Effect of endogenous LH secretion on ovarian cyclic AMP and cyclic GMP levels in the rat

Injection of LH (2 and 10 μg) into proestrus rats increased ovarian cyclic AMP levels and concomitantly decreased the levels of cyclic GMP. When injected into diestrus rats, cyclic AMP increases were even greater, whereas cyclic GMP levels were not significantly different from controls receiving saline injections. Ovarian cyclic nucleotide levels were also examined on different days of the cycle. On the afternoon of proestrus (1700 h), the time when circulating levels of LH are at their maximum, the concentration of cyclic AMP showed a moderate but insignificant increase. At the same time, cyclic GMP levels were significantly decreased. An inverse relation between cyclic AMP and cyclic GMP levels was seen on each day of the cycle. When rats were injected with pentobarbital (35 mg/kg) on the afternoon of proestrus (1300 h) to block the LH surge, the expected increases in ovarian cyclic AMP and decreases in cyclic GMP were effectively blocked. These results indicate that ovarian cyclic AMP and cyclic GMP levels are regulated by circulating LH. The apparent differences in direction of nucleotide response to LH, suggest divergent roles for the nucleotides in ovarian function.     

Regulation by beta-adrenergic receptor and muscarinic cholinergic receptor activation of intracellular cyclic AMP and cyclic GMP levels in rat lung slices

The effects of adrenergic and cholinergic agents, present singly or in combination, on the levels of cyclic AMP and cyclic GMP in slices of rat lung were studied. It was found that isoproterenol increased pulmonary cyclic AMP levels about 3-fold, and this increase was abolished by propranolol, but not by phenoxybenzamine. Acetylcholine increased the cyclic GMP levels also about 3-fold (thus raising its tissue content above that of cyclic AMP), and this increment was largely reduced by atropine, but not by hexamethonium. While without effects on the cyclic GMP levels when present alone, isoproterenol antagonized acetylcholine in increasing cyclic GMP levels. Acetylcholine, while lacking effects on the basal levels of cyclic AMP, on the other hand, depressed the augmented levels caused by isoproterenol.The data presented indicate that cyclic GMP may mediate the cholinergic action in lung and that the pulmonary cyclic GMP levels are also closely regulated by β-adrenergic receptor activation.     

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.     

Amylase secretion by rabbit parotid gland. Role of cyclic AMP and cyclic GMP.

Amylase secretion and changes in the levels of cyclic AMP and GMP were studied in rabbit parotid gland slices incubated in vitro with a variety of neurohumoral transmitters, their analogs and inhibitors. Cyclic GMP levels increased 8-fold 5 min after exposure to carbachol (10(-4) M), without a change in cyclic AMP levels; amylase output also rose. These effects were completely inhibited by muscarinic blockade with atropine, but were unaffected by alpha-adrenergic blockade with phenoxybenzamine. Epinephrine (4 - 10(-5) M) produced a rapid increase in the levels of both cyclic nucleotides and in amylase release. The increase in cyclic GMP level was inhibited by previous exposure of the slices to phenoxybenzamine, while the cyclic AMP rise was prevented by the beta-blocking agent, propranolol. Pure alpha-adrenergic stimulation with methoxamine (4 - 10(-4) M) produced modest elevations in cyclic GMP content and amylase output, effects blocked by pre-treatment of slices with either atropine or phenoxybenzamine. At a concentration of 4 - 10(-6) M, isoproterenol (a beta-agonist) failed to affect cyclic GMP levels, but promptly stimulated increases in cyclic AMP levels, and after a short lag, amylase secretion. At a higher dose (4 - 10(-5) M) isoproterenol produced elevations in the levels of both nucleotides. The carbachol-induced effects on cyclic GMP content and amylase release were greatly potentiated by the addition of isoproterenol (4 - 10(-6) M). These data strongly suggest that cholinergic muscarinic agonists and alpha-adrenergic agonists stimulate amylase output in rabit parotid gland by mechanisms involving cyclic GMP. The atropine-sensitive intracellular events effected by alpha-stimulation may be dependent upon endogenous generation of acetylcholine. Both cyclic nucleotides seem to be required for the early rapid secretion of amylase. The unique responses achieved by the combination of carbachol and isoproterenol suggest that isoproterenol may increase the sensitivity of this tissue to the effects of cholinergic stimuli.     

Effects of 8 bromo-cyclic GMP on cyclic AMP levels in urine and tissues of hypothyroid rats.

The effects of 8-bromo-guanosine 3', 5' cyclic monophosphate (8Brcyclic GMP) on the levels of cyclic AMP in urine, brain, liver, and muscle were determined in hypothyroid rats. Cyclic AMP urinary levels were significantly lower in untreated hypothyroid rats than in normal rats, and when hypothyroid rats were treated with replacement thyroxine, urinary cyclic AMP returned to normal after six days of treatment. Hypothyroid rats treated with 8Brcyclic GMP, 30 mg/kg body weight subcutaneously every 12 hours exhibited a biphasic response. From days 2 through 4 of treatment, cyclic AMP excretion rose to approximately 2.5 times normal levels. Subsequently, the cyclic AMP excretion returned to hypothyroid levels and remained low throughout the rest of the treatment period. Tissue cyclic AMP levels in hypthyroid rats treated with 8Br-cyclic GMP were increased in comparison to those of untreated hypothyroid rats. Increase in brain was 134%, in liver 55%, and in muscle 42%. We conclude from these studies that 8Br-cyclic GMP can significantly alter cyclic AMP levels in hypothyroid rats.     

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.     

The effect of methadone addiction on cyclic nucleotide levels in regions of rat brain

Studies of tissue culture cells and tissue slices have implicated the nucleotides, cyclic AMP and cyclic GMP, in the mechanism of action of opiates. However, there are little in vivo data to corroborate this hypothesis. We addicted rats to the synthetic opiate, methadone, by providing the drug in their drinking water (dosage 2.1 mg./kg./day). The two cyclic nucleotides were measured in four brain areas which contain a high concentration of opiate receptors: amygdala, neostriatum, periventricular grey, and thalamus. Data were obtained after acute exposure of the drug (1 day), tolerance (35 days), withdrawal (35 days on drug then 1 day off drug), and readjustment (35 days on drug then 21 days off drug). Cyclic GMP levels were low (0.03 pmol./mg. tissue) in the four regions and did not differ significantly during the experiment. Cyclic AMP levels were higher (1-3 pmol./mg.) and fluctuated consistently in the four regions. After acute methadone treatment, there was a reduction in cyclic AMP, which continued at lower levels after tolerance. One day of withdrawal led to increased cAMP, which rose to near control levels. After readjustment, the levels were reduced. These data indicate an involvement of cyclic AMP in the addiction and withdrawal processes in the intact animal.     

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.     

Effects of parathyroid hormone on cyclic AMP, cyclic GMP, and efflux of calcium in isolated renal tubules.

The effects of parathyroid hormone (PTH) on concentrations of cyclic AMP and cyclic GMP were investigated in isolated renal cortical tubules from hamsters. Efflux of 45Ca from tubules was compared to temporal changes in both cyclic nucleotide concentrations. A rapid increase in cyclic AMP occurred following addition of PTH which was maximal by 1 min but decreased over the next 4 min period. Cyclic GMP concentrations were not significantly altered at 1 min but increased between 1 and 5 min from basal levels. Concentrations of both nucleotides remained significantly elevated from basal levels between 5 and 15 min following PTH. Efflux of 45Ca was increased by PTH with time-course changes closely paralleling changes in cyclic GMP concentrations. Changes in both cyclic AMP and cyclic GMP were related to PTH concentrations of the incubation media and were increased by addition of theophylline. Increasing the calcium concentration from 1 to 3 mM did not significantly alter the effect of PTH on cyclic AMP, however, cyclic GMP concentrations were further increased.     

Distribution and regulation of cyclic nucleotide levels in cerebellum, in vivo.

Abstract— In mouse cerebellum, in vivo. cyclic GMP levels are 7 pmol/mg protein in the vermis and 40% lower in the hemispheres, whereas cyclic AMP levels are 7 9 pmol/mg protein in both regions. In the vermis. most of the cyclic GMP is contained in the molecular layer; cyclic AMP levels are highest in the granular layer. Amphetamine, harmaline. pentylenetetrazol and physical shaking elevate, and diazepam and reserpine depress levels of cyclic GMP in both vermis and hemispheres. Oxotremorine and atropine, respectively, increase and decrease cyclic GMP levels only in vermis. Regardless of the agent used, most of the change (67 89%) in cyclic GMP levels occurs in the molecular layer of the vermis; the remainder occurs in the granular layer. Of the drugs tested, only pentylenetetrazol affects cyclic AMP levels, and this drug increases cyclic AMP levels in both vermis and hemispheres and causes equal elevations in the molecular and granular layers of the vermis. In incubated slices of mouse cerebellum, none of the drugs produces changes in cyclic nucleotide levels which are similar to those in vivo. These data indicate that many drugs and conditions that alter cyclic GMP levels in cerebellum act via a common, but indirect, process. We suggest that cyclic GMP levels in cerebellum are regulated by the activity of both the climbing fiber and mossy fiber cerebellar afferent systems. Increased activity in these afferent pathways causes elevation of cyclic GMP levels in Purkinje cells and perhaps in other cells; decreased activity leads to depressed cyclic GMP levels.     

The effect of isoproterenol and its analogs upon adenosine 3′,5′-monophosphate and guanosine 3′,5′-monophosphate levels in mouse parotid gland in vivo: Relationship to the stimulation of DNA synthesis

The ability of a large number of catecholamine analogs to stimulate DNA synthesis in the mouse parotid gland in vivo was compared to their effect on the levels of adenosine 3′,5′-monophosphate (cyclic AMP) and guanosine 3′,5′-monophosphate (cyclic GMP) in this tissue. In the normal parotid gland the level of cyclic GMP is very low (10^?9 moles/kg wet wt), being only 1/800th of the cyclic AMP concentration. Isoproterenol increases the levels of cyclic AMP and cyclic GMP 30- and 3-fold, respectively. The increase in cyclic AMP is biphasic with an apparent early maximum at 2.5 min and a main peak at 15 min while the increase in cyclic GMP is monophasic with maximum levels at 15 min. Other analogs showed a similar effect on cyclic AMP levels but the time course of increases in cyclic GMP was very variable with peak stimulation as early as 1 min in some cases. The ability of analogs to cause the accumulation of cyclic AMP was correlated with their capacity to activate adenylate cyclase in parotid extracts and to act as β-adrenergic agonists in other systems. All compounds which raised cyclic AMP levels stimulated DNA synthesis but a number of other analogs also stimulated DNA synthesis. The effects of these analogs have been correlated with their ability to raise the intracellular concentration of cyclic GMP. Cholinergic agents also cause the accumulation of cyclic GMP but the effect of the analogs does not appear to be mediated through the cholinergic system as atropine does not block their effects and cholinergic agonists do not stimulate DNA synthesis. It is suggested that cholinergic agonists and the catecholamine analogs act primarily on the duct and acinar cells, respectively.Significant with inhibitors of the rises in cyclic nucleotide levels suggest that in isoproterenol stimulation it is the rise in cyclic GMP which is the more significant event in relation to stimulation of DNA synthesis.     

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.     

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.     

Amylase secretion by rabbit parotid gland role of cyclic AMP and cyclic GMP

Amylase secretion and changes in the levels of cyclic AMP and GMP were studied in rabbit parotid gland slices incubated in vitro with a variety of neurohumoral transmitters, their analogs and inhibitors. Cyclic GMP levels increased 8-fold 5 min after exposure to carbachol (10⁻⁴ M), without a change in cyclic AMP levels; amylase output also rose. These effects were completely inhibited by muscarinic blockade with atropine, but were unaffected by α-adrenergic blockade with phenoxybenzamine. Epinephrine (4 · 10⁻⁵ M) produced a rapid increase in the levels of both cyclic nucleotides and in amylase release. The increase in cyclic GMP level was inhibited by previous exposure of the slices to phenoxybenzamine, while the cyclic AMP rise was prevented by the β-blocking agent, propranolol. Pure α-adrenergic stimulation with methoxamine (4 · 10⁻⁴ M) produced modest elevations in cyclic GMP content and amylase output, effects blocked by pre-treatment of slices with either atropine or phenoxybenzamine. At a concentration of 4 · 10^{−6 M}, isoproterenol (a β-agonist) failed to affect cyclic GMP levels, but promptly stimulated increases in cyclic AMP levels, and after a short lag, amylase secretion. At a higher dose (4 · 10⁻⁵ M) isoproterenol produced elevations in the levels of both nucleotides. The carbachol-induced effects on cylcic GMP content and amylase release were greatly potentiated by the addition of isoproterenol (4 · 10⁻⁶ M).These data strongly suggest that cholinergic muscarinic agonists and α-adrenergic agonist stimulate amylase output in rabbit parotid gland by mechanisms involving cyclic GMP. The atropine-sensitive intracellular events effected by α-stimulation may be dependent upon endogenous generation of acetylcholine. Both cyclic nucleotides seem to be required for the early rapid secretion of amylase. The unique responses achieved by the combination of carbachol and isoproterenol suggest that isoproterenol may increase the sensitivity of this issue to the effects of cholinergic stimuli.     

Cyclic Nucleotide Response of the Hippocampal Formation to Septal Stimulation in Naive and Kindled Rats

Rats were kindled through nonmagnetic electrodes stereotaxically implanted into the medial septum. Concentrations of cyclic AMP and cyclic GMP were measured by radioimmunoassay in seven brain regions after microwave fixation during the development and expression of kindled seizures. Hippocampal concentrations were similar to untreated controls (cyclic GMP level in the left and right hippocampus, 0.66 +/- 0.04 and 0.68 +/- 0.07 pmol/mg of protein, respectively; cyclic AMP, 9.4 +/- 0.9 and 9.6 +/- 0.8 pmol/mg of protein, respectively), in kindled animals that were not stimulated, and in naive animals in response to septal stimulation, in spite of the presence in the latter group of bilateral hippocampal afterdischarges. Animals that failed to develop kindling and kindled animals that failed to have a seizure in response to stimulation also showed no change in cyclic nucleotide concentrations in any brain region. Kindled animals that developed a seizure following stimulation showed significant elevations in levels of both cyclic GMP and cyclic AMP in hippocampus and in several other brain regions. A single naive animal that had a seizure in response to its first stimulation also appeared to have elevated concentrations of both cyclic nucleotides in hippocampus. These data suggest that the elevation in levels of both cyclic GMP and cyclic AMP during kindled seizures is associated with seizure development rather than with the generation of afterdischarges or with the kindling engram.     

Levels of cyclic nucleotides in mouse regional brain following 300 ms microwave inactivation.

Abstract— The uniformity and speed of inactivation of mouse brain adenylate cyclase, guanylate cyclase and cyclic nucleotide phosphodiesterase were measured after 6 kW microwave irradiation (MWR). Inactivation of enzymes was uniform throughout the brain during heating and 100% loss of activity was evident after 300 ms. MWR. For comparison of effects of inactivation times on levels of cyclic nucleotides measured in regional brain areas, cyclic AMP and cyclic GMP were estimated after 1.5 kW MWR requiring 4 s of heating and 6 kW MWR requiring 300 ms. Except for corpus striatum, uniformly lower levels of cyclic AMP were measured following 300 ms vs. 4s MWR . There was no change in cyclic GMP levels in regional brain areas after 4s vs. 300 ms MWR . Cyclic AMP and cyclic GMP were measured from the same regional brain tissue samples after 300 ms and ratios calculated. The finding of much lower cyclic AMP:cyclic GMP ratios than had previously been reported suggests that slow inactivation times provide for the measurement of regional brain cyclic nucleotide values which are not consistent with the in-vivo state.     

Changes in rat adrenal cyclic nucleotides during normal and neoplastic growth

In an attempt to correlate changes in cyclic nucleotide levels with in vivo growth of the rat adrenal gland we have measured adrenal cyclic AMP and cyclic GMP in normal, hyperplastic, and neoplastic rat adrenals. The first group of animals were subject to either unilateral adrenalectomy (ADX) or acute hypophysectomy 1 h prior to unilateral adrenalectomy (HADX). Cyclic nucleotides were measured in the contralateral adrenal post-operatively. In HADX rats cyclic GMP rose steadily throughout the 7 day study period, while ADX rats exhibited significant decreases in adrenal cyclic GMP. Cyclic AMP remained approximately 1.5 pm/mg tissue in HADX rats, while in ADX rats there was significant elevation of adrenal cyclic AMP at all time points. Cyclic GMP/cyclic AMP ratios remained constant in HADX animals; however, the growing adrenals of ADX animals exhibited depressed cyclic GMP/cyclic AMP ratios at all time periods.Adrenal hyperplasia was induced in a seond group of animals by a transplantable, corticotropin-secreting, pituitary tumor. Adrenals from age-matched animals served as controls. Adrenal cyclic AMP was significantly elevated in tumor-bearers at a time correspinding to the peak accumulation of adrenal weight, protein and DNA in these animals. In contrast, adrenal cyclic GMP in both tumor-beares and control animals fell steadily throughout the study period. Cyclic GMP/cyclic AMP ratios of control animals decreased from 2 to 3 weeks post-transplant remaining at the 3 week value during the period corresponding to rapid adrenal growth in tumor-bearers. The cyclic GMP/cyclic AMP ratio in the hyperplastic adrenals of tumor-bearers decreased steadily throughout their rapid growth period, suggesting a positive correlation between adrenal growth and depression of the cyclic GMP/cyclic AMP ratio.Cyclic nucleotide levels in neoplastic adrenals of rats bearing the transplantable adrenocortical carcinoma 494 were compared with cyclic nucleotides in normal rat adrenal glands. Cyclic AMP was not different in the two groups. However, the cyclic GMP content of neoplastic adrenals was significantly lower than that of normal adrenal tissue, causing a suppression of the cyclic GMP/cyclic AMP ratio in the neoplastic tissue. Thus, measurement of adrenal cyclic nucleotides in both hyperplastic and neoplastic rat adrenal glands suggests that adrenal growth in vivo may be characterized by a depression of the cyclic GMP/cyclic AMP ratio.     

Inhibition of cardiac slow action potentials by 8-bromo-cyclic GMP occurs independent of changes in cyclic AMP levels

Cyclic GMP inhibits the slow inward Ca current of cardiac cells. This effect could be due to a cyclic GMP-mediated phosphorylation of the Ca channel (or some protein modifying Ca channel activity), or alternatively, to enhanced degradation of cyclic AMP owing to stimulation of a phosphodiesterase by cyclic GMP. To test the latter possibility, we examined the effect of extracellular 8-bromo-cyclic GMP on cyclic AMP levels in guinea pig papillary muscles, in parallel with electrophysiological experiments. Isoproterenol (10(-6) M) significantly increased the cyclic AMP levels and induced Ca-dependent slow action potentials. Superfusion with 8-bromo-cyclic GMP (10(-3) M) inhibited the slow action potentials induced by isoproterenol. However, muscles superfused with 8-bromo-cyclic GMP had cyclic AMP levels identical to those of muscles superfused with isoproterenol alone. Similarly, 8-bromo-cyclic GMP had no effect on the increase in cyclic AMP levels of muscles treated with forskolin (10(-6) M) or histamine (10(-6) M). We conclude that the inhibitory effect of cyclic GMP on slow Ca channels in guinea pig ventricular cells is not due to a decrease in the cyclic AMP levels. We hypothesize that a cyclic GMP-mediated phosphorylation is the most likely explanation for the Ca channel inhibition observed in this preparation.     

Effect of acetylcholine on glycogen phosphorylase activity and cyclic nucleotide content in isolated perfused rat hearts.

Acetylcholine (1muM) increased cyclid GMP content in paced perfused rat hearts within 15 sec., with peak content occurring at 1 min. No effect of acetylcholine on cyclic AMP content, phosphorylase activity or glycogen synthase was observed. Epinephrine (1muM) infusion increased both cyclic AMP content and phosphorylase, but did not alter cyclic GMP content or glycogen synthase activity. When acetylcholine was infused during the second min. of a 2 min. infusion of epinephrine, the cholinergic agent increased cyclic GMP and reduced the stimulated phosphorylase activity and elevated cyclic AMP.     

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.