Siegfried Stengelin

Palytoxin-induced permeability changes in excitable membranes.

Palytoxin, a toxin isolated from the Caribean corrall Palythoa caribaeorum, increases the cation permeability of excitable membranes in vitro. Three membrane systems have been investigated: axonal membranes from crayfish walking leg nerves, membranes rich in nicotinic acetylcholine receptor isolated from Torpedo californica electric tissue and, for control, artificial liposomes. Ion permeability of the latter was not affected by palytoxin, but with both biological membranes an increase in cation permeability was observed at a palytoxin concentration of 0.14 microM. Palytoxin-induced cation flow through the axonal membrane was not inhibited by tetrodotoxin, indicating that the voltage-dependent sodium channels were not involved. The effect of palytoxin on the receptor-rich membranes was not blocked by alpha-bungarotoxin, a competitive antagonist of the nicotinic acetylcholine receptor, nor by triphenylmethylphosphonium, a blocker of the receptor-ion channel. But with both the axonal and the receptor-rich membranes ouabain was an inhibitor of the palytoxin-induced cation flow. Evidence is presented that it is not the (Na+ + K+)-ATPase which is affected by palytoxin as has been postulated for similar observations with non-neuronal membranes (Chhatwal, G.S., Hessler, H.-J. and Habermann, E. (1983) Naunyn-Schmiedebergs Arch. Pharmacol. 323, 261-268).

Radioactive labeling of toxin II from Anemonia sulcata.

Abstract Anemone toxins are useful tools for the investigation of sodium channels in nerve membranes. For this application radioactive derivatives are necessary and are described in this report. Toxin II from Anemonia sulcata (ATX II) has been tritiated by reductive alkylation via the Schiff base formed by pyridoxal phosphate and amino groups of the peptide toxin. From the mixture of reaction products two monosubstituted toxins have been isolated by ion-exchange chromatography. The site of modification has been identified as the N -terminal amino group in the one toxin and the ϵ-amino group of lysine 35 in the other. The modified toxins prolonged action potentials similar to those of the native toxins. The threshold concentration to obtain this effect was approximately three times higher for the tritiated derivatives.

Azidophenantridinium compounds as photoaffinity labels of cholinergic proteins

The synthesis of diazidopropidium and diazidoethidium is described. The applicability of these compounds as photoaffinity labels for cholinergic proteins has been investigated: diazidopropidium inhibits neuromuscular transmission. This inhibition is reversible if the compound is applied in the dark but becomes irreversible after irradiation with white light. Inhibition is accompanied by a disappearance of miniature endplate potentials. Electrophysiological analysis of this effect indicates that diazidopropidium acts postsynaptically by blocking the acetylcholine receptors. At the molecular level the action of diazidopropidium and diazidoethidium on acetylcholinesterase has been investigated: both compounds appear to bind to a peripheral acetylcholine binding site of this enzyme. Binding of 125I-labeled alpha-neurotoxin from Naja naja siamensis to purified membranes from Torpedo californica electric tissue rich in acetylcholine receptors is diminished after incubation and irradiation with diazidopropidium. About half of the toxin binding sites appear to be blocked by the photoaffinity label.