RT Journal Article SR Electronic T1 Structure of human PIEZO1 and its slow inactivating channelopathy mutants JF bioRxiv FD Cold Spring Harbor Laboratory SP 2024.07.14.603468 DO 10.1101/2024.07.14.603468 A1 Shan, Yuanyue A1 Guo, Xinyi A1 Zhang, Mengmeng A1 Chen, Meiyu A1 Li, Ying A1 Zhang, Mingfeng A1 Pei, Duanqing YR 2024 UL http://biorxiv.org/content/early/2024/07/16/2024.07.14.603468.abstract AB PIEZO channels transmit mechanical force signals to cells, allowing them to make critical decisions during development and in pathophysiological conditions. Their fast/slow inactivation modes have been implicated in mechanopathologies, but remain poorly understood. Here, we report several near-atomic resolution cryo-EM structures of fast-inactivating wild-type human PIEZO1 (hPIEZO1) and its slow-inactivating channelopathy mutants with or without its auxiliary subunit MDFIC. Our results suggest that the faster inactivating hPIEZO1 has a more flattened and extended architecture than the slower inactivating curved mouse PIEZO1 (mPIEZO1). The multi-lipidated MDFIC subunits insert laterally into the hPIEZO1 pore module like mPIEZO1, resulting in a more curved and extended state. Interestingly, the high-resolution structures suggest that the pore lipids, which directly seal the central hydrophobic pore, are involved in the rapid inactivation of hPIEZO1. While the severe hereditary erythrocytosis mutant R2456H significantly slows down the inactivation of hPIEZO1, the hPIEZO1-R2456H-MDFIC complex shows a more curved and contracted structure with an inner helix twist due to the broken link between the pore lipid and R2456H. These results suggest that the pore lipids may be involved in the mechanopathological rapid inactivation mechanism of PIEZO channels.Competing Interest StatementThe authors have declared no competing interest.