Cyclic AMP synthesis in Xenopus laevis oocytes inhibition by progesterone

[α-³²P] ATP was microinjected into Xenopus oocyte and neosynthesized cyclic AMP was isolated. Cholera toxin inhibited progesterone-induced maturation and stimulated after 3 h of preincubation the amount of neosynthesized cyclic AMP. Progesterone decreased the neosynthesis of cyclic AMP during the first hour following addition of the hormone.     

Regulation of protooncogenes c-fos and c-myc expressions by protein tyrosine kinase, protein kinase C, and cyclic AMP mitogenic pathways in dog primary thyrocytes: a positive and negative control by cyclic AMP on c-myc expression

The proliferation of dog thyrocytes in primary culture is stimulated by three distinct intracellular signaling pathways: (1) the thyrotropin or forskolin-cyclic AMP-mediated cascade which is compatible with the differentiated state of the cell; (2) the protein kinase C pathway activated by diacylglycerol and phorbol esters; and (3) a protein tyrosine kinase system activated by epidermal growth factor. The two latter pathways also induce dedifferentiation. The activation of the three cascades induced the expression of the protooncogenes c-fos and c-myc with dose-response curves similar to those for DNA synthesis. After TPA and EGF, the time courses of stimulation of c-fos and c-myc were the same as those for mitogenically stimulated fibroblasts. However, after the cyclic AMP stimulation, c-myc expression was biphasic with an enhancement at 1 h followed by a down-regulation. A similar inhibition by cyclic AMP was also observed on the increased c-myc expression induced by EGF. This down-regulation is suppressed by cycloheximide, which suggests the involvement of a neosynthesized or a labile protein intermediate. The action of cyclic AMP on c-myc mRNA levels could be related to the opposite requirements of the stimulation of both proliferation and differentiation expression by the cyclic AMP pathway in the differentiated thyrocytes.     

Investigation of the adenosine 3', 5'-cyclic phosphate binding site of pig brain histone kinase with the aid of some analogues of adenosine 3', 5'-cyclic phosphate.

2'-O-Chloroacetyl cyclic AMP, 2'-O-acrylyl cyclic AMP and N-6, 2'-O-diacrylyl cyclic AMP were synthesized by the reaction of cyclic AMP with chloroacetic and acrylic anhydrides, respectively. Selective O-deacylation of N-6, 2'-O-diacrylyl cyclic AMP yielded N-6 -monoacrylyl cyclic AMP. In the reaction of gamma-mercaptobutyric acid with 8-bromo cyclic AMP, 8-(gamma-carboxypropylthio) cyclic AMP was obtained. The compounds synthesized and other cyclic AMP analogues (8-bromo cyclic AMP and adenosine 3', 5'-cyclic sulphate) were tested for ability to interact with the highly purified pig brain histone kinase. All compounds under study were found to be activators of the enzyme. The highest activating potency was manifested by 8-bromo cyclic AMP and 8-(gamma-carboxypropylthio) cyclic AMP; adenosine 3', 5'-cyclic sulphate was the least potent in this respect. All compounds were shown to inhibit binding of cyclic [-3-H]AMP to histone kinase. The inhibition was competitive with respect to cyclic AMP in all cases. All compounds, except for 2'-O-chloroacetyl cyclic AMP may indicate the formation of a covalent bond between this analogue and the enzyme. These findings suggest that an active site of the regulatory subunit of the histone kinase contains at least three specific areas responsible for cyclic AMP binding.     

1,N6-Etheno-2-aza-adenosine 3', 5'-cyclic phosphate: human erythrocyte membrane binding and activation of membrane protein kinase.

The relative efficiency of 1,N6-etheno-2aza-adenosine 3', 5'-monophosphate (cyclic 2-aza-epsilon AMP), 1,N6-etenoadenosine 3', 5'-monophosphate (cyclic epsilon AMP) and cyclic AMP in activation of membrane protein kinase and binding to membrane was examined using isolated membranes from human erythrocytes. Cyclic 2-aza-epsilon AMP was 81% as active as cyclic AMP in erythrocyte membrane binding and activation of membrane protein kinase. On the other hand, cyclic epsilon AMP was 37% as active toward membrane protein kinase and 29% toward membrane cyclic AMP binding. Since we have previously shown that the fluorescence of cyclic 2-aza-epsilon AMP is highly sensitive to the polarity of solvents, the high efficiency of cyclic 2-aza-epsilon AMP to substitute for cyclic amp suggests that it may be a suitable microenvironmental fluorescent probe for cyclic AMP binding sites.     

The effect of metabolites,papaverine, and probenecid on cyclic AMP efflux from isolated rat islets of Langerhans

The process of cyclic AMP efflux from rat islets of Langerhans has been studied. The dynamics of glucose-induced cyclic AMP efflux closely resembled the pattern of glucose-induced insulin release. Thus, both processes were dose-dependent for glucose having the same threshold concentrations (4–8 mmol/l glucose), with the time course of cyclic AMP efflux and insulin release from 0–60 min being very similar. Galactose did not affect insulin release, cyclic AMP efflux and intra-islet cyclic AMP accumulation. On the other hand, inosine, N-acetylglucosamine, α-ketoisocaproic acid, L-leucine and xylitol all promoted insulin release and cyclic AMP efflux. Except for L-leucine, all these substances enhanced the intracellular accumulation of cyclic AMP. The phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine, greatly augmented all these parameters in the presence of glucose whereas in the absence of glucose, insulin release was not enhanced, while both cyclic AMP efflux and cyclic AMP accumulation were elevated. The drug, probenecid, did not alter either insulin release or intra-islet cyclic AMP levels, while cyclic AMP efflux was markedly reduced (though not abolished). Papaverine inhibited both insulin release and cyclic AMP efflux, but was found to augment the intra-islet cyclic AMP levels. The efflux of cyclic AMP correlates more closely with insulin release than with the cyclic AMP accumulation in most instances. The efflux is independent of either insulin secretory granule extrusion or intracellular fluctuations of the nucleotide, though it is not yet known whether cyclic AMP efflux may have some regulatory significance in insulin release.     

The uptake of cyclic AMP by human erythrocytes and its effect on membrane phosphorylation.

The effects of time and cyclic AMP concentration on cyclic AMP uptake and membrane phosphorylation were studied using intact human erythrocytes. The rate of uptake of cyclic [³H]AMP was nearly linear with respect to cyclic AMP concentration. The amount taken up was small compared to the extracellular cyclic AMP concentration, but was sufficient to significantly increase the intracellular cyclic AMP concentration. Incubation with cyclic AMP resulted in increased incorporation of ³²P_i into several phosphorylated membrane peptides of the intact erythrocytes. Although cyclic AMP altered the distribution of radioactivity among the membrane components, the total amount of incorporation was not increased. The effect of cyclic AMP on phosphorylation of membrane peptides was observed with extracellular cyclic AMP concentrations as low as 1 μm and was most pronounced in incubations of 1 to 4 h. These results indicate that cyclic AMP can enter erythrocytes in sufficient amounts to alter the activity of cyclic AMP-dependent protein kinases, or to alter the rate of turnover of certain phosphorylated membrane peptides.     

Steroidogenesis in isolated adrenocortical cells. Correlation with receptor-bound adenosine 3′:5′-cyclic monophosphate

Because several groups have recently questioned a mediating role for cyclic AMP in adrenocortical steroidogenesis, we analysed the problem in more detail by measuring three different cyclic AMP pools in cells isolated from decapsulated rat adrenals. Extra-cellular, total intracellular and bound intracellular cyclic AMP were determined by radioimmunoassay in comparison with corticosterone production induced by low corticotropin concentrations. The increase in extracellular and total intracellular cyclic AMP with low corticotropin concentrations was dependent on the presence of a phosphodiesterase inhibitor and short incubation times. Bound intracellular cyclic AMP was less dependent on these two parameters. In unstimulated cells cyclic AMP bound to its receptor represents only a small fraction of the total intracellular cyclic AMP. After stimulation by a concentration of corticotropin around the threshold for corticosterone production, an increase in bound cyclic AMP was observed which correlated very well with steroidogenesis both temporally and with respect to corticotropin concentration. This finding was complemented by measuring a concomitant decrease in free receptor sites. Full occupancy of the receptors was not necessary for maximal steroidogenesis. Binding kinetics of cyclic [(3)H]AMP in concentrations equivalent to the intracellular cyclic AMP concentration suggest the presence of at least three different intracellular cyclic AMP pools. These observations are in agreement with a possible role for cyclic AMP as a mediator of acute steroidogenesis induced by low corticotropin concentrations.     

Effects of adenosine 3'':5''-cyclic monophosphate and serum on synthesis of hyaluronic acid in confluent rat fibroblasts.

A small amount of hyaluronic acid is synthesized in confluent cultures of rat fibroblasts, which have a high content of cyclic AMP. Addition of calf serum caused a rapid decrease in the cellular cyclic AMP content and large increases in hyaluronic acid synthetase activity and hyaluronic acid production. Addition of cyclic AMP also caused a marked increase in hyaluronic acid synthetase activity within 2h and then increased hyaluronic acid production. The effects of cyclic AMP and serum on hyaluronic acid synthesis were additive. Prostaglandin E2, which increased the cyclic AMP by stimulating adenylate cyclase, was as effective as cyclic AMP in increasing hyaluronic acid synthetase activity, but AMP was far less effective than cyclic AMP. These results indicate that cyclic AMP itself stimulates the mucopolysaccharide synthesis and that the effect of serum is not due to a decrease in cyclic AMP in the cells.     

α2-Adrenoceptors Mediate Inhibition of Cyclic AMP Production in the Spinal Cord After Stimulation of Cyclic AMP with Forskolin but Not After Stimulation with Capsaicin or Vasoactive Intestinal Peptide

In slices obtained from the ventral and the dorsal guinea pig spinal cord both forskolin and vasoactive intestinal peptide (VIP) caused a dose-dependent stimulation of the production of cyclic AMP. By contrast capsaicin stimulated cyclic AMP formation only in the dorsal cord; no effect was observed in the ventral cord. The alpha 2-adrenergic agonist UK-14,304 dose-dependently inhibited the production of cyclic AMP in both the dorsal and ventral aspects of the cord when the formation of cyclic AMP had been stimulated with 3 microM forskolin, the maximal inhibition amounting to 25-32%. Also the basal (i.e., unstimulated) production of cyclic AMP was inhibited, the inhibition amounting to about 16-18%. However, after stimulation of cyclic AMP formation in the dorsal cord with capsaicin, UK-14,304 was virtually ineffective in inhibiting the accumulation of cyclic AMP. Also, when the formation of cyclic AMP was stimulated with VIP, UK-14,304 was virtually ineffective in inhibiting the formation of cyclic AMP both in the ventral and the dorsal parts of the cord. When cyclic AMP production had been stimulated with forskolin the ability of UK-14,304 to inhibit the formation of cyclic AMP was not attenuated by capsaicin, either in the ventral or in the dorsal cord. The results are discussed with the notion that cyclic AMP inhibitory spinal cord alpha 2-adrenoceptors are located on cells accessible to stimulation of cyclic AMP with forskolin but not with capsaicin or VIP.     

Effects of crp mutations on adenosine 3'',5''-monophosphate metabolism in Salmonella typhimurium.

Wild-type Salmonella typhimurium could not grow with exogenous cyclic adenosine 3',5'-monophosphate (AMP) as the sole source of phosphate, but mutants capable of cyclic AMP utilization could be isolated provided the parental strain contained a functional cyclic AMP phosphodiesterase.All cyclic AMP-utilizing mutants had the growth and fermentation properties of cyclic AMP receptor protein (crp) mutants, and some lacked cyclic AMP binding activity in vitro. The genetic defect in each such mutant was due to a single point mutation, which was co-transducible with cysG. crp mutants isolated by alternative procedures also exhibited the capacity to utilize cyclic AMP. crp mutants synthesized cyclic AMP at increased rates and contained enhanced cellular cyclic AMP levels relative to the parental strains, regardless of whether or not cyclic AMP phosphodiesterase was active. Moreover, adenylate cyclase activity in vivo was less sensitive to regulation by glucose, possibly because the enzyme II complexes of the phosphotransferase system, responsible for glucose transport and phosphorylation, could not be induced to maximal levels. This possibility was strengthened by the observation that enzyme II activity (measured both in vitro by sugar phosphorylation and in vivo by sugar transport and chemotaxis) was inducible in the parental strain but not in crp mutants. The results suggest that the cyclic AMP receptor protein regulates cyclic AMP metabolism as well as catabolic enzyme synthesis.     

Cyclic AMP transport across membrane vesicles of ultra-violet light irradiatedEscherichia coli

Transport of cyclic AMP acrossEscherichia coli membrane was studied using membrane vesicles. Uptake of cyclic AMP was measured using normally oriented vesicles, whereas uptake in everted vesicles was taken as a measure of the efflux of cyclic AMP. Ultra-violet irradiation of the cells led to an inhibition of both uptake and efflux of cyclic AMP across the membrane. The presence of cyclic AMP in the growth medium prior to ultra-violet irradiation caused an enhancement of the uptake and efflux. The uptake and efflux of cyclic AMP were less in vesicles from glucose grown cells as compared to the uptake and efflux by the vesicles prepared from glycerol grown cells. Similarly both uptake and efflux of cyclic AMP were more in vesicles prepared from cells grown on glycerol or glucose in the presence of cyclic AMP than in vesicles from cells grown in absence of cyclic AMP. It is suggested that the number of cyclic AMP carrier molecules were reduced in cells under catabolite repression by glucose as well as by ultra-violet irradiation     

The binding of cyclic AMP to renal brush border membranes.

The binding of cyclic AMP to the proximal tubule luminal (brush border) membrane isolated from the rabbit renal cortex was studied. The rate of binding was dependent on temperature; at 37 degrees equilibrium was attained in 45 min, whereas at 0 degrees 120 min was required. The final levels of binding were identical. The binding of 3H-cyclic AMP was reversed by dilution or addition of unlabeled cyclic nucleotide. Debinding was markedly temperature sensitive. Binding was only partially saturable with respect to cyclic AMP concentration, apparently with more than one binding site. The cyclic AMP bound to the membrane was recovered unchanged. When bound to the membrane cyclic AMP was resistant to hydrolysis by endogenous membrane or exogenously added phosphodiesterase. The binding to the membranes was relatively specific for cyclic AMP, although other cyclic purine nucleotides inhibited, cyclic IMP greater than dibutyryl cyclic AMP greater than cyclic GMP. The renal membranes did bind cyclic GMP, but this binding was relatively non-specific. Hormones and drugs, that mediate cyclic AMP generation or renal function, as well as other compounds common to the proximal tubule were without significant effect on cyclic AMP binding. Binding was inhibited by sulfhydryl reacting agents and this inhibition could be blocked and partially reversed by mercaptoethanol.     

An increase of pituitary 3', 5' cyclic adenosine monophosphate produced by estradiol benzoate in vitro: possible implication of this increase in the secretion of luteinizing hormone.

In an attempt to study the site and mechanism of action of estrogen in producing positive feedback control, porcine anterior pituitary slices were incubated in vitro in the presence of estradiol benzoate (EB). EB elevated pituitary cyclic AMP concentration within 5 min and augmented pituitary release of luteinizing hormone (LH). The magnitude of increase of cyclic AMP and LH release was related to the doses of EB used. Also, luteinizing hormone releasing hormone (LH-RH) elevated pituitary cyclic AMP concentration and stimulated pituitary release of LH. The magnitude of increase of cyclic AMP and LH release was inversely related to the doses of LH-RH used. EB and LH-RH were additive in increasing cyclic AMP. Progesterone and clomiphene citrate interfered with an increase of pituitary cyclic AMP produced by EB, but did not significantly affect the basal level of pituitary cyclic AMP. Testosterone propionate, human chorionic gonadotropin and hexestrol were without effect on either basal or stimulated level of pituitary cyclic AMP. Since cyclic AMP and dibutyryl cyclic AMP (DBC) stimulated LH release, it is suggested that EB directly stimulates the release of LH by augmenting cyclic AMP synthesis in the anterior pituitary.     

Uptake and catabolism of N6, 2'-O-dibutyryl cyclic AMP by the perfused heart

Dibutyryl cyclic AMP when administered to perfused rat hearts produced increased contractile tension and increased intracellular levels of cyclic AMP. When [³H]dibutyryl cyclic AMP was administered, it was taken up by the heart in extremely small amounts. The material was present in the tissue throughout the duration of the inotropic response. The compound was slowly degraded to monobutyryl cyclic AMP and traces of cyclic AMP. It is suggested that N⁶-monobutyryl-cyclic AMP, or possibly cyclic AMP, may mediate the effects of the dibutyryl analog.     

Stimulation of cartilage macromolecule synthesis by adenosine 3',5'-monophosphate.

The role of cyclic AMP in the regulation of cartilage macromolecule synthesis in vitro was studied in pelvic cartilage from 10-12 day chick embryos. Incubation of cartilages in medium containing 0.5 mM cyclic AMP resulted in a 30% inhibition of 35SO4-2, [3H]leucine and [3H]uridine incorporation into proteoglycan, total protein and RNA, respectively. Higher concentrations of cyclic AMP had no greater effects. In contrast, butyrylated cyclic AMP derivatives (0.5-5.0 mM) added to the incubation medium stimulated (50-100%) the incorporation of these radiolabeled precursors into cartilage macromolecules. Theophylline, in concentrations (0.1-0.5 mM) which raise intracellular cyclic AMP, also increases the incorporation of radiolabeled precursors into macromolecules. The data indicate that exogenous cyclic AMP and butyrylated cyclic AMP derivatives have paradoxical effects on cartilage macromolecule synthesis. Butyrylated cyclic AMP derivatives, not exogenous cyclic AMP, mimic the effects of intracellular cyclic AMP. Incubation of embryonic chicken cartilage with exogenous cyclic AMP results in the extracellular degradation of the cyclic AMP to adenosine. Adenosine (0.125 mM) inhibits precursor incorporation into cartilage macromolecules. The metabolism of exogenous cyclic AMP generates sufficient adenosine to account for the observed inhibitory effects of exogenous cyclic AMP on cartilage macromolecule synthesis. Butyrylated cyclic AMP derivatives are not degraded during incubation with cartilage. The data indicate that cartilage is a tissue in which the effect of cyclic AMP is to stimulate anabolic processes.     

Purification, characterization and production of rabbit antibodies to rat liver particulate, high-affinity, cyclic AMP phosphodiesterase

The cyclic nucleotide phosphodiesterase (EC 3.4.16) activities of a rat liver particulate fraction were analyzed after solubilization by detergent or by freeze-thawing. Analysis of the two extracts by DEAE-cellulose chromatography revealed that they contain different complements of phosphodiesterase activities. The detergent-solubilized extract contained a cyclic GMP phosphodiesterase, a low affinity cyclic nucleotide phosphodiesterase whose hydrolysis of cyclic AMP was activated by cyclic GMP and a high affinity cyclic AMP phosphodiesterase. The freeze-thaw extract contained a cyclic GMP phosphodiesterase and two high affinity cyclic AMP phosphodiesterase, but no low affinity cyclic nucleotide phosphodiesterase. The cyclic AMP phosphodiesterase activities from the freeze-thaw extract and from the detergent extract all had negatively cooperative kinetics. One of the cyclic AMP phosphodiesterases from the freeze-thaw extract (form A) was insensitive to inhibition by cyclic GMP; the other freeze-thaw solubilized cyclic AMP phosphodiesterase (form B) and the detergent-solubilized cyclic AMP phosphodiesterase were strongly inhibited by cyclic GMP. The B enzyme appeared to be converted into the A enzyme when the particulate fraction was stored for prolonged periods at -20 degrees C. The B form was purified extensively, using DEAE-cellulose, a guanine-Sepharose column and gel filtration. The enzyme retained its negatively cooperative kinetics and high affinity for both cyclic AMP and cyclic GMP throughout the purification, although catalytic activity was always much greater for cyclic AMP. Rabbit antiserum was raised against the purified B enzyme and tested via a precipitin reaction against other forms of phosphodiesterase. The antiserum cross-reacted with the A enzyme and the detergent-solubilized cyclic AMP phosphodiesterase from rat liver. It did not react with the calmodulin-activated cyclic GMP phosphodiesterase of rat brain, the soluble low affinity cyclic nucleotide phosphodiesterase of rat liver or a commercial phosphodiesterase preparation from bovine heart. These results suggest a possible interrelationship between the high affinity cyclic nucleotide phosphodiesterase of rat liver.     

Influence of epinephrine on the degradation of cyclic AMP in chicken erythrocytes.

The rate of cyclic AMP degradation in intact chicken erythrocytes was estimated by following cyclic AMP decay after blocking epinephrine-stimulated cyclic AMP synthesis with propranolol. The apparent half life time for cyclic AMP was found to be markedly slowed down by a prolonged exposure of the cells to epinephrine. The first order rate of cyclic AMP breakdown was 2–3 fold slower after a long exposure (45 min) to the hormone as compared to a brief period (8 min) of incubation. The effect of epinephrine on the rate of cyclic AMP hydrolysis is not related to the level of intracellular cyclic AMP. Exposure of erythrocytes to epinephrine did not alter the activity of phosphodiesterase measured in cell-free extracts over a wide range of physiological concentrations.     

Effects of isoproterenol and forskolin on tension, cyclic AMP levels, and cyclic AMP dependent protein kinase activity in bovine coronary artery

The effects of isoproterenol and forskolin on tension, cyclic AMP levels, and cyclic AMP dependent protein kinase activity were compared in helical strips of bovine coronary artery. Elevation of cyclic AMP and activation of the protein kinase appeared to be well correlated with relaxation of potassium-contracted arteries by isoproterenol. Forskolin, at 1 microM or higher concentrations, also markedly elevated cyclic AMP levels, activated the kinase, and relaxed the arteries. However, a lower concentration of forskolin (0.1 microM) caused significant increases in both cyclic AMP levels and cyclic AMP dependent protein kinase activity, but did not relax the muscles. Relaxation caused by isoproterenol was accompanied by an apparent translocation of cyclic AMP dependent protein kinase activity from the soluble to the particulate fraction in these preparations. A similar shift in the distribution of the kinase was caused by various concentrations of forskolin, irrespective of whether the arteries were relaxed or not. In contrast to previous results in other tissues, low concentrations of forskolin (less than or equal to 1 microM), which themselves markedly elevated cyclic AMP levels in the arteries, did not potentiate the effects of isoproterenol on cyclic AMP levels or tension in these preparations. These results suggest that either cyclic AMP is not solely responsible for the relaxation caused by these agents, or some form of functional compartmentalization of cyclic AMP and cyclic AMP dependent protein kinase exists in this tissue.     

Urinary adenosine 3',5'-monophosphate (cyclic AMP) in normal and cryptorchid boys.

The 24-hour urinary excretion of cyclic AMP was determined in 102 normal boys aged 1.9-16.9 years and in 136 cryptorchids aged 2.5-16.9 years. A marked increase of the normal cyclic AMP excretion was found in pubertal years. There was a positive correlation between urinary excretion of cyclic AMP and the excretion of testosterone, androstenedione, LH and FSH. A positive correlation was also found between cyclic AMP excretion and height and weight, respectively. Mean cyclic AMP excretion of bilateral and unilateral cryptorchids was normal in all bone age groups except in unilateral cases with bone age 8-9.9 years and bone aged greater than or equal to 14 years. In these two groups, mean cyclic AMP excretion was moderately increased. After HCG stimulation of 25 cryptorchids, urinary cyclic AMP excretion varied between increased, unchanged and decreased values. The cyclic AMP excretion changes observed in some of our patients were difficult to interpret and were possibly of unspecific nature. Further information about the testiclar cyclic AMP secretion and the relationship between this nucleotide and sexual hormones may be obtained from studies in testicular biopsy tissue.     

Iodide induced suppression of thyrotropin-stimulated adenosine 3',5'-monophosphate production in cat thyroid slices.

Cat thyroid slices were studied to investigate their responsiveness to thyrotropin stimulation of cyclic AMP accumulation. Ovine and bovine thyrotropin, in the presence of 2.5 mM aminophylline, induced a dose-dependent increase in the cyclic AMP content of cat thyroid tissue. Half-maximal stimulation of cyclic AMP accumulation was obtained at a thyrotropin concentration of 1-2 mU/ml. The maximal effect of thyrotropin was observed at 10 mU/ml, and was associated with a mean 77 +/- 19-fold increase in thyroidal cyclic AMP. Preincubation of cat thyroid tissue for 2 h with 50 micron NaI resulted in an impairment in the subsequent ability of thyrotropin to enhance cyclic AMP accumulation, without altering the level of cyclic AMP in tissues not exposed to the hormone. Preincubation alone was without effect on thyrotropin stimulation of cyclic AMP, and the inhibitory effect of iodide was prevented by addition of 3 mM methimazole to the preincubation medium. In addition, the time course of thytrotropin stimulation of cyclic AMP accumulation in cat thyroid slices was not significantly altered by the preincubation with excess iodide. These studies provide additional evidence that excess iodide inhibits the adenylate cyclase-cyclic AMP system in thyroid tissue.