Type A botulinum toxin disorganizes quantal acetylcholine release and inhibits energy metabolism.

Journal de physiologie Pub Date : 1990-01-01
Y Dunant, J E Esquerda, F Loctin, J Marsal, D Muller
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Abstract

The physiological, morphological and biochemical effects of type A Botulinum toxin (BoTX) were analysed in the electric organ of Torpedo, a modified neuromuscular system. The quantal content of the postsynaptic potential, or electroplaque potential (EPP), was reduced by BoTX but the quantum size remained unchanged till complete failure of the neurally evoked transmission. BoTX also suppressed the occurrence of spontaneous electroplaque potentials (MEPPs) of a quantal size but potentials of a smaller amplitude still kept on occurring in the intoxicated synapses. BoTX inhibited the evoked release of acetylcholine (ACh; biochemically measured) but the rate of spontaneous ACh release transiently increased during the period when evoked release went down. On the other hand, there were no significant change of ACh content, of ACh turnover, of ACh repartition in the vesicular and free compartments, or in the number of synaptic vesicles. Surprisingly, the amount of ATP was reduced to 50% in BoTX treated tissue at the time of transmission failure; also the level of creatine phosphate (CrP) was lowered to less than 20% and the rate of activity of creatine kinase was reduced. It was concluded that, electrophysiologically, BoTX affects synaptic transmission in a very similar way in the electric organ and in the neuromuscular junctions. On the other hand, the shortage of ATP supply found in the present study may play a role in the pathophysiology of intoxication and should be taken into account in investigations designed to see whether BoTX affects various phosphorylations in cholinergic nerve terminals.

A型肉毒杆菌毒素破坏量乙酰胆碱的释放并抑制能量代谢。
分析了A型肉毒毒素(BoTX)对鱼雷(鱼雷是一种改良的神经肌肉系统)电器官的生理、形态和生化影响。BoTX降低了突触后电位或电斑电位(EPP)的量子含量,但量子大小保持不变,直到神经诱发传递完全失败。BoTX也抑制了量子大小的自发电斑电位(MEPPs)的发生,但在醉酒突触中仍继续发生较小幅度的电位。BoTX抑制乙酰胆碱(ACh)的释放;但乙酰胆碱的自发释放率在诱发释放下降期间短暂增加。另一方面,乙酰胆碱含量、乙酰胆碱周转、囊室和自由室乙酰胆碱再分配以及突触囊泡数量均无显著变化。令人惊讶的是,在传输失败时,BoTX处理组织的ATP量减少到50%;磷酸肌酸(CrP)水平降低至20%以下,肌酸激酶活性降低。结果表明,从电生理角度看,BoTX对电器官和神经肌肉连接处突触传递的影响非常相似。另一方面,本研究中发现的ATP供应不足可能在中毒的病理生理中发挥作用,在研究BoTX是否影响胆碱能神经末梢的各种磷酸化时应考虑到这一点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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