Correlation between cyclic AMP levels and calcium efflux in isolated renal cortical tubules.

Isolated renal cortical tubules from male hamsters were utilized to examine the possible relationship between cyclic AMP (cAMP) and efflux of calcium. Both parathyroid hormone (PTH) and prostaglandin E1 (PGE1) produced dose-related increases in cAMP levels and calcium efflux from isolated tubules. Maximal concentrations of both hormones resulted in changes in cAMP which were 6 fold greater and changes in calcium efflux which were 2 fold greater with PGE1 than with PTH. Effects of sub-maximal amounts of either hormone on both cAMP and calcium efflux were potentiated to tubule incubations resulted in increases in tissue-associated cAMP over the same degree by inclusion of methyl-isobutylxanthine (MIX). Addition of either exogenous cAMP or dibutyryl cAMP (db-cAMP) produced dose-related increases in calcium efflux which occurred more rapidly with db-cAMP than with cAMP. Increasing amounts of cAMP added to the same concentration range resulting in increases in calcium efflux. Addition of 2', 3' cyclic AMP, 5'AMP or db-cyclic GMP had no significant effect on calcium efflux while 3', 5' cyclic CMP significantly reduced this response. The results indicate that cAMP increases efflux of calcium from renal tubules and may play a central role in hormone-dependent transport of this ion.     

Metabolism of cyclic AMP in isolated renal tubules: effects of prostaglandins and parathyroid hormone.

Concentrations of cyclic AMP (cAMP) were increased in isolated renal cortical tubules from hamsters by both parathyroid hormone (PTH) and prostaglandin E1 (PGE1) with maximal effects of PGE1 being 6-8 fold greater than those of PTH during a 10 min period. However, cAMP concentrations in cells treated with 1-methyl-3-isobutylxanthine (MIX) were increased with maximal concentrations of either hormone to the same degree. Similar effects of both hormones were observed on adenylate cyclase activity in renal homogenates. Simultaneous addition of hormones produced changes in both cAMP concentrations in intact tubules as well as adenylate cyclase activity of homogenates which were not completely additive. Degradation of cAMP, estimated in intact tubules as the difference in cAMP levels in the presence and absence of MIX, was increased by both hormones, however, changes were 2-3 fold greater in tubules exposed to PTH than to PGE1. Neither hormone directly altered cAMP phosphodiesterase (PDE) activity in either 30,000 x g supernatant or pellets from renal cortical homogenates. The results suggest that both hormones increase the production of cAMP in renal cortical tubules and may share a common target cell type in this response. Degradation of cAMP, however, is differentially effected by the two hormones, probably reflecting differences exerted on intracellular mechanisms regulating the enzymatic hydrolysis of cAMP.     

The accumulation of cyclic AMP and cyclic GMP in guinea pig brain slices: Effect of calcium ions,norepinephrine and adenosine

The effect of Ca²⁺ and putative neurotransmitters on formation of cyclic AMP and cyclic GMP has been studied in incubated slices of brain tissue. Cyclic AMP levels in cerebellar slices after about 90 min of incubation ranged from 10 pmol/mg protein in rabbit, to 25 in guinea pig, to 50 in mouse and 200 in rat. Cyclic GMP levels in the same four species showed no correlation with cyclic AMP levels and were, respectively, 1.3, 20, 5 and 30 pmol/mg protein. The absence of calcium during the prolonged incubation of cerebellar slices had little effect on final levels of cyclic AMP, while markedly decreasing final levels of cyclic GMP. Reintroduction of Ca²⁺ resulted in a rapid increase in cerebellar levels of cyclic GMP which was most pronounced for guinea pig where levels increased nearly 7-fold within 5 min. Prolonged incubation of guinea pig cerebral cortical slices in calcium-free medium greatly elevated cyclic AMP levels apparently through enhanced formation of adenosine, while having little effect on final levels of cyclic GMP. Norepinephrine and adenosine elicited accumulations of cyclic AMP and cyclic GMP in both guinea pig cerebral cortical and cerebellar slices. Glutamate, γ-aminobutyrate, glycine, carbachol, and phenylephrine at concentrations of 1 mM or less had little or noe effect on cyclic nucleotide levels in guinea pig cerebellar slices. Prostaglandin E₁ and histamine slightly increased cerebellar levels of cyclic AMP. Isoproterenol increased both cyclic AMP and cyclic GMP. The accumulation of cyclic AMP and cyclic GMP elicited by norepinephrine in cerebellar slices appeared, baed on dose vs. response curves, agonist-antaganonist relationships and calcium dependency, to involve in both cases activation of a similar set of ß-adrenergic receptors. In cerebellar slices accumulations of cyclic AMP and cyclic GMP elicted by norepinephrine and by a depolarizing agent, veratridine, were strongly dependent on the presence of calcium. The stimulatory effects of adenosine on cyclic AMP and cyclic GMP formation were antagonized by theophylline. The lack of correlations between levels of cyclic AMP and cyclic GMP under the various conditions suggested independent activation of cyclic AMP- and cyclic GMP-generating systems in guinea pig cerebellar slices by interactions with Ca²⁺, norephinephrine and adenosine.     

Metabolism of cyclic AMP in isolated renal tubules: Effects of prostaglandins and parathyroid hormone

Concentrations of cyclic AMP (cAMP) were increased in isolated renal cortical tubules from hamsters by both parathyroid hormone (PTH) and prostaglandin E₁ (PGE₁) with maximal effects of PGE₁ being 6–8 fold greater than those of PTH during a 10 min period. However, cAMP concentrations in cells treated with 1-methyl-3-isobutylxanthine (MIX) were increased with maximal concentrations of either hormone to the same degree. Similar effects of both hormones were observed on adenylate cyclase activity in renal homogenates. Simultaneous addition of hormones produced changes in both cAMP concentrations in intact tubules as well as adenylate cyclase activity of homogenates which were not completely additive. Degradation of cAMP, estimated in intact tubules as the difference in cAMP levels in the presence and absence of MIX, was increased by both hormones, however, changes were 2–3 fold greater in tubules exposed to PTH than to PGE₁. Neither hormone directly altered cAMP phosphodiesterase (PDE) activity in either 30,000 x g supernatant or pellets from renal cortical homogenates.The results suggest that both hormones increase the production of cAMP in renal cortical tubules and may share a common target cell type in this response. Degradation of cAMP, however, is differentially effected by the two hormones, probably reflecting differences exerted on intracellular mechanisms regulating the enzymatic hydrolysis of cAMP.     

Differential inhibition of cyclic AMP and cyclic GMP hydrolysis in rat renal cortex.

Adenosine 3′,5′-monophosphate (cyclic AMP) and guanosine 3′,5′-monophosphate (cyclic GMP) metabolism in rat renal cortex was examined. Athough the cyclic AMP and cyclic GMP phosphodiesterases are similarly distributed between the soluble and particulate fractions following differential centrifugation, their susceptibility to inhibition by theophylline, dl-4-(3-butoxy-4-methoxybenzyl)-2-imidazolidinone (Ro 20-1724), and 1-methyl-3-isobutylxanthine (MIX) are quite different. Ro 20-1724 selectively inhibited both renal cortical-soluble and particulate cyclic AMP degradation, but had little effect on cyclic GMP hydrolysis. Theophylline and MIX effectively inhibited degradation of both cyclic nucleotides, with MIX the more potent inhibitor. Effects of these agents on the cyclic AMP and cyclic GMP content of cortical slices corresponded to their relative potency in broken cell preparations. Thus, in cortical slices, Ro 20-1724 (2 mm) had the least effect on basal (without agonist), carbamylcholine, and NaN₃-stimulated cyclic GMP accumulation, but markedly increased basal and (parathyroid hormone) PTH-mediated cyclic AMP accumulation, MIX (2 mm) which was as effective as Ro 20-1724 in potentiating basal and PTH-stimulated increases in cyclic AMP also mediated the greatest augmentation of basal, carbamylcholine, and NaN₃-stimulated accumulation of cyclic GMP. By contrast, theophylline (10 mm) which was only 12% as effective as Ro 20-1724 in increasing the total slice cyclic AMP content in the presence of PTH was much more effective than Ro 20-1724 in potentiating carbamylcholine and NaN₃-mediated increases in cyclic GMP. These results demonstrate selective inhibition of cyclic nucleotide phosphodiesterase activities in the rat renal cortex and support the possibility of multiple cyclic nucleotide phosphodiesterases in this tissue. Furthermore, both cyclic nucleotides appear to be rapidly degraded in the renal cortex.     

Effects of dose and time after administration of 4-isopropyl-2,6,7-trioxa-1-phosphabicyclo (2,2,2)octane-1-oxide (IPTBO) on cyclic nucleotide concentrations in mouse cerebellum

The concentrations of cyclic AMP and cyclic GMP in the mouse cerebellum after intracerebroventricular administration of a range of doses of IPTBO have been studied with particular interest in the temporal changes after injection. A non typical dose relationship was observed. After the lowest and non-convulsive dose used (0.06 μg/animal) cyclic AMP levels decreased and cyclic GMP levels increased within 1 min, but after higher doses cyclic AMP and cyclic GMP levels were both raised. At three different convulsive doses of IPTBO there were increased levels of cyclic AMP with time which were more apparent in convulsing animals. Raised levels of cyclic GMP however, were not so influenced by convulsions. The results suggest that (1) the immediate decrease in cyclic AMP and the immediate increase in cyclic GMP may play a part in the mechanism of action of IPTBO—possibly by triggering convulsions and (2) there is an increase in cyclic AMP in response to, or because of, the convulsions. It is concluded that time after treatment and time into convulsions are critical when studying cyclic nucleotide changes, particularly for cyclic AMP and that such factors may explain conflicting observations with respect to this nucleotide.     

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.     

Change in levels of cyclic AMP and cyclic GMP during pregnancy and larval development of the tsetse fly, Glossina morsitans

Cyclic AMP and cyclic GMP levels change very little in response to feeding and mating, but during pregnancy and at parturition major changes can be detected in both the mother and larva. In both the female head and larva (whole body) cyclic AMP levels reach a peak at parturition. In the larval brain and ring gland cyclic AMP is at its lowest at parturition but rises sharply, reaching a peak 1.5 hr later at the time of pupariation . Though cyclic AMP levels in the head and thorax are consistently 10-60 times greater than levels of cyclic GMP, both the female abdomen and larva contain high concentrations of cyclic GMP with a ratio of cyclic AMP:cyclic GMP approaching 1:1. In the abdomen, the pattern of high cyclic GMP closely parallels the activity cycle of the female's milk gland.     

On the role of cyclic AMP and cyclic GMP in steroid production by bovine cortical cells

The time course of corticotropin-induced steroidogenesis and changes in intracellular cyclic AMP and cyclic GMP levels were investigated in isolated bovine adrenocortical cells prepared by trypsin digestion. Corticotropin produced a pea a peak rise in cyclic AMP during the first 5 min of stimulation and enhanced steroid production after 15 min. Corticotropin also caused a decrease in cortical cyclic GMP at 5 min; this decrease in cyclic GMP reverted to a 2–3 fold increase at 15–30 min which gradually subsided by 60 min. A steroidogenic concentration of prostaglandin E₂ also produced an elevation in the levels of both nucleotides, but the rise in cyclic GMP preceded the rise incyclic AMP. These results suggest that the relative amount of cyclic AMP and cyclic GMP, rather than the absolute levels of cyclic AMP, may be a key factor in the regulation of steroidogenesis.     

Interactions between parathyroid hormone and prostaglandins on renal cortical cyclic AMP

Effects of parathyroid hormone (PTH) and several prostaglandins (PGs) on cyclic AMP (cAMP) metabolism were studied and compared in isolated renal cortical tubules from male hamsters. Both production and intracellular degradation of cAMP were increased by PTH and each of the PGs tested (PGE2, PGE1, PGI2). Production of cAMP was increased to similar levels by maximal concentrations of PTH and each PG, however, degradation of cAMP was significantly higher in response to PTH than with any of the PGs. This difference in intracellular degradation of cAMP was responsible for the much higher concentrations of cAMP in renal cortical tubules exposed to PGs (PGE1, PGE2, PGI2) than to PTH. Submaximal amounts of each PG produced additive increases in cAMP concentrations in the presence of maximal amounts of PTH. Additivity of the combined responses was lost, however, as the PGs concentrations reached their maxima. The results suggest that renal PGs (PGE2 and PGI2) may modulate the effects of PTH on cAMP concentrations in renal cortical tubules.     

On the role of cyclic AMP and cyclic GMP in steroid production by bovine cortical cells.

The time course of corticotropin-induced steroidogenesis and changes in intracellular cyclic AMP and cyclic GMP levels were investigated in isolated bovine adrenocortical cells prepared by trypsin digestion. Corticotropin produced a peak rise in cyclic AMP during the first 5 min of stimulation and enhanced steroid production after 15 min. Corticotropin also caused a decrease in cortical cyclic GMP at 5 min; this decrease in cyclic GMP reverted to a 2-3 fold increase at 15-30 min which gradually subsided by 60 min. A steroidogenic concentration of prostaglandin E2 also produced an elevation in the levels of both nucleotides, but the rise in cyclic GMP preceded the rise in cyclic AMP. These results suggest that the relative amounts of cyclic AMP and cyclic GMP, rather than the absolute levels of cyclic AMP, may be a key factor in the regulation of steroidogenesis.     

Use of forskolin to study the relationship between cyclic AMP formation and bone resorption in vitro.

The effect of the adenylate cyclase activator forskolin on bone resorption and cyclic AMP accumulation was studied in an organ-culture system by using calvarial bones from 6-7-day-old mice. Forskolin caused a rapid and fully reversible increase of cyclic AMP, which was maximal after 20-30 min. The phosphodiesterase inhibitor rolipram (30 mumol/l), enhanced the cyclic AMP response to forskolin (50 mumol/l) from a net cyclic AMP response of 1234 +/- 154 pmol/bone to 2854 +/- 193 pmol/bone (mean +/- S.E.M., n = 4). The cyclic AMP level in bones treated with forskolin (30 mumol/l) was significantly increased after 24 h of culture. Forskolin, at and above 0.3 mumol/l, in the absence and the presence of rolipram (30 mumol/l), caused a dose-dependent cyclic AMP accumulation with an calculated EC50 (concentration producing half-maximal stimulation) value at 8.3 mumol/l. In 24 h cultures forskolin inhibited spontaneous and PTH (parathyroid hormone)-stimulated 45Ca release with calculated IC50 (concentration producing half-maximal inhibition) values at 1.6 and 0.6 mumol/l respectively. Forskolin significantly inhibited the release of 3H from [3H]proline-labelled bones stimulated by PTH (10 nmol/l). The inhibitory effect by forskolin on PTH-stimulated 45Ca release was significant already after 3 h of culture. In 24 h cultures forskolin (3 mumol/l) significantly inhibited 45Ca release also from bones stimulated by prostaglandin E2 (1 mumol/l) and 1 alpha-hydroxycholecalciferol (0.1 mumol/l). The inhibitory effect of forskolin on spontaneous and PTH-stimulated 45Ca release was transient. A dose-dependent stimulation of basal 45Ca release was seen in 120 h cultures, at and above 3 nmol of forskolin/l, with a calculated EC50 value at 16 nmol/l. The stimulatory effect of forskolin (1 mumol/l) could be inhibited by calcitonin (0.1 unit/ml), but was insensitive to indomethacin (1 mumol/l). Forskolin increased the release of 3H from [3H]proline-labelled bones cultured for 120 h and decreased the amount of hydroxyproline in bones after culture. Forskolin inhibited PTH-stimulated release of Ca2+, Pi, beta-glucuronidase and beta-N-acetylglucosaminidase in 24 h cultures. In 120 h cultures forskolin stimulated the basal release of minerals and lysosomal enzymes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Oppositional effects of acetylcholine and isoproterenol on isometric tension and cyclic nucleotide concentrations in rabbit atria.

The effects of acetylcholine chloride and isoproterenol on myocardiial cyclic GMP, cyclic AMP and on isometric tension were studied in isolated electrically driven rabbit atria. Acetylcholine (0.5 muM) produced a significant decrease in isometric force that was associated with a significant elevation in atrial cyclic GMP. Cyclic AMP was significantly lowered at 15 seconds after the addition of acetylcholine, but was only slightly decreased at earlier time periods. Both the negative inotropic action and increase in cyclic GMP after addition of acetylcholine were blocked by atropine. Isoproterenol (0.1 muM) produced a significant increase in isometric tension that was associated with a significant elevation in atrial cyclic AMP levels, whereas cyclic GMP levels were not changed. These effects were blocked by practolol. The increases in atrial cyclic GMP and cyclic AMP following addition of acetylcholine and isoproterenol, respectively, preceded the changes in isometric tension in response to these agents. These data support the hypothesis that changes in intracellular levels of cyclic AMP and cyclic GMP may mediate the positive and negative inotropic effects of adrenergic and cholinergic agents.     

Effects of pyruvate and other metabolites on cyclic GMP levels in incubations of rat hepatocytes and kidney cortex

Pyruvate increased cyclic GMP levels in rat hepatocytes. The effects were observed without or with 1-methyl-3-isobutylxanthine. Lactate, acetate, oxaloacetate, alpha-ketoglutarate, succinate, acetoacetate and beta-hydroxybutyrate also increased cyclic GMP levels. Some compounds increased cyclic GMP in kidney cortex slices. The effects were dependent upon Ca2+ in the medium. Cyclic AMP was increased 30-50% by some of these substances with 2.6 mM Ca2+. Rotenone, oligomycin, antimycin, dinitrophenol, KCN, and arsenate decreased GTP and ATP, basal cyclic GMP and the pyruvate effect, but did not alter cyclic AMP. Although fluoroacetate alone had no effect on cyclic nucleotides, GTP, or ATP, it potentiated the pyruvate effect on cyclic GMP. Adenosine and guanosine increased cyclic GMP and GTP to a similar extent of 30-50%. Aminooxyacetate, cycloserine, pentenoic acid and mepacrine decreased the pyruvate effect while cycloserine or mepacrine alone increased cyclic GMP. Citrate and mepacrine inhibited soluble and particulate guanylate cyclase from rat liver while cycloserine and acetoacetate increased guanylate cyclase activity. None of the other compounds altered guanylate cyclase activity. These results indicate that various metabolites and inhibitors can alter cyclic GMP accumulation in hepatocytes and renal cortex slices. Several mechanisms may be involved in these effects.     

Effects of an ATP analogue (alpha,beta-methylene-adenosine-5'-triphosphate) on cyclic AMP and cyclic GMP levels, 45Ca efflux, and protein secretion from rat pancreas.

The effects of the alpha,beta-methylene analogue of ATP (Ap(CH2)pp), described as a competitive inhibitor of adenylate cyclase (EC 4.6.1.1), were studied in the rat pancreas in vitro. The analogue did not alter basal cyclic AMP production and basal or carbachol-stimulated efflux of 45Ca from isotope-preloaded glands. On the other hand, Ap(CH2)pp reduced the secretory responses to carbachol, carbachol in the presence of dibutyryl cyclic AMP, pancreozymin (PZ), and the calcium ionophore, A-23187. Release of pancreatic protein in response to dibutyryl cyclic AMP itself was unaffected by the ATP analogue, suggesting that the other secretagogues tested share a common, Ap(CH2)pp-inhibitable pathway in their respective stimulatory actions. Though carbachol, PZ, and A-23187 all stimulated a rapid production (30 s) of pancreatic cyclic GMP, these responses were not affected by Ap(CH2)pp. Additional studies with the analogue indicated that it has a slow onset of action (30-45 min), i.e., its effect on secretion is preceded by secretagogue-induced changes in nucleotide levels and calcium efflux. Nonetheless, the analogue may affect cellular calcium homeostasis, if not during the initial events triggering secretion then during those events which maintain continued secretory output in the presence of a stimulus.     

Interrelations between cyclic AMP, cyclic GMP and contraction in guinea pig gallbladder stimulated by cholecystokinin.

The changes in isometric tension and in concentrations of cyclic AMP and cyclic GMP in guinea pig gallbladder muscle induced by the C-terminal octapeptide of cholecystokinin (C8-CCK) were studied before and after the addition of indomethacin 3 × 10^?6 g/ml. The contractile response to the hormone was not affected by indomethacin, nor was the associated decrease in cyclic AMP concentration. However, indomethacin completely prevented the increase in cyclic GMP following addition of C8-CCK. The results suggest that in isolated guinea pig gallbladder, cyclic GMP is not essential for the C8-CCK-induced decrease in cyclic AMP concentration, and that the contractile response induced by the hormone is independent of this nucleotide.     

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.     

Effects of isoproterenol,theophylline and carbachol on cyclic nucleotide levels and relaxation of bovine tracheal smooth muscle

The effect of theophylline and isoproterenol on bovine tracheal smooth muscle tension and cyclic AMP levels was investigated. Concentrations of isoproterenol (4 × 10^?6 M) and theophylline (10 mM) that relaxed carbachol-contracted tracheal muscle by 85–95% did not significantly elevate control levels of cyclic AMP. In the absence of carbachol, several-fold increases in cyclic AMP were caused by isoproterenol although no elevations by theophylline were measurable. However, when isoproterenol and theophylline were administered together, theophylline potentiated the rise in cyclic AMP caused by isoproterenol. Phosphodiesterase studies in tracheal muscle showed the presence of a high and a low K_m enzyme which were inhibited by theophylline. Cyclic GMP levels were elevated in muscles contracted by carbachol as well as in carbachol-contracted muscles that had been relaxed by theophylline. In non-tension studies, in which the tracheal muscle was not under isometric tension, carbachol or theophylline alone increased cyclic GMP and together they synergistically elevated cyclic GMP. Atropine blocked the elevation caused by carbachol but not that caused by theophylline. In contrast to theophylline, isoproterenol did not elevate cyclic GMP, and in carbachol-contracted muscles that had been relaxed by isoproterenol, cyclic GMP levels were no different from control. Also, in non-tension studies, isoproterenol decreased basal cyclic GMP and antagonized the increase in cyclic GMP due to carbachol.The results indicate that whole-tissue levels of cyclic AMP and cyclic GMP do not correlate with the state of tracheal smooth muscle tension. Cyclic GMP levels do not clearly correlate with either contraction or relaxation. The inhibition by carbachol of increases in cyclic AMP due to isoproterenol and the inhibition by isoproterenol of increases in cyclic GMP due to carbachol provide evidence for a reciprocal cholinergic-adrenergic antagonism of cyclic AMP and cyclic GMP levels. The antagonism did not appear to be due to either cyclic nucleotide affecting the elevation of the other since the levels of both cyclic nucleotides were depressed.     

A cholera toxin substrate regulates cyclic GMP content of rat pinealocytes

The adrenergic regulation of cyclic GMP in isolated pinealocytes was investigated. In this cell, norepinephrine stimulates cyclic GMP and cyclic AMP greater than 100-fold by activating both alpha 1- and beta-adrenoceptors. beta-Adrenergic activation is a requisite event and is potentiated by alpha 1-adrenergic activation (Vanecek, J., Sugden, D., Weller, J. L., and Klein, D. C. (1985) Endocrinology 116, 2167-2173). The current study found that cholera toxin could substitute for beta-adrenergic agonists in stimulating pinealocyte cyclic GMP content, as has been found to be the case for cyclic AMP. Treatment with cholera toxin alone (1 microgram/ml for 90 min) had a small effect (2- to 4-fold increase) on cyclic GMP; addition of the alpha 1-adrenergic agonists, phenylephrine, cirazoline, or methoxamine to cholera toxin-treated cells rapidly (peak at 5 min) caused a further 30- to 300-fold increase. The alpha 1-adrenergic agonists had little effect by themselves at concentrations which potentiated the effects of cholera toxin. The potentiating effect of phenylephrine was inhibited nearly completely by an alpha 1-adrenergic antagonist, but not by either an alpha 2- or beta-adrenergic antagonist. The purified cholera toxin subunits A and B did not stimulate cyclic GMP either alone or in the presence of phenylephrine. Furthermore, the potentiating action of phenylephrine was observed following 90 min but not 20 min of cholera toxin pretreatment. these results suggest that the regulation of cyclic GMP levels in the pineal gland involves an Ns-like GTP-binding regulatory protein. This is of interest because it is the first indication that cyclic GMP is regulated by such a GTP-binding protein in nonretinal tissue. It remains to be determined whether the mechanisms involved in the transmembrane regulation of cyclic AMP and cyclic GMP in any other tissue are similar.     

Calcium and pancreatic beta-cell function. 7. Evidence for cyclic AMP-induced translocation of intracellular calcium

The effect of cyclic AMP on calcium movements in the pancreatic beta-cell was evaluated using an experimental approach based on in situ labelling of intracellular organelles of ob/ob-mouse islets with 45Ca. Whereas the glucose-stimulated 14Ca incorporation by mitochondria and secretory granules was increased under a condition known to reduce cyclic AMP (starvation), raised levels of this nucleotide (addition of 3-isobutyl-1-methylxanthine or N6,O2'-dibutyryl adenosine 3',5'-cyclic monophosphate) reduced the mitochondrial accumulation of 45Ca. Conditions with increased cyclic AMP were associated with a stimulated efflux of 45Ca from the secretory granules but not from the mitochondria. The microsomal fraction differed from both the mitochondrial and secretory granule fractions by accumulating more 45Ca after the addition of 3-isobutyl-1-methylxanthine. The results suggest that cyclic AMP potentiates glucose-stimulaated insulin release by increasing cytoplasmic Ca2+ at the expense of the calcium taken up by the organelles of the pancreatic beta-cells.