A lysine residue from an extracellular turret switches the ion preference in a Cav3 T-Type channel from calcium to sodium ions

Cav3 T-type calcium channels from great pond snail Lymnaea stagnalis have a selectivity-filter ring of five acidic residues, EE(D)DD. Splice variants with exons 12b or 12a spanning the extracellular loop between the outer helix IIS5 and membrane-descending pore helix IIP1 (IIS5-P1) in Domain II of t...

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Published in:The Journal of biological chemistry 2022-12, Vol.298 (12), p.102621-102621, Article 102621
Main Authors: Guan, Wendy, Orellana, Kaidy G., Stephens, Robert F., Zhorov, Boris S., Spafford, J. David
Format: Article
Language:English
Subjects:
AlphaFold2 molecular modeling
Animals
Aspartic Acid
Calcium - chemistry
calcium channels
Calcium Channels, T-Type - chemistry
Glutamic Acid
ion selectivity
Ions
Lymnaea
Lysine - chemistry
patch clamp
Sodium - chemistry
sodium channels
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cites cdi_FETCH-LOGICAL-c451t-b3b1697a3533cbfced7f22e0f114f92c32b4dad6a6da22a61db38a9262aa20513
container_end_page 102621
container_issue 12
container_start_page 102621
container_title The Journal of biological chemistry
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creator Guan, Wendy
Orellana, Kaidy G.
Stephens, Robert F.
Zhorov, Boris S.
Spafford, J. David
description Cav3 T-type calcium channels from great pond snail Lymnaea stagnalis have a selectivity-filter ring of five acidic residues, EE(D)DD. Splice variants with exons 12b or 12a spanning the extracellular loop between the outer helix IIS5 and membrane-descending pore helix IIP1 (IIS5-P1) in Domain II of the pore module possess calcium selectivity or dominant sodium permeability, respectively. Here, we use AlphaFold2 neural network software to predict that a lysine residue in exon 12a is salt-bridged to the aspartate residue immediately C terminal to the second-domain glutamate in the selectivity filter. Exon 12b has a similar folding but with an alanine residue in place of lysine in exon 12a. We express LCav3 channels with mutated exons Ala-12b-Lys and Lys-12a-Ala and demonstrate that they switch the ion preference to high sodium permeability and calcium selectivity, respectively. We propose that in the calcium-selective variants, a calcium ion chelated between Domain II selectivity-filter glutamate and aspartate is knocked-out by the incoming calcium ion in the process of calcium permeation, whereas sodium ions are repelled. The aspartate is neutralized by the lysine residue in the sodium-permeant variants, allowing for sodium permeation through the selectivity-filter ring of four negatively charged residues akin to the prokaryotic sodium channels with four glutamates in the selectivity filter. The evolutionary adaptation in invertebrate LCav3 channels highlight the involvement of a key, ubiquitous aspartate, “a calcium beacon” of sorts in the outer pore of Domain II, as determinative for the calcium ion preference over sodium ions through eukaryotic Cav1, Cav2, and Cav3 channels.
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We express LCav3 channels with mutated exons Ala-12b-Lys and Lys-12a-Ala and demonstrate that they switch the ion preference to high sodium permeability and calcium selectivity, respectively. We propose that in the calcium-selective variants, a calcium ion chelated between Domain II selectivity-filter glutamate and aspartate is knocked-out by the incoming calcium ion in the process of calcium permeation, whereas sodium ions are repelled. The aspartate is neutralized by the lysine residue in the sodium-permeant variants, allowing for sodium permeation through the selectivity-filter ring of four negatively charged residues akin to the prokaryotic sodium channels with four glutamates in the selectivity filter. 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subjects AlphaFold2 molecular modeling
Animals
Aspartic Acid
Calcium - chemistry
calcium channels
Calcium Channels, T-Type - chemistry
Glutamic Acid
ion selectivity
Ions
Lymnaea
Lysine - chemistry
patch clamp
Sodium - chemistry
sodium channels
title A lysine residue from an extracellular turret switches the ion preference in a Cav3 T-Type channel from calcium to sodium ions
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