Presence of “Ra” and “P”-site receptors for adenosine coupled to adenylate cyclase in cultured vascular smooth muscle cells

The existence of adenosine receptors coupled to adenylate cyclase in cultured vascular smooth muscle cells from rat aorta is demonstrated in these studies. Adenosine, N⁶-phenylisopropyladenosine, adenosine N′-oxide and 2-chloroadenosine stimulated adenylate cyclase in a concentration dependent manner. The stimulation was dependent on the presence of guanine nucleotides and was blocked by 3-isobutyl-1-methylxanthine. In contrast, 2′ deoxyadenosine inhibited adenylate cyclase activity. Adenosine and 2-chloroadenosine showed a biphasic effect on adenylate cyclase, stimulation occurred at low concentrations. The activation of adenylate cyclase by N⁶-phenylisopropyladenosine was also dependent on the Mg²⁺ concentration. The data suggest that vascular smooth muscle cells have both “Ra” and “P” receptors for adenosine, and it can be postulated that the relaxant effect of adenosine on vascular smooth muscle may be mediated by its interaction with “Ra” receptors associated with adenylate cyclase.     

Purinergic regulation of basal and arginine vasopressin-stimulated hydraulic conductivity in rabbit cortical collecting tubule

Summary An extracellular adenosine responsive site that stimulates adenylate cyclase activity has been identified in several tissues. There is limited information on the presence and physiologic significance of adenosine receptors in well-defined segments of the mammalian nephron. We therefore examined the effect of adenosine and selected analogues on basal hydraulic conductivity in rabbit cortical collecting tubules (CCT) perfused in vitro. Adenosine and analogues with an intact ribose moiety produced a significant, sustained increase in hydraulic conductivity. No increase in hydraulic conductivity was seen in either time control CCT's or CCT's exposed to an adenosine analogue with an altered ribose moiety. These experiments are compatible with the presence of a functional adenosine receptor which requires an intact ribose moiety and acts to increase hydraulic conductivity in the mammalian CCT.An intracellular adenosine responsive site, termed the P site, which inhibits adenylate cyclase activity, has also been described in several tissues. We therefore examined the effect of aP site agonist on hydraulic conductivity responses to arginine vasopressin, forskolin and cAMP.P site stimulation with 25 dideoxyadenosine inhibited the effect of AVP and of forskolin but not of cAMP to increase hydraulic conductivity. These results are compatible with a functionalP site in the rabbit CCT which acts at the catalytic subunit of adenylate cyclase to inhibit hydraulic conductivity. Together, these results demonstrate purinergic modulation of basal and arginine vasopressin-stimulated water flux in the mammalian collecting tubule.     

Recognition of Ribose Moiety by Adenosine (Phosphate) Deaminase from Squid Liver

An adenosine (phosphate) deaminase from the squid liver had much lower activity for 5′-deoxyadenosine than that for adenosine, 2′-, or 3′-deoxyadenosine. 3′-IMP and inosine as well as purine riboside and adenine competitively inhibited the deamination of adenosine 3′ phenylphosphonate by the enzyme, but 5′-AMP and 5′-IMP did not. The enzyme deaminated the 5′-hydroxyl terminal adenosine residue in dinucleotides and trinucleotide, but not the 3′-hydroxyl terminal one in dinucleotides. The 5′-hydroxyl group of the ribose moiety was necessary for the substrate binding and catalytic activity of the squid enzyme. These results indicated that the recognition of ribose moiety in the substrate by the squid enzyme might be intermediate between those by adenosine deaminase and adenosine (phosphate) deaminase from microorganisms.     

Solubilization and conversion of hepatic adenylate cyclase to a form requiring MnATP as substrate

A general feature of membrane-bound adenylate cyclase systems is the “lability” of the basal enzyme to dispersion by detergents. A stable form of the detergentsolubilized enzyme is obtained only if the membrane-bound enzyme is first pretreated with fluoride or Gpp(NH)p. However, we have found with the basal hepatic enzyme that the lability is evident primarily when MgATP is used as substrate; substitution of MnATP for MgATP reveals that substantial basal activity survives detergent treatment. This effect is independent of the detergent; it is seen with either Lubrol PX or with deoxycholate. In addition to the altered substrate requirement, the membrane-bound and solubilized forms of the basal enzyme exhibit other differences. In contrast to the membrane-bound form, the solubilized enzyme shows (1) weak stimulation by Gpp(NH)p; (2) little inhibition by adenosine, (3) strong inhibition by P_i or PP_i, and (4) and apparent loss of the Me²⁺-reactive regulatory site. Such dissimilarities between membranebound and solubilized cyclase are not seen if the membranes are pretreated with Gpp(NH)p prior to exposure to detergents. The characteristics of the solubilized basal hepatic enzyme are similar to those of the naturally occurring soluble adenylate cyclase found in mature rat testes. It would appear that separation of adenylate cyclase from components that confer regulation by divalent cation and guanine nucleotides produces a form of the enzyme that will turnover only MnATP; this may represent the free catalytic moiety. Such preparations could be useful in reconstructing some of the regulatory functions of adenylate cyclase seen in its membrane-bound form.     

Effects of adenosine and adenosine-analogs on adenylate cyclase activity in the rat adipocyte plasma membrane: comparison of the properties of the enzyme with Mn2+ and Mg2+ as divalent cations

Summary We investigated the influence of Mg²⁺ and Mn²⁺ on the effects of adenosine and some derivatives on basal adenylate cyclase activity in rat fat cell membranes as well as on enzyme activity stimulated by isoprenaline or sodium fluoride. Adenosine and derivatives modified in the ribose function were inhibitory, irrespective of the stimulant used, both in the presence of MgCl₂ or MnCl₂. Inhibition of basal and sodium fluoride stimulated adenylate cyclase activity was more pronounced in the presence of MnCl₂ than in the presence of MgCl₂. N⁶-substituted adenosine analogs proved to be inhibitory in the presence of 5 MM MgCl₂, but in the presence of 1 mM MnCl₂ the fluoride stimulated adenylate cyclase activity was potentiated, while basal and isoprenaline stimulated activity were not significantly inhibited. These effects of adenosine and derivatives could not be blocked by theophylline with or without guanyl nucleotides.The potentiating effect of N⁶-substituted adenosine derivatives on sodium fluoride activated adenylate cyclase is dependent on the structure of the N₆-substitutent and consists of an enhancement of Vrnax in combination with a small decrease of the K_m for MnATP^2–, indicative of an allosteric effect on adenylate cyclase. No potentiation by N⁶-phenylisopropyladeno sine of sodium fluoride stimulated cyclase was found on digitonin solubilized cyclase, while the inhibitory effect of adenosine was retained. The relevance of these findings is discussed in connection with the current hypothesis concerning the presence of two adenosinesensitive sites on rat fat cell membranes.     

Inhibition of nuclear protein kinases by adenosine analogues

Two cyclic AMP-independent protein kinases from rat liver nuclei were inhibited competitively by adenosine and a variety of its analogues: cardycepin, tubercidin, 6-mercaptopurine riboside, 6-methylaminopurine riboside, 6-dimethylaminopurine riboside, and 2'-deoxyadenosine. Neither enzyme was inhibited by 6-methoxypurine riboside. Kinase NI was more sensitive to cordycepin, tubercidin, 6-methylaminopurine riboside,, 2'-deoxyadenosine, and adenosine than was kinase NII. Although the effects of all analogues tested were reversed by increasing the concentration of ATP, kinases NII and NI exhibited marked differences in their affinities for adenosine. The results presented here suggest that 1) differences in the catalytic properties of nuclear protein kinases can be detected by inhibitor studies and 2) modifications in the purine ring and sugar moiety of an adenosine analogue can alter its ability to inhibit nuclear protein kinases.     

Regulation of adenylate cyclase by adenosine

Summary Adenosine may well be as important in the regulation of adenylate cyclase as hormones. Sattin and Rall first demonstrated in 1970 that adenosine was a potent stimulator of adenylate cyclase in the brain. However, adenosine is an equally potent inhibitor of adenylate cyclase in other cells such as adipocytes. The concentration of adenosine required for this regulation of adenylate cyclase is in the nanomolar range (10 to 100 nm). Both the inhibitory and stimulatory effects of low concentrations of adenosine on adenylate cyclase are antagonized by methylxanthines. This antagonism of adenosine action may account for all or part of the effects of methyl xanthines on cyclic AMP levels in many tissues. Adenosine appears to be a particularly important endogenous regulator of adenylate cyclase in brain, smooth muscle and fat cells. Under conditions in which intracellular AMP rises, adenosine formation and release is accelerated. In addition to its direct effects on adenylate cyclase, adenosine (at higher concentrations approaching millimolar) exerts multiple effects on cellular metabolism as a result of its intracellular metabolism and especially conversion to nucleotides.The effects of nanomolar concentrations of adenosine on adenylate cyclase are mediated through an adenosine site possessing strict structural specificity for the ribose moiety of the molecule (the R adenosine site) which is presumably located on the external surface of the plasma membrane. In brain, lung, platelets, bone, lymphocytes, skin, adrenals, Leydig tumors, and coronary arteries adenosine stimulates adenylate cyclase via this site. However, in rat adipocytes, brain astroblasts and ventricular myocardium adenosine inhibits adenylate cyclase through the R or adenosine site. Although the R site requires an intact ribose moiety, adenosine analogs modified in the purine ring such as N⁶-phenylisopropyladenosine appear to be potent agonists for this site. All effects of adenosine mediated via the R site are competitively antagonized by methyl xanthines.The effects of micromolar concentrations of adenosine appear to be mediated via a site with strict structural specificity with respect to the purine moiety of the molecule (the P or adenine adenosine site). This P site is postulated to be located on the intracellular face of the plasma membrane and mediates the effects of adenosine due to conversion of adenosine to 5-AMP or perhaps other nucleotides. The effects of high concentrations of adenosine are always inhibitory to adenylate cyclase activity, are readily demonstrated in broken cell preparations, and are unaffected by methylxanthines. An intact purine ring is required for these adenosine effects but modifications of the ribose moiety of the molecule generally increases the potency of the analog. A prime example is 2,5-dideoxyadenosine, which is the most potent known R-site specific adenosine analog.We propose a unitary model which explains both the stimulatory and inhibitory effects of low concentrations of adenosine on adenylate cyclase. In brief, adenylate cyclase is postulated to exist in three interconvertible activity states: (i) an inactive state (E₀); (ii) a GTP-liganded state with high activity (E_GTP); and (iii) a GDP-liganded state (E_GDP) which is inactive in cells where adenosine stimulates adenylate cyclase, but active in cells where adenosine inhibits adenylate cyclase. We postulate that the enzyme cycles through these states in the following manner: the E₀ state binds GTP and forms the E_GTP state; hydrolysis of bound GTP converts the E_GTP to the E_GDP state; and release of bound GDP converts E_GDP to the E₀ state. The E₀ state is the only form of the enzyme which can be stimulated by either hormones or GTP and its formation from the E_GDP state is rate-limiting in this cycle. The conversion of E_GDP to E₀ regulates the ability of hormones and GTP to activate adenylate cyclase and is postulated to be adenosine sensitive.In cells where both E_GDP and E₀ states are inactive, adenosine stimulates adenylate cyclase activity. In cells where E₀ is inactive, but E_GDP is active, adenosine inhibits adenylate cyclase activity. In addition we suggest that in cells where adenosine inhibits adenylate cyclase activity (cells postulated to have an E_GDP state which is active) high concentrations of GTP favor accumulation of the enzyme in E_GDP and thus are inhibitory to activity. Prostaglandins may also regulate adenylate cyclase in a manner similar to that described above for adenosine.We conclude that adenosine is an important regulator of adenylate cyclase whose role has only been appreciated recently. Further studies are warranted on both its binding to cells and mechanisms by which it regulates adenylate cyclase.This work was supported by United States Public Health Service Research Grant AM-10149 from the National Institute of Arthritis, Metabolism and Digestive Diseases.     

“Reverse” Carbocyclic Fleximers: Synthesis of a New Class of Adenosine Deaminase Inhibitors

A series of flexible carbocyclic pyrimidine nucleosides has been designed and synthesized. In contrast to previously reported “fleximers” from our laboratory, these analogues have the connectivity of the heterocyclic base system “reversed”, where the pyrimidine ring is attached to the sugar moiety, rather than the five membered imidazole ring. As was previously seen with the ribose fleximers, their inherent flexibility should allow them to adjust to enzyme binding site mutations, as well as increase the affinity for atypical enzymes. Preliminary biological screening has revealed surprising inhibition of adenosine deaminase, despite their lack of resemblance to adenosine.     

Specific MG2+ and adenosine sites involved in a bireactant mechanism for adenylate cyclase inhibition and their probable localization on this enzyme's catalytic component.

The specificity of adenosine sites involved in adenylate cyclase inhibition (P sites) is identical on membrane-bound and on solubilized enzyme. Kinetic analysis indicates that in addition to a low affinity Mg²⁺ site involved in adenylate cyclase stimulation (Km = 10 mM), there is a high affinity Mg²⁺ site (Km = 2.10^?4M) involved together with P sites in a bireactant mechanism for triggering adenylate cyclase inhibition. Guanyl nucleotide-binding protein does not seem to be implicated in this inhibition. We were not able to separate the catalytic component of adenylate cyclase from P sites, either on a sucrose density gradient or in gel filtration experiments. It is suggested that P sites are located on the catalytic component of the enzyme.     

Adenosine Inhibition of Calmodulin-Sensitive Adenylate Cyclase from Bovine Cerebral Cortex

Calmodulin (CaM)-sensitive adenylate cyclase has recently been purified extensively from bovine brain. In this study, the sensitivity of the CaM-sensitive adenylate cyclase to adenosine and adenosine analogs was examined. The highly purified enzyme preparation retained sensitivity to inhibition by adenosine and adenosine analogs with ribose ring modifications, but not to those with purine ring modifications. Adenosine inhibition of this enzyme was not dependent on GTP and was noncompetitive with respect to ATP. Enzyme that had been dissociated from functional guanine nucleotide binding protein interactions by gel filtration in the presence of the zwitterionic detergent 3-[3-(cholamidopropyl)-dimethylammonio]-propanesulfonate and Mn2+ retained sensitivity to adenosine inhibition. The Ki for adenosine inhibition of the CaM-sensitive adenylate cyclase was approximately 2.6 X 10(-4) M. 5'-Guanylylimidodiphosphate and CaM did not affect the Ki of 3'-deoxyadenosine for the enzyme, but the presence of Ca2+ in the millimolar range raised the Ki by a factor of 5. These results show that the CaM-sensitive form of adenylate cyclase from bovine brain is subject to adenosine inhibition, and strongly suggest that this inhibition is due to interaction of ligands with a purine-specific ("P") site located on the catalytic subunit of the enzyme.     

Regulation of adenylate cyclase in cultured cardiocytes from neonatal rats by adenosine and other agonists

The presence of adenosine receptors coupled to adenylate cyclase in cultured cardiocytes from atria and ventricles from neonatal rats is demonstrated in these studies. N-Ethylcarboxamideadenosine (NECA), l-N⁶-phenylisopropyladenosine (PIA), and 2-chloroadenosine (2-cl-Ado) stimulated adenylate cyclase in a concentration-dependent manner in both cultured atrial and ventricular cells. The order of potency of stimulation was NECA > PIA > 2-cl-Ado. The stimulation of adenylate cyclase by NECA was enhanced by guanine nucleotides and was blocked by 3-isobutyl-1-methylxanthine in both these cells. Other agonists such as epinephrine, norepinephrine, dopamine, F^?, and forskolin were also able to stimulate adenylate cyclase, although the extent of stimulation by these agents was higher in ventricular than in atrial cells. The stimulation of adenylate cyclase by epinephrine and norepinephrine was inhibited by propranolol but not by phentolamine. On the other hand, phentolamine, propranolol, and haloperidol inhibited dopamine-stimulated adenylate cyclase activity to the same extent. Forskolin, at its maximal concentration, potentiated the stimulatory effect of epinephrine, norepinephrine, and dopamine on adenylate cyclase in both atrial and ventricular cardiocytes, but the interaction of NECA with epinephrine, norepinephrine, or dopamine was different in atrial and ventricular cells. The stimulation by an optimal concentration of NECA was additive with maximal stimulation by the catecholamines in atrial cells but not in ventricular cells. The data suggest the existence of adenosine “Ra” and catecholamine receptors in cultured atrial and ventricular cardiocytes. It can be postulated that adenosine in addition to its role as a potent vasodilator might regulate cardiac performance through its interaction with “Ra” receptors associated with adenylate cyclase. The difference in the mode of interaction of adenosine with catecholamines in atrial and ventricular cells suggests that the mechanism by which these agents activate adenylate cyclase may be different in these cells.     

Apparent “negative cooperativity” kinetics in the absence of a nonlinear Scatchard plot of thyrotropin-receptor interaction in a human thyroid adenoma

A human thyroid adenoma (benign nodule) was identified which exhibited a linear Scatchard plot of ¹²⁵I-TSH binding, characteristic of a single class of binding site with high affinity (K_d = 0.5±0.1 nM) and low binding capacity (0.8±0.2 pmol/mg protein). In contrast, Scatchard analysis of binding to adjacent normal thyroid was nonlinear, suggesting the presence of high and low-affinity binding sites with K_d's of 0.4±0.2 and of 27.9±11.0 nM and capacities of 0.7±0.3 and 1.8±1.0 pmol/mg protein, respectively. Dissociation of bound ¹²⁵I-TSH from membranes of both adenoma and normal tissue revealed identical enhancement of dissociation in the presence of excess native hormone, thought to be evidence for the “negative cooperativity” model of hormone-receptor interaction. Furthermore, adenylate cyclase from both tissues was equally responsive to TSH. Thus, a thyroid adenoma which contains TSH-responsive adenylate cyclase still exhibited enhanced dissociation by native hormone, even though Scatchard analysis yielded a single, non-cooperative class of binding sites. This suggests that enhanced dissociation of bound hormone does not provide a demonstration of negatively-cooperative site-site interaction. Furthermore, nonlinear Scatchard plots, typical of TSH binding in normal thyroid, represent two classes of binding sites, of which the high affinity type is responsible for stimulation of adenylate cyclase.     

Synthesis of 2′-Deoxyformycin B and 2′-Deoxyoxoformycin B

Abstract

3-β-D-Ribofuranosylpyazolo[4,3-d]pyrimidines (formycins)¹ modified in the heteroaromatic moiety are of biological interest as analogues of adenosine and guanosine, and have been the objects of intensive synthetic chemical effort by several groups.^2-9 2′-Deoxynucleosides^2c,2d,7b,13 and other analogties of the formycins modified in the sugar moiety^10-12 are also of potential interest, but have been less extensively studied. Examples of the 2′-deoxyribonucleoside type known to date include the 2′-deoxy-6-thioguanosine analogue 1, the 2′-deoxyadenosine (dAdo) analogue 2 (2′-deoxyformycin A),^10,13 and the 2-chloro-2′-deoxyadenosine analogue 3.^7b Compound 2 was found to be 10-15 times more potent than 2′-deoxyadenosine as an inhibitor of the growth of S49 cells, a murine lymphoma line of T-cell origin.¹³ Activity depended on 5′- phosphorylation, since mutants lacking the enzymes adenosine kinase (AK) and deoxycytidine kinase (dCK) were insensitive to the drug. Furthermore, activity was comparable in the presence and absence of an AK inhibitor, suggesting that 2, unlike dAdo, may be a poor substrate for adenosine deaminase. That 5′-phosphorylation of 2 was mediated by AK rather than dCK was indicated by the fact that miitants lacking only dCK retained sensitivity. This contrasted with the behavior of dAdo, which is known to be n substrate for both AK and dCK.¹⁴     

The molecular size of adenylate cyclase in the absence and presence of nucleotide and hormone effectors

The molecular size of adenylate cyclase solubilized from frog erythrocyte membranes by digitonin extraction has been determined by chromatography on Sepharose 6B. Regardless of whether the membranes are exposed to catecholamines, GPP(NH)P, NaF or no effector prior to solubilization, the apparent molecular size of the adenylate cyclase enzyme is the same. Furthermore, a similar elution profile for the enzyme is observed when the catalytic activity in the eluates is measured in the presence of Mn++, rather than Mg++. Since it is generally assumed that the persistent activation of adenylate cyclase by GPP(NH)P requires interaction of the catalytic moiety with the guanine nucleotide regulatory site, it appears that the adenylate cyclase activity detected in the column eluates represents an intact catalytic-regulatory site complex. The adenylate cyclase activity derived from catecholamine pretreated frog erythrocyte membranes does not co-elute with catecholamine-occupied beta-adrenergic receptors, indicating that the agonist-promoted increase in apparent receptor size observed here and in earlier studies does not represent a physical coupling of the receptor and the adenylate cyclase enzyme.     

Adenosine and gpp(NH)p modulate mouse sperm adenylate cyclase

The possible roles of adenosine and the GTP analogue Gpp(NH)p in regulating mouse sperm adenylate cyclase activity were investigated during incubation in vitro under conditions in which after 30 min the spermatozoa are essentially uncapacitated and poorly fertile, whereas after 120 min they are capacitated and highly fertile. Adenylate cyclase activity, assayed in the presence of 1 mM ATP and 2 mM Mn²⁺, was determined by monitoring cAMP production. When adenosine deaminase (1 U/ml) was included in the assay to deplete endogenous adenosine, enzyme activity was decreased in the 30-min suspensions but increased in the 120-min samples (P < 0.02). This suggests that endogenous adenosine has a stimulatory effect on adenylate cyclase in uncapacitated spermatozoa but is inhibitory in capacitated cells. Since the expression of adenosine effects at low nucleoside concentrations usually requires guanine nucleotides, the effect of adding adenosine in the presence of 5 x 10^–5 M Gpp(NH)p was examined. While either endogenous adenosine or adenosine deaminase may have masked low concentration (10^?9?10^?7 M) effects of exogenous adenosine, a marked inhibition (P < 0.001) of adenylate cyclase activity in both uncapacitated and capacitated suspensions was observed with higher concentrations (>10^?5 M) of adenosine. Similar inhibition was also observed in the absence of Gpp(NH)p, suggesting the presence of an inhibitory P site on the enzyme. In further experiments, the effects of Gpp(NH)p in the presence and absence of adenosine deaminase were examined. Activity in 30-min suspensions was stimulated by the guanine nucleotide and in the presence of adenosine deaminase this stimulation was marked, reversing the inhibition seen with adenosine deaminase alone. In capacitated suspensions the opposite profile was observed, with Gpp(NH)p plus adenosine deaminase being inhibitory; again, this was a reversal of the effects obtained in the presence of adenosine deaminase alone, which had stimulated enzyme activity. These results suggest the existence of a stimulatory adenosine receptor site (R_a) on mouse sperm adenylate cyclase that is expressed in uncapacitated spermatozoa and an inhibitory receptor site (R_i) that is expressed in capacitated cells, with guanine nucleotides modifying the final response to adenosine. It is concluded that adenosine and guanine nucleotides may regulate mouse sperm adenylate cyclase activity during capacitation.     

Deaza-analogues of Adenosine and 2-Chloroadenosine as Agonists of Adenosine Receptors

Abstract

A variety of adenosine analogues have been recently evaluated in order Lo find more potent and selective agonists on adenosine receptors. The most potent adenosine analogues acting on A₁ receptor, a high affinity receptor inhibitory to adenylate cyclase, are N⁶-substituted compounds. So ⁶-cyclohexyladenosine (CHA) and ⁶-L-phenylisopropyladenosine (L-PIA) are extremely potent agonists on A₂ receptor, whereas they are relatively weak agonists on A receptor, a lower affinity receptor which is stirnulatory to cyclase, and they have no effect on the adenosine P site.     

Adenosine receptors in the central nervous system: relationship to the central actions of methylxanthines

Adenosine has a significant role in many functions of the central nervous system. Behaviorally, adenosine and adenosine analogs have marked depressant effects. Electrophysiologically, adenosine reduces spontaneous neuronal activity and inhibits transsynaptic potentials $\text{via}$ interaction with extracellular receptors. Biochemically, adenosine inhibits adenylate cyclase $\text{via}$ a “high” affinity receptor, and activates adenylate cyclase $\text{via}$ a “low” affinity receptor. These receptors, called “A₁” and “A₂” respectively, show differing profiles for activation by adenosine analogs. Radioactive N⁶-cyclohexyladenosine binds selectively to the “high” affinity receptor. One major class of antagonists is known at adenosine receptors: the alkylxanthines, including caffeine and theophylline. Radioactive 1,3-diethyl-8-phenylxanthine, a particularly potent antagonist, appears to bind to both low and high affinity adenosine receptors. Behavioral, electrophysiological, and biochemical effects of alkylxanthines are consistent with the hypothesis that the central stimulatory actions of caffeine and theophylline are due in large part to antagonism of central adenosine receptors.     

The role of phospholipids in TSH stimulation of adenylate cyclase in thyroid plasma membranes

Treatment of bovine thyroid plasma membranes with phospholipase A or C inhibited the stimulation of adenylate cyclase activity by thyroid-stimulating hormone (TSH). In general, basal and NaF-stimulated adenylate cyclase activity was not influenced by such treatment. When plasma membranes were incubated with 1–2 units/ml phospholipase A, subsequent addition of phosphatidylcholine or phosphatidylserine but not phosphatidylethanolamine partially restored TSH stimulation. Phosphatidylcholine was more effective than phosphatidylserine in that it caused greater restoration of the TSH response and smaller amounts of phosphatidylcholine were active. However, when the TSH effect was obliterated by treatment of plasma membranes with 10 units/ml phospholipase A, phospholipids were unable to restore any response to TSH. Lubrol PX, a nonionic detergent, inhibited basal, TSH- and NaF-stimulated adenylate cyclase activities in thyroid plasma membranes. Although phosphatidylcholine partially restored TSH stimulation of adenylate cyclase activity in the presence of Lubrol PX, it did not have a similar effect on the stimulation induced by NaF. These results indicate that phospholipids are probably essential components in the system by which TSH stimulates adenylate cyclase activity in thyroid plasma membranes. The effects do not seem to involve the catalytic activity of adenylate cyclase but the data do not permit a distinction between decreased binding of TSH to its receptor or impairment of the signal from the bound hormone to the enzyme activity.     

The effect of gonadotropins on the mitochondrial adenylate cyclase of rat testis

The formation of adenosine 3′:5′-cyclic monophosphate from ATP by testicular mitochondria of immature and mature rats was increased to the same extent by addition of either human chorionic gonadotropin or luteinizing hormone. Follicle stimulating hormone was found to be more active in stimulating adenylate cyclase activity in testicular mitochondria of immature rats. The stimulatory effect of gonadotropins were not suppressed by Ca⁺⁺ complexing agent ethylene-glycol-bis-(β-amino-ethyl ether) N,N′-tetra-acetic acid. The detergent Lubrol PX, solubilized 75–80% of the mitochondrial adenylate cyclase. The solubilized enzyme was activated by sodium fluoride but not by gonadotropins. The present results indicate a direct effect of gonadotropins on the adenylate cyclase attached to mitochondrial membranes.     

Multiple effects of guanine nucleotides on human platelet adenylate cyclase

We report that the adenylate cyclase system in human platelets is subject to multiple regulation by guanine nucleotides. Previously it has been reported that GTP is either required for or has little effect on the response of the enzyme to prostaglandin E₁. We have found that when platelet lysates were prepared in the presence of 5 mM EDTA, GTP lowered the basal and prostaglandin E₁-stimulated adenylate cyclase activity when the enzyme was assayed in the presence of Mg²⁺. The basal and prostaglandin E₁-stimulated adenylate cyclase activities were also increased by washing, which presumably removes endogenous GTP. The analog, guanyl-5′-yl-imidodiphosphate mimics the inhibitory effect of GTP on prostaglandin E₁-stimulated adenylate cyclase activity but it stimulates basal enzyme activity. The onset of the inhibitory effect of GTP on the adenylate cyclase system is rapid (1 min) and is maintained at a constant rate during incubation for 10 min. GTP and guanyl-5′-yl-imidodiphosphate were noncompetitive inhibitors of prostaglandin E₁. An increase in the concentration of Mg²⁺ gradually reduces the effect of GTP while having little influence on the effect of guanyl-5′-yl-imidodiphosphate. Neither the substrate concentration nor the pH (7.2–8.5) is related to the inhibitory effect of guanine nucleotides. The inhibition by nucleotides was found to show a specificity for purine nucleotides with the order of potency being guanyl-5′-yl-imidodiphosphate > dGTP > GTP > ITP > XTP > CTP > TTP. The inhibitory effect of GTP is reversible while the effect of guanyl-5′-yl-imidodiphosphate is irreversible. The GTP inhibitory effect was abolished by preparing the lysates in the presence of Ca²⁺. However, the inhibitory effect of guanyl-5′-yl-imidodiphosphate persisted. Substitution of Mn²⁺ for Mg²⁺ in the assay medium resulted in a diminution of the inhibitory effect of GTP on basal activity and converted the inhibitory effect of GTP on prostaglandin E₁-stimulated activity to a stimulatory effect. At a lower concentration of Mn²⁺ (less than 2 mM) guanyl-5′-yl-imidodiphosphate inhibited prostaglandin E₁-stimulated adenylate cyclase activity, but at a higher concentration of Mn²⁺, it caused an increase in enzyme activity exceeding that occuring in the presence of prostaglandin E₁. In the presence of Mn²⁺, dGTP mimics the effect of GTP and is 50% as effective as GTP. Our data suggest that the inhibitory effect of GTP on prostaglandin E₁-stimulated adenylate cyclase is mainly due to its direct effect on the enzyme itself, whereas the stimulatory effect of GTP on prostaglandin E₁-stimulated adenylate cyclase is due to enhancement of the coupling between the prostaglandin E₁ receptor and adenylate cyclase. These studies also indicate that the method of preparation of platelet lysates can profoundly alter the nature of guanine nucleotide regulation of adenylate cyclase.