Determination of the turn-off reaction for the hormone-activated adenylate cyclase.

Previous work suggested that hormonal activation of adenylate cyclase involves the introduction of GTP to the regulatory site, and subsequent hydrolysis of the bound GTP terminates the activation. In many tissues the turn-off GTPase reaction cannot be readily measured because of a high background of nonspecific GTP hydrolysis. To circumvent this problem a general assay for the turn-off reaction has now been developed. The adenylate cyclase is first activated by hormone and GTP and the introduction of GTP is then stopped either by addition of an excess of guanosine 5'-O-(2-thiodiphosphate) (GDP beta S) or by addition of a receptor blocking agent. The decay of adenylate cyclase activity brought on by these inhibitors is used to calculate the rate constant of the turn-off reaction. In turkey erythrocyte and rat parotid membranes the rate constant of the decay process as determined with GDP beta S is similar to that determined with the beta-adrenergic blocker propranolol. The rate constants (min-1 at 30 degrees C) for various adenylate cyclase preparations are 10 for turkey erythrocyte, 7.5 for rat parotid, and 6.2 for the rat liver enzyme. The finding of similar rate constants in the various preparations indicates that GTP hydrolysis at the regulatory site is a general mechanism for terminating the activation of adenylate cyclase.     

The regulatory GTPase cycle of turkey erythrocyte adenylate cyclase.

It has recently been suggested that adenylate cyclase activity is controlled by a regulatory cycle consisting of two reactions: a hormone induced formation of the active adenylate cyclase-GTP complex, and a subsequent turn-off reaction in which hydrolysis of the bound nucleotide reverts the system to the inactive state. To test this model each of the two reactions was measured separately and their rate constants were used to estimate the steady state adenylate cyclase and GTPase activities. The first order rate constants were kon = 3 min-1 for the activation reaction and koff = 15 min-1 for the turn-off reaction. Substitution of these rate constants in the steady state equation of the regulatory cycle gave values of hormone stimulated adenylate cyclase and GTPase activities similar to those determined by direct measurements. Treatment of the adenylate cyclase with cholera toxin caused a decrease of 96% in the rate constant of the turn-off reaction. In this case too the activities calculated from the steady state equation were in good agreement with those determined directly.     

Uncoupling of alpha-adrenoceptor-mediated inhibition of human platelet adenylate cyclase by N-ethylmaleimide

Human platelet adenylate cyclase is stimulated by prostaglandin E1 (PGE1) and is inhibited by epinephrine via alpha-adrenoceptors. Both agonists, epinephrine more than PGE1, increase the activity of a low Km GTPase in platelet membranes. Pretreatment of intact platelets or platelet membranes with the sulfhydryl reagent, N-ethylmaleimide (NEM), abolished the inhibition of the adenylate cyclase and the concomitant stimulation of the GTPase by epinephrine. In contrast, stimulation of the adenylate cyclase by PGE1 was not affected or even increased by NEM pretreatment; only at high NEM concentrations were both basal and PGE1-stimulated activities decreased. Similarly, the PGE1-induced activation of the low Km GTPase was not or was only partially reduced by NEM. Adenylate cyclase activation by stable GTP analogs, NaF, and cholera toxin was also not decreased by NEM pretreatment. Exposure of intact platelets to NEM did not reduce alpha-adrenoceptor number and affinities for agonists and antagonists, as determined by [3H]yohimbine binding in platelet particles. The data indicate that NEM uncouples alpha-adrenoceptor-mediated inhibition of platelet adenylate cyclase, leaving the receptor recognition site and the adenylate cyclase itself relatively intact. Although the effect of NEM may be based on a reaction with the alpha-adrenoceptor site interacting with a coupling component, the selective loss of the adenylate cyclase inhibition together with an even increased stimulation of the enzyme by PGE1 suggests that there are two at least partially distinct regulatory sites involved in opposing hormonal regulations of adenylate cyclase activity, with that involved in hormonal inhibition being highly susceptible to inactivation by NEM.     

Interaction of guanine nucleotides with adenylate cyclase in normal and spontaneously transformed RL-RP-C cloned rat hepatocytes

Spontaneous transformation of RL-PR-C hepatocytes leads to alterations in the adenylate cyclase complex which include a lower than normal basal level of activity, a loss of sensitivity to exogenous GTP, and a decreased sensitivity to isoproterenol. Both normal and transformed membranes possess substantial GTPase activity. Treatment of transformed hepatocyte membranes with either isoproterenol plus GMP or with cholera toxin, under conditions that displace tightly bound GDP, restored the GTP effect on adenylate cyclase, and eliminated the lag in the activation by guanyl-5'-yl-imidodiphosphate. Such pretreatment also enhanced guanine nucleotide effects on the adenylate cyclase of normal hepatocytes. These results are explainable on the basis that transformation increases adenylate cyclase-associated GTPase activity, and increases occupancy of nucleotide regulatory sites by inactive or inhibitory guanine nucleotides, e.g., GDP. Seemingly, both catecholamines and cholera toxin promote an exchange reaction at the regulatory sites, resulting in clearance of these sites of inhibitory nucleotides.     

Interaction of guanine nucleotides with adenylate cyclase in normal and spontaneously transformed RL-PR-C cloned rat hepatocytes

Spontaneous transformation of RL-PR-C hepatocytes leads to alterations in the adenylate cyclase complex which include a lower than normal basal level of activity, a loss of sensitivity to exogenous GTP, and a decreased sensitivity to isoproterenol. Both normal and transformed membranes posses substantial TGPase activity. Treatment of transformed hepatocyte membranes with either isoproterenol plus GMP or with cholera toxin, under conditions that displace tightly bound GDP, restored the GTP effect on adenylate cyclase, and eliminated the lag in the activation by guanyl-5′-yl-imidodiphosphate. Such pretreatment also enhanced guanine nucleotide effects on the adenylate cyclase of normal hepatocytes. These results are explainable on the basis that transformation increases adenylate cyclase-associated GTPase activity, and increase occupancy of nuceotide regulatory sites by inactive or inhibitory guanine nucleotides, e.g., GDP. Seemingly, both catecholamines and cholera toxin promote an exchange reaction at the regulatory sites, resulting in clearance of these sites of inhibitory nucleotides.     

Evidence for two GTPases activated by thrombin in membranes of human platelets.

Thrombin inhibits adenylate cyclase and stimulates GTP hydrolysis by high-affinity GTPase(s) in membranes of human platelets at almost identical concentrations. Both of these thrombin actions are similar to those observed with agonist-activated alpha 2-adrenoceptors coupling to the inhibitory guanine nucleotide-binding protein N1. However, stimulation of GTP hydrolysis caused by adrenaline (alpha 2-adrenoceptor agonist) and by thrombin at maximally effective concentrations was partially additive, whereas with regard to adenylate cyclase inhibition no additive response was observed. Furthermore, treatment of platelet membranes with pertussis toxin, which inactivates Ni and largely abolishes thrombin- and adrenaline-induced adenylate cyclase inhibition and adrenaline-induced GTPase stimulation, decreased the thrombin-induced stimulation of GTP hydrolysis by only about 30%. Additionally, the thiol reagent N-ethylmalemide (NEM) at rather low concentrations abolished thrombin- and adrenaline-induced stimulation of GTP hydrolysis was decreased by only 30-40% by treatment of platelet membranes with even high concentrations of NEM. Treatment with cholera toxin, which inhibits GTPase activity of the Ns (stimulatory guanine nucleotide-binding) protein, has no effect on thrombin-stimulated GTP hydrolysis. The data suggest that thrombin interaction with its receptor sites in platelet membranes leads to stimulation of two GTP-hydrolysing enzymes. One of these enzymes is apparently Ni and is also activated by agonist-activated alpha 2-adrenoceptors and is inactivated by pertussis toxin and NEM treatment. The other GTP-hydrolysing enzyme activated by thrombin may represent a guanine nucleotide-binding protein apparently involved in the coupling of thrombin receptors to the phosphoinositide phosphodiesterase.     

Opioids, Noradrenaline and GTP Analogs Inhibit Cholera Toxin Activated Adenylate Cyclase in Neuroblastoma × Glioma Hybrid Cells

D-Ala2-Met5-enkephalin, morphine, and noradrenaline inhibit the adenylate cyclase in homogenates of neuroblastoma x glioma hybrid cells in a dose-dependent manner even after the enzyme has been preactivated by cholera toxin. Half-maximal inhibition and extent of inhibition are the same with native or cholera toxin-activated enzyme. The inhibition caused by opioids or noradrenaline are antagonized by naloxone or phentolamine, respectively. The effect of D-Ala2-Met5-enkephalin on cholera toxin-activated enzyme is immediate in onset and rapidly reversed by the addition of naloxone. Guanyl-5'-yl-imidodiphosphate stimulates basal activity but inhibits the enzyme activated by cholera toxin or prostaglandin E1. Stimulation occurs at a concentration of 100 microM or above, inhibition even at 0.1 microM. The inhibitory effect of the non-hydrolysable GTP analog is antagonized by GTP. Guanyl-5'-yl-methylenediphosphonate, another nonhydrolysable GTP analog, inhibits basal as well as cholera toxin-stimulated or prostaglandin E1-stimulated adenylate cyclase. Other guanine derivatives such as GDP, GMP, cyclic GMP, guanyl-5'-yl-phosphoric acid amide and guanosine have no effect under the same conditions. The results may be taken as a piece of evidence for two separate guanyl nucleotide-binding sites accompanying the adenylate cyclase in the hybrid cells and mediating, respectively, stimulation and inhibition of the enzyme by hormones.     

Functional homology between signal-coupling proteins. Cholera toxin inactivates the GTPase activity of transducin

Both the light-stimulated cGMP phosphodiesterase of retinal rod outer segments (ROS) and hormone-stimulated adenylate cyclase are regulated by guanine nucleotide-binding regulatory proteins (N). Transducin serves as the signal-carrying regulatory protein in ROS, and the N protein (also called G or G/F) performs this role in the adenylate cyclase system. The GTP form of these regulatory proteins activates the corresponding enzyme, whereas the GDP form does not. Both transducin and the N protein possess a GTPase activity that restores the regulatory protein to the unstimulated state. Cholera enterotoxin catalyzes the transfer of ADP-ribose from NAD+ to the N protein, which inhibits its GTPase activity and activates adenylate cyclase. We report here that the toxin also catalyzes ADP-ribosylation of the alpha-subunit of transducin in ROS membranes. This modification of the guanine nucleotide-binding subunit of transducin is markedly enhanced by the bleaching of rhodopsin and by the addition of guanosine-5'-(beta, gamma-imino)triphosphate. In contrast, GDP, GTP, and guanosine-5'-(3-O)thiotriphosphate inhibit the reaction, while GMP and ATP have no effect. Under optimal conditions, toxin catalyzes labeling of 0.7 mol of the alpha-subunit of transducin/mol of bound [3H]guanosine-5'-(beta, gamma-imido)triphosphate and causes 70% inhibition of the light-dependent GTPase activity of transducin in ROS. These results indicate close functional homology between transducin of ROS and the N protein of adenylate cyclase.     

Cholera toxin action on rabbit corpus luteum membranes: effects on adenylyl cyclase activity and adenosine diphospho-ribosylation of the stimulatory guanine nucleotide-binding regulatory component

Cholera toxin elicited 5- to 7-fold stimulation of adenylyl cyclase activity. Half-maximal activation was at 4.42 micrograms/ml cholera toxin. Cholera toxin-mediated activation was time dependent. At 0.1 mM ATP, both guanosine triphosphate (GTP) and nicotinamide adenine dinucleotide (NAD+) were required for cholera toxin activation of luteal adenylyl cyclase. The concentrations of GTP and NAD+ required for half-maximal activation were 1 and 200 microM, respectively. The GTP requirement could be eliminated by increasing the ATP concentration to 1.0 mM. Guanosine-5'-O-(2-thiodiphosphate) [GDP beta S] did not support cholera toxin activation of the luteal enzyme. Cholera toxin treatment increased GTP-stimulated activity, did not significantly alter guanyl-5'-yl imidodiphosphate [GMP-P(NH)P]-stimulated activity, and depressed NaF-stimulated activity. Furthermore, toxin treatment resulted in a 3.4-fold reduction in the Kact values for ovine luteinizing hormone (oLH) to activate adenylyl cyclase. A similar reduction in Kact values for oLH was obtained when concentration-effect curves performed in the presence of GMP-P(NH)P were compared to those performed in the presence of GTP. In addition, luteal membranes treated with cholera toxin and [32P]NAD+ were subjected to autoradiographic analysis following sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This treatment resulted in the [32P] adenosine diphospho (ADP)-ribosylation of a 45,000-dalton protein doublet, corresponding to the alpha subunit of the stimulatory guanine nucleotide-binding regulatory component (Ns). As with activation of adenylyl cyclase activity, cholera toxin-specific [32P] ADP-ribosylation was time dependent and increased with increasing concentrations of cholera toxin. GTP, GMP-P(NH)P, and NaF, but not GDP beta S, were capable of supporting [32P] ADP-ribosylation of the protein doublet. oLH did not alter the ability of cholera toxin to ADP-ribosylate the protein activation of luteal adenylyl cyclase activity is due to the ADP-ribosylation of the alpha subunit of Ns and the concomitant inhibition of a GTPase associated with adenylyl cyclase.     

Differential susceptibility to GTP formed from added GDP via membrane-associated nucleoside diphosphate kinase of GTP-sensitive adenylate cyclases achieved by hormone and cholera toxin

GTP-sensitive adenylate cyclases in liver membranes achieved by glucagon and by cholera toxin pretreatment displayed similar responses to added GTP in assay with respect to magnitude and sensitivity. However, their susceptibility to GTP formed during incubation from added GDP catalyzed by membrane-associated nucleoside diphosphate kinase(mNDPK) was different. Adenylate cyclase pretreated with cholera toxin was essentially unaffected by added GDP, while further addition of glucagon produced activation. GTP-stimulated adenylate cyclase activity in toxin-treated membranes was inhibited by added GDP, whereas glucagon addition reduced the inhibitory action of GDP by two orders of magnitude. Since neither pretreatment with toxin nor glucagon addition altered GTP formation by mNDPK, these observations suggest a possible presence of a mechanism by which hormone makes adenylate cyclase susceptible to the GTP formed via mNDPK for activation.     

Essential role of GTP in the expression of adenylate cyclase activity after cholera toxin treatment.

Expression of activation of rat liver adenylate cyclase by the A1 peptide of cholera toxin and NAD is dependent on GTP. The nucleotide is effective either when added to the assay medium or during toxin (and NAD) treatment. Toxin treatment increases the Vmax for activation by GTP and the effect of GTP persists in toxin-treated membranes, a property seen in control membranes only with non-hydrolyzable analogs of GTP such as Gpp(NH)p. These observations could be explained by a recent report that cholera toxin acts to inhibit a GTPase associated with denylate cyclase. However, we have observed that one of the major effects of the toxin is to decrease the affinity of guanine nucleotides for the processes involved in the activation of adenylate cyclase and in the regulation of the binding of glucagon to its receptor. Moreover, the absence of lag time in the activation of adenylate cyclase by GTP, in contrast to by Gpp(NH)p, and the markedly reduced fluoride action after toxin treatment suggest that GTPase inhibition may not be the only action of cholera toxin on the adenylate cyclase system. We believe that the multiple effects of toxin action is a reflection of the recently revealed complexity of the regulation of adenylate cyclase by guanine nucleotides.     

Thrombin, unlike vasopressin, appears to stimulate two distinct guanine nucleotide regulatory proteins in human platelets.

The thrombin-stimulated GTPase activity of human platelets was additive with respect to the GTPase stimulation effected by prostaglandin E1, but not with that stimulated by adrenaline, vasopressin and platelet-activating factor (PAF). Treatment of platelet membranes with pertussis toxin partially inhibited the thrombin-stimulated GTPase, but had no effect on the vasopressin-stimulated GTPase activity, whereas cholera toxin treatment had no effect on either of these stimulated GTPase activities. Thrombin, adrenaline and PAF, but not vasopressin, inhibited the adenylate cyclase activity of isolated plasma membranes through the action of Ni only, this being inhibited by pertussis toxin. It is suggested that thrombin exerts effects through both the inhibitory guanine nucleotide regulatory protein Ni and through the putative guanine nucleotide regulatory protein, Np, involved in regulating receptor-stimulated inositol phospholipid metabolism. However, vasopressin appears to exert its effects solely through the putative Np.     

Influence of pertussis toxin on the effects of guanine nucleotide on adenylate cyclase in rat striatal membranes

The influence of pertussis toxin on the effects of guanine nucleotide on adenylate cyclase activity were investigated in rat striatal membranes. GTP promoted and inhibited the activity at 1 and 100 microM, respectively. The inhibitory effects of GTP were abolished by pretreatment of the membranes with pertussis toxin. GppNHp (guanyl-5'-y1-beta,gamma-imidodiphosphate) exerted only stimulatory effects and pertussis toxin did not affect the effects of GppNHp. GDP at 10 and 100 microM caused significant inhibition which was completely suppressed by pertussis toxin. It is suggested that guanine nucleotide regulates the affinity of as in stimulatory GTP-binding regulatory protein to either beta gamma or catalytic units of adenylate cyclase in a flip-flop manner. Inhibitory GTP-binding regulatory protein seems to play a regulatory role in inhibiting alpha s activity supplying the beta gamma heterodimer.     

The inhibitory guanine nucleotide-binding regulatory component of adenylate cyclase. Properties and function of the purified protein

Treatment of membranes with islet activating protein (IAP), a toxin from Bordetella pertussis, results in abolition of GTP-dependent, receptor-mediated inhibition of adenylate cyclase. This appears to result from IAP-catalyzed ADP-ribosylation of a 41,000-Da membrane-bound protein. A protein with 41,000- and 35,000-Da subunits has been purified from rabbit liver membranes as the predominant substrate for IAP. This protein has now been shown to be capable of regulating membrane-bound adenylate cyclase activity of human platelets under various conditions. The characteristics of the actions of the IAP substrate are as follows. 1) Purified 41,000/35,000-Da dimer is capable of restoring the inhibitory effects of guanine nucleotides and the alpha 2-adrenergic agonist, epinephrine, on the adenylate cyclase activity of IAP-treated membranes. 2) The subunits of the dimer dissociate in the presence of guanine nucleotide analogs or A1(3+), Mg2+, and F-. The 41,000-Da subunit has a high affinity binding site for guanine nucleotides. 3) The resolved 35,000-Da subunit of the dimer mimics guanine nucleotide- and epinephrine-induced inhibition of adenylate cyclase. 4) The resolved (unliganded) 41,000-Da subunit stimulates adenylate cyclase activity and relieves guanine nucleotide- +/- epinephrine-induced inhibition of the enzyme. In contrast, the GTP gamma S-bound form of the 41,000-Da subunit inhibits adenylate cyclase activity, although with lower apparent affinity than does the 35,000-Da subunit. 5) The 35,000-Da subunit increases the rate of deactivation of Gs, the stimulatory regulatory protein of adenylate cyclase. In contrast, the 41,000-Da subunit can interact with Gs and inhibit its deactivation. These data strongly suggest that the IAP substrate is another dimeric, guanine nucleotide-binding regulatory protein and that it is responsible for inhibitory modulation of adenylate cyclase activity.     

GTP-activated GTP binding protein(Gs) in membranes achieved by hormone plus GDP does not serve as a substrate for ADP-ribosylation by cholera toxin

Adenylate cyclase in the presence of GTP became active by the addition of cholera toxin irrespective of the presence of glucagon, and under the same condition the Gs of these activated enzymes were good acceptor of an ADP-ribose moiety. On the other hand, the cyclase in the presence of GDP remained inactive with cholera toxin but became active by the further addition of glucagon. However, neither of these Gs served as a cholera toxin substrate. Glucagon reduced an inhibitory action of added GDP for cholera toxin plus GTP-stimulated adenylate cyclase activity but did not for toxin plus GTP-enhanced ADP-ribosylation of Gs. These results demonstrate that Gs-GTP complex formation alone is not sufficient for Gs to serve as a cholera toxin substrate, and suggest an additional GTP binding site responsible for ADP-ribosylation by the toxin. Hormone dependent preferential interaction between the GTP binding site on Gs coupled with adenylate cyclase regulation and membrane-associated nucleoside diphosphate kinase is discussed.     

3H]GDP release from rat and hamster adipocyte membranes independently linked to receptors involved in activation or inhibition of adenylate cyclase. Differential susceptibility to two bacterial toxins

When rat adipocyte membranes had been labeled with [3H]GTP in the presence of a beta-adrenergic agonist, the subsequent [3H]GDP release was stimulated by beta-agonists or agonists (e.g. glucagon and secretin) of other "activatory" receptors involved in activation of adenylate cyclase, but was not stimulated by agonists (e.g. prostaglandin E1 and adenosine) of "inhibitory" receptors involved in cyclase inhibition. On the contrary, agonists of inhibitory receptors were effective in stimulating GDP release from hamster adipocyte membranes that had been labeled via inhibitory alpha 2-adrenergic receptors, but an activatory receptor agonist such as isoproterenol was not. Thus, the guanine nucleotide regulatory protein (Ni) involved in adenylate cyclase inhibition is an entity distinct from the regulatory protein (Ns) involved in cyclase activation, and multiple activatory or inhibitory receptors are coupled to a respective common pool of Ns or Ni. Preactivated cholera toxin added together with NAD enhanced GDP release from rat adipocyte membranes prelabeled with isoproterenol but was without effect on the release from hamster adipocyte membranes that had been labeled with an alpha-agonist. In sharp contrast, the active subunit of islet-activating protein, pertussis toxin, failed to alter GDP release from the former membrane but completely abolished inhibitory agonist-induced stimulation of GDP release from the latter membrane preparation in the presence of NAD. Thus, the site of action of cholera toxin is Ns, while that of islet-activating protein is Ni. The function of Ni to communicate between inhibitory receptors and adenylate cyclase was lost when it was ADP-ribosylated by islet-activating protein.     

Modulation of adenylate cyclase in human keratinocytes by protein kinase C

Adenylate cyclase (ATP-pyrophosphate lyase (cyclizing); EC 4.6.1.1) in the human keratinocyte cell line SCC 12F was potentiated by 12-O-tetradecanoyl-phorbol-13-acetate (TPA), phorbol-12,13-diacetate, and 1,2-dioctanoylglycerol. Keratinocytes exposed to TPA showed a 2-fold enhancement of adenylate cyclase activity when assayed in the presence of isoproterenol or GTP. The half-maximal effective concentration (EC50) for both isoproterenol and GTP were unaltered by TPA treatment of the cells. Basal adenylate cyclase activity in membranes from TPA-treated cultures was also increased 2-fold relative to activity in control membranes. Potentiation of adenylate cyclase activity was dependent on the concentration of TPA to which the keratinocytes were exposed (EC50 for TPA = 3 nM). TPA actions on adenylate cyclase were maximal after 15 min of incubation of the cells with the compound, correlating well with the time course of translocation of protein kinase C (Ca2+/phospholipid-dependent enzyme) from cytosol to membrane. The action of cholera toxin on adenylate cyclase was additive with TPA. In contrast, pertussis toxin actions on adenylate cyclase were not additive with TPA. Treatment of control cells with pertussis toxin activated adenylate cyclase 1.5-fold, whereas cells exposed to pertussis toxin for 6 h followed by TPA for 15 min showed the same 2-fold increase in adenylate cyclase activity as observed in membranes from cells exposed to TPA without prior exposure to pertussis toxin. Pertussis toxin catalyzed ADP-ribosylation was increased 2-fold in membranes from SCC 12F cells exposed to TPA, indicating an increase in the alpha beta gamma form of Gi. These data suggest that exposure of human keratinocytes to phorbol esters increases adenylate cyclase activity by a protein kinase C-mediated increase in the heterotrimeric alpha beta gamma form of Gi resulting in decreased inhibition of basal adenylate cyclase activity.     

Cholera toxin and adenylate cyclase: properties of the activated enzyme in liver plasma membranes.

Adenylate cyclase (EC 4.6.1.1) activity in mouse liver plasma membranes is increased fivefold when animals are pretreated with cholera toxin. The increase in activity is detectable within 20 min of an intravenous injection of the toxin. The response of the control and cholera-toxin-activated adenylate cyclase to hormones, GTP, and NaF is complex. GTP causes the same fold stimulation of control and toxin-activated cyclase, but glucagon and NaF remain the most potent activators of liver adenylate cyclase irrespective of whether the enzyme is activated by cholera toxin. Determination of kinetic parameters of adenylate cyclase indicates that cholera toxin, hormones, and NaF do not change the affinity of the enzyme for ATP-Mg nor do they alter the Ka for free Mg2+. High concentrations of Mg2+ inhibit adenylate cyclase that is stimulated by either cholera toxin, glucagon, or NaF. These same Mg2+ concentrations have no effect on the basal activity of the enzyme or its activity in the presence of GTP.     

Influence of cholera toxin on the regulation of adenylate cyclase by GTP.

In the presence of NAD⁺, cholera toxin activates adenylate cyclase in membranes of S49 mouse lymphoma cells. The following evidence supports the hypothesis that the toxin acts by inhibiting a specific GTPase associated with a guanyl nucleotide regulatory component of hormone-responsive cyclase: 1. GTP alone markedly stimulates cyclase activity in toxin-treated, but not in untreated membranes; 2. The poorly hydrolyzable GTP analog, guanosine 5′-(β,γ-imino) triphosphate (Gpp(NH)p), stimulates cyclase equally well in toxin-treated and untreated membranes; 3. Cyclase activation by isoproterenol plus GTP persists in toxin-treated membranes, but not in controls, after addition of propranolol; 4. GTP is a more potent competitive inhibitor of the irreversible activation of cyclase by Gpp(NH)p in toxin-treated than in untreated membranes.     

Human platelet adenylate cyclase: persistent binding of guanine nucleotide is central to the regulation of both hormone-stimulated and basal activities

Prostaglandin E1 stimulation of human platelet adenylate cyclase, in purified plasma membranes, occurs without the addition of exogenous GTP. Possible contamination of the adenylate cyclase assay mixture by GTP either from nonspecifically bound nucleotide in the plasma membrane or from the substrate ATP was ruled out as follows: (a) variation of the membrane concentration, repeated washing, inclusion of EDTA, GDP beta S, or GMP in the wash step, or UDP in the assay, are all without effect, and (b) analysis of the substrate by high-performance liquid chromatography revealed no contaminating GTP. Other prostaglandins (I2, E2, D2) also activate cyclase without the addition of GTP. In sharp contrast, stimulation of adenylate cyclase in the human neutrophil plasma membrane by prostaglandin E1 shows an obligatory requirement for GTP, under identical assay conditions. GDP beta S pretreatment amplifies the fold cyclase stimulation by GTP in the presence and absence of prostaglandin E1, by lowering the basal activity. This alteration occurs without lowering the GTP-independent prostaglandin E1 activation, and is specific for inhibitory guanine nucleotides (GDP beta S, GMP, GDP) in the pretreatment. Extensive washing with buffer or incubation with other nucleotides, epinephrine, or prostaglandin E1 prior to the assay, is without effect. GTP gamma S treatment of the membrane induces a high-activity state and abolishes the GDP beta S effect on basal activity as well as prostaglandin E1 activation of cyclase. The results suggest distinct patterns of prostaglandin stimulation in platelet and neutrophil cyclase systems, and further imply that guanine nucleotide, prebound to specific sites within the GTP-regulatory proteins, may modify the kinetic characteristics of platelet adenylate cyclase.