The activation of adenylate cyclase by guanyl nucleotides in Saccharomyces cerevisiae is controlled by the CDC25 start gene product.

In the thermosensitive cdc25 start mutant of Saccharomyces cerevisiae, the regulation of adenylate cyclase by guanyl nucleotides was rapidly nullified when the enzyme was prepared from nonsynchronized cells shifted to the restrictive temperature. In agreement with previous in vivo complementation studies, this biochemical defect was fully suppressed by the expression of either the whole cloned CDC25 gene or its C-terminal portion. Moreover, membranes prepared from cdc25(Ts) cells grown at the permissive temperature evinced an altered regulation of adenylate cyclase by guanyl nucleotides. These results indicate that the CDC25 protein, together with RAS, is involved in the regulation of adenylate cyclase by guanyl nucleotides and raise the possibility that adenylate cyclase might form a ternary complex with RAS and CDC25.     

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.     

Release of guanyl nucleotides from the regulatory subunit of adenylate cyclase

Choleragen and beta-adrenergic agonists, both of which activate turkey erythrocyte adenylate cyclase, have been reported to accelerate release of bound [3H]guanyl nucleotides from turkey erythrocyte membranes. We have now obtained evidence that choleragen- or isoproterenol-stimulated release reflects a change in the affinity of the regulatory subunit (G/F) of adenylate cyclase for guanyl nucleotides. Solubilized preparations of turkey erythrocytes that had bound radiolabeled GTP were chromatographed on Ultrogel AcA 34. The protein from which guanyl nucleotide was released upon incubation with choleragen or isoproterenol was co-eluted with G/F activity. Furthermore, this protein appears to be the same size as the complex containing the 42,000-dalton peptide, ADP*-ribosylated by choleragen, which is presumably a subunit of G/F. ADP ribosylation of the 42,000-dalton subunit of G/F by choleragen occurred with a half-time of about 5 min, whereas choleragen-stimulated release of guanyl nucleotides was much slower (t1/2 greater than or equal to 60 min). When membranes were treated with choleragen and NAD, the delay in activation of adenylate cyclase by guanylyl imidodiphosphate was decreased but not abolished, a finding consistent with the idea that release of endogenously bound nucleotide (and subsequent binding of the nonhydrolyzable GTP analog) occurs only slowly following ADP ribosylation. In contrast, activation of the adenylate cyclase of either toxin-treated or untreated membranes in the presence of isoproterenol and guanylyl imidodiphosphate was very rapid. These data support the hypothesis that isoproterenol and choleragen may activate adenylate cyclase, at least in part, by increasing the rate of release of guanyl nucleotides from G/F.     

The role of GTP in the activation of adenylate cyclase.

An attempt is made to integrate the knowledge on the role of hormones and guanyl nucleotides in regulating adenylate cyclase into a single molecular model. It is suggested that the hormone catalyzes the activation of the enzyme adenylate cyclase by facilitating the conversion of the enzyme from its inactive state to its active form. The hormone is also responsible for the termination of the signal namely the deactivation of the enzyme by inducing the hydrolysis of GTP at its regulatory site. The relative rates of these two processes determine the steady state concentration of the active form of the enzyme. The model also explains the difference in behaviour between GTP and its non-hydrolyzable analogs GppNHp and GTPγS.     

Heterologous desensitization of pigeon erythrocyte adenylate cyclase by the catalytic subunit of cAMP-dependent protein kinase

Preincubation of pigeon erythrocyte plasma membranes with the catalytic subunit of cAMP-dependent protein kinase results in the desensitization of erythrocyte adenylate cyclase. The adenylate cyclase activity measured in the presence of 10 microM isoproterenol and 50 microM GTP-gamma-S decreases by 40% after 10 min incubation; that in the presence of 50 microM GTP-gamma-S by 35% (20 min). The decrease of the adenylate cyclase activity is due to the prolongation of the lag phase of the enzyme activation in the presence of a hydrolysis-resistant GTP analog and to the drop in activity in the steady state of the activation. The heterologous desensitization of adenylate cyclase induced by cAMP-dependent protein kinase is also coupled with the decrease of the number of beta-adrenoreceptors capable of acquiring a high affinity for the agonists in the absence of guanyl nucleotides. The effect of the catalytic subunit on adenylate cyclase is fully compatible with the process of the enzyme desensitization in erythrocytes treated with isoproterenol or cAMP.     

Genetic evidence that cholera toxin substrates are regulatory components of adenylate cyclase.

Cholera toxin, using [32P]NAD+ as substrate, specifically radiolabels at least two proteins in plasma membranes of wild type S49 mouse lymphoma cells. The toxin-specific substrates are detectable by sodium dodecyl sulfate-polyacrylamide gel electrophoresis as bands corresponding to molecular weights of 45,000 and a doublet of 52,000 to 53,000. Membranes of two other cell types exhibit similar patterns of radiolabeled bands specifically produced by incubation with cholera toxin: the "uncoupled" variant S49 cell, which possesses adenylate cyclase activity unresponsive to hormones, and the HTC4 rat hepatoma cell, which lacks detectable catalytic adenylate cyclase activity but contains components of the cyclase system necessary for regulation by guanyl nucleotides and NaF. Little or no toxin-specific radiolabeling is observed in membranes of a fourth cell type, the adenylate cyclase activity-deficient S49 variant, which functionally lacks components of the cyclase system involved in cholera toxin action and regulation by guanyl nucleotides and NaF. The toxin-specific labeling pattern is not observed in membranes prepared from wild type S49 cells previously treated with cholera toxin in culture. One or both of the toxin substrates thus appears to be involved in regulation of adenylate cyclase by guanyl nucleotides and fluoride ion.     

Ontogenetic study of the regulatory and coupling function of guanyl nucleotide-binding proteins in the hormone-sensitive adenylate cyclase system

Reconstitution of catecholamine-sensitive adenylate cyclase from chick embryonic muscle membranes and guanyl nucleotide-binding proteins of mature rabbit muscle makes it possible to reveal the coupling (potentiating) effect of these nucleotides 1 week earlier than in the native condition. The effective insertion of guanyl-nucleotide-binding proteins into the embryonic membrane coincides with the onset of a pronounced increase in membrane lipid fluidity during the course of embryogenesis. The different ontogenetic time-courses for the origination of the two guanyl nucleotide effects, on catalytic adenylate cyclase activity (in early embryogenesis) and on the coupling process (in postembryonic life), suggest the existence in this system of two separate guanyl-nucleotide-binding proteins performing regulatory and coupling functions, respectively.     

Calmodulin-Sensitive and Calmodulin-Insensitive Components of Adenylate Cyclase Activity in Rat Striatum Have Differential Responsiveness to Guanyl Nucleotides

The interaction between the Ca2+-binding protein, calmodulin, and guanyl nucleotides was investigated in a rat striatal particulate fraction. We found that the ability of calmodulin to stimulate adenylate cyclase in the presence of guanyl nucleotides depends upon the type and concentration of the guanyl nucleotide. Adenylate cyclase activity measured in the presence of calmodulin and GTP reflected additivity at every concentration of these reactants. On the contrary, when the activating guanyl nucleotide was the nonhydrolyzable analog of GTP, guanosine-5'-(beta,gamma-imido)triphosphate (GppNHp), calmodulin could further activate adenylate cyclase only at concentrations less than 0.2 microM GppNHp. Kinetic analysis of adenylate cyclase by GppNHp was compatible with a model of two components of adenylate cyclase activity, with over a 100-fold difference in sensitivity for GppNHp. The component with the higher affinity for GppNHp was competitively stimulated by calmodulin. The additivity between calmodulin and GTP in the striatal particulate fraction suggests that they stimulate different components of cyclase activity. The calmodulin-stimulatable component constituted 60% of the total activity. Our two-component model does not delineate, at this point, whether there are two separate catalytic subunits or one catalytic subunit with two GTP-binding proteins.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dicyclohexylcarbodiimide influences the regulatory properties of the adenylate cyclase system in rat reticulocyte membranes

Treatment of rat reticulocyte plasma membranes with dicyclohexylcarbodiimide (DCCD) decreased the GTP-stimulated adenylate cyclase activity and reduced the number of receptors that bind the agonist with high affinity in the absence of GTP. Besides, the agonist's competition curve was shifted to the right, irrespective of the presence of guanyl nucleotides. The dissociation constant for the antagonist and the number of binding sites did not change. Preincubation of the DCCD-treated membranes with GMP in the presence of isoproterenol restored the regulation of the agonist's affinity by guanyl nucleotides; however, in this case the GTP-independent change in the agonist's affinity was retained. This suggests that one of the DCCD-modified components of the adenylate cyclase system is a regulatory protein.     

On the role of guanyl nucleotides in adenylate cyclase system of embryonic skeletal muscle

The effects of guanyl nucleotides on the catalytic and catecholamine-stimulated activities of adenylate cyclase in developing chick skeletal muscles were studied. GTP and guanylyl imidodiphosphate stimulate the cyclase catalytic activity already at the early embryonic stages without having potentiating influence on the catecholamine-stimulated activity in embryonic muscle. In a distinct and regular form this effect can be observed only after hatching. Therefore during embryogenesis the coupling function of the GTP-binding component of adenylate cyclase system characteristic of its mature state is not manifested. The effects of the nucleotide suggest that they occur as two independent processes.     

The regulatory effect of ATP and its non-hydrolyzed analogs on heart adenylate cyclase

The effect of ATP on rabbit heart adenylate cyclase was investigated. The activation of adenylate cyclase by isoproterenol, guanyl nucleotides and NaF increases at a rise in ATP concentration. A similar regulatory effect is exerted by nonhydrolyzed analogs of ATP - adenyl-5'-ilimidodiphosphate and adenosine-5'-(alpha, beta-methylene) triphosphate. Consequently the regulatory influence of ATP is not due to chemical modification of the enzyme or to phosphorylation of endogenous GDP. Earlier we demonstrated that regulation of heart adenylate cyclase by ATP is not mediated by the adenosine binding center (Biokhimiya USSR (1982), 47, 455-464). It is assumed that the regulatory effect of ATP is accomplished by a specific binding site for this nucleotide.     

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.     

The epinephrine-sensitive adenylate cyclase of rat liver plasma membranes. Role of guanyl nucleotides.

The epinephrine sensitivity in vitro of the adenylate cyclase system in liver plasma membranes from adrenalectomized rats was increased by the addition of 1 to 100 muM GTP or GDP in the incubation medium. Basal and glucagon-stimulated cyclase activities were also enhanced by GTP and GDP. These effects occurred even in the absence of an ATP-regenerating system. They were mimicked by 5'-guanyl diphosphonate and a series of guanyl derivatives, indicating that the structural requirement for the GTP action is not very stringent. Guanyl nucleotides did not increase the affinity of the adenylate cyclase system for the activating hormones, nor did they protect the enzyme activity against denaturation. Their synergic effect was due to an enhancement of the affinity of the enzyme for the substrate MgATP and also to an increase of the maximal velocity of the reaction. It is proposed that the guanyl nucleotides act directly and primarily upon the catalytic component of the cyclase system, independently of their effects on the binding of the activating hormones to liver plasma membrane. Since the activating effects of epinephrine and glucagon are similar in the presence of GTP, but not in its absence, it is suggested that the lower efficiency of epinephrine under normal conditions is not due to intrinsic membrane characteristics, but rather, to superimposed extraneous modulations.     

Loss of calcium/calmodulin responsiveness in adenylate cyclase of rutabaga,a Drosophila learning mutant

We have isolated and mapped an X-linked recessive mutation in Drosophila that blocks associative learning, and have partially characterized it biochemically. The mutation affects adenylate cyclase activity. Cyclase activity from mutant flies differed from the wild-type enzyme in that it was not stimulated by calcium or calmodulin. Mutant cyclase activity did respond to guanyl nucleotides, fluoride, and monoamines, which suggests that the defect is neither in the hormone receptor nor in either known GTP-binding regulatory protein. The mutation possibly affects the catalytic subunit directly. We postulate that there is at least one other type of adenylate cyclase activity that is unaffected by the mutation and insensitive to calcium/calmodulin.     

Characterization of Adenylate Cyclase Purified from Rat Brain by Hydrophobic Chromatography

Abstract. Hydrophobic chromatography of detergent-solubilized rat brain adenylate cyclase on dodecyl-Sepharose produced a species that was soluble in the absence of detergent and could be manipulated like a conventional hydrophilic protein. Sevenfold purification was achieved by this technique. Further purification could then be effected by affinity chromatography on ATP-Sepharose. The purified enzyme was no longer sensitive to fluoride or guanyl nucleotides. No interaction of brain adenylate cyclase was observed with immobilized triazinyl dyes such as Cibacron Blue 3GA nor with concanavalin A-Sepharose. The molecular weight of the fluoride-activated catalytic complex in a freeze-dried membrane preparation was estimated to be 133,000 by irradiation inactivation.     

Coupling of glucagon receptor to adenylyl cyclase. Requirement of a receptor-related guanyl nucleotide binding site for coupling of receptor to the enzyme.

Effects of glucagon and guanyl nucleotides on the rat liver plasma membrane adenylyl cyclase were studied. It was established that: 1) glucagon stimulates the fully guanyl-5'-yl imidodiphosphate (GMP-P(NH)P)-activated enzyme between 20 and 70%, provided a guanyl nucleotide is present in the assay; 2) glucagon has no effect on adenylyl cyclase activity in membranes activated fully by GMP-P(NH)P and then washed free of nucleotides. It is concluded that occupancy of the guanyl nucleotide binding site that activates the catalytic moiety of the system is not sufficient to promote hormone-receptor coupling to adenylyl cyclase and that occupancy of a second site by guanyl nucleotides is essential to effect stimulation of adenylyl cyclase by the glucagon-receptor complex. The data presented raise the question whether the guanyl nucleotide site that promotes coupling is distinct from the guanyl nucleotide site that modulates binding of glucagon to receptor and whether the occupancy of the guanyl nucleotide site associated with the catalytic moiety is necessary for coupling.     

Modulation byn-alkanols of rat cardiac adenylate cyclase activity

Summary n-Alkanols (from methanol to decanol) have a biphasic effect on rat cardiac adenylate cyclase either basal or stimulated by GTP, GppNHp, NaF or hormones (isoproterenol, glucagon, secretin) in the presence of GTP. At high concentration, all the enzyme activities are inhibited. At low concentration, adenylate cyclase activity is either unchanged or potentiated depending on both the stimulus and the alkanols involved. Potentiation is due to an increase of maximum velocity with no change in the activation constant of the enzyme. Basal activity is unchanged as well as the isoproterenol-and glucagon-stimulated enzyme. The secretin-stimulated enzyme is potentiated. It is the guanyl nucleotide regulatory protein-mediated stimulation of adenylate cyclase which is mainly affected. An attempt was made to relate these effects on adenylate cyclase with physical parameters of the alkanols (partition coefficient). From the data obtained as a function of the alkanol chain-length and of temperature on the adenylate cyclase stimulated by GTP, GppNHp, NaF and permanently activated, it is concluded that the increase in efficacy observed in the presence of alkanol is due to an interaction with the protein moeity particularly with the guanyl nucleotide regulatory protein.     

ADENYLATE CYCLASE IN HELIX AND APLYSIA GANGLIA: CHARACTERISTICS OF ITS STIMULATION BY A PEPTIDE-CONTAINING NERVOUS SYSTEM EXTRACT

Abstract— A crude particulate fraction, prepared from the central ganglia of Helix or Aplysia , contains levels of adenylate cyclase activity comparable to those in mammalian brain. This activity can be stimulated up to 50-fold by NaF, and 4- to 10-fold by guanyl nucleotides such as GTP and guanylylimidodiphosphate (Gpp(NH)p). A peptide-containing extract from Helix or Aplysia nervous system also stimulates the adenylate cyclase, by 50-400°. In contrast, a number of peptides known to occur in vertebrate and invertebrate nervous system are without effect. The adenylate cylase stimulation by the endogenous molluscan peptide-containing extract may be receptor-mediated, but the effect is not enhanced in the presence of guanyl nucleotides: in this respect it differs from many other hormone-sensitive adenylate cyclases. The endogenous extracts prepared from Helix and Aplysia each stimulate both Helix and Aplysia adenylate cyclases, suggesting that the putative cyclase-linked receptors may be similar in the two species. Furthermore, the active components in the extracts from Helis and Aplysia appear to be similar, since preliminary evidence suggests that they may interact with the same adenylate cyclase-linked receptor in particulate fraction from Helix ganglia.     

Guanine nucleotide regulation of adenylate cyclase in permeabilized cells of Saccharomyces cerevisiae

Adenylate cyclase in permeabilized cells of Saccharomyces cerevisiae was examined. Among various permeabilization procedures, including organic solvents, detergents and other reagents, dimethylsulfoxide (DMSO) and digitonin treatments resulted in the highest recovery of adenylate cyclase activity. Incubation of cells at 30 degrees C with digitonin at 0.01% to 0.1%, or DMSO at 20% to 40% for 15 to 30 min gave optimal adenylate cyclase activity. The enzyme activity in digitonin-permeabilized cells could be supported only by Mn2+, whereas Mg2+ with or without guanine nucleotides did not support cyclase activity. DMSO-permeabilized cells exhibit efficient Mn2+- and Mg2+/Gpp[NH]p-dependent stimulation. Furthermore, digitonin added to yeast membranes at a 1:50 detergent to protein ratio (w/w) abolishes guanyl nucleotide regulation without significantly affecting the Mn2+-supported cyclase activity. The superiority of DMSO is further supported by the fact that recovery of adenylate cyclase activity is better in the DMSO-treated cells than in the digitonin-treated cells. DMSO most probably causes less disturbance of the fabric of the native cell. We conclude that digitonin, but not DMSO, uncouples the catalytic unit of adenylate cyclase from the regulatory GTP binding (ras) proteins.     

Relationship of calmodulin and dopaminergic activity in the striatum

Increasing evidence suggests a relationship between dopaminergic activity in the striatum and the content of calmodulin (CaM), an endogenous Ca2+-binding protein. The content of CaM in striatal membranes is increased by treatments that produce supersensitivity in striatal membranes is increased by treatments that produce supersensitivity of striatal dopaminergic receptors such as chronic neuroleptic treatment or injection of 6-hydroxydopamine. Concomitant with the increase in CaM is a greater sensitivity of adenylate cyclase to dopamine and an increase in Ca2+-sensitive phosphorylation in the striatal membranes. Procedures that result in dopaminergic subsensitivity, such as amphetamine treatment, increase the cytosolic content of CaM that can subsequently activate Ca2+ and CaM-dependent phosphodiesterase activity. In vitro studies have demonstrated that CaM and Ca2+ can stimulate basal adenylate cyclase activity in a striatal particulate fraction as well as increase the sensitivity of the enzyme to dopamine. Ca2+ and CaM most likely affect the dopamine-sensitive adenylate cyclase by interacting with guanyl nucleotides, which are required for dopamine sensitivity. It is concluded that a change in CaM concentration and/or location occurs during conditions of altered dopaminergic sensitivity in the striatum. These changes in CaM coupled with potential alterations in the Ca2+ concentration could modulate the sensitivity of the dopamine system and many CaM-dependent enzymes.