated rat glomerulosa cells. PGE1 stimulated aldosterone release in a dose-dependent fashion at concentrations between 10(-8) and 10(-6) M and caused approximately a two-fold increase over the basal aldosterone level at 10(-6) M. A significant and dose-dependent increase in cAMP production was also produced by PGE1 at concentrations greater than 10(-8) M. Aldosterone release induced by 10(-7) M or 10(-6) M PGE2 was significantly reduced by a competitive receptor blocking PG-antagonist, SC 19220 (10(-7) M), but not affected by (Sar1, Ileu8)-angiotensin-II (A-II), a competitive inhibitor of A-II. PGE-stimulated aldosterone release was almost completely abolished by depleting the extracellular Ca2+ by EGTA, or by verapamil, a Ca2+-channel blocker or W-7, a calmodulin inhibitor. These findings suggest that PGE stimulates aldosterone release through the membrane receptor binding and activation of adenylate cyclase and that Ca2+-calmodulin system plays an essential role in mediating the steroidogenic action of PGE in the adrenal glomerulosa cells. However, the physiological significance of PGE in the regulation of aldosterone secretion remains to be elucidated.     

Calcium rather than cyclic AMP is an intracellular messenger of parathyroid hormone action on glycogen metabolism in isolated rat hepatocytes.

The synthetic 1-34 fragment of human parathyroid hormone (1-34hPTH) stimulated glucose production in isolated rat hepatocytes. The effect of 1-34hPTH was dose-dependent and 10(10) M-1-34 hPTH elicited the maximum glucose output, which was approx. 80% of that by glucagon. Although 1-34hPTH induced a small increase in cyclic AMP production at concentrations higher than 10(-9) M, 10(-10) M-1-34hPTH induced the maximum glucose output without significant elevation of cyclic AMP. This is in contrast to the action of forskolin, which increased glucose output to the same extent as 10(-10) M-1-34hPTH by causing a 2-fold elevation of cyclic AMP. In addition to increasing cyclic AMP, 1-34hPTH caused an increase in cytoplasmic free calcium concentration ([Ca2+]c). When the effect of 1-34hPTH on [Ca2+]c was studied in aequorin-loaded cells, low concentrations of 1-34hPTH increased [Ca2+]c: the 1-34hPTH effect on [Ca2+]c was detected at as low as 10(-12) M and increased in a dose-dependent manner. 1-34hPTH increased [Ca2+]c even in the presence of 1 microM extracellular calcium, suggesting that PTH mobilizes calcium from an intracellular pool. In line with these observations, 1-34hPTH increased the production of inositol trisphosphate. These results suggest that: (1) PTH activates both cyclic AMP and calcium messenger systems and (2) PTH stimulates glycogenolysis mainly via the calcium messenger system.     

Effects of potassium chloride and smooth muscle relaxants on tension and cyclic nucleotide levels in rat myometrium.

Ten minutes after KCl-depolarization of rat myometrial strips, at which time the muscles were in a state of sustained contracture, tissue levels of adenosine 3',5'-cyclic monophosphate (cyclic AMP) were increased by approximately 40% over relaxed controls, and levels of guanosine 3',5'-cyclic monophosphate (cyclic GMP) were decreased by 40%. At this point both nitroglycerin (4 X 10(-4) M) and papaverine (2 X 10(-5) M) were capable of relaxing the depolarized muscles without significantly increasing cyclic AMP levels. Isoproterenol, in concentrations from 5 X 10(-9) M to 10(-6) M, relaxed the depolarized muscles and significantly increased tissue levels of cyclic AMP. However, the magnitudes of the cyclic AMP increases seen after the lower concentrations of isoproterenol were small relative to the increases observed during KCl-contracture alone. For example, the 40% elevation of cyclic AMP seen 10 min after KCl-depolarization did not cause the muscles to relax, whereas 5 X 10(-9) M isoproterenol caused relaxation with an increase in cyclic AMP levels of only 16% over depolarized controls. It was concluded that changes in total tissue levels of cyclic AMP were not responsible for the uterine relaxation caused by nitroglycerin, papaverine or isoproterenol in these experiments. Cyclic GMP levels in the depolarized muscles were not significantly changed by isoproterenol or papaverine but were increased approximately 80% by nitroglycerin. The above results are not consistent with the previously suggested roles for cyclic GMP and cyclic AMP as mediators of smooth muscle contraction and relaxation, respectively.     

Regulation of cyclic AMP level and lactic acid production in Ehrlich ascites tumor cells.

1. Quercetin (3.3',4',5,7-pentahydroxy flavone) at the concentration of 10(-4) M, as well as 2-10(-2) M theophylline and 1.5 - 10(-4) M prostaglandin E2 caused maximal rise of cyclic AMP in Ehrlich ascites tumor cells. 2. No additional increase of cyclic AMP level in these cells was found when both quercetin (10(-4) M) and theophylline (2-10(-2) M) were present in the incubation medium, while combination of quercetin (10(-4) M) and prostaglandin E2 (1.5 - 10(-4) M) has a synergistic effect on the level of cyclic AMP. 3. Degradation of cyclic AMP by homogenate of Ehrlich ascites tumor cells was inhibited by both quercetin and theophylline. 4. Quercetin, and to a smaller but significant extent theophylline, inhibited the lactic acid production in Ehrlich ascites tumor cells while prostaglandin E2 did not change the glycolytic rate in these cells. No synergistic inhibitory effect on lactic acid production was found when combinations of quercetin and prostaglandin E2, quercetin and theophylline or prostaglandin E2 and theophylline were tested. 5. Treatment of Ehrlich ascites tumor cells with dextran sulfate abolished the inhibitory effect of quercetin on lactic acid production, while the effect of the bioflavonoid on cyclic AMP levels was not altered.     

Uroporphyria development in cultured chick embryo fibroblasts long-term treated with chloramphenicol and ethidium bromide

In brain cortex, low concentrations of GTP or Gpp(NH)p activated the membrane-bound low Km cyclic AMP phosphodiesterase while higher concentrations of GTP, but not of Gpp(NH)p, reversed this activation. The adenosine analog N6-phenylisopropyladenosine (N6-PIA) elicited biphasic effect on this enzyme (activation up to 10(-8) M, complete reversion at 10(-5) M), provided that GTP was present. N6-PIA activation was reduced in the presence of Gpp(NH)p and blocked by sodium (80 mM). In contrast, the soluble low Km cyclic AMP phosphodiesterase was insensitive to GTP or N6-PIA. This study suggests that guanine nucleotides and N6-PIA exert their effects on the membrane-bound enzyme through guanine nucleotide regulatory proteins.     

Galanin Inhibits Noradrenaline-Induced Accumulation of Cyclic AMP in the Rat Cerebral Cortex

The effect of galanin on noradrenaline (NA)-induced accumulation of cyclic AMP was investigated in slices of rat cerebral cortex. NA (10(-4)M) increased cyclic AMP levels during a 20-min observation period. Galanin (3 X 10(-7)M) significantly inhibited this response at all time points examined, although it did not change the basal levels of cyclic AMP. Galanin (10(-8)-3 X 10(-6)M) inhibited the cyclic AMP response to NA (10(-4)M) in a dose-dependent manner, with an IC50 of approximately 5.6 X 10(-8)M and a maximum inhibition of 59%. These results suggest that galanin, devoid of any detectable effects by itself, modulates the cyclic AMP response to NA in the rat cerebral cortex.     

Effects of ACTH and calcium on cyclic AMP production and steroid output by the zona glomerulosa of the adrenal cortex.

Effects of ACTH and calcium on cyclic AMP production and steroid output by the zona glomerulosa (the capsular fraction) from the rat adrenal cortex have been studied. Although high concentrations of extracellular calcium potentiated the stimulatory action of ACTH on cyclic AMP and aldosterone output, tetracaine or verapamil inhibited aldosterone output but not cyclic AMP production during ACTH-stimulation. Lanthanum reduced both aldosterone and cyclic AMP accumulation induced by ACTH. These results suggest that an extracellular calcium would be essential in stimulating the capsular steroidogenesis without involvement of the cyclic AMP system.