Adenylate cyclase from rabbit small intestine: activation by cholera toxin and interaction with calcium

The stimulation of adenylate cyclase in various fractions of plasma membranes from rabbit small intestinal epithelium has been studied. In crude plasma membranes cholera toxin activated 5-fold at 10 micrograms/ml; vasoactive intestinal peptide (VIP) activated at concentration from 10(-8) to 10(-7) M, the maximal stimulation being 6-fold. Fluoride activated 10-fold at 10 mM. VIP-stimulated enzyme was inhibited by Ca2+ concentrations in the micromolar range. In the presence of calmodulin a biphasic response was obtained. At low Ca2+ concentration (4 x 10(-9)-6 x 10(-8) M) the enzyme was activated. As the Ca2+ concentration was increased the enzyme was concomitantly inhibited. We have investigated the mechanism by which cholera toxin activates intestinal adenylate cyclase. We have found that cholera toxin catalyzed incorporation of 32P into proteins located in the brush-border membrane whose molecular weights are in the range of 40-45kDa. These membranes bind [3H]GTP with a Kd of 1.8 x 10(-7) M. In contrast, basal lateral membranes do not contain any protein which becomes labeled in a toxin-dependent manner when incubated with cholera toxin and [32P]NAD. The modification of brush-border membrane protein occurred in spite of the absence of adenylate cyclase in these membranes. Adenylate cyclase in basal lateral membranes was poorly activated by cholera toxin as compared to crude plasma membranes. On the other hand, the ability of VIP and fluoride to activate the enzyme was enhanced in basal lateral membranes with respect to crude membranes. The results are discussed in relation to the mechanism by which cholera toxin activates adenylate cyclase in intact intestinal cells.     

Some comparative properties and localization of porcine jejunal adenylate cyclase.

Cholera toxin is thought to cause intestinal secretion by activating adenylate cyclase and increasing intracellular 3',5'-cyclic AMP concentrations in intestinal mucosa. Cholera toxin causes profuse secretion of fluid into ligated intestinal loops of both pigs and rabbits, but cholera toxin-induced increases in 3',5'-cyclic AMP concentration are much lower in the pig than in the rabbit. Porcine jejunal adenylate cyclase was examined for unusual properties which might account for a lack of 3'-5'-cyclic AMP accumulation after treatment with cholera toxin. The divalent cation requirements, the pH optimum, and the stimulation by fluoride ion were unremarkable. The Km for ATP was 0.11 mM with negative cooperativity indicated by a Hill coefficient of 0.83. Triton X-100 was inhibitory and guanosine diphosphate methylenephosphate stimulated enzyme activity. Adenylate cyclase activity was highest in the basal and lateral membrane fractions of jejunal mucosa and relatively low in brush-border preparations. Pretreatment of pig jejunum with cholera toxin caused a 30-40% activation of the crude and of the partly purified enzyme. A relatively low activation of adenylase cyclase in pig jejunal mucosa, compared with rabbit, may account for the absence of 3',5'-cyclic AMP accumulation after cholera-toxin treatment in the pig.     

Influence of dietary omega-3 fatty acids on transmembrane signalling in rat submandibular salivary gland

We have previously shown the incorporation of dietary omega-3 and omega-6 fatty acids from menhaden oil and corn oil, respectively, into membrane phospholipids of submandibular salivary gland (SMSG) of rat [Alam S. Q. and Alam B. S. (1988) Arch. Oral Biol. 33, 295-299]. We now demonstrate the influence of such incorporation on the regulation of G proteins and adenylate cyclase activity. Cholera toxin ribosylated three protein peptides (Mr 42,000, 44,000 and 46,000) to different extents in the two groups. We found 4.9- and 2.6-fold higher and 0.4-fold lower ribosylation of Mr 42,000, 44,000 and 46,000 peptides, respectively, in SMSG membranes of rats fed a diet containing 10% menhaden oil (group II) compared to those fed 10% corn oil (group I). Functional distinctions between different forms of these peptides are not known. Cholera toxin also exhibited radiolabelling of three peptides in the SMSG membranes from normal or fasting rats. In these membranes inhibitory G proteins were not detected by pertussis toxin dependent ADP ribosylation or by a low concentration of guanylyl 5-imidodiphosphate (10(-8) M), which selectively activates inhibitory G proteins which inhibit forskolin stimulated activity of adenylate cyclase. In group II membranes both basal and fluoride stimulated activities of adenylate cyclase were found to be significantly higher than the corresponding values in group I (P less than 0.02). In cholera toxin dependent ribosylated membranes of group I, basal and fluoride stimulated activities of adenylate cyclase were significantly higher than those obtained in the absence of cholera toxin (P less than 0.02). Surprisingly, corresponding values were found to be lower in ribosylated membranes of group II. This could be due either to conformational changes in heavily ribosylated G proteins, which alters coupling with the catalytic subunit of adenylate cyclase, or due to dissociation of excessive inhibitory beta gamma complex from alpha beta gamma complex upon the activation of G proteins.     

Studies on the time course and rate-limiting steps in the activation of adenylate cyclase in rat liver by cholera toxin.

Cholera toxin stimulates adenylate cyclase in rat liver after intravenous injection. The stimulation follows a short latent period of 10min, and maximum stimulation was attained at 120min. Half-maximal stimulation was achieved at 35min. In contrast with this lengthy time course in the intact cell, adenylate cyclase in broken-cell preparations of rat liver in vitro were maximally stimulated by cholera toxin (in the presence of NAD+) in 20min with half-maximal stimulation in 8min. Binding of cholera toxin to cell membranes by the B subunits is followed by translocation of the A subunit into the cell or cell membrane, and separation of the A1 polypeptide chain from the A2 chain by disulphide-bond reduction, and finally activation of adenylate cyclase by the A1 chain and NAD+. As the binding of cholera toxin is rapid, two possible rate-limiting steps could be the determinants of the long time course of action. These are translocation of the A1 chain from the outside of the cell membrane to its site of action (this includes the time required for separation from the whole toxin) or the availability of NAD+ for activation. When NAD+ concentrations in rat liver were elevated 4-fold, by the administration of nicotinamide, no change in the rate of activation of adenylate cyclase by cholera toxin was observed. Thus the intracellular concentration of NAD+ is not rate-limiting and the major rate-limiting determinant in intact cells must be between the time of toxin binding to the cell membrane and the appearance of subunit A1 at the enzyme site.     

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.     

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.     

Biphasic regulation of adenylate cyclase by cholera toxin in neuroblastoma x glioma hybrid cells is due to the activation and subsequent loss of the alpha subunit of the stimulatory GTP binding protein (GS)

Exposure of neuroblastoma x glioma hybrid (NG108-15) cells to low concentrations of cholera toxin produced a stimulation of both basal and forskolin-amplified adenylate cyclase activity in membranes prepared from these cells. Higher concentrations of cholera-toxin reversed this effect. Mn2+ activation of adenylate cyclase indicated that this effect was not due to a modification of the intrinsic activity of this enzyme. Cholera toxin was demonstrated to produce a concentration and time-dependent loss of GS alpha from membranes of these cells. Loss of GS alpha from membranes of these cells was preceded by its ADP-ribosylation. The effects of cholera toxin were specific for GS alpha, as no alterations in levels of the pertussis toxin-sensitive G-proteins Gi2, Gi3 and Go, were noted in parallel. Equally, no alteration in levels of G-protein beta-subunit were produced by the cholera toxin treatment. These experiments demonstrate that cholera toxin-catalysed ADP-ribosylation does not simply maintain an activated population of GS at the plasma membrane and that alterations in levels of GS at the plasma membrane can modify adenylate cyclase activity.     

Alterations in components of adenylate cyclase associated with transformation of chicken embryo fibroblasts by Rous sarcoma virus

Regulation of adenylate cyclase coincident with transformation of chicken embryo fibroblasts by Rous sarcoma virus is manifest as a 10-50% decrease in basal, Mg2+-, and forskolin-stimulated activities; activities elicited by fluoride and guanosine 5'-O-(3-thiotriphosphate) are unaltered. The level of the catalytic component of adenylate cyclase, assessed with activated stimulatory guanine nucleotide-binding protein (Gs), increases approximately 1.5-fold. The level of the beta subunit common to Gs and the inhibitory regulatory protein assessed by enzyme-linked immunotransfer blotting, increases 2.7-fold. The isoelectric behavior of the beta subunit is unaltered. The amount of radiolabel incorporated into the alpha subunit of Gs (Mr = 45,000) upon incubation of membranes with 32P-labeled NAD and cholera toxin increases 3-fold upon transformation. Detergent extracts prepared from membranes of untransformed and transformed fibroblasts nevertheless exhibit equivalent abilities to reconstitute fluoride-stimulated activities to membranes of the cyc-variant of mouse S49 lymphoma cells. Islet-activating protein catalyzes incorporation of radiolabel from 32P-labeled NAD into 39,000- and 41,000-dalton proteins; the extent of radiolabel incorporation does not change upon transformation. Modest alterations in the isoelectric behaviors of substrates for cholera toxin and islet-activating protein occur.     

ADP-ribosylation of membrane proteins and activation of adenylate cyclase by cholera toxin in fat cell ghosts from euthyroid and hypothyroid rats.

Incubation of fat cell ghosts with activated cholera toxin, nucleoside triphosphate, cytosol, and NAD results in increased adenylate cyclase activity and the transfer of ADP-ribose to membrane proteins. The major ADP-ribose protein comigrates on sodium dodecyl sulfate-polyacrylamide gels with the putative GTP-binding protein of pigeon erythrocyte membranes (Mr 42 000), which is also ADP-ribosylated by cholera toxin. The treatment with cholera toxin enhances the stimulation of the fat cell membrane adenylate cyclase by GTP, but the stimulation by guanyl-5'-yl imidodiphosphate is unaltered. Subsequent stimulation of fat cell adenylate cyclase by 10 micrometers epinephrine is not particularly affected. These changes were qualititatively the same for membranes isolated from fat cells of hypothyroid rats. Although the cyclase of these membranes has a reduced response to epinephrine, guanyl-5'-yl imidodiphosphate or GTP, as compared to euthyroid rat fat cell membranes, the defect is not rectified by toxin treatment and cannot be explained by a deficiency in the cholera toxin target.     

ADP-Ribosylation of Membrane Proteins in Cholinergic Nerve Terminals

Abstract: Lysed Torpedo synaptosomes or washed synaptosomal membranes were incubated with [³²P]NAD⁺ and subjected to electrophoresis on SDS-polyacrylamide gels. More than eight membrane proteins were ADP-ribosylated. The most intensely labeled proteins were those of M_r= 62,000 and 82,000. Radiolabeling was more intense in synaptosomes than in other subcel-lular fractions. Cholera toxin caused ribosylation of additional synaptosomal proteins with M_r= 42,000 and (in some preparations) 49,000. Neither endogenous nor cholera toxin-catalyzed ADP-ribosylation required added guanyl nu-cleotides. Cholera toxin increased the adenylate cyclase activity of synaptosomal membranes, suggesting that the cholera toxin substrates are regulatory components of adenylate cyclase in these synaptosomes.     

Regulation by forskolin of octopamine-stimulated adenylate cyclase from brain of the dipterous Ceratitis capitata

Forskolin, a diterpene that exerts several pharmacological effects, activates adenylate cyclase in brain and in some other mammalian tissues. Properties of forskolin activation of adenylate cyclase from central nervous system of the dipterous Ceratitis capitata are described. The interaction of forskolin with the insect adenylate cyclase system was studied by evaluating its effect on metal-ATP kinetics, protection against thermal inactivation, membrane fluidity and enzyme modulation by fluoride, guanine nucleotides, octopamine, and ADP-ribosylation by cholera toxin. The diterpene stimulated basal enzyme activity both in membranes and Triton X-100-solubilized preparations, apparently devoid of functional regulatory unit, this effect being rapidly reversed by washing the membranes. An increase of Vmax accounts for the activation of soluble and membrane adenylate cyclase preparations by forskolin, whereas the affinity of the enzyme for the substrate was not affected. Forskolin apparently protects the membrane enzyme from thermal inactivation, and at concentrations that promote the enzyme activity the diterpene does not alter membrane microviscosity. Forskolin does not appear to alter the sensitivity of insect adenylate cyclase to sodium fluoride, guanine nucleotide, or regulatory subunit ADP ribosylated by cholera toxin, the combined effect of these factors with the diterpene resulting in a nearly additive enzymatic activation. However, forskolin blocks the octopamine stimulatory input. Results obtained with the insect adenylate cyclase system are discussed and compared to what is known about mammalian systems to propose a mechanism of enzyme activation by forskolin.     

Possible Involvement of Inhibitory GTP Binding Regulatory Protein in α2-Adrenoceptor-Mediated Inhibition of Adenylate Cyclase Activity in Cerebral Cortical Membranes of Rats

Influences of alpha 2-adrenoceptor stimulation on adenylate cyclase activity were investigated in cerebral cortical membranes of rats. Pretreatment of the membranes with islet-activating protein and NAD resulted in a significant increase in basal activity as well as in GTP- or forskolin/GTP-induced elevation of adenylate cyclase activity. Strong activation of adenylate cyclase was also caused in membranes pretreated with cholera toxin together with NAD in comparison to that in control membranes, suggesting that adenylate cyclase activity is perhaps regulated by stimulatory and inhibitory GTP binding regulatory protein existing in synaptic membranes. In addition, adrenaline (with propranolol) or clonidine significantly reduced adenylate cyclase activity stimulated by pretreatment with forskolin and GTP. The inhibitory effects of adrenaline were also observed in membranes pretreated with cholera toxin and NAD. Moreover, the inhibition by adrenaline or clonidine was completely abolished by treatment with (a) yohimbine or (b) islet-activating protein and NAD. It is suggested that alpha 2-receptor stimulation causes inhibitory influences on adenylate cyclase activity mediated by the inhibitory GTP binding regulatory protein in synaptic membranes of rat cerebral cortex.     

Cholera toxin can catalyze ADP-ribosylation of cytoskeletal proteins

Cholera toxin catalyzes transfer of radiolabel from [32P]NAD+ to several peptides in particulate preparations of human foreskin fibroblasts. Resolution of these peptides by two-dimensional gel electrophoresis allowed identification of two peptides of Mr = 42,000 and 52,000 as peptide subunits of a regulatory component of adenylate cyclase. The radiolabeling of another group of peptides (Mr = 50,000 to 65,000) suggested that cholera toxin could catalyze ADP-ribosylation of cytoskeletal proteins. This suggestion was confirmed by showing that incubation with cholera toxin and [32P]NAD+ caused radiolabeling of purified microtubule and intermediate filament proteins.     

Forskolin-resistant Y1 mutants harbor defects associated with the guanyl nucleotide-binding regulatory protein, Gs

The properties of the adenylate cyclase from forskolin-resistant mutants of Y1 adrenocortical tumor cells was compared with the properties of the enzyme from parental Y1 cells in order to localize the site of mutation. In parental Y1 cells, forskolin stimulated adenylate cyclase activity with kinetics suggestive of an interaction at two sites; in mutant cells, forskolin resistance was characterized by a decrease in enzymatic activity at both sites. Forskolin potentiated the enzyme's responses to NaF and guanyl-5'-yl imidodiphosphate (Gpp(NH)p) in parent and mutant clones, and the mutant enzyme showed the same requirements for Mg2+ and Mn2+ as did the parent enzyme. The adenylate cyclase associated with forskolin-resistant mutants was insensitive to ACTH and was less responsive to Gpp(NH)p than was the parent enzyme. In parental Y1 cells and in the forskolin-resistant mutants, cholera toxin catalyzed the transfer of [32P]ADP-ribose from [32P]NAD+ into three membrane proteins associated with the alpha subunit of Gs; however, the amount of labeled ADP-ribose incorporated into mutant membranes was reduced by as much as 70%. Both parent and mutant membranes were labeled by pertussis toxin to the same extent. The insensitivity of the mutant adenylate cyclase to ACTH and Gpp(NH)p and the selective resistance of the mutant membranes to cholera toxin-catalyzed ADP-ribosylation suggest that a specific defect associated with Gs is involved in the mutation to forskolin resistance in Y1 cells.     

Evidence that thyrotropin-releasing hormone-induced increases in GTPase activity and phosphoinositide metabolism in GH3 cells are mediated by a guanine nucleotide-binding protein other than Gs or Gi

Thyrotropin-releasing hormone (TRH), vasoactive intestinal polypeptide (VIP) and acetylcholine stimulated high affinity GTPase activity in GH3 cell membrane preparations. The effects of acetylcholine and VIP were blocked by pretreatment of cultured cells with pertussis toxin and cholera toxin respectively. Such pretreatment, which causes covalent modification of the guanine nucleotide-binding proteins (G-proteins) of adenylate cyclase, did not, however, block the effects of TRH on GTPase activity or phosphoinositide breakdown. These data suggest that TRH receptors interact with a G-protein discrete from those associated with regulation of adenylate cyclase activity.     

Inhibition of ADP-ribosyltransferase activity of cholera toxin by MDL 12330A and chlorpromazine

ADP-ribosylation by cholera toxin of the guanine nucleotide binding regulatory protein (Gs) of rat liver membrane adenylate cyclase was inhibited by 0.1-1 mM MDL 12330A or 0.1-1 mM chlorpromazine. Basal as well as cholera toxin activated adenylate cyclase activity in liver membranes was also inhibited by the two drugs. NAD glycohydrolase activity and self-ADP-ribosylation of cholera toxin were also inhibited by MDL 12330A and chlorpromazine. These effects of MDL 12330A and chlorpromazine may be related to their effects on cholera toxin-induced fluid secretion in vivo.     

Differential effects of cholera toxin on guanine nucleotide regulation of beta-adrenergic agonist high affinity binding and adenylate cyclase activation in frog erythrocyte membranes

The guanine nucleotide regulatory protein(s) regulates both adenylate cyclase activity and the affinity of adenylate cyclase-coupled receptors for hormones or agonist drugs. Cholera toxin catalyzes the covalent modification of the nucleotide regulatory protein of adenylate cyclase systems. Incubation of frog erythrocyte membranes with cholera toxin and NAD+ did not substantially alter the dose dependency for guanine nucleotide activation of adenylate cyclase activity. In contrast, toxin treated membranes demonstrated a 10 fold increase in the concentrations of guanine nucleotide required for a half maximal effect in regulating beta-adrenergic receptor affinity for the agonist (+/-) [3H]hydroxybenzylisoproterenol. The data emphasize the bifunctional nature of the guanine nucleotide regulatory protein and suggest that distinct structural domains of the guanine nucleotide regulatory protein may mediate the distinct regulatory effects on adenylate cyclase and receptor affinity for agonists.     

Effects of guanine nucleotides on cholera toxin catalyzed ADP-ribosylation in rat adipocyte plasma membranes

ADP-ribosylation of rat adipocyte plasma membrane proteins was investigated following incubation of membranes with [alpha-32P]NAD and cholera toxin in the presence and absence of various guanine nucleotides. In membranes incubated without guanine nucleotides, cholera toxin induced incorporation of 32P into three discrete proteins of 48, 45, and 41 kDa. In membranes containing 100 microM GTP or GDP, toxin-catalyzed incorporation of 32P into the 41-kDa protein was inhibited. GMP and Gpp(NH)p (100 microM) allowed moderate incorporation of 32P into the 41-kDa protein. Toxin-catalyzed labeling of all proteins was rapid, reaching maximal levels between 5 and 10 min. Toxin-catalyzed ADP-ribosylation of the 48- and 45-kDa proteins was stimulated by GTP, reaching maximal levels at 10(-5) M GTP. Inhibition of toxin-dependent labeling of the 41-kDa protein required GTP concentrations above 10(-7) M with complete inhibition occurring between 10(-5) and 10(-4) M GTP. Cholera toxin catalyzed ADP-ribosylation was increased up to 2-fold in membranes supplemented with adipocyte cytosol. These results indicate that cholera toxin catalyzes ADP-ribosylation of three distinct adipocyte plasma membrane proteins, each of which is regulated by the amount and type of added guanine nucleotides.     

Adenylate cyclase stimulation by VIP in rat and human parotid membranes

Adenylate cyclase activity was stimulated by vasoactive intestinal peptide (VIP) in rat parotid membranes, in the presence of 100 microM guanosine triphosphate (GTP). The threshold concentration of VIP was 300 nM and the activity doubled at the maximal VIP concentration tested (30 microM). The relative potency of peptides of the VIP family was: VIP greater than peptide histidine isoleucinamide (PHI) greater than secretin. The beta-adrenergic agent isoproterenol was a more efficient activator of rat parotid adenylate cyclase and its stimulatory effect, like that of VIP, depended on the presence of GTP. The effects of VIP and isoproterenol were both potentiated by 10 microM forskolin. By comparison with rat parotid preparations, membranes from a human parotid gland responded similarly to the VIP family of peptides (VIP greater than PHI greater than secretin). In both rat and human parotid membranes, two proteins (Mr 44 kDa and 53 kDa) of the alpha-subunit of Ns (the guanyl nucleotide-binding stimulatory protein) were labelled by ADP-ribosylation, in the presence of cholera toxin. Taken together, these results indicate that VIP receptors, when coupled to Ns, were able to activate the adenylate cyclase system in rat and human parotid membranes.     

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.