Potent and cooperative feedback inhibition of adenylate cyclase activity by calcium in pituitary-derived GH3 cells

Calcium (Ca2+) ion concentrations that are achieved intracellularly upon membrane depolarization or activation of phospholipase C stimulate adenylate cyclase via calmodulin (CaM) in brain tissue. In the present study, this range of Ca2+ concentrations produced unanticipated inhibitory effects on the plasma membrane adenylate cyclase activity of GH3 cells. Ca2+ concentrations ranging from 0.1 to 0.8 microM exerted an increasing inhibition on enzyme activity, which reached a plateau (35-45% inhibition) at around 1 microM. This inhibitory effect was highly cooperative for Ca2+ ions, but was neither enhanced nor dependent upon the addition of CaM (1 microM) to EGTA-washed membranes. The inhibition was greatly enhanced upon stimulation of the enzyme by vasoactive intestinal peptide (VIP) and/or GTP. Prior exposure of cultured cells to pertussis toxin did not affect the inhibition of plasma membrane adenylate cyclase activity by Ca2+, although in these membranes, hormonal (somatostatin) inhibition was significantly attenuated. Maximally effective concentrations of Ca2+ and somatostatin produced additive inhibitory effects on adenylate cyclase. The addition of phosphodiesterase inhibitors demonstrated that inhibitory effects of Ca2+ were not mediated by Ca2(+)-dependent stimulation of a phosphodiesterase activity. These observations provide a mechanism for the feedback inhibition by elevated intracellular Ca2+ levels on cAMP-facilitated Ca2+ entry into GH3 cells, as well as inhibitory crosstalk between Ca2(+)-mobilizing signals and adenylate cyclase activity.     

7-Oxa-13-prostynoic acid and polyphloretin phosphate as non-specific antagonists of the stimulatory effects of different agents on adenylate cyclase from various tissues

7-Oxa-13-prostynoic acid (OPA) and polyphloretin phosphate (PPP) are believed to act as specific antagonists of prostaglandin action. In order to estimate their specificity, the inhibitory effects of these drugs were tested on the activity of adenylate cyclase from several tissues which were stimulated by prostaglandins and several other compounds.

In adenylate cyclaae preparation from L-fibroblasts both OPA (0.15–1.5 mM) and PPP (0.01–1.0 mg/ml) antagonized not only the stimulatory effects of PGE₁ but also the stimulatory effects of sodium fluoride and increased enzyme activity due to the previous treatment of cell cultures by cholera toxin. Both OPA and PPP produced a dose dependent depression of adenylate cyclase activity to zero values both under basal conditions and after stimulation by sodium fluoride and various hormones in all preparations studied, including rat liver, heart, brain, epididymal adipose tissue, small intestine, renal cortex and renal medulla.

The present results indicate that both prostaglandin antagonists may, in higher concentrations, act as nonspecific inhibitors of the catalytic unit of adenylate cyclase rather than specific antagonists of the prostaglandin effects on adenylate cyclase.     

Vasoactive intestinal polypeptide and glucagon: stimulation of adenylate cyclase activity via distinct receptors in liver and fat cell membranes

Vasoactive intestinal polypeptide (VIP), a peptide hormone that is chemically and biologically related to glucagon and secretin, stimulates the activity of adenylate cyclase in liver and fat cell membranes. Effects of combinations of VIP with glucagon and secretin at concentrations that maximally activate adenylate cyclase suggest that in adipose tissue, the three hormones act on the same enzyme, whereas in liver, VIP and secretin activate a common enzyme that is distinct from that responding to glucagon. Studies with radioiodinated derivatives of VIP and glucagon indicate that these hormones interact with separate receptors. Secretin, which gives a maximal stimulation of adenylate cyclase activity virtually identical to that elicited by VIP, inhibits the binding of the latter to its receptor. However, the apparent affinity of secretin for adenylate cyclase and for the VIP receptor is about two order of magnitude lower than that of VIP. It is suggested that VIP and secretin may activate adenylate cyclase via a common receptor.     

7-oxa-13-prostynoic acid and polyphloretin phosphate as non-specific antagonists of the stimulatory effects of different agents on adenylate cyclase from various tissues.

7-oxa-13-prostynoic acid (OPA) and polyphloretin phosphate (PPP) are believed to act as specific antagonists of prostaglandin action. In order to estimate their specificity, the inhibitory effects of these drugs were tested on the activity of adenylate cyclase from several tissues which were stimulated by prostaglandins and several other compounds. In adenylate cyclase preparation from L-fibroblasts both OPA (0.15-1.5 MM) and PPP (0.01-1.0 MG/ML) antagonized not only the stimulatory effects of PGE but also the stimulatory effects of sodium fluoride and increased enzyme activity due to the previous treatment of cell cultures by cholera toxin. Both OPA and PPP produced a dose dependent depression of adenylate cyclase activity to zero values both under basal conditions and after stimulation by sodium fluoride and various hormones in all preparations studied, including rat liver, heart, brain, epididymal adipose tissue, small intestine, renal cortex and renal medulla. The present results indicate that both prostaglandin antagonists may, in higher concentrations, act as nonspecific inhibitors of the catalytic unit of adenylate cyclase rather than specific antagonists of the prostaglandin effects on adenylate cyclase.     

Species and organ differences in the activity and regulation of adenylate and guanylate cyclases

The activity of adenylate and guanylate cyclases was determined in adrenal, heart, liver and fat tissues of guinea pigs, mice, rabbits and monkeys. The enzymes activities varied markedly depending both on the species and organs. The highest basal activities of adenylate cyclase was observed in all organs of guinea pigs. It was found that organs with low basal level of adenylate cyclase possess high guanylate cyclase. Species variations of the basal and stimulated adenylate cyclase activity may determine the functional activity of an organ: the higher the adenylate cyclase activity, the more intensive steroidogenesis in adrenals, lipolysis in the fat tissue, muscle contraction and nerve impulse conduction in heart.     

Characterization of an octopamine-sensitive adenylate cyclase from insect brain (Mamestra configurata Wlk.).

An adenylate cyclase present in the brain of the moth Mamestra configurata Wlk. that is stimulated selectively by low (micromolar) concentrations of octopamine has been characterized with respect to several properties. The optimum pH, optimum ATP:Mg2+ ratio, the concentration of ATP required for half-maximal and maximal reaction velocity, metal ion specificity, effect of NaF, and effects of GTP and 5'-guanylylimidodiphosphate were in general similar to those of catecholamine-sensitive adenylate cyclases from various regions of mammalian brain. However, ethylene glycol bis-(beta-aminoethyl ether)-N,N-tetraacetic acid (EGTA), a calcium chelator, stimulated both basal and octopamine-sensitive enzyme activity in the insect brain, whereas in mammalian brain EGTA is usually observed to inhibit basal activity but not catecholamine-stimulated activity. Adenylate cyclase activity of the 47,000 g particulate fraction of the insect brain was almost undetectable in the absence of added GTP. Addition of saturating concentrations (100 micrometer) of GTP to the particles restored about 30% of the basal and octopamine-sensitive enzyme activity present in the homogenate. Addition of 100,000 g supernatant to the particles doubled both basal and octopamine-sensitive enzyme activity in the presence of saturating concentrations of GTP, indicating that in addition to GTP, a cytosolic factor(s) is necessary for enhanced adenylate cyclase activity.     

Crayfish abdominal muscle adenylate cyclase. Studies on the stimulation by a Ca2+-binding protein.

A plasma-membrane preparation of crayfish muscle showed an adenylate cyclase activity which is inhibited to about 80% of its original activity by 100 microM-EGTA. Measurements of the enzyme activity in the presence of 100 microM-EGTA and various concentrations of Ca2+ revealed an increase in enzyme activity of about 400%, indicating an adenylate cyclase which is dependent on Ca2+ for activity. Fluphenazine (1 mM), a blocker of the Ca2+-binding protein calmodulin, decreased enzyme activity to zero. The enzyme can be re-activated by the addition of certain concentrations of calmodulin to the assay medium. This suggests that crayfish muscle adenylate cyclase is dependent on Ca2+ and calmodulin for activity.     

Domoic acid inhibits adenylate cyclase activity in rat brain membranes

Adenylate cyclase activity measured by the formation of cyclic AMP in rat brain membranes was inhibited by a shellfish toxin, domoic acid (DOM). The inhibition of enzyme was dependent on DOM concentration, but about 50% of enzyme activity was resistant to DOM-induced inhibition. Rat brain supernatant resulting from 105,000×g centrifugation for 60 min, stimulated adenylate cyclase activity in membranes. Domoic acid abolished the supernatant-stimulated adenylate cyclase activity. The brain supernatant contains factors which modulate adenylate cyclase activity in membranes. The stimulatory factors include calcium, calmodulin, and GTP. In view of these findings, we examined the role of calcium and calmodulin in DOM-induced inhibition of adenylate cyclase in brain membranes. Calcium stimulated adenylate cyclase activity in membranes, and further addition of calmodulin potentiated calcium-stimulated enzyme activity in a concentration dependent manner. Calmodulin also stimulated adenylate cyclase activity, but further addition of calcium did not potentiate calmodulin-stimulated enzyme activity. These results show that the rat brain membranes contain endogenous calcium and calmodulin which stimulate adenylate cyclase activity. However, calmodulin appears to be present in membranes in sub-optimal concentration for adenylate cyclase activation, whereas calcium is present at saturating concentration. Adenylate cyclase activity diminished as DOM concentration was increased, reaching a nadir at about 1 mM. Addition of calcium restored DOM-inhibited adenylate cyclase activity to the control level. Similarly, EGTA also inhibited adenylate cyclase activity in brain membranes in a concentration dependent manner, and addition of calcium restored EGTA-inhibited enzyme activity to above control level. The fact that EGTA is a specific chelator of calcium, and that DOM mimicked adenylate cyclase inhibition by EGTA, indicate that calcium mediates DOM-induced inhibition of adenylate cyclase activity in brain membranes. While DOM completely abolished the supernatant-, and Gpp (NH)p-stimulated adenylate cyclase activity, it partly blocked calmodulin-, and forskolin-stimulated adenylate cyclase activity in brain membranes. These results indicate that DOM may interact with guanine nucleotide-binding (G) protein and/or the catalytic subunit of adenylate cyclase to produce inhibition of enzyme in rat brain membranes.     

Immunological distinction between calmodulin-sensitive and calmodulin-insensitive adenylate cyclases

Previous studies using calmodulin-Sepharose affinity chromatography have suggested that bovine brain may contain a mixture of calmodulin-sensitive and -insensitive adenylate cyclase activities (Wescott, K. R., La Porte, D. C., and Storm, D. R. (1979) Proc. Natl. Acad. Sci. U.S.A. 82, 3086-3090). In this study, mice were immunized with a purified preparation of the calmodulin-sensitive adenylate cyclase from bovine brain, and a polyclonal antiserum was obtained which was specific to the calmodulin-sensitive form of the enzyme. The antiserum was not inhibitory and precipitated enzyme activity from a homogeneous preparation of the calmodulin-sensitive adenylate cyclase catalytic subunit. Furthermore, the antiserum did not interact with calmodulin-insensitive adenylate cyclase which was resolved from the calmodulin-sensitive form of the enzyme by calmodulin-Sepharose affinity chromatography. Since the only polypeptide specifically precipitated by the antiserum had an Mr of 135,000, which was identical to the Mr of the catalytic subunit of the enzyme, it is concluded that the antiserum interacted directly and specifically with the catalytic subunit of the calmodulin-sensitive isozyme of adenylate cyclase. Detergent-solubilized membranes from several rat tissues were examined for the presence of calmodulin-sensitive adenylate cyclase using anti-calmodulin-sensitive adenylate cyclase antiserum. Approximately 40-60% of the total adenylate cyclase activity of rat brain and kidney were immunoprecipitated by the antiserum, whereas liver and testes contained no detectable calmodulin-sensitive adenylate cyclase. Approximately 15% of the total adenylate cyclase activity in rat heart and lung was the calmodulin-sensitive form. These data indicate that the calmodulin-sensitive and insensitive adenylate cyclases from bovine brain are immunologically distinct and support the proposal that there may be two or more distinct adenylate cyclase isozymes in brain.     

Guanylate cyclase. Subcellular distribution in cardiac muscle, skeletal muscle, cerebral cortex and liver.

1. Guanylate cyclase of every fraction studied showed an absolute requirement for Mn2+ ions for optimal activity; with Mg2+ or Ca2+ reaction was barely detectable. Triton X-100 stimulated the particulate enzyme much more than the supernatant enzyme and solubilized the particulate-enzyme activity. 2. Substantial amounts of guanylate cyclase were recovered with the washed particulate fractions of cardiac muscle (63-98%), skeletal muscle (77-93%), cerebral cortex (62-88%) and liver (60-75%) of various species. The supernatants of these tissues contained 7-38% of total activities. In frog heart, the bulk of guanylate cyclase was present in the supernatant fluid. 3. Plasma-membrane fractions contained 26, 21, 22 and 40% respectively of the total homogenate guanylate cyclase activities present in skeletal muscle (rabbit), cardiac muscle (guinea pig), liver (rat) and cerebral cortex (rat). In each case, the specific activity of this enzyme in plasma membranes showed a five- to ten-fold enrichment when compared with homogenate specific activity. 4. These results suggest that guanylate cyclase, like adenylate cyclase, and ouabain-sensitive Na+ + K+-dependent ATPase (adenosine triphosphatase), is associated with the surface membranes of cardiac muscle, skeletal muscle, liver and cerebral cortex; however, considerable activities are also present in the supernatant fractions of these tissues which contain very little adenylate cyclase or ouabain-sensitive Na+ + K+-dependent ATPase activities.     

Activation of adenylate cyclase by molybdate.

The effect of molybdate on adenylate cyclase (EC 4.6.1.1) in rat liver plasma membranes has been examined. The apparent K alpha for molybdate activation of the enzyme is 4.5 mM, and maximal, 7-fold stimulation is achieved at 50 mM. The observed increase in cAMP formation in the adenylate cyclase assay is not due to: (a) an inhibition of ATP hydrolysis; (b) a molybdate-catalyzed conversion of ATP to cAMP; (c) an inhibition of cAMP hydrolysis; or (d) an artifact in the isolation of cAMP formed in the reaction. Molybdate activation of adenylate cyclase is a general phenomenon exhibited by the enzyme in brain, cardiac, and renal tissue homogenates and in erythrocyte ghosts. However, like fluoride and guanyl-5'-yl imidodiphosphate (Gpp(NH)p), molybdate does not activate the soluble rat testicular adenylate cyclase. Molybdate is a reversible activator of adenylate cyclase. Activation is not due to an increase in ionic strength and is independent of the salt used to introduce molybdate. Molybdate does not activate adenylate cyclase previously stimulated with Gpp(NH)p or fluoride. At concentration greater than 20 mM, molybdate inhibits fluoride-stimulated adenylate cyclase, and at concentrations greater than 100 mM, molybdate stimulation of basal adenylate cyclase activity is diminished.     

Mechanism of molybdate activation of adenylate cyclase

Molybdate activation of rat liver plasma membrane adenylate cyclase has been examined and compared with the effect of glucagon, Gpp(NG)p and fluoride. Glucagon does not stimulate the detergent solubilized enzyme, though molybdate, fluoride, and Gpp(NH)p are effective in this regard. The stimulatory effects of either fluoride or molybdate are additive with those of GTP and do not require guanyl nucleotide to evoke their activation. Neither fluoride nor molybdate can substitute for GTP when glucagon is the activator of rat liver adenylate cyclase. The stimulatory effects of either ion on adenylate cyclase are additive with that produced by glucagon. Activation of adenylate cyclase by either molybdate or fluoride occurs by a mechanism distinct from that of glucagon or guanyl nucleotide. The data presented here suggest that fluoride and molybdate may act via a similar mechanism of action. Neither ion displays a lag in activation of adenylate cyclase. The pH profiles of fluoride and molybdate-stimulated adenylate cyclase activity are similar, and distinct from guanyl nucleotide-stimulated activity. Cholera toxin treatment of adenylate cyclase blocks fluoride and molybdate stimulation of the enzyme to the same extent, while enhancing the activation obtained with GTP and hormones.     

Protein activator of cyclic 3':5'-nucleotide phosphodiesterase of bovine or rat brain also activates its adenylate cyclase.

Bovine or rat brain adenylate cyclase (EC 4.6.1.1) solubilized by Lubrol PX contained an activator which was separated from the enzyme by an anionic exchange resin column. Dissociation of the activator from adenylate cyclase rendered the enzyme less active, and reconstituting with an exogenous activator restored full enzyme activity. A pure protein activator of cyclic 3′:5′-nucleotide phosphodiesterase (EC 3.1.4.17) isolated from bovine brain also stimulated this adenylate cyclase. Stimulation of adenylate cyclase by the activator required Ca⁺⁺, the effect being immediate and reversible. Although the activator was specific, it lacked tissue specificity; an activator isolated from bovine brain cross-activated effectively adenylate cyclase from rat, and vice versa. These findings indicate that brain adenylate cyclase required an activator for activity and that this activator is functionally identical to the protein activator of phosphodiesterase (J.B.C. 249: 4943–4954, 1974).     

Modulation of adenylate cyclase activity by Ca2+, phospholipid-dependent protein kinase in rat brain striatum

Summary The effects of purified Ca²⁺, phospholipid-dependent protein kinase (C-kinase) were studied on adenylate cyclase activity from rat brain striatum. C-kinase treatment of the membranes stimulated adenylate cyclase activity, the maximal stimulation between 50–80% was observed at 3.5 U/ml, whereas the catalytic subunit of cAMP dependent protein kinase did not show any effect on enzyme activity. The inclusion of Ca²⁺ and phosphatidyl serine did not augment the percent stimulation of adenylate cyclase by C-kinase, however EGTA inhibited the stimulatory effect of C-kinase on enzyme activity. Furthermore, the known inhibitors of C-kinase such as polymyxin-B and 1-(5-Isoquinoline sulfonyl)-2-methylpiperazine dihydrochloride (H-7) also inhibited the stimulatory effect of C-kinase on adenylate cyclase activity. In addition, in the presence of GTP the stimulatory effects of C-kinase on basal and N-Ethylcarboxamide adenosine- (NECA-), dopamine-(DA) and forskolin- (FSK) sensitive adenylate cyclase activities were augmented. On the other hand, the inhibitory effect of high concentrations of GTP on enzyme activity was attenuated by C-kinase treatment. In addition, oxotremorine inhibited adenylate cyclase activity in a concentration dependent manner, with an apparent Ki of about 10 µM and C-kinase treatment almost completely abolished this inhibition. These data suggest that C-kinase may play an important role in the regulation of adenylate cyclase activity possibly by interacting with a guanine nucleotide regulatory protein.Abbreviations C-kinase Ca^2– phospholipid-dependent protein kinase - NECA N-Ethylcarboxamide adenosine - DA Dopamine - FSK Forskolin - PMA Phorbol 12-(-Myristate), 13-Acetate, H-7, 1-(5-isoquinoline sulfonyl)-2-methylpiperazine dihydrochloride Presented in part at the VIth International Conference on Cyclic nucleotides, calcium and protein phosphorylation signal transduction in biological systems. September 2-6, 1986, Bethesda, MD (USA).M.B.A.-S. was Canadian Heart Foundation Scholar during the course of these studies.     

Activation of solubilized liver membrane adenylate cyclase by guanyl nucleotides.

Liver plasma membranes of hypophysectomized rats were purified, treated with 0.1 m Lubrol-PX and centrifuged at 165,000g for 1 h. The detergent solubilized 50% of the membrane protein; adenylate cyclase activity was present in the supernatant fraction. Optimal substrate concentration of the soluble enzyme was 0.32 mm ATP. Basal activity of 25 preparations of the solubilized enzyme ranged from 124 to 39 pmol cyclic AMP/mg protein/10 min. The solubilized enzyme retained the same sensitivity to activation by guanyl nucleotides as was present in the membrane preparation from which it was derived. Relative sensitivity of the solubilized enzyme with 0.1 mm nucleotides or -side was GDP > GTP > GMP > guanosine; GMP-PNP = GMP-PCP > ITP > GTP. GTP, GMP-PCP, GMP-PNP and other nucleotides were hydrolyzed by phosphohydrolases present in liver membranes that were solubilized with Lubrol-PX along with adenylate cyclase. The presence of the ATP regenerating system in the adenylate cyclase assay also aided in maintaining guanyl nucleotide concentrations. The degree of adenylate cyclase activation by guanyl nucleotides was not related to the sparing effects of nucleotides on substrate ATP hydrolysis. These findings demonstrate that activation of adenylate cyclase by nucleotides is a consequence of a nucleotide-enzyme interaction that is independent of membrane integrity.     

Pertussis Toxin Attenuates D2 Inhibition and Enhances D1 Stimulation of Adenylate Cyclase by Dopamine in Rat Striatum

The response of adenylate cyclase to GTP and to dopamine (DA) was investigated in synaptic plasma membranes isolated from rat striatum injected with pertussis toxin, which inactivates the inhibitory guanine nucleotide-binding regulatory protein (Ni) of adenylate cyclase. Pertussis toxin treatment reverted the inhibitory effects on the enzyme activity elicited by micromolar concentrations of GTP and reduced by 50% the DA inhibition of cyclase activity via D2 receptors. The toxin treatment enhanced the net stimulation of enzyme activity by DA in the presence of micromolar concentrations of GTP. However, the stimulatory effect of the selective D1 receptor agonist SKF 38393 was not significantly affected. The data indicate that Ni mediates D2 inhibition of striatal adenylate cyclase and participates in the modulation of D1 stimulation of the enzyme activity by DA.     

Subcellular location of adenylate cyclase in rat cardiac muscle

Crude homogenates of rat cardiac muscle were fractionated in order to examine the subcellular location of adenylate cyclase in this tissue. The fractionation procedure employed differential centrifugation of homonized material, followed by collagenase treatment, centrifugation on a discontinuous sucrose density gradient and extraction with 1 M KCl. The particulate fraction obtained by this procedure contained a high specific activity and yield of adenylate cyclase, moderate levels of mitochondria and low levels of sarcoplasmic reticulum and contractile protein as judged by marker enzyme activities. Adenylate cyclase was purified 20-fold with a 33% yield from the crude homogenate, while mitochondrial, sarcoplasmic reticulum and contractile protein yields were 5, 0.4 and 0.7% respectively. The membrane fractions prepared in this manner were examined by sodium dodecyl sulfate · gel electrophoresis.Adenylate cyclase copurified with ouabain-sensitive (Na⁺ + K⁺)-ATPase, a plasma membrane marker enzyme, and not with Ca²⁺-accumulating activity, which is associated with the sarcoplasmic reticulum. The distribution of marker enzyme activities indicates that heart adenylate cyclase is not located in the sarcoplasmic reticulum but is localized predominantly, if not exclusively, in the plasma membrane.     

Stimulation of rat liver adenylate cyclase by halothane.

Rat liver membranes prepared by a modification of the procedure of Neville were exposed to clinical and toxic concentrations of the general anesthetic, halothane, for 10 minutes. Basal, glucagon (5 × 10⁻⁵M) and sodium fluoride (20 mM) stimulated adenylate cyclase activity was assayed. Clinical and toxic concentrations of halothane augmented basal adenylate cyclase activity. Glucagon and sodium fluoride stimulated adenylate cyclase activity was enhanced at greater than clinically useful halothane concentrations only. The study provides direct evidence that halothane stimulates adenylate cyclase, the extent of augmentation of enzyme activity is halothane concentration dependent, and modified by other drugs.     

Regulation by adenosine of the vasopressin-sensitive adenylate cyclase in pig-kidney cells (LLC-PK1L) grown in defined media

LLC-PK1L cells, a kidney-derived cell line, had sustained growth in a defined medium. When compared to the parent cell line growing with 10% fetal bovine serum, LLC-PK1L cells had about 100-times fewer vasopressin receptors. Upon modifications of the cell culture medium, the vasopressin response of the adenylate cyclase could be increased by more than 10-fold with a parallel increase in vasopressin receptor number. Using cells with high or low receptor densities, the stimulatory and inhibitory effects of N6-L-2-phenylisopropyl-adenosine on the modulation of the adenylate cyclase responsiveness to vasopressin were investigated. When high concentrations of GTP were added, low concentrations of phenylisopropyladenosine inhibited the enzyme, while higher concentrations were found to be stimulatory. The adenylate cyclase activity stimulated by vasopressin could only be inhibited by phenylisopropyladenosine under these conditions in membranes with high receptor density; only the increase in enzyme activity due to high GTP concentration was inhibitable. The analysis of the dependency of the adenylate cyclase activity as a function of the vasopressin concentration showed that, besides reducing the maximum velocity of the system for vasopressin, the addition of phenylisopropyladenosine generated an heterogeneity in the adenylate cyclase response to vasopressin (as judged by a curvilinear Eadie plot). A high-affinity component in the adenylate cyclase response appeared when phenylisopropyladenosine was added. The growth of the cells in a medium containing adenosine deaminase gave results identical to those obtained for control cells. However, growing the cells with both phenylisopropyladenosine and adenosine deaminase abolished the inhibitory effects of the former on the adenylate cyclase and greatly reduced its stimulatory action. Under these conditions, the vasopressin response of the adenylate cyclase was not further regulated by phenylisopropyladenosine. These results indicate a role of adenosine on vasopressin response, especially at low physiological concentrations of the hormone where a high-affinity component of the hormonal response could be demonstrated.     

Stimulation of mammalian adenylate cyclase activity with guanosine 5′-tetraphosphate and other guanine nucleotides

Guanosine 5′-tetraphosphate (GTP₄) stimulated mammalian adenylate cyclase activity at concentrations down to 1 μM. Greater stimulatory activity was apparent with lung than with heart, brain or liver from the rat. At a concentration of 0.1 mM, GTP₄ stimulated lung adenylate cyclase activity from rat, guinea pig and mouse about four-fold. Other guanine nucleotides such as GTP, GDP, GMP, guanosine 3′, 5′-monophosphate and 5′-guanylylimidodiphosphate (GMP · PNP) also stimulated mammalian adenylate cyclase activity. GMP · PNP irreversibly activated, whereas GTP₄ and GTP reversibly activated adenylate cyclase. Adenosine 5′-tetraphosphate (ATP₄) stimulated rat lung and liver but inhibited rat heart and brain adenylate cyclase activities. Lung from guinea pig and mouse were not affected by ATP₄. The formation of cyclic AMP by GTP₄-stimulated rat lung adenylate cyclase was verified by Dowex-50 (H⁺), Dowex 1-formate and polyethyleneimine cellulose column chromatography. GTP₄ was at least three times more potent than 1-isoproterenol in stimulating rat lung adenylate cyclase activity. The β-adrenergic receptor antagonist propranolol blocked the effect of 1-isoproterenol but not that of GTP₄, thus, suggesting that GTP₄ and β-adrenergic agonists interact with different receptor sites on membrane-bound adenylate cyclase. Stimulation of rat lung and liver adenylate cyclase activities with 1-isoproterenol was potentiated by either GTP₄ or GMP. PNP, thus indicating that GTP₄ resembles other guanine nucleotides in their capacity to increase the sensitivity of adenylate cyclase to β-adrenergic agonists. Stimulation of adenylate cyclase activity by guanine derivatives requires one or more free phosphate moieties on the 5 position of ribose, as no effect was elicited with guanine, guanosine, guanosine 2′-monophosphate, guanosine 3′-monophosphate or guanosine 2′,5′-monophosphate. Ribose, ribose 5-phosphate, phosphate and pyrophosphate were inactive. Pyrimidine nucleoside mono-, di-, tri- and tetraphosphates elicited negligible effects on mammalian adenylate cyclase activity.