Fixation and inactivation of cholera toxin by GM1 ganglioside

Aeromonas hydrophila in acute diarrheal disease: detection of enterotoxin and biotyping of strains

Eleven isolates of Aeromonas species from human stool cultures were found to produce enterotoxin activity as determined by assay of culture filtrates in rabbit intestinal loops and rabbit skin and on adrenal Y1 cells. Hemolysin(s) and a cytotoxic protein were found to interfere in all three assay systems but could be inactivated upon heating at 56 degrees C or by specific antihemolysin. Biotyping of each isolate was performed with a conventional test system and with API 50E and APIZYM kit systems (Analytab, Inc.). No single test of the more than 70 biochemical reactions investigated was found to correlate with enterotoxigenicity in the strains of Aeromonas hydrophila examined. All strains were found to belong to ideal phenotypes of A. hydrophila, but each strain possessed its own biochemical profile.

Activation of the nigrostriatal dopaminergic pathway by injection of cholera enterotoxin into the substantia nigra

Twenty-four hours after unilateral injection of cholera enterotoxin into the rat substantia nigra there is an increase, in the striatum on the injected side, of basal adenylate cyclase activity, 3,4-dihydroxyphenylacetic acid, and 3-methoxy-4-hydroxyphenylacetic acid. Moreover, there is an increase of motor activity, and rats tend to circle contralateral to the side of the injection. Injection of cholera enterotoxin into brain nuclei may be a useful procedure for pharmacologically activating selected neuronal systems of brain and for studying the pharmacology of drugs that are suspected of interacting with these systems.

Ultrastructural study of plasma membrane GM1 in neuroectodermal cells using cholera-peroxidase

Cholera toxin was coupled to peroxidase to yield a highly specific marker for GM1 gangliosides. Study of embryonic brain cells in culture revealed intense binding of cholera-peroxidase by plasma membranes of both neurons and glial cells. In contrast, long-term monolayer glioblastoma cultures, including one producing C-type virus, revealed virtually no labelling of their plasma membranes. Such cells were shown to be capable of incorporating exogenously applied GM1 into their plasma membranes. Studies with fixed brain and synaptosomal fractions were in accord with results on embryonic brain cells in culture, and autoradiographic findings with 125I cholera supported observations made utilizing cholera-peroxidase. From our studies there is some indication that long-term propagation in vitro alters the plasma membrane GM1.

Cholera toxin-peroxidase: changes in surface labeling of glioblastoma cells with increased time in tissue culture

Cholera toxin coupled to peroxidase yielded a highly specific ultrastructural marker of plasma membrane monosialogangliosides. Studies with cultures of brain and brain tumors suggested that long-term culture of tissue in monolayers results in eventual loss of surface monosialogangliosides.

Partial purification and characterization of a heat-labile enterotoxin of Escherichia coli

A partially purified enterotoxin was obtained from the growth medium of Escherichia coli strain 711 (P307), a derivative of E. coli K-12, by ultrafiltration, precipitation with ammonium sulfate, molecular sieving, and anion exchange column chromatography. The active moiety, which is heat-labile, behaved like a protein particle of 180,000 to 200,000 daltons during molecular sieving and ultracentrifugation. During polyacrylamide gel electrophoresis in sodium dodecyl sulfate (SDS-PAGE), it dissociated into two subunits with apparent molecular weights of 68,000 to 70,000 and 14,000 to 15,000. SDS-PAGE after heating in SDS changed the larger subunit to an apparent molecular weight of about 40,000; the smaller subunit did not change. The intact particle induced rounding of the cells in Y-1 mouse adrenal tumor cells used for assay. The detergent-dissociated molecules were not active. Proteolysis of the purified toxin by tolylsulfonyl phenylalanyl chloromethyl ketone-trypsin appeared to enhance its activity. The addition of serum to the assay medium resulted in partial depression of the activity. Activity was also abolished by preincubation of the toxin with either a rabbit antiserum to it or solutions containing GM1 ganglioside. The length of time needed to evoke a response in the assay system by fractions from different stages in the purification of the enterotoxin was a useful parameter in the evaluation of specific activity.

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 GM1. 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 enzyne 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 absorb adenylate cyclase activity, and specific antibodies against the choleragen can be used for selective immunoprecipitation of adenylate cyclase activity from detergent-solubilized 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 perturbation of adenylate cyclase molecules (virtually irreversibly). These studies suggest new insights into the normal mechanisms by which hormone receptors modify membrane functions.

Interaction of cholera toxin and ganglioside G(M1)

The exotoxin produced by Vibrio cholerae is rapidly and firmly bound to the outer membrane of mammalian cells. With simple in vitro and in vivo methods and very pure gangliosides and allied glycolipids we have demonstrated that the monosialosylganglioside GM1 is the natural receptor for the cholera toxin. This ganglioside binds the toxin with a high affinity and inactivates it. The inactive derivative, choleragenoid toxoid has the same affinity to GM1 as the toxin. Ganglioside GM1 was isolated from the small intestinal mucosa of man, pig and ox in amounts of 0.1, 2.0 and 43 nmoles per g mucosa, respectively. These very large differences in the ability of the mucosal cells to bind cholera toxin. Exogenous GM1 was incorporated in vitro and in vivo in intestinal mucosal cells. The incorporation of GM1 increased the number of toxin-binding sites and increased the secretion of fluid in the gut. Vibrio cholerae sialidase did not hydrolyse the di- and trisialogangliosides of intact mucosal cells to the parent GM1-ganglioside, neither did it increase the number of cholera toxin-binding sites.

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.

Mobility of cholera toxin receptors on rat lymphocyte membranes

Fluorescein-labeled cholera toxin binds detectably to 40-60% of rat mesenteric lymph node cells and induces a temperature-dependent redistribution (patch and cap formation) of cell surface toxin receptors. The redistribution is inhibited by several "metabolic," "microtubule," and "microfilament" inhibitors, by concanavalin A, and by anticholera toxin IgG. Various studies indicate that cholera toxin is at least bivalent, and that this property may be related to both the induction of receptor redistribution and to the activation of adenylate cyclase. Membrane components which are probably identical to the sialo-glycolipid, GM1 ganglioside, appear to be mobile in the plane of the membrane. The possible role of toxin multivalency and receptor mobility in the mechanism of toxin action is considered.

Ligand-induced redistribution of lymphocyte membrane ganglioside GM1

Dynamic aspects of the binding of cholera toxin to lymphocyte membranes have been studied. We have shown that the receptor for this ligand--the GM1 ganglioside--can be laterally redistributed into aggregates and caps. Exogenous purified GM1 inserted into GM1-deficient human leukaemic cells can undergo a similar pattern of ligand-induced mobilisation. These observations may have important implications for both the general behaviour of cell surface glycolipids and the mode of action of cholera toxin on adenyl cyclase.

Mechanism of activation of adenylate cyclase by cholera toxin

Cholera toxin (choleragen) can stimulate adenylate cyclase [EC 4.6.1.1; ATP pyrophosphate-lyase (cyclizing)] activity in whole particulate fractions or purified plasma membranes of homogenates of isolated fat cells provided special precautions are taken to stabilize the enzyme during the required preincubation period. As observed with intact cells, the activation exhibits a protracted (about 25 min) lag phase, and it is blocked by ganglioside GM1 and choleragenoid ("binding" subunit of toxin). The 36,000 molecular weight subunit ("active" subunit), a hydrophobic polypeptide which does not block choleragen binding or action, can directly activate the enzyme in intact cells without a lag phase. Its effects are not blocked by ganglioside GM1 or choleragenoid, yet the stimulated activity exhibits reduced fluoride and enhanced isoproterenol sensitivity, properties characteristic of the choleragen-activated enzyme. Binding of the 125I-labeled 36,000 molecular weight subunit to cells is not saturable and is unaffected by gangliosides, choleragen, or choleragenoid, and the bound material behaves as an integral membrane protein; this protein may simply partition into the membrane matrix. With increasing time of incubation cell-bound choleragen may dissociate into its component subunits, but these remain in the membrane. Using a double antibody immunoprecipitin system, substantial precipitation of cyclase activity occurs with antisera against the 36,000 molecular weight subunit provided toxin activation has occurred. The normal process of activation may involve an initially inactive toxin--ganglioside complex which, as a result of lateral mobility and multivalent binding (lag phase), results in destabilization of the molecule with release of the "active" subunit into the membrane core where it can spontaneously associate with and perturb the cyclase complex.

Cholera toxin and cell growth: role of membrane gangliosides

The binding of cholera toxin to three transformed mouse cell lines derived from the same parent strain, and the effects of the toxin on DNA synthesis and adenylate cyclase activity, vary in parallel with the ganglioside composition of the cells. TAL/N cells of early passage, which contain large quantities of gangliosides G(M3), G(M2), G(M1), and G(Dla), as well as the glycosyltransferases necessary for the synthesis of these gangliosides, bind the most cholera toxin and are the most sensitive to its action. TAL/N cells of later passage, which lack chemically detectable G(M1) and G(Dla) and which have no UDP-Gal:G(M2) galactosyltransferase activity, are intermediate in binding and response to the toxin. SVS AL/N cells, which lack G(M2) in addition to G(M1) and G(Dla) and which have little detectable UDP-GalNAc:G(M3)N-acetylgalactosaminyltransferase activity, bind the least amount of toxin. The SVS AL/N cells are the least responsive to inhibition of DNA synthesis and stimulation of adenylate cyclase activity by cholera toxin. Gangliosides (especially G(M1)), which appear to be the natural membrane receptors for cholera toxin, may normally have important roles in the regulation of cell growth and cAMP-mediated responses.

Mode of action of cholera toxin: stabilization of catecholamine-sensitive adenylate cyclase in turkey erythrocytes

Preincubating turkey erythrocytes with cholera toxin alters their adenylate cyclase (EC 4.6.1.1) system: basal activity, maximal epinephrine-stimulatable activity, and affinity of the enzyme reaction for epinephrine are all increased. Pretreatment of erythrocytes with choleragenoid prevents these changes. Cholera toxin does not alter [(3)H]epinephrine uptake by intact erythrocytes. The increase in epinephrine-stimulatable cyclase activity appears to occur at the expense of fluoride-stimulatable activity, which is decreased by the toxin. In lysates from both toxin-treated and control cells, maximally stimulating amounts of epinephrine and fluoride, when added in combination, have a nearly additive effect on cyclase activity. These observations suggest that the adenylate cyclase system of the turkey erythrocyte may exist in two interconvertible forms, one that is catecholamine-responsive but fluoride-insensitive, and another that is fluoride-sensitive but not coupled to catecholamine receptors. Cholera toxin appears to stabilize the enzyme in its hormone receptor-coupled form.

Interaction of cholera toxin and toxin derivatives with lymphocytes. I. Binding properties and interference with lectin-induced cellular stimulation

The interaction of cholera toxin and a number of toxin derivatives, containing different proportions of light and heavy toxin-composing subunits (L and H), with mouse lymphocytes was studied. Experiments with [(125)I]toxin showed that a single cell can rapidly, within minutes, bind up to 40,000 molecules of toxin, the association constant was estimated to 7 +/- 4 x 10(8) liters/mol, and binding was found to be very similar at 37 degrees C and 5 degrees C. Immunofluorescence studies revealed that the toxin attachment is located on the cell surface, and that purified L subunit but not H subunit binds to the cells. A natural cholera toxoid, built up by aggregated L subunits, showed almost identical binding properties as toxin to the cells. Pure G(M1) ganglioside, the proposed membrane receptor structure for toxin, prevented entirely the cellular binding of both toxin and toxoid. Cholera toxin in concentrations down to approximately 5 x 10(-11) mol/liter (corresponding to 10 bound molecules/cell) inhibited thymus cells from being stimulated to DNA synthesis by concanavalin A (con A), and spleen cells from such stimulation by phytohemagglutinin. The G(M1) ganglioside but not a series of other pure structurally related gangliosides and neutral glycosphingolipids neutralized this toxin activity. Toxin derivatives which, in similarity with toxin, possessed H as well as L subunits but in other proportions, were potent inhibitors of con A-induced thymocyte stimulation, whereas the natural toxoid (aggregated L subunits), purified toxin L subunit and purified toxin H subunit were up to 300-fold less active on a weight basis. The capacity of cholera proteins to inhibit con A-induced thymocyte stimulation correlated well with their activity in the rabbit intradermal toxicity assay. The inhibitory action of cholera toxin on con A-induced thymocyte stimulation did not depend on decreased cell viability from the toxin treatment, nor was it caused by a reaction between toxin and con A. [(125)I]con A bound equally well to the cells when toxin was present as when it was absent, which proves that the toxin did not compete for cellular con A receptors. Nor did the toxin seem to disturb the general mobility of membrane receptors or their ability to accumulate in caps. It is concluded that the L type of subunit confers rapid and firm binding of cholera toxin to lymphocyte membranes, probably to G(M1) ganglioside receptors. For biologic activity the additional presence of H subunit is important. One manifestation of toxin action on lymphocytes is inhibition of lectin-induced DNA synthesis; probably this effect relates to the ability of cholera toxin to raise the levels of intracellular cyclic 3'5'-adenosine monophosphate.

Comparison of the tissue receptors for Vibrio cholerae and Escherichia coli enterotoxins by means of gangliosides and natural cholera toxoid

The in vitro binding properties of enterotoxins of Vibrio cholerae and Escherichia coli to different pure gangliosides and related neutral glycosphin-golipids were analyzed with a sorbent assay utilizing plastic tubes to which the glycolipid substances had been coupled. It was found that the cholera toxin bound to G(M1) ganglioside better than to the other tested substances G(M3), G(M3)-NGN, G(M2), G(D1a), G(D1b), G(T), G(A1), tetrahexoside-GlcNac and globoside. With this assay using G(M1)-coated tubes it is possible to measure cholera toxin even at concentrations below 1 ng/ml. Also enterotoxin of various E. coli strains bound to G(M1), but the affinity was much less than for cholera toxin. The G(M1) ganglioside, in contrast to the other glycosphingolipids, effectively inactivated cholera toxin as determined with the intradermal and the ileal loop assays; approximately equimolar concentrations of the ganglioside in relation to toxin sufficed. Also, the skin and ileal loop activities of E. coli enterotoxins could be inhibited by G(M1); however, several orders more of the ganglioside were required for such inhibition than for inactivation of the cholera toxin, and the differences between G(M1) and the other substances were less pronounced for E. coli toxins. Preincubation of rabbit ileal loops with choleragenoid, a natural toxoid of V. cholerae which has binding properties to the G(M1) ganglioside similar to cholera toxin, made the loops resistant to subsequently added enterotoxin of V. cholerae. The responsiveness to enterotoxin of E. coli was not reduced by this toxoid. A likely interpretation of these data is that the G(M1) ganglioside constitutes or at least contains the structure of functional tissue receptors for the cholera toxin, whereas the weak binding to G(M1) by E. coli enterotoxins is probably a pathogenetically insignificant reflection of structural similarities between these toxins and cholera toxin. Consequently, the cholera toxoid by occupying functional intestinal G(M1) receptors for the cholera toxin could inhibit the ileal response to this toxin, but not the response to E. coli enterotoxin since the intestinal receptors for the latter toxin are not affected by the cholera toxoid.

Stimulation of steroid secretion in adrenal tumor cells by choleragen

Choleragen, the pure protein from cholera toxin, stimulates steroid secretion by Y-1 adrenal tumor cells in culture. The secreted steroids are the same as seen after addition of adrenocorticotropic hormone. Half-maximal stimulation occurs at 15 pM; stimulation is essentially irreversible by washing and partially reversible (for about 1 hr) by antibody, and there is a latent period of about 60 min before stimulation is seen. Stimulation of adenylate cyclase occurs at about 30-fold higher choleragen concentrations. Gangliosides inhibit choleragen stimulation when added before but not after the toxin. Lipopolysaccharides from Escherichia coli, Salmonella typhosa, and Serratia marcescens also stimulate steroid secretion, but are less potent than choleragen.

Tissue receptor for cholera exotoxin: postulated structure from studies with GM1 ganglioside and related glycolipids

By a double-diffusion precipitation-in-gel technique, isolated cholera toxin as well as its natural toxoid were shown to be fixed and precipitated by the ganglioside G(M1) but not by any of the related glycolipids G(M3), G(M2), G(M1)-GlcNAc, G(D1a), G(D1b), G(T1), globoside, G(A1), and tetrahexoside-GlcNAc. Twenty-five nanograms of G(M1) was enough to give a precipitation line with 1.2 mug of toxin, whereas about 50 ng was required with this amount of toxoid. G(M1) also inactivated the toxin in the ileal loop as well as in the intradermal models in rabbits. A 1: 1 molar ratio of ganglioside to toxin was found limiting, e.g., 100 pg of G(M1) could inactivate 5 ng (about 50 blueing doses) of isolated toxin. G(M1) inactivated crude toxin (culture fil rate) with the same efficiency as isolated toxin, and the inactivating capacity of G(M1) was unaffected by mixing with other gangliosides, indicating the specificity in the reaction between G(M1) and toxin. The other glycolipids tested did not inactivate toxin except G(D1a) and G(A1) which did so with approximately 1,000 times less efficiency than G(M1). This identified the portion Gal --> GalNAc [Formula: see text] as the critical region in G(M1) for toxin fixation, and it is postulated that this may be the tissue receptor structure for the cholera toxin.