Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0027819 (neuroblastoma)
 27,800 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

1. Sodium uptake associated with the activation of voltage-sensitive sodium channels by alkaloid activators, batrachotoxin, veratridine, and aconitine in presynaptic nerve terminals isolated from the central nervous system of cockroach (Periplaneta americana) was investigated. 2. Batrachotoxin (K0.5, 0.2 microM) was full agonist as for most effective activator of Na+ uptake; veratridine (K0.5, 2.5 microM) and aconitine (K0.5, 7.6 microM) produced a maximal stimulation of 22Na+ uptake that were 71% and 43% respectively of that produced by batrachotoxin. 3. Veratridine-dependent 22Na+ uptake was completely inhibited by tetrodotoxin (I0.5, 11 nM), a specific inhibitor of the nerve membrane sodium channels. 4. The present study describes appropriate conditions for measuring neurotoxins--stimulated sodium transport in insect central nervous system synaptosomes. The data show that voltage-sensitive sodium channels as defined by specific activation by the alkaloid neurotoxins are qualitatively distinct in insect synaptosomes than those previously described for vertebrate brain synaptosomes, cultured neuronal cell, nerve membrane vesicles and neuroblastoma cells.
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PMID:Alkaloid neurotoxins-dependent sodium transport in insect synaptic nerve-ending particles. 290 50

Batrachotoxin, veratridine and aconitine, activators of the voltage-dependent sodium channel in excitable cell membranes, increase the rate of 22Na+ uptake by mouse brain synaptosomes. Batrachotoxin was both the most potent (K0.5, 0.49 microM) and most effective activator of specific 22Na+ uptake. Veratridine (K0.5, 34.5 microM) and aconitine (K0.5, 19.6 microM) produced maximal stimulations of 22Na+ uptake that were 73% and 46%, respectively, of that produced by batrachotoxin. Activation of 22Na+ uptake by veratridine was completely inhibited by tetrodotoxin (I50, 6 nM ), a specific blocker of nerve membrane sodium channels. These results identify appropriate conditions for measuring sodium channel-dependent 22Na+ flux in mouse brain synaptosomes. The pharmacological properties of mouse brain synaptosomal sodium channels described here are distinct from those previously described for sodium channels in rat brain synaptosomes and mouse neuroblastoma cells.
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PMID:Mouse brain synaptosomal sodium channels: activation by aconitine, batrachotoxin, and veratridine, and inhibition by tetrodotoxin. 614 26

Batrachotoxin has been reported to inhibit fast axonal transport. We have examined the effect of batrachotoxin on saltatory organelle movements in N115 neuroblastoma cells (a model of fast axonal transport) using time-lapse video intensification microscopy. Batrachotoxin (0.1-1.0 microM) inhibits saltatory organelle movement. Contrary to previously published hypotheses, this inhibition of intra-axonal movement depends upon the action of batrachotoxin on action potential Na+ channels. Evidence for this conclusion is: (1) the range of concentrations of batrachotoxin which inhibit saltatory organelle movement is consistent with the dose-response curve for the activation of action potential Na+ channels by batrachotoxin in N18 neuroblastoma cells; (2) tetrodotoxin, which blocks action potential Na+ channels, prevents the inhibition of organelle movements by batrachotoxin; (3) batrachotoxin has no effect on saltatory movement in cells, including some neuroblastoma cell lines, which lack action potential Na+ channels; and (4) in Na+-free or low Na+ media, batrachotoxin does not block organelle movement. We suggest that changes in internal ion concentrations which follow the influx of Na+ are responsible for the inhibition of fast axonal transport by batrachotoxin.
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PMID:Batrachotoxin blocks saltatory organelle movement in electrically excitable neuroblastoma cells. 626 81