Molecular basis of force-from-lipids gating in the mechanosensitive channel MscS

Reddy, Bharat; Bavi, Navid; Lu, Allen; Park, Yeonwoo; Perozo, Eduardo

doi:10.7554/elife.50486

Cited by 94 publications

(158 citation statements)

References 90 publications

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“…Towards the interface region, attracting forces between the carbonyls dominate, generating strong tensions between 1000 and 2000 bar. The head group region of the bilayer is then again usually dominated by intermolecular repulsion between negatively charged phosphate moieties [ 32 , 33 , 34 ]. These interactions give rise to lateral pressure profiles that look for most bilayers comparable to the one depicted in Figure 2 (cf.…”

Section: Interactions Of Gpcrs With Their Membrane Environmentmentioning

confidence: 99%

Structure and Dynamics of GPCRs in Lipid Membranes: Physical Principles and Experimental Approaches

et al. 2020

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Over the past decade, the vast amount of information generated through structural and biophysical studies of GPCRs has provided unprecedented mechanistic insight into the complex signalling behaviour of these receptors. With this recent information surge, it has also become increasingly apparent that in order to reproduce the various effects that lipids and membranes exert on the biological function for these allosteric receptors, in vitro studies of GPCRs need to be conducted under conditions that adequately approximate the native lipid bilayer environment. In the first part of this review, we assess some of the more general effects that a membrane environment exerts on lipid bilayer-embedded proteins such as GPCRs. This is then followed by the consideration of more specific effects, including stoichiometric interactions with specific lipid subtypes. In the final section, we survey a range of different membrane mimetics that are currently used for in vitro studies, with a focus on NMR applications.

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Section: Interactions Of Gpcrs With Their Membrane Environmentmentioning

confidence: 99%

Structure and Dynamics of GPCRs in Lipid Membranes: Physical Principles and Experimental Approaches

et al. 2020

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“…Intrinsically sensitive to membrane tension, MscS channels from several prokaryotes have been extensively characterized and served as a prevailing model system for understanding physicochemical principles in mechanotransduction 9 . X-ray and cryo-electron microscopy (Cryo-EM) structures reveal that each protomer of the homo-heptameric MscS channel consists of three transmembrane helices (TM1-3) followed by a cytoplasmic barrel structure [15][16][17][18][19][20][21][22] . The presumed closed and open structures suggest that TM1 and TM2 constitute a peripheral membrane 'tension sensor', which is attached to the central pore-lining helix TM3a followed by the amphipathic TM3b running approximately parallel to the membrane [15][16][17][18] .…”

mentioning

confidence: 99%

“…According to this model, rotation and tilting of TM1 and TM2 as a rigid body under elevated membrane tension, accompanied by displacement of channel-bound lipid molecules, pulls TM3a to open the hydrophobic pore gate 16,18 . However, different gating models derived from electron paramagnetic resonance (EPR) spectroscopy, molecular dynamics (MD) simulations, and recent cryo-EM studies have also been proposed 20,[23][24][25][26] , and these competing models are actively debated 9,20 .…”

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confidence: 99%

Structural mechanism for gating of a eukaryotic mechanosensitive channel of small conductance

et al. 2020

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Mechanosensitive ion channels transduce physical force into electrochemical signaling that underlies an array of fundamental physiological processes, including hearing, touch, proprioception, osmoregulation, and morphogenesis. The mechanosensitive channels of small conductance (MscS) constitute a remarkably diverse superfamily of channels critical for management of osmotic pressure. Here, we present cryo-electron microscopy structures of a MscS homolog from Arabidopsis thaliana, MSL1, presumably in both the closed and open states. The heptameric MSL1 channel contains an unusual bowl-shaped transmembrane region, which is reminiscent of the evolutionarily and architecturally unrelated mechanosensitive Piezo channels. Upon channel opening, the curved transmembrane domain of MSL1 flattens and expands. Our structures, in combination with functional analyses, delineate a structural mechanism by which mechanosensitive channels open under increased membrane tension. Further, the shared structural feature between unrelated channels suggests the possibility of a unified mechanical gating mechanism stemming from membrane deformation induced by a non-planar transmembrane domain.

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“…Multiple structures of EcMscS describe a homoheptameric channel with a transmembrane (TM) domain, comprised of three TM helices per monomer, atop a large cytoplasmic "cage" [17][18][19][20][21][22][23]. A key feature of the EcMscS structure is the porelining TM helix, TM3, which, in the nonconducting state, kinks mid-way through at G113, such that its C-terminal portion points outward from the pore and lies parallel to the lipid bilayer [17,18,20,21]. During gating, TM3 is proposed to pivot outward around and partially straighten this kink, thus removing pore occlusions and allowing for ion flow [18,19,23,24].…”

Section: Introductionmentioning

confidence: 99%

Charged pore-lining residues are required for normal channel kinetics in the eukaryotic mechanosensitive ion channel MSL1

Schlegel

Haswell

2020

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Mechanosensitive (MS) ion channels are widespread mechanisms for cellular mechanosensation that can be directly activated by increasing membrane tension. The well-studied MscS family of MS ion channels is found in bacteria, archaea, and plants. MscS-Like (MSL)1 is localized to the inner mitochondrial membrane of Arabidopsis thaliana, where it is required for normal mitochondrial responses to oxidative stress. Like Escherichia coli MscS, MSL1 has a pore-lining helix that is kinked. However, in MSL1 this kink is comprised of two charged pore-lining residues, R326 and D327. Using single-channel patch-clamp electrophysiology in E. coli, we show that altering the size and charge of R326 and D327 leads to dramatic changes in channel kinetics. Modest changes in gating pressure were also observed while no effects on channel rectification or conductance were detected. MSL1 channel variants had differing physiological function in E. coli hypoosmotic shock assays, without clear correlation between function and particular channel characteristics. Taken together, these results demonstrate that altering pore-lining residue charge and size disrupts normal channel state stability and gating transitions, and led us to propose the "sweet spot" model. In this model, the transition to the closed state is facilitated by attraction between R326 and D327 and repulsion between R326 residues of neighboring monomers. In the open state, expansion of the channel reduces inter-monomeric repulsion, rendering open state stability influenced mainly by attractive forces. This work provides insight into how unique chargecharge interactions can be combined with an otherwise conserved structural feature to help modulate MS channel function.

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Molecular basis of force-from-lipids gating in the mechanosensitive channel MscS

Cited by 94 publications

References 90 publications

Structure and Dynamics of GPCRs in Lipid Membranes: Physical Principles and Experimental Approaches

Structure and Dynamics of GPCRs in Lipid Membranes: Physical Principles and Experimental Approaches

Structural mechanism for gating of a eukaryotic mechanosensitive channel of small conductance

Charged pore-lining residues are required for normal channel kinetics in the eukaryotic mechanosensitive ion channel MSL1

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