A Membrane-Bound Biosensor Visualizes Shear Stress-Induced Inhomogeneous Alteration of Cell Membrane Tension

Cell membrane is the first medium from where a cell senses and responds to external stress stimuli. Exploring the tension changes in cell membrane will help us to understand intracellular force transmission. Here, a biosensor (named MSS) based on fluorescence resonance energy transfer is developed t...

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Published iniScience Vol. 7; pp. 180 - 190
Main Authors Li, Wang, Yu, Xinlei, Xie, Fei, Zhang, Baohong, Shao, Shuai, Geng, Chunyang, Aziz, Aziz Ur Rehman, Liao, Xiaoling, Liu, Bo
Format Journal Article
LanguageEnglish
Published United States Elsevier 28.09.2018
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Summary:Cell membrane is the first medium from where a cell senses and responds to external stress stimuli. Exploring the tension changes in cell membrane will help us to understand intracellular force transmission. Here, a biosensor (named MSS) based on fluorescence resonance energy transfer is developed to visualize cell membrane tension. Validity of the biosensor is first verified for the detection of cell membrane tension. Results show a shear stress-induced heterogeneous distribution of membrane tension with the biosensor, which is strengthened by the disruption of microfilaments or enhancement of membrane fluidity, but weakened by the reduction of membrane fluidity or disruption of microtubules. These findings suggest that the MSS biosensor is a beneficial tool to visualize the changes and distribution of cell membrane tension. Besides, cell membrane tension does not display obvious polar distribution, indicating that cellular polarity changes do not first occur on the cell membrane during mechanical transmission.
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ISSN:2589-0042
2589-0042
DOI:10.1016/j.isci.2018.09.002