Cooperative activation of action potential Na+ ionophore by neurotoxins.
(17/1174)
Four neurotoxins that activate the action potential Na+ ionophore of electrically excitable neuroblastoma cells interact with two distinct classes of sites, one specific for the alkaloids veratridine, batrachotoxin, and aconitine, and the second specific for scorpion toxin. Positive heterotropic cooperativity is observed between toxins bound at these two classes of sites. Tetrodotoxin is a noncompetitive inhibitor of activation by each of these toxins (KI = 4-8 nM). These results suggest the existence of three functionally separable components of the action potential Na+ ionophore: two regulatroy components, which bind activating neurotoxins and interact allosterically in controlling the activity of a third ion-transport component, which binds tetrodotoxin. (+info)
Interaction of cholera toxin and membrane GM1 ganglioside of small intestine.
(18/1174)
Ganglioside GM1 was isolated from the small intestinal mucosa of man, pig, and beef and amounted to 0.1, 2.0, and 43 nmol per g fresh weight, respectively. These differences in GM1 content were associated with a quantitatively differing ability of the mucosal cells to bind cholera toxin. Human cells bound about 15,000 toxin molecules when saturated with the toxin, porcine cells 120,000, and bovine cells 2,600,000 molecules. The association constant (KA) of the cholera toxin binding was, for cells of all three species, about 10(9) liters/mol. Exogenously added GM1 ganglioside was incorporated in intestinal mucosal cells as well as in intact rabbit small bowel. The increment in GM1 was associated with a correspondingly increased number of binding sites for cholera toxin, whereas KA was unchanged. GM1 incorporation increased the sensitivity of the rabbit small bowel to the diarrheogenic action of cholera toxin. Vibrio cholerae sialidase hydrolyzed isolated intestinal diand trisialogangliosides to GM1. However, the enzyme did not change the ganglioside pattern of intestinal mucosa, had very little influence on the number of toxin binding sites on intestinal cells, and did not alter the sensitivity of the small bowel to the diarrheogenic action of the toxin. These results demonstrate a relationship in the intestinal mucosa between the GM1 ganglioside concentration, the number of binding sites for cholera toxin, and the sensitivity to the biologic action of the toxin. Thus, the study strongly supports the concept that the GM1 ganglioside is the intestinal binding receptor for cholera toxin. (+info)
Cholera toxin activation of adenylate cyclase in cancer cell membrane fragments.
(19/1174)
Activation of adenylate [ATP pyrophosphate-lyase (cyclizing), EC 4.6.1.1] by cholera toxin (84,000 daltons, 5.5 S) is demonstrated in plasma membrane fragments of mouse ascites cancer cells. The activation of adenylate cyclase is mediated by a macromolecular cyclase activating factor (MCAF), which has a sedimentation constant of 2.7 S and a molecular weight of about 26,000. MCAF is derived from, and may be identical to the "A fragment" of cholera toxin. Generation of MCAF depends on prior interaction of cholera toxin with either dithiothreitol, NADH, NAD, or a low-molecular-weight component (less than 700 daltons) present in cytoplasm. Subsequent exposure of this pretreated cholera toxin to cell membranes from a variety of mouse ascites cancer cells is followed rapidly by the appearance of MCAF, which no longer requires dithiothreitol, NADH, or NAD for the activation of adenylate cyclase. Activation of adenylate cyclase by MCAF in ascites cancer cell membrane fragments is not reversed by repeated washing of these membrane fragments. Adenylate cyclase in normal cell membrane fragments fails to respond either to cholera toxin or MCAF in the presence of dithiothreitol. In striking contrast, the adenylate cyclase in membrane fragments from five ascites cancer cells responds to either MCAF or native cholera toxin preincubated with dithiothreitol, NADH, or NAD. (+info)
Mechanism of activation of adenylate cyclase by cholera toxin.
(20/1174)
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. (+info)
Intradialytic removal of protein-bound uraemic toxins: role of solute characteristics and of dialyser membrane.
(21/1174)
BACKGROUND: The efficiency of dialysis membranes is generally evaluated by assessing their capacity to remove small, water-soluble and non-protein-bound reference markers such as urea or creatinine. However, recent data suggest that protein-bound and/or lipophilic substances might be responsible for biochemical alterations characterizing the uraemic syndrome. METHODS: In the present study, the total concentrations of four uraemic retention compounds (indoxyl sulphate, hippuric acid, 3-carboxy-4-methyl-5-propyl-2-furanpropionic acid (CMPF) and p-cresol) and of tryptophan, the only protein-bound amino acid and a precursor of indoxyl sulphate, were compared with those of urea and creatinine in pre- and post-dialysis serum and in dialysate of 10 patients; two high-flux (HF) membranes (cellulose triacetate (CTA) and polysulphone (PS)) and a low-flux polysulphone (LFPS) membrane were compared in a crossover design, using HPLC. RESULTS: Except for hippuric acid (67.3+/-17.5% decrease), major differences were found in the percentage removal of the classical uraemic markers on one hand (creatinine 66.6+/-7.0% and urea 75.5+/-5.8% decrease) and the studied protein-bound and/or lipophilic substances on the other (indoxyl sulphate, 35.4+/-15.3% and p-cresol 29.0+/-14.2% decrease; tryptophan, 27.5+/-40.3%, and CMPF, 22.4+/-17.5% increase; P<0.01 vs urea and creatinine in all cases). Hippuric acid removal was more pronounced than that of the remaining protein-bound compounds (P<0. 01). After correction for haemoconcentration, per cent increase of tryptophan and CMPF was less substantial, while per cent negative changes for the remaining compounds became more important. There was a correlation between creatinine and urea per cent removal at min 240 (r=0.51, P<0.01), but all the other compounds showed no significant correlation with either of these two. The three membranes were similar regarding the changes of total solute concentrations from the start to the end of dialysis. CONCLUSIONS: Urea and creatinine are far more efficiently removed than the other compounds under study, except for hippuric acid. There are no striking differences between the HF membranes. Moreover, compared with the LF membrane these HF membranes do not appear to be superior in removing the studied compounds. (+info)
The cytotoxic plant protein, beta-purothionin, forms ion channels in lipid membranes.
(22/1174)
Thionins are small cysteine-containing, amphipathic plant proteins found in seeds and vegetative tissues of a number of plant genera. Many of them have been shown to be toxic to microorganisms such as fungi, yeast, and bacteria and also to mammalian cells. It has been suggested that thionins are present in seeds to protect them, and the germinating seedling, from attack by phytopathogenic microorganisms, but the mechanism by which they kill cells remains unclear. Using electrophysiological measurements, we have shown that beta-purothionin from wheat flour can form cation-selective ion channels in artificial lipid bilayer membranes and in the plasmalemma of rat hippocampal neurons. We suggest that the generalized toxicity of thionins is due to their ability to generate ion channels in cell membranes, resulting in the dissipation of ion concentration gradients essential for the maintenance of cellular homeostasis. (+info)
Pharmacologic characterization of the Na+ ionophores in L6 myotubes.
(23/1174)
We present a pharmacologic characterization of the Na+ ionophores present in L6 myotubes in vitro. Action potentials are abolished by replacement of the external Na+ by Tris. The amplitude of the action potential is generally resistant to high concentrations of tetrodotoxin (10(-5) M) and saxitoxin (10(-6 M), but the effect of these agents is highly variable. Veratridine (10(-4 M) consistently induces, as a short-term effect, a marked prolongation of the falling phase of the action potential. As a long-term effect, veratridine consistently induces a Na+-dependent reduction in the resting potential of the cell. The effects of veratridine on the action potential are not antagonized by tetrodotoxin or saxitoxin. However, the effects of veratridine on the resting potential are strongly antagonized by tetrodotoxin (10(-5) M) and fully inhibited by saxitoxin (10(-6) M). Significantly, under conditions where saxitoxin has fully inhibited the effects of veratridine on the resting potential, the myotubes are capable of generating overshooting action potentials. In contrast to their sensitivity to veratridine, L6 myotubes are insensitive to 10(-5) M alpha-dihydro-grayanotoxin-II. These results are discussed in the contexts of developmental significance and current views about Na+ ionophores. (+info)
Membrane potential dependent binding of scorpion toxin to action potential Na+ ionophore.
(24/1174)
Depolarization of neuroblastoma cells causes a 70-fold increase in the apparent dissociation constant KD for scorpion toxin enhancement of activation of the action potential Na+ ionophore by veratridine and a large increase in the rate of reversal of scorpion toxin action. Depolarization also inhibits binding of 125I-labeled scorpion toxin to a small number of saturable binding sites on electrically excitable neuroblastoma cells and increases the rate of dissociation of scorpion toxin from these sites. The results suggest that scorpion toxin binds to a regulatory component of the action potential Na+ ionophore whose conformation changes on depolarization. (+info)