Marc Duque scite author profile

Ultrasound has been used to non-invasively manipulate neuronal functions in humans and other animals. However, this approach is limited as it has been challenging to target specific cells within the brain or body. Here, we identify human Transient Receptor Potential A1 (hsTRPA1) as a candidate that confers ultrasound sensitivity to mammalian cells. Ultrasound-evoked gating of hsTRPA1 specifically requires its N-terminal tip region and cholesterol interactions; and target cells with an intact actin cytoskeleton, revealing elements of the sonogenetic mechanism. Next, we use calcium imaging and electrophysiology to show that hsTRPA1 potentiates ultrasound-evoked responses in primary neurons. Furthermore, unilateral expression of hsTRPA1 in mouse layer V motor cortical neurons leads to c-fos expression and contralateral limb responses in response to ultrasound delivered through an intact skull. Collectively, we demonstrate that hsTRPA1-based sonogenetics can effectively manipulate neurons within the intact mammalian brain, a method that could be used across species.

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Sonogenetic control of mammalian cells using exogenous Transient Receptor Potential A1 channels

Duque

Lee-Kubli

Tufail

et al. 2020

Preprint

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Our understanding of the nervous system has been fundamentally advanced by light- and small molecule-sensitive proteins that can be used to modify neuronal excitability. However, optogenetics requires invasive instrumentation while chemogenetics lacks temporal control. Here, we identify a candidate channel that confers sensitivity to non-invasive ultrasound on millisecond timescales. Using a functional screen, we find that human Transient Receptor Potential A1 (hsTRPA1) increases ultrasound-evoked intracellular calcium levels and membrane potentials. Ultrasound, but not agonist, -evoked, gating of hsTRPA1, requires the N-terminal tip region, intact actin cytoskeleton, and cholesterol, implicating these features in the sonogenetic mechanism. We then use calcium imaging and electrophysiology to confirm that ultrasound-evoked responses of primary neurons are potentiated by hsTRPA1. We also show that unilateral expression of hsTRPA1 in mouse layer V motor cortical neurons leads to ultrasound-evoked contralateral limb responses to ultrasound delivered through an intact skull. Finally, ultrasound induces c-fos in hsTRPA1-expressing neurons, suggesting that our approach can be used for targeted activation of neural circuits. Together, our results demonstrate that hsTRPA1-based sonogenetics can effectively and non-invasively modulate neurons within the intact mammalian brain, a method that could be extended to other cell types across species.

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Ultrasound Mediated Cellular Deflection Results in Cellular Depolarization

et al. 2021

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Ultrasound has been used to manipulate cells in both humans and animal models. While intramembrane cavitation and lipid clustering have been suggested as likely mechanisms, they lack experimental evidence. Here, high‐speed digital holographic microscopy (kiloHertz order) is used to visualize the cellular membrane dynamics. It is shown that neuronal and fibroblast membranes deflect about 150 nm upon ultrasound stimulation. Next, a biomechanical model that predicts changes in membrane voltage after ultrasound exposure is developed. Finally, the model predictions are validated using whole‐cell patch clamp electrophysiology on primary neurons. Collectively, it is shown that ultrasound stimulation directly defects the neuronal membrane leading to a change in membrane voltage and subsequent depolarization. The model is consistent with existing data and provides a mechanism for both ultrasound‐evoked neurostimulation and sonogenetic control.

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Observation of topological action potentials in engineered tissues

et al. 2022

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Ultrasound mediated cellular deflection results in cellular depolarization

Vasan

Orosco

Magaram

et al. 2021

Preprint

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Ultrasound has been used to manipulate cells in both humans and animal models. While intramembrane cavitation and lipid clustering have been suggested as likely mechanisms, they lack experimental evidence. Here we use high-speed digital holographic microscopy (to 100-kHz order) to visualize the cellular membrane dynamics. We show that neuronal and fibroblast membranes deflect about 150 nm upon ultrasound stimulation. Next, we develop a biomechanical model that predicts changes in membrane voltage after ultrasound exposure. Finally, we validate our model predictions using whole-cell patch clamp electrophysiology on primary neurons. Collectively, we show that ultrasound stimulation directly defects the neuronal membrane leading to a change in membrane voltage and subsequent depolarization. Our model is consistent with existing data and provides a mechanism for both ultrasound-evoked neurostimulation and sonogenetic control.

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Marc Duque

Sonogenetic control of mammalian cells using exogenous Transient Receptor Potential A1 channels

Sonogenetic control of mammalian cells using exogenous Transient Receptor Potential A1 channels

Ultrasound Mediated Cellular Deflection Results in Cellular Depolarization

Observation of topological action potentials in engineered tissues

Ultrasound mediated cellular deflection results in cellular depolarization

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