Cellular response to short-time mechanical stimuli: mediating Ca2+ influx via PIEZO1

Cellular response to short-time mechanical stimuli: mediating Ca2+ influx via PIEZO1

Physical activity shows a positive correlation with overall health, and vigorous intermittent lifestyle physical activity (VILPA) similarly offers advantages in reducing the risk of all-cause mortality. Might the short-time mechanical stimuli be discernible to cells, eliciting commensurate physiolog...

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Main Authors: Fuan Wang, Hongkun Chen, Zhongyuan He, Jianfeng Li, Zhengya Zhu, Tao Tang, Junhong Li, Jiaxiang Zhou, Qiuxiao Tan, Zhen Li, Martin J. Stoddart, Xizhe Liu, Manman Gao, Zhiyu Zhou, Shaoyu Liu
Format: Article
Language:English
Published: Forum Multimedia Publishing LLC 2024-07-01
Series:European Cells & Materials
Subjects:
vigorous intermittent lifestyle physical activity
short-time mechanical stimuli
piezo1
ca2+ influx
yoda1
Online Access:https://www.ecmjournal.org/papers/vol048/vol048a01.php
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Summary:Physical activity shows a positive correlation with overall health, and vigorous intermittent lifestyle physical activity (VILPA) similarly offers advantages in reducing the risk of all-cause mortality. Might the short-time mechanical stimuli be discernible to cells, eliciting commensurate physiological responses? The study's objective was to investigate the cellular response to short-time mechanical stimuli. Human umbilical cord-derived mesenchymal stem cells (hUCMSCs), isolated and thoroughly characterized, were subjected to various stimuli, including activation and mechanical stretching, with Ca2+ influx assessed through alterations in fluorescence intensity. Further validation of these findings was confirmed through short hairpin RNA (shRNA) and inhibitors. In addition, a comprehensive examination of PIEZO1 alterations was conducted through quantitative real-time polymerase chain reaction (qRT-PCR) and western blot (WB) techniques. The results shown different frequencies of stretching stimulation and durations induced varying degrees of Ca2+ influx. The most substantial increase occurred within 2–3 minutes in the group subjected to 0.5 Hz stretching for 2 minutes (p < 0.05). Stretching at 0.5 Hz resulted in significant elevation in PIEZO1 mRNA expression at 15 minutes and 1 hour. Additionally, stretching cause a gradual rise in PIEZO1 protein levels, with a notable peak observed at 2 hours. In conclusion, cells primarily sense short-time mechanical stimuli through PIEZO1, predominantly mediated by regulated Ca2+ influx. This underscores PIEZO1's crucial role in cellular responsiveness to transient mechanical cues, advancing our understanding of mechanosensory mechanisms in cellular physiology.
ISSN:1473-2262

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