Yiechang Lin scite author profile

Cell membranes contain incredible diversity in the chemical structures of their individual lipid species and the ratios in which these lipids are combined to make membranes. Nevertheless, our current understanding of how each of these components affects the properties of the cell membrane remains elusive, in part due to the difficulties in studying the dynamics of membranes at high spatiotemporal resolution. In this work, we use coarse-grained molecular dynamics simulations to investigate how individual lipid species contribute to the biophysical properties of the neuronal plasma membrane. We progress through eight membranes of increasing chemical complexity, ranging from a simple POPC/ CHOL membrane to a previously published neuronal plasma membrane [Ingoĺfsson, H. I., et al. (2017) Biophys. J. 113 (10), 2271−2280] containing 49 distinct lipid species. Our results show how subtle chemical changes can affect the properties of the membrane and highlight the lipid species that give the neuronal plasma membrane its unique biophysical properties. This work has potential far-reaching implications for furthering our understanding of cell membranes.

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Characterizing the lipid fingerprint of the mechanosensitive channel Piezo2

Lin

Buyan

Corry

2022

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Piezo2 is a mechanosensitive ion channel that plays critical roles in sensing touch and pain, proprioception, and regulation of heart rate. Global knockout of Piezo2 leads to perinatal lethality in mice, and Piezo2 gain-of-function mutations are associated with distal arthrogryposis, a disease characterized by congenital joint contractures. Emerging evidence suggests that Piezo channels (Piezo1 and Piezo2) can be regulated by their local membrane environment and particularly by cholesterol and phosphoinositides. To characterize the local Piezo2 lipid environment and investigate key lipid–protein interactions, we carried out coarse-grained molecular dynamics simulations of Piezo2 embedded in a complex mammalian membrane containing >60 distinct lipid species. We show that Piezo2 alters its local membrane composition such that it becomes enriched with specific lipids, such as phosphoinositides, and forms specific, long-term interactions with a variety of lipids at functionally relevant sites.

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Computational studies of Piezo1 yield insights into key lipid–protein interactions, channel activation, and agonist binding

2021

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1H, 13C and 15N backbone NMR chemical shift assignments of the C-terminal P4 domain of Ahnak

et al. 2018

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Ahnak is a ~ 700 kDa polypeptide that was originally identified as a tumour-related nuclear phosphoprotein, but later recognized to play a variety of diverse physiological roles related to cell architecture and migration. A critical function of Ahnak is modulation of Ca signaling in cardiomyocytes by interacting with the β subunit of the L-type Ca channel (Ca1.2). Previous studies have identified the C-terminal region of Ahnak, designated as P3 and P4 domains, as a key mediator of its functional activity. We report here the nearly complete H,C and N backbone NMR chemical shift assignments of the 11 kDa C-terminal P4 domain of Ahnak. This study lays the foundations for future investigations of functional dynamics, structure determination and interaction site mapping of the Ca1.2-Ahnak complex.

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A binding site for phosphoinositides described by multiscale simulations explains their modulation of voltage gated sodium channels

Lin

Tao

Champion

et al. 2023

Preprint

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Voltage gated sodium channels (Nav) are membrane proteins which open to facilitate the inward flux of sodium ions into excitable cells. In response to stimuli, Nav channels undergo a transition from the resting, closed state to an open state which allows ion influx, before rapidly inactivating. Dysregulation of this functional cycle due to mutations leads to diseases including epilepsy, pain conditions and cardiac disorders, making Nav channels a significant pharmacological target. Phosphoinositides are important lipid cofactors for ion channel function. The phosphoinositide PI(4,5)P2 decreases Nav1.4 activity by increasing the difficulty of channel opening, accelerating fast activation and slowing recovery from fast inactivation. Using multiscale molecular dynamics simulations, we show that PI(4,5)P2 binds stably to inactivated Nav at a conserved site within the DIV S4-S5 linker, which couples the voltage sensing domain (VSD) to the pore. As the Nav C-terminal domain is proposed to also bind here during recovery from inactivation, we hypothesise that PI(4,5)P2 prolongs inactivation by competing to bind to this site. In atomistic simulations, PI(4,5)P2 reduces the mobility of both the DIV S4-S5 linker and the DIII-IV linker, responsible for fast inactivation, slowing the conformational changes required for the channel to recover to the resting state. We further show that in a resting state Nav model, phosphoinositides bind to VSD gating charges, which may anchor them and impede VSD activation. Our results provide a mechanism by which phosphoinositides alter the voltage dependence of activation and the rate of recovery from inactivation, an important step for the development of novel therapies to treat Nav-related diseases.

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Yiechang Lin

Understanding the Link between Lipid Diversity and the Biophysical Properties of the Neuronal Plasma Membrane

Characterizing the lipid fingerprint of the mechanosensitive channel Piezo2

Computational studies of Piezo1 yield insights into key lipid–protein interactions, channel activation, and agonist binding

1H, 13C and 15N backbone NMR chemical shift assignments of the C-terminal P4 domain of Ahnak

A binding site for phosphoinositides described by multiscale simulations explains their modulation of voltage gated sodium channels

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