Abstract
Under physiological conditions, mammalian PIEZO channels (PIEZO1 and PIEZO2) elicit transient currents mostly carried by monovalent and divalent cations. PIEZO1 is also known to permeate chloride ions, with a Cl- / Na+ permeability ratio of about 0.2. Yet, little is known about how anions permeate PIEZO channels. Here, by separately measuring sodium and chloride currents using non-permanent counter-ions, we show that both PIEZO1 and PIEZO2 rectify chloride currents outwardly, favoring entry of chloride ions at voltages above their reversal potential, whereas little to no rectification was observed for sodium currents. Interestingly, chloride currents elicited by 9K, an anion-selective PIEZO1 mutant harboring multiple positive residues along intracellular pore fenestrations, also rectify but in the inward direction. Molecular dynamics simulation indicate that the inward rectification of chloride currents in 9K correlates with the largely positive electrostatic potential at the intracellular pore entrance, suggesting that rectification can be tuned by pore polarity. These results demonstrate that the pore of mammalian PIEZO channels inherently rectifies chloride currents.
Statement of significance Mechanosensitive PIEZO ion channels play many important roles across cells and tissues. Their open pore facilitates the flow of cations down their electrochemical gradients, eliciting sodium-driven membrane depolarization and calcium-dependent signaling under physiological conditions. Yet, these channels also permeate chloride ions. In this study, we show that the two mammalian PIEZO channel homologs preferentially permeate chloride ions into the cells at voltages more positive than the chloride reversal potential. Although PIEZOs permeate cations more effectively than chloride ions, the influx of chloride ions mediated by PIEZOs could participate in certain physiological processes.
Competing Interest Statement
The authors have declared no competing interest.