Molecular Insights into Single Chain Lipid Modulation of Acid-Sensing Ion Channel 3
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Abstract
Polyunsaturated fatty acids (PUFAs) and their analogs play a significant role in modulating the activity of diverse ion channels, and recent studies show that these lipids potentiate acid-sensing ion channels (ASICs), leading to increased activity. The potentiation of the channel stems from multiple gating changes, but the exact mechanism of these effects remains uncertain. We posit a mechanistic explanation for one of these changes in channel function, the increase in the maximal current, by applying a combination of electrophysiology and all-atom molecular dynamics simulations on the open-state hASIC3. Microsecond-scale simulations were performed on open-state hASIC3 in the absence and presence of a PUFA, docosahexaenoic acid (DHA), and a PUFA analog, N-arachidonyl glycine (AG). Intriguingly, our simulations in the absence of PUFA or PUFA analogs reveal that a tail from the membrane phospholipid POPC inserts itself into the pore of the channel through lateral fenestrations on the sides of the transmembrane segments, obstructing ion permeation through the channel. The binding of either DHA or AG prevented POPC from accessing the pore in our simulations, relieving the block of ionic conduction by phospholipids. Finally, we use the single-channel recording to show that DHA increases the amplitude of the single-channel currents in ASIC3, which is consistent with our hypothesis that PUFAs relieve the pore block of the channel induced by POPCs. Together, these findings offer a potential mechanistic explanation of how PUFAs modulate ASIC maximal current, revealing a novel mechanism of action for PUFA-induced modulation of ion channels.
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We repeated these experiments after preincubating our cells in 10μM DHA for 10 minutes
Is 10uM near the physiologic concentration for docosahexaenoic acid?
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Overall, the presence of DHA, whether docked to the TM helices of hASIC3 or partitioned into the lipid layer, prevented POPC lipids from accessing and penetrating the pore, ensuring high permeability for water and Na+ ions to flow through the channel.
Based on your model, can you postulate different lipid structures or lipid classes that could alter pore function?
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Based on this experimental data, we designed our PUFA-bound simulations where we docked either AG
This is a very interesting study! Using your model, can you predict other channel-specific amino acids that are important for binding to lipid mediators? If so, it would be interesting to mutate these residues and show they have a similar effect as R63 mutants.
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