Abstract
BackgroundBacterial sodium channels are important models for understanding ion permeation and selectivity. However, their homotetrameric structure limits their use as models for understanding the more complex eukaryotic voltage-gated sodium channels (which have a pseudo-heterotetrameric structure formed from an oligomer composed of four domains). To bridge this gap we attempted to synthesise oligomers made from four covalently linked bacterial sodium channel monomers and thus resembling their eukaryotic counterparts.ResultsWestern blot analyses revealed NaChBac oligomers to be inherently unstable whereas intact expression of NavMs oligomers was possible. Immunodectection using confocal microscopy and electrophysiological characterisation of NavMs tetramers confirmed plasma membrane localisation and equivalent functionality with wild type NavMs channels when expressed in human embryonic kidney cells.ConclusionThis study has generated new tools for the investigation of eukaryotic channels. The successful covalent linkage of four bacterial Nav channel monomers should permit the introduction of radial asymmetry into the structure of bacterial Nav channels and enable the known structures of these channels to be used to gain unique insights into structure-function relationships of their eukaryotic counterparts.
Highlights
Bacterial sodium channels are important models for understanding ion permeation and selectivity
This synthetic gene was designed to encode a tetrameric oligomer containing four identical domains corresponding to NaChBac channels tethered together using a 16 amino acid hydrophilic linker derived from Xenopus γ-globin gene
The covalent linkage of four bacterial Voltage gated sodium channels (Navs) channel monomers resembles the macroscopic structure of their eukaryotic counterparts, which should enable the introduction of radial asymmetry into the structure of bacterial Nav channels
Summary
Bacterial sodium channels are important models for understanding ion permeation and selectivity Their homotetrameric structure limits their use as models for understanding the more complex eukaryotic voltage-gated sodium channels (which have a pseudo-heterotetrameric structure formed from an oligomer composed of four domains). To bridge this gap we attempted to synthesise oligomers made from four covalently linked bacterial sodium channel monomers and resembling their eukaryotic counterparts. Voltage-gated sodium channels (Navs) play fundamental roles in eukaryotes, including electrical signaling, secretion and synaptic transmission.
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