Joseph C. Sudar scite author profile

Inner-ear sensory hair cells convert mechanical stimuli from sound and head movements into electrical signals during mechanotransduction. Identification of all molecular components of the inner-ear mechanotransduction apparatus is ongoing; however, there is strong evidence that TMC1 and TMC2 are pore-forming subunits of the complex. We present molecular dynamics simulations that probe ion conduction of TMC1 models built based on two different structures of related TMEM16 proteins. Unlike most channels, the TMC1 models do not show a central pore. Instead, simulations of these models in a membrane environment at various voltages reveal a peripheral permeation pathway that is exposed to lipids and that shows cation permeation at rates comparable to those measured in hair cells. Furthermore, our analyses suggest that TMC1 gating mechanisms involve protein conformational changes and tension-induced lipid-mediated pore widening. These results provide insights into ion conduction and activation mechanisms of hair-cell mechanotransduction channels essential for hearing and balance.

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The ups and downs of elevator‐type di‐/tricarboxylate membrane transporters

Sauer

Wang

Sudar

et al. 2021

The FEBS Journal

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The divalent anion sodium symporter (DASS) family contains both sodium‐driven anion cotransporters and anion/anion exchangers. The family belongs to a broader ion transporter superfamily (ITS), which comprises 24 families of transporters, including those of AbgT antibiotic efflux transporters. The human proteins in the DASS family play major physiological roles and are drug targets. We recently determined multiple structures of the human sodium‐dependent citrate transporter (NaCT) and the succinate/dicarboxylate transporter from Lactobacillus acidophilus (LaINDY). Structures of both proteins show high degrees of structural similarity to the previously determined VcINDY fold. Conservation between these DASS protein structures and those from the AbgT family indicates that the VcINDY fold represents the overall protein structure for the entire ITS. The new structures of NaCT and LaINDY are captured in the inward‐ or outward‐facing conformations, respectively. The domain arrangements in these structures agree with a rigid body elevator‐type transport mechanism for substrate translocation across the membrane. Two separate NaCT structures in complex with a substrate or an inhibitor allowed us to explain the inhibition mechanism and propose a detailed classification scheme for grouping disease‐causing mutations in the human protein. Structural understanding of multiple kinetic states of DASS proteins is a first step toward the detailed characterization of their entire transport cycle.

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Structural basis of ion – substrate coupling in the Na+-dependent dicarboxylate transporter VcINDY

et al. 2022

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The Na+-dependent dicarboxylate transporter from Vibrio cholerae (VcINDY) is a prototype for the divalent anion sodium symporter (DASS) family. While the utilization of an electrochemical Na+ gradient to power substrate transport is well established for VcINDY, the structural basis of this coupling between sodium and substrate binding is not currently understood. Here, using a combination of cryo-EM structure determination, succinate binding and site-directed cysteine alkylation assays, we demonstrate that the VcINDY protein couples sodium- and substrate-binding via a previously unseen cooperative mechanism by conformational selection. In the absence of sodium, substrate binding is abolished, with the succinate binding regions exhibiting increased flexibility, including HPinb, TM10b and the substrate clamshell motifs. Upon sodium binding, these regions become structurally ordered and create a proper binding site for the substrate. Taken together, these results provide strong evidence that VcINDY’s conformational selection mechanism is a result of the sodium-dependent formation of the substrate binding site.

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Structural basis of ion – substrate coupling in the Na⁺-dependent dicarboxylate transporter VcINDY

Sauer

Marden

Sudar

et al. 2022

Preprint

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The Na+-dependent dicarboxylate transporter from Vibrio cholerae (VcINDY) is a prototype for the divalent anion sodium symporter (DASS) family. While the utilization of an electrochemical Na+ gradient to power substrate transport is well established for VcINDY, the structural basis of this coupling between sodium and substrate binding is not currently understood. Here, using a combination of cryo-EM structure determination, succinate binding and site-directed cysteine alkylation assays, we demonstrate that the VcINDY protein couples sodium- and substrate-binding via a previously unseen induced-fit mechanism. In the absence of sodium, substrate binding is abolished, with the succinate binding regions exhibiting increased flexibility, including HPinb, TM10b and the substrate clamshell motifs. Upon sodium binding, these regions become structurally ordered and create a proper binding site for the substrate. Taken together, these results provide strong evidence that VcINDY's induced-fit mechanism is a result of the sodium-dependent formation of the substrate binding site.

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Elastic properties of the inner-ear tip link explored using all-atom molecular dynamics simulations

Wheat¹,

Sandhu²,

Tamilselvan³

et al. 2023

Biophysical Journal

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Joseph C. Sudar

In Silico Electrophysiology of Inner-Ear Mechanotransduction Channel TMC1 Models

The ups and downs of elevator‐type di‐/tricarboxylate membrane transporters

Structural basis of ion – substrate coupling in the Na+-dependent dicarboxylate transporter VcINDY

Structural basis of ion – substrate coupling in the Na⁺-dependent dicarboxylate transporter VcINDY

Elastic properties of the inner-ear tip link explored using all-atom molecular dynamics simulations

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