Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:4.6.1.1 (adenylate cyclase)
19,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The aim of the present study is twofold: to establish the response of hepatic machinery of plasma protein biosynthesis to cholera intoxication, and to examine the same response of alloxan-diabetic hepatocytes with minimal capacity of synthesis of plasma proteins. Direct lesion of hepatic plasma membranes via ip administration of cholera toxin to male rats resulted in a typical acute-phase response (APR) of plasma proteins, which had regressed to levels similar to those of healthy controls approximately at 240 h postintoxication. The d 2 response to a single 0.16 mg/kg body weight dose was typified by a 23% reduction in the level of albumin, but a 6- and 24-fold increase in the levels of fibrinogen and alpha-1-acid glycoproteins, respectively. This response was similar (in direction but not in magnitude) to the acute-phase reaction to a simple subcutaneous administration of carrageenan. The intoxication was accompanied by a massive leakage, into the peritoneal cavity, of plasma fluid, which embraced the complete profile of acute-phase reactants. A three-step mechanism is proposed to account for the observations as follows: (1) There is a rapid formation of a stable complex between subunit B of the toxin and ganglioside GM1 of hepatic plasma membrane. An APR is induced in response to the alteration(s) of hepatic plasma membranes. (2) The release, from the choleragen-membrane complex, of polypeptide A1 and its subsequent penetration of the hepatic membrane result in both activation of adenylate cyclase and increased vascular permeability of hepatic membranes. This leads, in turn, to exudation of components of plasma fluid in the peritoneal cavity of intoxicated rats. An alternate rationale for this exudation is the slow leakage of plasma proteins out of the blood vascular system (possibly through microvesicles) into the peritoneal cavity of cholera intoxicated rats. The spectrum of acute-phase hepatic secretory components was mirrored in the corresponding peritoneal exudate. (3) The increased hepatic membrane flow provides the continued renewal of plasma membrane proteins required for its eventual repair by either endocytosis or sloughing off the toxin-bound membrane segments into the circulatory system, thus producing regression of APR. Livers of diabetic rats, an already established model in terms of APR, responded to ip administration of cholera toxin by increased biosynthesis of the identified plasma proteins and a marked reduction in total free-glucose in serum.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Acute-phase plasma protein response to cholera intoxication in healthy and diabetic rats. 767 33

Cholera toxin (CT) consists of a pentameric B subunit which binds with high affinity to ganglioside GM1, and an A subunit which stimulates adenylate cyclase, resulting in the elevation of cAMP. We now examine the effect of cationic amphiphilic drugs (CADs) on the internalization of rhodamine (Rh)-CT in cultured hippocampal neurons. CADs have recently been shown to inhibit receptor recycling by disrupting the assembly-disassembly of clathrin at the plasma membrane and on endosomes (Wang, L.-H., Rothberg, K. G., and Anderson, R. G. W. (1993) J. Cell Biol. 123, 1107-1117). Rh-CT was internalized by an energy- and temperature-dependent (presumably vesicular) mechanism to the Golgi apparatus. Internalization to the Golgi apparatus was completely but reversibly blocked by CADs, and the ability of CT to stimulate the elevation of cAMP was significantly reduced. In control cells, cAMP levels were elevated 2.3-fold after 20 min of incubation with CT, but in CAD-treated cells cAMP levels were only elevated 1.3-fold. The effect of CADs on CT internalization was not due to a direct effect of CADs on the Golgi apparatus. Our data demonstrate that CADs inhibit vesicular transport of CT to the Golgi apparatus and imply that the sorting of CT to the Golgi apparatus occurs in the same endosomal compartment involved in sorting recycling receptors to the plasma membrane, since both pathways are inhibited by CADs.
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PMID:Cationic amphiphilic drugs inhibit the internalization of cholera toxin to the Golgi apparatus and the subsequent elevation of cyclic AMP. 774 60

The effects of exogenous ganglioside GM1 (1 microM) from bovine brain on the morphological state and biochemical parameters (creatine kinase, acetylcholinesterase and adenylate cyclase activities as well as the protein, phospholipid and ganglioside content) have been studied in primary cultures of trypsin-treated dissociated cells of chicken embryonic brain. Ganglioside GM1 accelerated the growth and differentiation of cultured cells, increased the phospho- and glycolipid content and stimulated the activity of the enzymes.
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PMID:[Modification of biochemical changes in developing cultures of chick embryo nerve tissue cultures]. 781 90

The neurotoxic effect of glutamate in cultured mouse mesencephalic dopaminergic neurons was investigated. Neuron-rich cell cultures were prepared from 13-14-day-old fetal mouse ventral mesencephalic tissue. Cultures were exposed to glutamate for 10 min and evaluated for glutamate neurotoxicity (GNT) 18-24 hr later by tyrosine hydroxylase (TH) immunostaining, microtubule associated protein-2 (MAP2) immunostaining, and radiolabeled dopamine uptake assay. In glutamate-exposed cultures, the number of TH-positive neurons and the level of dopamine uptake were reduced to 40% (35-45%) and 50% (47-52%), respectively, of control cultures. The number of MAP2-positive neurons was also reduced to 47%, indicating that the GNT was not restricted or selective to dopaminergic neurons. It is concluded that GNT was mediated by the N-methyl-D-aspartic acid (NMDA) receptor from the following observations: 1) GNT was completely blocked by MK-801, an NMDA receptor antagonist; 2) NMDA itself was as toxic as glutamate; 3) 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), an antagonist of the alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid/kainate (AMPA/KA) receptor, did not block GNT; 4) kainate did not show neurotoxicity at a low concentration; and 5) two modulators of the NMDA receptor, 7-chlorokynurenic acid and magnesium, were effective in blocking GNT. Protective effects of phorbol myristate acetate, a tumor promoter, and gangliosides (GM1 and GT1b) on GNT were also demonstrated. Possible interactions between GNT and several protein kinase cascades were also investigated. Forskolin, an activator of adenyl cyclase and protein kinase A, showed some protective effect on GNT. But okadaic acid, an inhibitor of phosphatases, and genistein, a tyrosine kinase inhibitor, did not show any protective effect. These results suggest that 1) glutamate is capable of causing neuronal death in the substantia nigra; 2) GNT on dopaminergic neurons is mainly mediated by the NMDA receptor under the conditions of our study; 3) protein kinase C translocation is a key mechanism of GNT; and 4) there is an interplay of a signal transduction system in the pathomechanism of GNT.
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PMID:Glutamate neurotoxicity in mesencephalic dopaminergic neurons in culture. 790 39

Cholera toxin (CT) consists of a pentameric B subunit that binds to specific cell surface receptors identified as ganglioside GM1 and an A subunit that activates adenylylcyclase. The A subunit consists of A1 and A2 peptides linked by a disulfide bond; A2 acts to connect A to B, whereas A1 is an ADP-ribosyltransferase that modifies the alpha subunit of the stimulatory G protein (Gs). How the toxin is oriented when it binds to the cell surface and the related issue of the mechanism by which A1 gains access to Gs alpha are not known. In the present study, we used subunit-specific antibodies and their corresponding Fab fragments to assess their affects on holotoxin binding to target cells and their immunoreactivity to cell-bound toxin. Our results suggest that CT binds with A1 facing away from the membrane. Our hypothesis is further supported by the ability to assemble active CT on the cell surface of cultured human intestinal and neurotumor cells by the sequential addition of purified B and A subunits. We also observed that when cells containing bound CT were incubated at 37 degrees C, both subunits rapidly became inaccessible to their respective antibodies. We propose that the holotoxin binds with its A subunit facing away from the membrane and must enter the cell in order for A1 to be released, gain access to Gs alpha, and activate adenylylcyclase.
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PMID:Orientation of cholera toxin bound to target cells. 834 92

Cholera toxin (CT) consists of a pentameric B subunit which binds to ganglioside GM1 on the cell surface and an A subunit which activates adenylylcyclase. The latter process involves the reduction of A to the A1 peptide which ADP-ribosylates the stimulatory G protein, Gs of adenylylcyclase. There is a distinct lag phase between toxin binding and activation of adenylylcyclase. Little is known about the events during this lag including where A1 is generated and how it gains access to Gs on the cytoplasmic side of the plasma membrane. We explored the effects of several inhibitors of intracellular trafficking on the response of human SK-N-MC neurotumor and Caco-2 intestinal tumor cells to CT. Whereas chloroquine or monensin had little or no effect on CT stimulation of cyclic AMP accumulation, brefeldin A (BFA) totally inhibited the response to CT in a time- and dose-dependent and reversible manner. BFA was effective when added at the same time as CT and had an IC50 of 30 ng/ml. BFA did not alter cell surface GM1 as cells treated with BFA for 30 min bound as much 125I-CT as control cells. Furthermore, BFA inhibited CT stimulation of GM1-treated rat glioma C6 cells. BFA treatment did not affect beta-adrenergic agonist stimulation of cyclic AMP. In addition, adenylylcyclase was activated by A1 peptide and NAD+ to the same extent in membranes from control and BFA-treated cells, or when BFA was added directly to the assay. Whereas control cells generated small amounts of A1 from bound CT with time, no A1 was detected in BFA-treated cells. BFA treatment did not prevent the internalization of CT but did inhibit its degradation. BFA is known to disrupt the organization of the Golgi complex, resulting in inhibition of protein transport from the endoplasmic reticulum and redistribution of Golgi enzymes to the endoplasmic reticulum. BFA also prevents the formation of non-clathrin-coated vesicles from Golgi membranes and thus vesicular transport between Golgi cisternae. We confirmed that BFA caused the morphological disruption of the Golgi apparatus in Caco-2 cells. The data support a role for a functional Golgi apparatus with its associated vesicular routing in CT action.
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PMID:Brefeldin A blocks the response of cultured cells to cholera toxin. Implications for intracellular trafficking in toxin action. 838 69

Cholera toxin is an ubiquitous activator of intracellular adenylate cyclase and is divided in two major components: A and B. The B-component consists of several subunits that specifically bind to the external cell membrane. The receptor for the toxin, the GM1 ganglioside, is concentrated in nervous tissues. The B subunit of the cholera toxin, conjugated to different molecules (i.e., choleragenoid) is therefore a sensitive anatomical tracer and has been used to detect the presence of GM1 in mammalian tissues. Using choleragenoid, unlabeled and labeled with FITC, we have determined the distribution of the GM1 ganglioside in the vestibular system of the chinchilla. Vestibular tissues were fixed in 4% paraformaldehyde in phosphate buffer, decalcified in 10% EDTA and prepared as either whole-mount, surface-preparations, or for radial cryosections. Positive control tissue consisted of binding to normal brain tissues. Negative controls consisted of several treatments: masking of the GM1 receptors with unlabeled choleragenoid, tissue extraction of GM1 using ethanol, and preabsorbing the choleragenoid with bovine GM1. In addition, to exclude staining of glycoproteins that may have a carbohydrate structure similar to GM1, tissues were digested with trypsin prior to choleragenoid exposure. In the vestibular system, a strongly positive reaction was observed in: the sensory stereocilia and supporting cells of the maculae and cristae, epithelial cells of the planum semilunatum, and polygonal cells of the semicircular canal. Positive but less strong reactivity was observed in the sensory cell body of maculae and cristae, nerve fibers, epithelial cells of utricle and ampulla walls and flattened epithelial cells of the semicircular canals. No reactivity was present in the supporting connective tissue cells and fibrils, blood vessels, gelatinous cupula of the cristae ampullaris and statoconial membranes. Brain tissue showed strong choleragenoid reactivity. The negative controls showed no or greatly reduced reactivity to choleragenoid. Trypsin digestion did not decrease reactivity to choleragenoid.
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PMID:Localization of the GM1 ganglioside in the vestibular system using cholera toxin. 843 86

Prolongation of the action potential duration of dorsal root ganglion (DRG) neurons by low (nM) concentrations of opioids occurs through activation of excitatory opioid receptors that are positively coupled via Gs regulatory protein to adenylate cyclase. Previous results suggested GM1 ganglioside to have an essential role in regulating this excitatory response, but not the inhibitory (APD-shortening) response to higher (microM) opioid concentrations. Furthermore, it was proposed that synthesis of GM1 is upregulated by prolonged activation of excitatory opioid receptor functions. To explore this possibility we have utilized cultures of hybrid F11 cells to carry out closely correlated electrophysiological and biochemical analyses of the effects of chronic opioid treatment on a homogeneous population of clonal cells which express many functions characteristic of DRG neurons. We show that chronic opioid exposure of F11 cells does, in fact, result in elevated levels of GM1 as well as cyclic adenosine monophosphate (AMP), concomitant with the onset of opioid excitatory supersensitivity as manifested by naloxone-evoked decreases in voltage-dependent membrane K+ currents. Such elevation of GM1 would be expected to enhance the efficacy of excitatory opioid receptor activation of the Gs/adenylate cyclase/cyclic AMP system, thereby providing a positive feedback mechanism that may account for the remarkable supersensitivity of chronic opioid-treated neurons to the excitatory effects of opioid agonists as well as antagonists. These in vitro findings may provide novel insights into the mechanisms underlying naloxone-precipitated withdrawal syndromes and opioid-induced hyperalgesia after chronic opiate addiction in vivo.
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PMID:Chronic opioid treatment of neuroblastoma x dorsal root ganglion neuron hybrid F11 cells results in elevated GM1 ganglioside and cyclic adenosine monophosphate levels and onset of naloxone-evoked decreases in membrane K+ currents. 856 36

The role of receptor binding in the toxicity, immunogenicity, and adjuvanticity of the heat-labile enterotoxin of Escherichia coli (LT) was examined by comparing native LT and LT(G33D), a B-subunit receptor binding mutant, with respect to the ability to bind to galactose and to GM1, toxicity on mouse Y-1 adrenal tumor cells, the ability to stimulate adenylate cyclase in Caco-2 cells, enterotoxicity in the patent mouse model, and oral immunogenicity and adjuvanticity. In contrast to native LT, LT(G33D) was unable to bind to the galactosyl moiety of Sepharose 4B or GM1 but did retain the lectin-like ability to bind to immobilized galactose on 6% agarose beads. LT(G33D) had no enterotoxicity in the patent mouse model but exhibited residual toxicity on mouse Y-1 adrenal tumor cells and had an ability equivalent to that of native LT to stimulate adenylate cyclase in Caco-2 cells (5,000 versus 6,900 pmol per mg of protein). In addition, LT(G33D) was unable to serve as an effective oral adjuvant for induction of immunoglobulin G or A directed against a coadministered antigen. Furthermore, LT(G33D) elicited negligible serum and mucosal antibody responses against itself. These data indicate that the toxicity, immunogenicity, and oral adjuvanticity of LT are dependent upon binding of the B subunit to ganglioside GM1.
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PMID:Role of receptor binding in toxicity, immunogenicity, and adjuvanticity of Escherichia coli heat-labile enterotoxin. 939 80

The ability of membrane ABH blood group-active glycoconjugates to act as receptors of the heat-labile enterotoxin of Escherichia coli (LTh) was studied in vitro and in vivo when GM1 was blocked by the cholera toxin B subunit. Rabbits were classified as AB or H based on intestinal ABH-antigenic activities. Brush border membranes from AB rabbits contained 4 times more LTh binding sites than the H ones. LTh interaction could be inhibited by lectins that recognize ABH determinants. LTh induced a similar dose-dependent secretory response in ligated ileal loops of both types of animals. Anti-AB antibodies and Ulex europaeus I lectin could significantly reduce the fluid accumulation in AB and H rabbits, respectively. LTh caused adenylate cyclase activation even when GM1 was blocked, and this effect was abolished by the addition of specific ABH ligands. These results suggest that ABH glycoconjugates are involved in the host secretory response to LTh in rabbit intestine.
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PMID:Participation of ABH glycoconjugates in the secretory response to Escherichia coli heat-labile toxin in rabbit intestine. 1039 58


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