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活细胞中驱动蛋白介导的HER2囊泡运输的逐步运动。

Stepwise movements in vesicle transport of HER2 by motor proteins in living cells.

作者信息

Watanabe Tomonobu M, Higuchi Hideo

机构信息

Biomedical and Engineering Research Organization, Tohoku University, Sendai, Japan.

出版信息

Biophys J. 2007 Jun 1;92(11):4109-20. doi: 10.1529/biophysj.106.094649. Epub 2007 Mar 16.

DOI:10.1529/biophysj.106.094649
PMID:17369416
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1868978/
Abstract

The stepwise movements generated by myosin, dynein, and kinesin were observed in living cells in an attempt to understand the molecular mechanisms of movement within cells. First, the sequential process of the transport of vesicles, including human epidermal factor 2 receptor, after endocytosis was observed for long periods in three dimensions using quantum dots (QDs) and a three-dimensional confocal microscope. QD vesicles, after being endocytosed into the cells, moved along the membrane by transferring actin filaments and were then rapidly transported toward the nucleus along microtubules. Second, the position of vesicles was detected with a precision up to 1.9 nm and 330 micros using a new two-dimensional tracking method. The movement of the QDs transported by myosin VI lying just beneath the cell membrane consisted of 29- and 15-nm steps with a transition phase between these two steps. QD vesicles were then transported toward the nucleus or away from the nucleus toward the cell membrane with successive 8-nm steps. The stepwise movements of these motor proteins in cells were observed using new imaging methods that allowed the molecular mechanisms underlying traffic to and from the membrane to be determined.

摘要

为了理解细胞内运动的分子机制,人们在活细胞中观察了由肌球蛋白、动力蛋白和驱动蛋白产生的逐步运动。首先,使用量子点(QD)和三维共聚焦显微镜,在三维空间中长时间观察了包括人表皮生长因子2受体在内的囊泡在胞吞作用后的运输顺序过程。量子点标记的囊泡被细胞内吞后,通过转移肌动蛋白丝沿着膜移动,然后沿着微管迅速向细胞核运输。其次,使用一种新的二维跟踪方法,以高达1.9纳米的精度和330微秒的时间分辨率检测囊泡的位置。位于细胞膜下方的肌球蛋白VI运输的量子点的运动由29纳米和15纳米的步移组成,这两个步移之间有一个过渡阶段。然后,量子点标记的囊泡以连续8纳米的步移向细胞核或远离细胞核向细胞膜运输。利用新的成像方法观察了这些运动蛋白在细胞中的逐步运动,从而确定了往返细胞膜的运输过程的分子机制。

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