Action potential counting at giant mossy fiber terminals gates information transfer in the hippocampus

Chamberland Simon; Timofeeva Yulia; Evstratova AlesyaVolynski KirillToth Katalin

首页> 外文期刊>Proceedings of the National Academy of Sciences of the United States of America. >Action potential counting at giant mossy fiber terminals gates information transfer in the hippocampus

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Action potential counting at giant mossy fiber terminals gates information transfer in the hippocampus

机译：Action potential counting at giant mossy fiber terminals gates information transfer in the hippocampus

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Neuronal communication relies on action potential discharge, with the frequency and the temporal precision of action potentials encoding information. Hippocampal mossy fibers have long been recognized as conditional detonators owing to prominent short-term facilitation of glutamate release displayed during granule cell burst firing. However, the spiking patterns required to trigger action potential firing in CA3 pyramidal neurons remain poorly understood. Here, we show that glutamate release from mossy fiber terminals triggers action potential firing of the target CA3 pyramidal neurons independently of the average granule cell burst frequency, a phenomenon we term action potential counting. We find that action potential counting in mossy fibers gates glutamate release over a broad physiological range of frequencies and action potential numbers. Using rapid Ca2+ imaging we also show that the magnitude of evoked Ca2+ influx stays constant during action potential trains and that accumulated residual Ca2+ is gradually extruded on a time scale of several hundred milliseconds. Using experimentally constrained 3D model of presynaptic Ca2+ influx, buffering, and diffusion, and a Monte Carlo model of Ca2+-activated vesicle fusion, we argue that action potential counting at mossy fiber boutons can be explained by a unique interplay between Ca2+ dynamics and buffering at release sites. This is largely determined by the differential contribution of major endogenous Ca2+ buffers calbindin-D-28K and calmodulin and by the loose coupling between presynaptic voltage-gated Ca2+ channels and release sensors and the relatively slow Ca2+ extrusion rate. Taken together, our results identify a previously unexplored information-coding mechanism in the brain.

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《Proceedings of the National Academy of Sciences of the United States of America.》 |2018年第28期|7434-7439|共6页
作者
Chamberland Simon; Timofeeva Yulia; Evstratova AlesyaVolynski KirillToth Katalin;
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作者单位

Univ Laval, CERVO Brain Res Ctr, Dept Psychiat & Neurosci, Quebec City, PQ G1J 2G3, Canada;

Univ Warwick, Dept Comp Sci, Coventry, W Midlands, England;

UCL, Inst Neurol, London WC1E 6BT, England;

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收录信息美国《科学引文索引》(SCI);美国《生物学医学文摘》(MEDLINE);美国《化学文摘》(CA);
原文格式 PDF
正文语种英语
中图分类自然科学总论;
关键词
short-term plasticity; presynaptic release; mossy fiber; hippocampus;

Action potential counting at giant mossy fiber terminals gates information transfer in the hippocampus

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