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.     

Mechanism of action of choleragen. Evidence for ADP-ribosyltransferase activity with arginine as an acceptor.

Choleragen catalyzed the hydrolysis of NAD to ADP-ribose and nicotinamide; nicotinamide production was dramatically increased by L-arginine methyl ester and to a lesser extent by D- or L-arginine, but not by other basic amino acids. Guanidine was also effective. Nicotinamide formation in the presence of L-arginine methyl ester was greatest under conditions previously shown to accelerate the hydrolysis of NAD by choleragen (Moss, J., Manganiello, V. C., and Vaughan, M. (1976) Proc. Natl. Acad. Sci. U.S.A. 73, 4424-4427). After incubation of [adenine-U14C]NAD and L[3H]arginine with coleragen, a product was isolated by thin layer chromatography that contained adenine and arginine in a 1:1 ratio and has been tentatively identified as ADP-ribose-L-arginine. Parallel experiments with [carbonyl-14C]NAD have demonstrated that formation of the ADP-ribosyl-L-arginine derivative was associated with the production of [carbonyl-14C]nicotinamide. As guanidine itself was active and D- and L-arginine was equally effective in promoting nicotinamide production, whereas citrulline, which possesses a ureido rather than a guanidino function, was inactive, it seems probable that the guanidino group rather than the alpha-amino moiety participated in the linkage to ADP-ribose. Based on the assumption that the ADP-ribosylation of L-arginine by choleragen is a model for the NAD-dependent activation of adenylate cyclase by choleragen, it is proposed that the active A protomer of choleragen catalyzes the ADP-ribosylation of an arginine, or related amino acid residue in a protein, which is the cyclase itself or is critical to its activation by choleragen.     

NAD-dependent ADP-ribosylation of arginine and proteins by Escherichia coli heat-labile enterotoxin.

Escherichia coli heat-labile enterotoxin (labile toxin, LT) catalyzed the hydrolysis of NAD to ADP-ribose and nicotinamide and the ADP-ribosylation of arginine (Moss, J., and Richardson, S.H. (1978) J. Clin. Invest. 62, 281-285). Analysis of the product of the ADP-ribosylation of arginine by nuclear magnetic resonance spectroscopy indicated that the reaction was stereospecific and resulted in the formation of alpha-ADP-ribosyl-L-arginine. This reaction product rapidly anomerized to yield a mixture of the alpha and beta forms. In the presence of [adenine-U-14C]NAD, E. coli enterotoxin catalyzed the transfer of the radiolabel to proteins; the ADP-ribosylation of proteins was inhibited by arginine methyl ester, an alternative substrate. Digestion of the 14C-protein with snake venom phosphodiesterase released predominantly 5'-AMP. No product was obtained with a mobility similar to that of 2'-(5'-phosphoribosyl)-5'-AMP. This result is consistent with the covalent attachment by the enterotoxin of ADP-ribose rather than poly(ADP-ribose) to protein. Thus, LT is catalytically equivalent to choleragen, an enterotoxin of Vibrio cholerae, and activates adenylate cyclase through a similar stereospecific ADP-ribosylation reaction.     

Amino acid-specific ADP-ribosylation. Sensitivity to hydroxylamine of [cysteine(ADP-ribose)]protein and [arginine(ADP-ribose)]protein linkages

Hydroxylamine stability has been used to classify (ADP-ribose)protein bonds into sensitive and resistant linkages, with the former representing (ADP-ribose)glutamate, and the latter, (ADP-ribose)arginine. Recently, it was shown that cysteine also serves as an ADP-ribose acceptor. The hydroxylamine stability of [cysteine([32P]ADP-ribose)]protein and [arginine([32P] ADP-ribose)]protein bonds was compared. In transducin, pertussis toxin catalyzes the ADP-ribosylation of a cysteine residue, whereas choleragen (cholera toxin) modifies an arginine moiety. The (ADP-ribose)cysteine bond formed by pertussis toxin was more stable to hydroxylamine than was the (ADP-ribose)arginine bond formed by choleragen. The (ADP-ribose)cysteine bond apparently represents a third class of ADP-ribose bonds. Pertussis toxin ADP-ribosylates the inhibitory guanyl nucleotide-binding regulatory protein (Gi) of adenylate cyclase, whereas choleragen modifies the stimulatory guanyl nucleotide-binding regulatory protein (Gs). These (ADP-ribose)protein linkages are identical in stability to those formed in transducin by the two toxins, consistent with the probability that cysteine and arginine are modified in Gi and Gs, respectively. Bonds exhibiting differences in hydroxylamine-stability were found in membranes from various non-intoxicated mammalian cells following incubation with [32P]NAD, which may reflect the presence of endogenous NAD:protein-ADP-ribosyl-transferases.     

Stimulation of choleragen enzymatic activities by GTP and two soluble proteins purified from bovine brain

Choleragen (cholera toxin) activates adenylate cyclase by catalyzing ADP-ribosylation of Gs alpha, the stimulatory guanine nucleotide-binding protein. It was recently found (Tsai, S.-C., Noda, M., Adamik, R., Moss, J., and Vaughan, M. (1987) Proc. Natl. Acad. Sci. U. S. A. 84, 5139-5142) that a bovine brain membrane protein known as ADP-ribosylation factor or ARF, which enhances ADP-ribosylation of Gs alpha, also increases the GTP-dependent NAD:arginine and NAD:protein ADP-ribosyltransferase, NAD glycohydrolase, and auto-ADP-ribosylation activities of choleragen. We report here the purification and characterization of two soluble proteins from bovine brain that similarly enhance the Gs alpha-dependent and independent ADP-ribose transfer reactions catalyzed by toxin. Like membrane ARF, both soluble factors are 19-kDA proteins dependent on GTP or GTP analogues for activity. Maximal ARF effects were observed at a molar ratio of less than 2:1, ARF/toxin A subunit. Dimyristoyl phosphatidylcholine was necessary for optimal ADP-ribosylation of Gs alpha but inhibited auto-ADP-ribosylation of the choleragen A1 subunit and NAD:agmatine ADP-ribosyltransferase activity. It appears that the soluble factors directly activate choleragen in a GTP-dependent fashion. The relationships of the ARF proteins to the ras oncogene products and to the family of guanine nucleotide-binding regulatory proteins that includes Gs alpha remains to be determined.     

Inhibitors of protein synthesis block action of cholera toxin

Prior treatment of macrophages with cycloheximide blocked the activation of adenylate cyclase by choleragen. The effect of cycloheximide was time and dose dependent and also caused by puromycin. Toxin receptors and the catalytic and regulatory components of the cyclase were still present. As degradation and generation of the A₁ subunit of choleragen was also blocked, we propose the existence of a membrane component that mediates the translocation of choleragen across the membrane.     

Isolation ofEscherichia coli heat-labile enterotoxin by affinity chromatography: Characterization of subunits

This paper describes the isolation ofEscherichia coli heat-labile enterotoxin (LT) by affinity chromatography on an anti-cholera toxin immunoglobulin-Sepharose column, and the subunit composition of crude and affinity-isolated LT. LT and its subunits were assayed with ganglioside (G_M1)-ELISA, immunodiffusion, skin toxicity, and broken cell adenylate cyclase activation methods. The results show that the immunoaffinity method, applied to LT of different strains and batches, yielded about 100-fold purification with approximately 50% recovery of LT antigen. LT was shown to contain a G_M1-ganglioside binding subunit as well as another subunit which does not bind to G_M1 but activates adenylate cyclase. Immunodiffusion tests showed that the two LT subunits were immunologically related to but not identical with, respectively, the B and A subunits of cholera toxin. The LT “A” and “B” subunits were present in similar proportions in the affinity-isolated and crude LT preparations, but in the purified fraction they had only partially reassociated into holotoxin.     

Location and amino acid sequence around the ADP-ribosylation site in the cholera toxin active subunit A1

Renatured, S-carboxymethylated subunit A₁ of cholera toxin possess the ADP-ribose transferase activity (Lai, et.al., Biochem. Biophys. Res. Commun. 1981, $\text{102}$, 1021). In the absence of acceptor self ADP-ribosylation of A₁ subunit was observed. Stoicheometric incorporation of ADP-ribose moiety was achieved in 20 min at room temperature in a 0.1 – 0.2M PO₄(Na) buffer, pH 6.6. On incubation of the complex with polyarginine, 75% of the enzyme-bound ADP-ribose moiety was transferred to the acceptor in 25 min. The ADP-ribosylated A₁ was stable at low pH, and on cleavage with BrCN, the ADP-ribose moiety was found associated with peptide Cn I, the COOH-terminal fragment of A₁ subunit. On further fragmentation with cathepsin D, a dodecapeptide containing ADP-ribose moiety was isolated whose structure was determined as: Asp-Glu-Glu-Leu-His-Arg-Gly-Tyr-Arg¹-Asp-Arg-Tyr. The Arg¹ in the peptide was indicated to be the site of ADP-ribosylation.     

ADP-ribosylation of brain synaptosomal proteins correlates with adenylate cyclase activation

ADP-ribosylation of the adenylate cyclase $\text{G}\text{F}$ regulatory subunit by cholera toxin is a major tool for the study of this enzyme. Investigation of the brain enzyme has been hampered up to now by the failure to demonstrate cholera toxin-dependent ADP-ribosylation of membrane-bound proteins. Synaptosomes prepared by flotation from fresh brains homogenized in the presence of protease inhibitors yielded membranes of which several proteins could be ADP-ribosylated by the toxin. The same membranes subjected to mild proteolysis could not be ADP-ribosylated. Adenylate cyclase activation and ADP-ribosylation were simultaneous processes. The major labeled species was of 47,000 M_r. It was solubilized by Lubrol-PX, together with other labeled polypeptides. As analyzed on sucrose gradients, the 47,000 M_r protein was found both in the 3S region, and in the adenylate cyclase containing fraction (9.1S).     

Demonstration of choleragen-dependent ADP-ribosylation in whole cells and correlation with the activation of adenylate cyclase

3T3C₂ mouse fibroblasts rendered permeable to (α^?32P)NAD⁺ show cholera toxin-dependent labeling of a 45,000 m.w. protein and of a doublet of polypeptides around 52,000 m.w. These same bands are ADP-ribosylated in broken cells. Membranes prepared from pigeon erythrocytes pretreated with choleragen show a decrease in subsequent cholera toxin-specific ADP-ribosylation of a 43,000 m.w. polypeptide. Both whole cell and broken cell adenylate cyclase activation and toxin-specific ADP-ribosylation are reversed specifically by low pH and high concentrations of toxin and nicotinamide in all systems. Thus ADP-ribosylation appears to be relevant to the molecular action of choleragen in whole cells as well as in broken cells.     

Structure and function of cholera toxin and hormone receptors

The enterotoxin from Vibrio cholerae is a protein of 100,000 mol wt which stimulates adenylate cyclase activity ubiquitously. The binding of biologically active ¹²⁵I-labeled choleragen to cell membranes is of extraordinary affinity and specificity. The binding may be restricted to membrane-bound ganglioside G_MI. This ganglioside can be inserted into membranes from exogenous sources, and the increased toxin binding in such cells can be reflected by an increased sensitivity to the biological effects of the toxin. Features of the toxin-activated adenylate cyclase, including conversion of the enzyme to a GTP-sensitive state, and the increased sensitivity of activation by hormones, suggest analogies between the basic mechanism of action of choleragen and the events following binding of hormones to their receptors. The action of the toxin is probably not mediated through intermediary cytoplasmic events, suggesting that its effects are entirely due to processes involving the plasma membrane. The kinetics of activation of adenylate cyclase in erythrocytes from various species as well as in rat adipocytes suggest a direct interaction between toxin and the cyclase enzyme which is difficult to reconcile with catalytic mechanisms of adenylate cyclase activation. Direct evidence for this can be obtained from the comigration of toxin radioactivity with adenylate cyclase activity when toxin-activated membranes are dissolved in detergents and chromatographed on gel filtration columns. Agarose derivatives containing the “active” subunit of the toxin can specifically adsorb adenylate cyclase activity, and specific antibodies against the choleragen can be used for selective immunoprecipitation of adenylate cyclase activity from detergentsolubilized preparations of activated membranes. It is proposed that toxin action involves the initial formation of an inactive toxin-ganglioside complex which subsequently migrates and is somehow transformed into an active species which involves relocation within the two-dimensional structure of the membrane with direct pertubation of adenylate cyclase molecules (virtually irreversibly). These studies suggest new insights into the normal mechanisms by which hormone receptors modify membrane functions.     

GTP stabilization of adenylate cyclase activated and ADP-ribosylated by choleragen

Choleragen activates adenylate cyclase in human skin fibroblasts by catalyzing the ADP-ribosylation of the 42,000 and 47,000 dalton guanyl nucleotide-binding regulatory components (G) of adenylate cyclase. The ADP-ribose linkage to 42,000 and 47,000 dalton proteins was stable at 30°C for 1 h with or without GTP, whereas GTP was required to stabilize activity of the G proteins. In human erythrocytes, choleragen catalyzed the ADP-ribosylation of only a 42,000 dalton G. The ADP-ribosyl-protein linkage was stable for 1 h at 30°C whether or not GTP was present, despite a rapid loss of G activity in the absence of GTP. Inactivation of choleragen-activated G in both the human fibroblast and human erythrocyte is, therefore, not secondary to the de-ADP-ribosylation of specifically labeled G subunits.     

Kinetic mechanisms of two NAD:arginine ADP-ribosyltransferases: the soluble, salt-stimulated transferase from turkey erythrocytes and choleragen, a toxin from Vibrio cholerae

A subunit of choleragen and an erythrocyte ADP-ribosyltransferase catalyze the transfer of ADP-ribose from NAD to proteins and low molecular weight guanidino compounds such as arginine. These enzymes also catalyze the hydrolysis of NAD to nicotinamide and ADP-ribose. The kinetic mechanism for both transferases was investigated in the presence and absence of the product inhibitor nicotinamide by using agmatine as the acceptor molecule. To obtain accurate estimates of kinetic parameters, the transferase and glycohydrolase reactions were monitored simultaneously by using [adenine-2,8-3H]NAD and [carbonyl-14C]NAD as tracer compounds. Under optimal conditions for the transferase assay, NAD hydrolysis occurred at less than 5% of the Vmax for ADP-ribosylation; at subsaturating agmatine concentrations, the ratio of NAD hydrolysis to ADP-ribosylation was significantly higher. Binding of either NAD or agmatine resulted in a greater than 70% decrease in affinity for the second substrate. All data were consistent with a rapid equilibrium random sequential mechanism for both enzymes.     

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.     

Pertussis Toxin-Catalyzed ADP-Ribosylation: Effects on the Coupling of Inhibitory Receptors to the Adenylate Cyclase System

Abstract

The adenylate cyclase system consists of stimulatory and inhibitory hormone and drug receptors coupled through different GTP-binding proteins to a catalytic unit, responsible for the synthesis of cAMP from ATP. Pertussis toxin blocks the effect of inhibitory agonists on the catalytic unit by enzymatically inactivating the inhibitory GTP-binding protein (G_i). Study of the inhibitory arm of the cyclase system has been facilitated by the dissection of the overall process of hormonal inhibition of cAMP formation into a series of reactions characteristic of the individual protein components of this complex system; pertussis toxin has proven to be a useful tool with which to study these individual reactions. Exposure of cells or membranes to pertussis toxin in the presence of NAD results in ADP-ribosylation of a 41,000 Da subunit of G_i. ADP-ribosylation of G_i has a number of effects on the overall and partial reactions of the cyclase system, including a loss of a) hormonal inhibition of cAMP formation, b) hormonal stimulation of GTPase and c) agonist-induced release of membrane-bound guanyl nucleotides. In addition, in toxin-treated membranes, the affinity of inhibitory receptors for agonist but not antagonist is decreased with no significant change in receptor number.     

Retinoic Acid-Induced Differentiation of Human Neuroblastoma SH-SY5Y Cells Is Associated with Changes in the Abundance of G Proteins

Abstract: Western blot analysis, using subtype-specific anti-G protein antibodies, revealed the presence of the following G protein subunits in human neuroblastoma SH- SY5Y cells: Gaα, G_iα1, G_jα2, G_cα, G_zα, and Gβ. Differentiation of the cells by all-trans-retinoic acid (RA) treatment (10 μmol/L; 6 days) caused substantial alterations in the abundance of distinct G protein subunits. Concomitant with an enhanced expression of μ-opioid binding sites, the levels of the inhibitory G proteins G_iα1 and G_jα1 were found to be significantly increased. This coordinate up-reg- ulation is accompanied by functional changes in μ-opioid receptor-stimulated Iow-K_m GTPase, μ-receptor-mediated adenylate cyclase inhibition, and receptor-independent guanosine 5′-(βγ-imido)triphosphate [Gpp(NH)p; 10 nmol/ L]-mediated attenuation of adenylate cyclase activity. In contrast, increased levels of inhibitory G proteins had no effect on muscarinic cholinergic receptor-mediated adenylate cyclase inhibition. With respect to stimulatory receptor systems, a reciprocal regulation was observed for prosta- glandin E₁ (PGE₁) receptors and G_sα, the G protein subunit activating adenylate cyclase. RA treatment of SH-SY5Y cells increases both the number of PGE₁ binding sites and PGE₁ stimulated adenylate cyclase activity, but significantly reduced amounts of G_zα were found. This down- regulation is paralleled by a decrease in the stimulatory activity of G_zα as assessed in S49 cyc- reconstitution assays. However, the reduction in G_aα levels had no effect on both intrinsic and receptor-independent-activated [Gpp(NH)p or forskolin; 100 μtmol/L each] adenylate cyclase, suggesting that the amount of G_zα is in excess over the functional capacity of adenylate cyclase in SH-SY5Y cell membranes. Additional quantitative changes were found for G_zα, G_cα, and Gβ subunits. In contrast, neuronal differentiation in the presence of 12-O-tetradecanoylphor- bol 13-acetate (16 nmol/L; 6 days) failed to affect G protein abundance. Our results provide evidence for a specific RA effect on the abundance of distinct G protein sub- units in human SH-SY5Y neuroblastoma cells. These alterations might contribute to functional changes in transmembrane signaling pathways associated with RA-in- duced neuronal differentiation of the cells.     

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.     

ADP-ribosylation of arginine

Arginine adenosine-5′-diphosphoribosylation (ADP-ribosylation) is an enzyme-catalyzed, potentially reversible posttranslational modification, in which the ADP-ribose moiety is transferred from NAD⁺ to the guanidino moiety of arginine. At 540 Da, ADP-ribose has the size of approximately five amino acid residues. In contrast to arginine, which, at neutral pH, is positively charged, ADP-ribose carries two negatively charged phosphate moieties. Arginine ADP-ribosylation, thus, causes a notable change in size and chemical property at the ADP-ribosylation site of the target protein. Often, this causes steric interference of the interaction of the target protein with binding partners, e.g. toxin-catalyzed ADP-ribosylation of actin at R177 sterically blocks actin polymerization. In case of the nucleotide-gated P2X7 ion channel, ADP-ribosylation at R125 in the vicinity of the ligand-binding site causes channel gating. Arginine-specific ADP-ribosyltransferases (ARTs) carry a characteristic R-S-EXE motif that distinguishes these enzymes from structurally related enzymes which catalyze ADP-ribosylation of other amino acid side chains, DNA, or small molecules. Arginine-specific ADP-ribosylation can be inhibited by small molecule arginine analogues such as agmatine or meta-iodobenzylguanidine (MIBG), which themselves can serve as targets for arginine-specific ARTs. ADP-ribosylarginine specific hydrolases (ARHs) can restore target protein function by hydrolytic removal of the entire ADP-ribose moiety. In some cases, ADP-ribosylarginine is processed into secondary posttranslational modifications, e.g. phosphoribosylarginine or ornithine. This review summarizes current knowledge on arginine-specific ADP-ribosylation, focussing on the methods available for its detection, its biological consequences, and the enzymes responsible for this modification and its reversal, and discusses future perspectives for research in this field.     

Pertussis-toxin insensitive enkephalin inhibition of adenylyl cyclase in lacrimal acinar cells

The mechanism by which the inhibitory effect of d-ala²-met-enkephalinamide (DALA) on lacrimal acinar adenylyl cyclase is exerted was assessed in membrane preparations by a cAMP protein binding assay. Inhibition by the analogue was GTP-dependent with a significant enhancement of the inhibitory effect by GTP. While pretreatment of membranes with either cholera or pertussis toxin resulted in stimulation of adenylyl cyclase activity, modification of the G_iα subunit by pertussis-toxin catalyzed ADP-ribosylation did not effect the hormonal inhibition of adenylyl cyclase. Incubation of membranes with manganese, however, prevented the inhibitory action of DALA in addition to enhancing basal and forskolin-stimulated adenylyl cyclase activity. The results suggest that the inhibitory effect of DALA in lacrimal acinar cells is exerted via a mechanism other than pertussis-toxin sensitive coupling of the receptor to adenylyl cyclase through G_i. The mechanism may be effected through a pertussis-toxin insensitive G protein, through an interaction with G_i that is pertussis-toxin insensitive, or through an interaction with the catalytic subunit of adenylyl cyclase.     

The sites on the regulatory component of adenylate cyclase which are ADP-ribosylated by cholera toxin

In rat liver membranes cholera toxin ADP-ribosylated two polypeptides (M_r 42000 and 47000) in the regulatory component of adenylate cyclase. L-arginine methyl ester specifically inhibited both the activation of adenylate cyclase and ADP-ribosylation by cholera toxin, suggesting that cholera toxin modified arginine, or arginine-like, residues. A hydrolysis-resistant analogue of GTP (β, γ-imidoguanosine 5′-triphosphate, p(NH)ppG) bound to the regulatory protein in an essentially irreversible manner. Pretreatment with the analogue failed to inhibit the labelling of polypeptides by cholera toxin showing that the sites for ADP-ribosylation were different from those at which guanyl nucleotides were bound.