Piezo1 ion channels are capable of conformational signaling.

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2024-05-29

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Abstract

Piezo1 is a mechanically activated ion channel that senses forces with short latency and high sensitivity. Piezos undergo large conformational changes, induce far-reaching deformation onto the membrane, and modulate the function of two-pore potassium (K2P) channels. Taken together, this led us to hypothesize that Piezos may be able to signal their conformational state to other nearby proteins. Here, we use chemical control to acutely restrict Piezo1 conformational flexibility and show that Piezo1 conformational changes, but not ion permeation through it, are required for modulating the K2P channel TREK1. Super-resolution imaging and stochastic simulations further reveal that both channels do not co-localize, which implies that modulation is not mediated through direct binding interactions; however, at high Piezo1 densities, most TREK1 channels are within the predicted Piezo1 membrane footprint, suggesting the footprint may underlie conformational signaling. We speculate that physiological roles originally attributed to Piezo1 ionotropic function could, alternatively, involve conformational signaling.

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10.1101/2024.05.28.596257

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Lewis, Amanda H, Marie E Cronin and Jörg Grandl (2024). Piezo1 ion channels are capable of conformational signaling. bioRxiv. 10.1101/2024.05.28.596257 Retrieved from https://hdl.handle.net/10161/31225.

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Grandl

Jorg Grandl

Associate Professor of Neurobiology

I am a biophysicist, Associate Professor of Neurobiology, and Director of Neurobiology Graduate Studies at Duke University. I received my PhD from the Ecole Polytéchnique Fédérale de Lausanne (EPFL), Switzerland and completed an NIH Ruth L. Kirschstein Postdoctoral Fellowship with Nobel Laureate Ardem Patapoutian at Scripps, La Jolla.

My research investigates the biophysics of force-gated ion channels and cellular mechanotransduction. This work produced over 30 publications, including in Nature, Nature Neuroscience, Neuron, and eLife. My past trainees have continued scientific training at academic institutions such as Harvard, The Broad Institute, MD Anderson, and Yale, or in the private biomedical sector. Further, I served on study sections for NIH R01, R03, R35, R00/K99, F32 and P20 awards, and for the German Research Foundation (DFG) Emmy Noether Award, and I regularly peer-review manuscripts for Nature, Science, Neuron, eLife, PNAS, and others.

As the Director of Duke Neurobiology Graduate Studies, I currently serve 47 intellectually diverse faculty from 15 Departments, who hold over $42M (or $900K per investigator) in research support, and 67 graduate trainees, who over the past 5 years have published 130 research articles and won 31 individual fellowships. In this capacity I oversee, coordinate, and direct all daily aspects of the Duke Neurobiology Graduate Training Program.


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