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A New Scorpion Venom Toxin Paralytic to Insects that Affects Na + Channel Activation
Author(s) -
Borchani Lamia,
Mansuelle Pascal,
Stankiewicz Maria,
Grolleau Françoise,
Cestèle Sandrine,
Karoui Habib,
Lapied Bruno,
Rochat Hervé,
Pelhate Marcel,
Ayeb Mohamed
Publication year - 1996
Publication title -
european journal of biochemistry
Language(s) - English
Resource type - Journals
eISSN - 1432-1033
pISSN - 0014-2956
DOI - 10.1111/j.1432-1033.1996.00525.x
Subject(s) - scorpion venoms , venom , depressant , sodium channel , depolarization , biology , scorpion toxin , periplaneta , scorpion , chemistry , biophysics , pharmacology , biochemistry , cockroach , sodium , ecology , organic chemistry
A new toxin, BotIT2, with a unique mode of action on the isolated giant axon of the cockroach Periplaneta americana and DUM (dorsal unpaired median) neurons, has been purified from the venom of the scorpion Buthus occitanus tunetunus. Its structural, antigenic and pharmacological properties are compared to those of three other groups of neurotoxins found in Buthidae scorpion venoms. Like excitatory, depressant and α‐type insect‐selective neurotoxins, BotIT2 is toxic to insects, but shows the following common and distinctive characteristics. (a) As α‐type toxins, BotIT2 lack strict selectivity to insects; they have measurable but low toxicity to mice. (b) As depressant toxins and unlike α‐type toxins, BotIT2 is able to displace iodinated AaHIT from its binding sites in insect neuronal membranes. This indicates that the binding site for BotIT2 is identical, contiguous or in allosteric interaction with that of AaHIT and depressant toxins. (c) The BotIT2 amino acid sequence shows strong similarity to depressant toxins. However, unexpectedly, despite this high sequence similarity, BotIT2 shares moderate cross‐antigenic reactivity with depressant toxins. (d) Voltage and current‐clamp studies show that BotIT2 induces limited depolarization concomitantly with the development of depolarizing after potential, repetitive activity and later plateau potentials terminated by bursts. Under voltage‐clamp conditions, BotIT2 specifically acts on Na + channels by decreasing the peak Na + current and by simultaneously inducing a new current with very slow activation/deactivation kinetics. The voltage dependence of this slow current is not significantly different from that of the control current. These observations indicate that BotIT2 chiefly modifies the kinetics of axonal and DUM neuronal membrane Na + ‐channel activation.

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