Author:
Huang Yao-Shen,Fan Ching-Hsiang,Hsu Ning,Wu Chun-Yao,Chang Chu-Yuan,Hong Shi-Rong,Chang Ya-Chu,Wu Anthony Yan-Tang,Guo Vanessa,Chiang Yueh-Chen,Hsu Wei-Chia,Chiu Nai-Hua,Chen Linyi,Lai Charles Pin-Kuang,Yeh Chih-Kuang,Lin Yu-Chun
Abstract
AbstractBiomolecules that respond to different external stimuli enable the remote control of genetically modified cells. Chemogenetics and optogenetics, two tools that can control cellular activities via synthetic chemicals or photons, respectively, have been widely used to elucidate underlying physiological processes. These methods are, however, very invasive, have poor penetrability, or low spatiotemporal precision, attributes that hinder their use in therapeutic applications. We report herein a sonogenetic approach that can manipulate target cell activities by focused ultrasound stimulation. This system requires an ultrasound-responsive protein derived from an engineered auditory-sensing protein prestin. Heterogeneous expression of mouse prestin containing two parallel amino acid substitutions, N7T and N308S, that frequently exist in prestins from echolocating species endowed transfected mammalian cells with the ability to sense ultrasound. An ultrasound pulse of low frequency and low pressure efficiently evoked cellular calcium responses after transfecting with prestin(N7T, N308S). Moreover, pulsed ultrasound can also non-invasively stimulate target neurons expressing prestin(N7T, N308S) in deep regions of mice brains. Our study delineates how an engineered auditory-sensing protein can cause mammalian cells to sense ultrasound stimulation. Moreover, owing to the great penetration of low-frequency ultrasound (∼400 mm in depth), our sonogenetic tools will serve as new strategies for non-invasive therapy in deep tissues of large animals like primates.
Publisher
Cold Spring Harbor Laboratory
Cited by
3 articles.
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