通过膜纳米管内的线粒体进行细胞间远距离物理信号传递：一种假设。

Pub Date : 2016-06-06 DOI:10.1186/s12976-016-0042-5

Felix Scholkmann

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摘要

单细胞之间通过细胞间通信（信号）进行协调互动，可实现多细胞生物体运作所需的复杂行为。一种新发现的细胞间信号传递机制依赖于纳米管状的细胞间连接，即 "膜纳米管"（MNTs）。本文提出的假设是，MNTs 内的线粒体可以形成一个连接结构（线粒体网络），从而实现细胞间的能量和信号交换。本文提出了两种能量和信号传输模式：电/电化学和电磁（光学）。本文回顾了支持这一假设的实验工作，并就所讨论主题的未来研究提出了建议。

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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Long range physical cell-to-cell signalling via mitochondria inside membrane nanotubes: a hypothesis.

Coordinated interaction of single cells by cell-to-cell communication (signalling) enables complex behaviour necessary for the functioning of multicellular organisms. A quite newly discovered cell-to-cell signalling mechanism relies on nanotubular cell-co-cell connections, termed "membrane nanotubes" (MNTs). The present paper presents the hypothesis that mitochondria inside MNTs can form a connected structure (mitochondrial network) which enables the exchange of energy and signals between cells. It is proposed that two modes of energy and signal transmission may occur: electrical/electrochemical and electromagnetic (optical). Experimental work supporting the hypothesis is reviewed, and suggestions for future research regarding the discussed topic are given.

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