Abstract
In humans, cellular mechanoperception serves as the basis of touch sensation and proprioception, contributes to the proper programming of cell fate during embryonic development, and plays a pivotal role in the development of mechanosensitive tissues. Molecular mechanoreceptors can respond to their environment by mediating transient adjustments of ion homeostasis, which subsequently trigger calcium‐dependent alteration of gene expression via specific signaling pathways such as the nuclear factor of the activated T‐cells pathway. Although, mechanoreceptors are potential drug targets for various diseases, current techniques to study mechanically gated processes are often based on custom‐tailored microfluidic systems, which require special setups or have limited throughput. Here, we present a platform to characterize shear‐stress‐triggered, calcium‐mediated gene expression, which employs a programmable, 96‐well‐format, shear‐stress induction device to examine the effects of imposing various mechanical loads on mammalian adherent cell lines. The presented method is suitable for high‐throughput experiments and provides a large tunable parameter space to optimize conditions for different cell types. Our findings indicate that the device is an effective tool to explore conditions in terms of frequency, intensity, intervals as well as extracellular matrix composition alongside the evaluation of different combinations of mechanosensitive proteins for mechanically activated gene expression. We believe our results can serve as a platform for further investigations into shear stress‐controlled gene expression in basic research and drug screening.
Highlights
Mechanical cues are omnipresent in the cellular environment and guide decisions of propagation and survival of prokaryotic and eukaryotic cells
Piezo‐type mechanosensitive ion channel component 1 (Piezo1) may play a key role in the sensation of touch, proprioception, and potentially blood pressure regulation (Saotome et al, 2018), while transmembrane channel‐like protein 1 (TMC1) may be a mediator of hearing (Pan et al, 2018)
To sense the mechanically induced increase in cytosolic calcium concentration, we employed a synthetic calcium‐inducible promoter based on NFAT‐responsive elements from the interleukin 4 (IL4)
Summary
Mechanical cues are omnipresent in the cellular environment and guide decisions of propagation and survival of prokaryotic and eukaryotic cells. Our findings indicate that the device is an effective tool to explore conditions in terms of frequency, intensity, intervals as well as extracellular matrix composition alongside the evaluation of different combinations of mechanosensitive proteins for mechanically activated gene expression.
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