Mechanism of action of choleragen andE. coli heat-labile enterotoxin: activation of adenylate cyclase by ADP-ribosylation

Summary Choleragen exerts its effects on cells through the activation of adenylate cyclase. The initial event appears to be the binding of the B subunit of the toxin to ganglioside G_M1 on the cell surface, following which there is a delay prior to activation of adenylate cyclase. Patching and capping of the toxin on the cell surface, perhaps involved in the internalization of the enzymatically active subunit, may be occuring during this time. The activation of adenylate cyclase, which is catalyzed by the A₁ peptide of choleragen, does not require the B subunit or ganglioside G_M1. The A₁ peptide catalyzes the transfer of ADP-ribose from NAD to an amino acid, probably arginine, in a 42 000 dalton membrane protein. This protein appears to be the GTP-binding component (or G/F factor) of the adenylate cyclase system and is cruical to the regulation of cyclase activity by hormones such as epinephrine. ADP-ribosylation of the G/F factor is enhanced by GTP and, in some systems, by a cytosolic factor. GTP is also required for stabilization and optimal catalytic function of the choleragen-activated cyclase. Calmodulin, a calcium-binding protein, is necessary for expression of catalytic activity of the toxin-activated adenylate cyclase in brain and other tissues. The ADP-ribosyltransferase activity required for activation of the cyclase is an intrinsic property of the A₁ peptide of choleragen which is expressed only after the peptide is released from the holotoxin by reduction of a single disulfide bond. In the absence of cellular components, choleragen catalyzes the ADP-ribosylation of small guanidino compounds such as arginine as well as peptides and proteins that contain arginine. It is assumed, therefore, that the site of ADP-ribosylation in the natural acceptor protein is an arginine or similar amino acid. When guanidino compounds are not present as ADP-ribose acceptors, choleragen hydrolyzes NAD to ADP-ribose and nicotinamide at a considerably slower rate. E. coli heat-labile enterotoxin (LT) is very similar to choleragen in structure and function. It consists of two types of subunits, A and B, with sizes comparable to those of the A and B subunits of choleragen. Binding of LT to the cell surface is enhanced by prior incorporation of G_M1 but not other gangliosides; the oligosaccharide of G_M1 specifically interacts with LT and its B subunit. The A subunit of LT exhibits ADP-ribosyltransferase activity following activation by thiol to release the A₁ peptide. The A subunit of LT can be isolated in an ‘unnicked’ form and thus requires, in addition to reduction by a thiol, proteolytic cleavage to generate the active A₁ peptide. Like choleragen, LT uses guanidino compounds as model ADP-ribose acceptors and catalyzes the ADP-ribosylation of a 42 000 dalton protein in cell membrane prepatations. ADP-ribosyltransferases that use arginine as ADP-ribose acceptors are not restricted to bacterial systems; such an enzyme has been purified to apparent homogeneity (>500 000-fold) from turkey erythrocytes. Based on a subunit molecular weight of 28 000, its turnover number with arginine as the ADP-ribose acceptor is considerably higher than that of either toxin. Although with low molecular weight guanidino derivatives the substrate specificity of the enzyme is similar to that of choleragen, with protein substrates it clearly differs. The physiological role of the turkey erythrocyte transferase remains to be established.     

Mechanism of activation of adenylate cyclase by Vibrio cholerae enterotoxin. Relations to the mode of activation by hormones.

The influence of Vibrio cholerae enterotoxin (choleragen) on the response of adenylate cyclase to hormones and GTP, and on the binding of 125I-labeled glucagon to membranes, has been examined primarily in rat adipocytes, but also in guinea pig ileal mucosa and rat liver. Incubation of fat cells with choleragen converts adenylate cyclase to a GTP-responsive state; (-)-isoproterenol has a similar effect when added directly to membranes. Choleragen also increases by two- to fivefold the apparent affinity of (-)-isoproterenol, ACTH, glucagon, and vasoactive intestinal polypeptide for the activation of adenylate cyclase. This effect on vasoactive intestinal polypeptide action is also seen with the enzyme of guinea pig ileal mucosa; the toxin-induced sensitivity to VIP may be relevant in the pathogenesis of cholera diarrhea. The apparent affinity of binding of 125I-labeled glucagon is increased about 1.5- to twofold in choleragen-treated liver and fat cell membranes. The effects of choleragen on the response of adenylate cyclase to hormones are independent of protein synthesis, and they are not simply a consequence to protracted stimulation of the enzyme in vivo or during preparation of the membranes. Activation of cyclase in rat erythrocytes by choleragen is not impaired by agents which disrupt microtubules or microfilaments, and it is still observed in cultured fibroblasts after completely suppressing protein synthesis with diphtheria toxin. Choleragen does not interact directly with hormone receptor sites. Simple occupation of the choleragen binding sites with the analog, choleragenoid, does not lead to any of the biological effects of the toxin.     

Cholera toxin and membrane gangliosides: Binding and adenylate cyclase activation in normal and transformed cells

Summary A virally transformed, ganglioside GM₁-deficient cell line binds 2% of the cholera toxin (choleragen) bound by the parent, line and is less responsive to choleragen with respect to adenylate cyclase stimulation. This biological response is maximal when 10% of choleragen-binding sites in the transformed line, or 0.5% in the parent line, are occupied. In contrast, in isolated fat cells saturation of binding and adenylate cyclase stimulation are seen at very similar concentrations.Incubation of ganglioside GM₁ with intact cells increases choleragen binding (defined here as ganglioside incorporation) in the transformed cell line but does not enhance the biological response to choleragen. Stimulation of adenylate cyclase is enhanced in isolated fat cells, however, by exogenous ganglioside GM₁. The binding and cyclase response in fat cells can be reduced by the addition of the inactive analog and competitive antagonist, choleragenoid, and there is recovery of the enzyme response and binding upon subsequent addition of exogenous GM₁. Failure of enhancement in the transformed cell line is explained by the presence of a five- to tenfold excess of binding sites over the number required for the full biological effect of choleragen. Cells with a large excess of toxin receptors are relatively refractory to the blocking effects of choleragenoid on biological responses. Notably, untransformed cells, which contain large quantities of toxin receptor, cannot incorporate exogenously added ganglioside GM₁. These findings suggest the possible existence in the cytoplasmic membrane of specific molecular structures, present in finite and limited number, for recognizing and accepting ganglioside molecules exposed to the external medium.     

Mechanism of action of choleragen

Choleragen exerts its effect on cells through activation of adenylate cyclase. Choleragen initially interacts with cells through binding of the B subunit of the toxin to the ganglioside G_M1 on the cell surface. Subsequent events are less clear. Patching or capping of toxin on the cell surface may be an obligatory step in choleragen action. Studies in cell-free systems have demonstrated that activation of adenylate cyclase by choleragen requires NAD. In addition to NAD, requirements have been observed for ATP, GTP, and calcium-dependent regulatory protein. GTP also is required for the expression of choleragen-activated adenylate cyclase. In preparations from turkey erythrocytes, choleragen appears to inhibit an isoproterenol-stimulated GTPase. It has been postulated that by decreasing the activity of a specific GTPase, choleragen would stabilize a GTP-adenylate cyclase complex and maintain the cyclase in an activated state. Although the holotoxin is most effective in intact cells, with the A subunit having 1/20th of its activity and the B subunit (choleragenoid) being inactive, in cell-free systems the A subunit, specifically the A₁ fragment, is required for adenylate cyclase activation. The B protomer is inactive. Choleragen, the A subunit, or A₁ fragment under suitable conditions hydrolyzes NAD to ADP-ribose and nicotinamide (NAD glycohydrolase activity) and catalyzes the transfer of the ADP-ribose moiety of NAD to the guandino group of arginine (ADP-ribosyltransferase activity). The NAD glycohydrolase activity is similar to that exhibited by other NAD-dependent bacterial toxins (diphtheria toxin, Pseudomonas exotoxin A), which act by catalyzing the ADP-ribosylation of a specific acceptor protein. If the ADP-ribosylation of arginine is a model for the reaction catalyzed by choleragen in vivo, then arginine is presumably an analog of the amino acid which is ADP-ribosylated in the acceptor protein. It is postulated that choleragen exerts its effects on cells through the NAD-dependent ADP-ribosylation of an arginine or similar amino acid in either the cyclase itself or a regulatory protein of the cyclase system.     

CHOLERA TOXIN

1. Death in several infectious diseases is caused by protein toxins secreted by invading bacteria. Cholera toxin is a simple protein secreted by Vibrio cholerae colonizing the gut; it is responsible for the massive diarrhoea that is cholera. 2. The primary action of cholera toxin is an activation of adenylate cyclase, an enzyme found on the inner membrane of eukaryotic cells that catalyses the conversion of ATP to cyclic AMP. Consequent increases in the intracellular concentration of cyclic AMP are responsible for other manifestations of cholera toxin including the diarrhoea. The toxin is active on almost all eukaryotic cells. 3. The toxin can be purified from culture filtrates of V. cholera. It has a molecular weight of 82000; and is composed of one subunit A (itself two polypeptide chains joined by a disulphide bond: AI (22000) and A2 (5000)) and five subunits B (11500). These can be separated in dissociating solvents such as detergents or 6 M guanidine hydrochloride. An amino-acid sequence of subunit B has been published. The five B subunits (sometimes found by themselves in the filtrate and known as ‘choleragenoid’) are probably arranged in a ring with the subunit A in the middle joined to them non-covalently by peptide A2. 4. The first action of cholera toxin on a cell is to bind to the membrane strongly and irreversibly. Several thousand molecules of toxin bind to each cell and the binding constants are of the order of 10^-10 M. The binding is rapid, but is followed by a lag phase of about an hour before the intracellular cyclic AMP concentration begins to increase. 5. Ganglioside G_M1, a complex amphiphilic lipid found in cell membranes, binds tightly to the toxin which shows an enzyme-like specificity for this particular ganglioside. Toxin that has already bound ganglioside can no longer bind to cells and is therefore inactive. This and other experiments using cells depleted of endogenous ganglioside suggest that ganglioside G_M1 is the natural receptor of the toxin on the cell surface. The binding is followed by a lateral movement of the toxin-ganglioside complex in the cell surface forming a ‘cap’ at one pole of the cell. 6. The binding of ganglioside by toxin is a function exclusively of subunit B; Subunit A does not bind and can be eluted with 8 M urea from an insolubilized toxin-ganglioside complex. Subunit B is not by itself active, and so preincubation with B can protect cells or even whole gut from the action of toxin by occupying all the ganglioside binding sites. 7. Subunit A is responsible for activation of adenylate cyclase. Purified subunit A or just peptide AI is active by itself and this activity is not inhibited by ganglioside or by antisera to subunit B. In intact cells the activity is low and shows the characteristic lag phase but in lysed cells the subunit (or the whole toxin) is much more active and there is no lag phase. This suggests that the lag phase represents the time that subunit A takes to cross the cell membrane and get to its target. 8. Several cofactors are needed for toxin activity in lysed cells: NAD+, ATP, sulphydryl compounds and another unidentified cytoplasmic component. The activity of the cyclase is altered in a complex way generally rather similarly to the action of hormones such as adrenalin, but it is difficult to draw any general conclusions. 9. There are two chief theories of how cholera toxin acts. The first is that subunit A (or just peptide AI) enters the cell and there catalyses some reaction leading to activation of the cyclase. The cleavage of NAD+ into nicotinamide and adenosine diphosphoribose could be such a reaction; it is catalysed by high concentrations of cholera toxin. 10. The other theory is that part of the toxin binds directly to the adenylate cyclase or to some other molecule that can then interact with the cyclase, perhaps after the lateral movement of the toxin-ganglioside complex in the cell surface. This binding may be related to the known action of guanyl nucleotides on the cell surface. 11. The entry of peptide AI into the cell and its transport through the membrane is mediated by the binding of subunits B to the cell surface, perhaps just because the binding increases the local concentration of subunit A, or perhaps following specific conformational changes in the subunits and the formation of a tunnel of B subunits through the membrane. An experiment showing that the toxin remains active when the subunits are covalently bonded together suggests that peptide AI does not separate completely from the rest of the molecule. 12. There are several other proteins that resemble cholera toxin in structure and function. For example, glycoprotein hormones such as thyrotrophin also activate adenylate cyclase and have an apparently similar subunit structure with one type of subunit that binds to a ganglioside. There may also be analogies between the amino-acid sequences of toxin and hormones. 13. The enterotoxin made by some strains of Escherichia coli produces a similar diarrhoea to that of cholera. Several different toxic proteins have been prepared but they all seem to activate adenylate cyclase in the same sort of way as cholera toxin does and also to cross-react immunologically with it. The E. coli toxin also reacts with ganglioside G, but the reaction is weak and probably physiologically insignificant. Salmonella typhimurium secretes a similar toxin. 14. Tetanus toxin also reacts with a ganglioside receptor. This protein has two polypeptide chains of which only one reacts with the ganglioside; but the molecular activity is not yet known. 15. Diphtheria toxin has an A fragment that is directly responsible for the toxicity (by catalysing an NAD+ cleavage reaction leading to the total inhibition of protein synthesis) and a B fragment that gets the A fragment into the cells. This structure of active and binding components therefore seems to be common to many toxins. 16. The ability to produce toxin may confer some selective advantage on V. cholerae. The toxin may originate from accidental incorporation of DNA from an eukaryotic host, or alternatively from some material involved with the cyclic AMP metabolism of the bacterium.     

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.     

Mechanism of action of cholera toxin: Studies on the lag period

Summary The lag period for activation of adenylate cyclase by choleragen was shorter in mouse neuroblastoma N18 cells than in rat glial C6 cells. N18 cells have 500-fold more toxin receptors than C6 cells. Treatment of C6 cells with ganglioside G_M1 increased the number of toxin receptors and decreased the lag phase. Choleragen concentration also effected the lag phase, which increased as the toxin concentration and the amount of toxin bound decreased. The concentration, however, required for half-maximal activation of adenylate cyclase depended on the exposure time; at 1.5, 24, and 48 hr, the values were 200, 1.1., and 0.35pm, respectively. Under the latter conditions, each cell was exposed to 84 molecules of toxin.The length of the lag period was temperature-dependent. When exposed to choleragen at 37, 24, and 20 °C, C6 cells began to accumulate cyclic AMP after 50, 90, and 180 min, respectively. In G_M1-treated cells, the corresponding times were 35, 60, and 120 min. Cells treated with toxin at 15 °C for up to 22 hr did not accumulate cAMP, whereas above this temperature they did. Antiserum to choleragen, when added prior to choleragen, completely blocked the activation of adenylate cyclase. When added after the toxin, the antitoxin lost its inhibitory capability in a time and temperature-dependent manner. Cells, however, could be preincubated with toxin at 15 °C, and the antitoxin was completely effective when added before the cells were warmed up. Finally, cells exposed to choleragen for >10 min at 37 °C accumulated cyclic AMP when shifted to 15 °C. Under optimum conditions at 37°C, the minimum lag period for adenylate cyclase activation in these cells was 10 min. These findings suggest that the lag period for cholerage action represents a temperature-dependent transmembrane event, during which the toxin (or its active component) gains access to adenylate cyclase.Abbreviations used: ganglioside nomenclature according to Svennerholm [32] (see Table 1 for structures) cAMP adenosine 35-monophosphate - MIX 3-isobutyl-1-methylxanthine - HEPES N-2-hydroxyethylpiperazine-N-2-ethane sulfonic acid - PBS phosphate-buffered saline (pH 7.4)     

Isolation, purification and characterization of regulatory properties of adenylate cyclase from rabbit heart]

Rabbit heart membranes possessing the adenylate cyclase activity were isolated and purified by extraction with high ionic strength solutions and centrifugation in the sucrose density gradient. It was shown that the membranes are characterized by a high percentage of cholesterol (molar ratio cholesterol/phospholipids is 0.24) and an increased activity of Na, K-ATPase, which suggests the localization of adenylate cyclase in the sarcolemma. During centrifugation in the sucrose density gradient the activities of andenylate cyclase and Na,K-ATPase are not separated. Treatment of heart sarcolemma with a 0.3% solution of lubrol WX results in 10--20% solubilization of adenylate cyclase. Purification of the enzyme in the membrane fraction is accompanied by a decrease in the activity of phosphodiesterase; however, about 2% of the heart diesterase total activity cannot be removed from the sarcolemma even after its treatment with 0.3% lubrol WX. Epinephrine and NaF activate adenylate cyclase without changing the pH dependence of the enzyme. The alpha-adrenergic antagonist phentolamine has no effect on the adenylate cyclase activation by catecholamines, glucagon and histamine; the beta-adrenergic antagonist alprenolol competitively inhibits the effects of isoproterenol, epinephrine and norepinephrine, having no effect on the enzyme activation by glucagon and histamine. There is no competition between epinephrine, glucagon and histamine for the binding site of the hormone; however, there may occur a competition between the hormone receptors for the binding to the enzyme. A combined action of several hormones on the membranes results in the averaging of their individual activating effects. When the hormones were added one after another, the extent of adenylate cyclase activation corresponded to that induced by the first hormone; the activation was insensitive to the effect of the second hormone added. It is assumed that the outer membrane of myocardium cells contains a adenylate cyclase and three types of receptors, each being capable to interact with the same form of enzyme. The activity of adenylate cyclase is determined by the type of the receptor, to which it is bound and by the amount of the enzyme-receptor complex.     

The mechanism of action of cholera toxin in pigeon erythrocyte lysates.

The adenylate cyclase activity of intact pigeon erythrocytes begins to rise after about 20 min of exposure to cholera toxin. The maximum rate at which the cyclase activity increases appears to be limited by the number of toxin molecules which can reach an intracellular target. If the erythrocytes are made permeable to the toxin by a bacterial hemolysin, no such limit exists, and adenylate cyclase activity starts to rise immediately upon the addition of toxin, and continues to rise to a maximum at an initially constant rate which is dependent upon the concentration of toxin. On lysed erythrocytes, the addition of cholera antitoxin immediately prevents any further rise in adenylate cyclase activity, but does not reverse any activation already achieved. Erythrocyte lysates may also be activated by isolated peptide A1 of cholera toxin, although activation of adenylate cyclase of intact erythrocytes requires the complete toxin molecule. In the intact cells, toxin first attaches by its Component B to surface receptors of which there are about 30 per erythrocyte. Subsequently, peptide A1 but not Component B is inserted into the erythrocyte. It takes only about 1 min at 37 degrees for peptide A1 to be sufficiently deep within the cell membrane to be inaccessible to extracellular antitoxin, but its complete transit through the membrane appears to take longer. The surface receptors are used only once, for they remain blocked by Component B. The number of receptors available on the surface may be increased by soaking cells in ganglioside GM1. Cholera toxin also decreases the rate of apparently spontaneous loss of adenylate cyclase activity and increases the response to epinephrine. Theophylline inhibits the action of cholera toxin.     

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.     

Guanine nucleotide activation and inhibition of adenylate cyclase as modified by islet-activating protein, pertussis toxin, in mouse 3T3 fibroblasts

Guanine nucleotide regulation of membrane adenylate cyclase activity was uniquely modified after exposure of 3T3 mouse fibroblasts to low concentrations of islet-activating protein (IAP), pertussis toxin. The action of IAP, which occurred after a lag time, was durable and irreversible, and was associated with ADP-ribosylation of a membrane Mr = 41,000 protein. GTP, but not Gpp(NH)p, was more efficient and persistent in activating adenylate cyclase in membranes from IAP-treated cells than membranes from control cells. GTP and Gpp(NH)p caused marked inhibition of adenylate cyclase when the enzyme system was converted to its highly activated state by cholera toxin treatment or fluoride addition, presumably as a result of their interaction with the specific binding protein which is responsible for inhibition of adenylate cyclase. This inhibition was totally abolished by IAP treatment of cells, making it very likely that IAP preferentially modulates GTP inhibitory responses, thereby increasing GTP-dependent activation and negating GTP-mediated inhibition of adenylate cyclase.     

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.     

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.     

Inhibition of cholera toxin-stimulated intestinal epithelial cell adenylate cyclase by adenosine analogs.

The ability of various adenosine analogs to inhibit cholera toxin activation of the intestinal epithelial cell adenylate cyclase-cyclic AMP system was investigated. After incubation of cells with cholera toxin for 6 hr, large increases in cellular cyclic AMP content were observed. Addition of 2', 5'-dideoxyadenosine during the last 30 min of this 6-hr incubation resulted in 70% reduction in elevated cyclic AMP content. Other analogs were not effective inhibitors. 2', 5'-Dideoxyadenosine was also a potent inhibitor of cholera toxin-activated intestinal cell adenylate cyclase activity with half-maximal inhibition occuring at 16 muM. NaF-stimulated cyclase was less susceptible to inhibition. The data suggest that inhibition by 2', 5'-dideoxyadenosine is due at least in part to direct inhibition of the cholera toxin-activated intestinal adenylate cyclase activity.     

Neuropeptide Y inhibits cardiac adenylate cyclase through a pertussis toxin-sensitive G protein

Neuropeptide Y, a major neuropeptide and potent vasoconstrictor, inhibited isoproterenol-stimulated adenylate cyclase activity in cultured rat atrial cells as well as in atrial membranes. Prior treatment of the cells with pertussis toxin blocked the inhibitory action of neuropeptide Y. Pertussis toxin is known to uncouple the receptors for other inhibitors of adenylate cyclase by ADP-ribosylation of the alpha-subunit of Gi, the inhibitory guanine nucleotide binding component of adenylate cyclase. The toxin specifically catalyzed the ADP-ribosylation of a 41-kilodalton atrial membrane protein which corresponded to the Gi subunit. These results suggest that neuropeptide Y may mediate some of its physiological effects through specific receptors linked to the inhibitory pathway of adenylate cyclase.     

Identification of the predominant substrate for ADP-ribosylation by islet activating protein

Islet activating protein (IAP), a toxin isolated from Bordetella pertussis, blocks the ability of inhibitory hormones to attenuate adenylate cyclase activity and enhances the ability of stimulatory hormones to activate the enzyme. The toxin appears to act by catalyzing the transfer of ADP ribose from NAD to a 41,000-dalton protein in target cell membranes. A protein purified from rabbit liver membranes, apparently composed of 41,000- and 35,000-dalton subunits, is shown to be a specific substrate for IAP. Cholera toxin does not ADP-ribosylate this protein. In contrast, the purified guanine nucleotide-binding regulatory component of adenylate cyclase (G/F), which is ADP-ribosylated by cholera toxin, is not covalently modified by IAP. Equilibrium binding studies and photoaffinity labeling experiments demonstrate that the 41,000-dalton subunit of the IAP substrate has a specific binding site for guanine nucleotides.     

Activity of covalently cross-linked cholera toxin with the adenylate cyclase of intact and lysed pigeon erythrocytes.

Reaction of cholera toxin with NN'-bis(carboximidomethyl)tartaramide dimethyl ester produced several cross-linked species that had subunit B (which binds to the cell surface) and peptides A1 (which activates adenylate cyclase) and A2 all covalently joined together. This cross-linded material had activity with pigeon erythrocytes that was comparable in all respects with that of native toxin. It activated the adenylate cyclase of whole cells, showing a characteristic lag phase, and this activation was increased if the cells had been preincubated with ganglioside GM1, but abolished if the protein had been preincubated with the ganglioside. It activated the enzyme in lysed cells more strongly and without the lag phase. These results show that the toxin is active even when peptide A1 cannot be released from the rest of the molecule.     

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.     

Stimulation and modulation of adenylate cyclase by Sendai virus.

Stimulation of adenylate cyclase activity occurs in membranes prepared from toad erythrocytes preincubated briefly (at 37° or 4°) with ultraviolet light-inactivated Sendai virus. Stimulation occurs with as few as five virions per cell, and it is blocked by pretreating the virus with the membrane glycolipid, ganglioside GM₁. Virus treatment also alters modulation of adenylate cyclase by hormones, nucleotides and sodium fluoride. Interactions of viral envelope antigens with plasma membrane components may thus elicit functional changes possibly important in the pathogenesis of viral infections.     

Prostaglandin E-induced heterologous desensitization of hepatic adenylate cyclase. Consequences on the guanyl nucleotide regulatory complex

Prostaglandin E (PGE) receptor density in hepatic plasma membranes can be down-regulated by in vivo exposure to the 16,16-dimethyl analog of PGE2, and this is associated with desensitization of PGE-sensitive adenylate cyclase. These studies examined adenylate cyclase response to other agonists in membranes whose PGE receptor density was 51% decreased and whose maximal PGE-stimulated adenylate cyclase activity was 31% decreased. Down-regulated membranes had a 37% decrease in their maximal response to glucagon, indicating that treatment with the PGE analog had induced both homologous and heterologous desensitization. To determine whether adenylate cyclase had been affected, stimulation with NaF, guanyl 5'-yl imidodiphosphate (GppNHp), and forskolin was examined in both intact and solubilized membranes. Intact membranes had decreased adenylate cyclase responses to all three stimulators (NaF, -41%; GppNHp, -25%; forskolin, -41%) as did solubilized membranes (NaF, -51%; GppNHp, -50%; forskolin, -50%), suggesting alterations in adenylate cyclase rather than indirect membrane effects. Cholera toxin activation and labeling were examined to more directly assess whether the guanine nucleotide (G/F) regulatory component of adenylate cyclase had been affected. Cholera toxin activation was 42% less in down-regulated membranes, and these membranes incorporated less label when the incubation was performed in the presence of [32]NAD. Solubilized G/F subunit activity from down-regulated membranes was less effective in reconstitution of adenylate cyclase activity from cyc- cell membranes than G/F activity from control membranes. These data indicate that in vivo exposure to the PGE analog causes both homologous and heterologous desensitization of adenylate cyclase as well as an apparent quantitative decrease in G/F.