Abstract
Voltage-gated sodium channels (Nav) are responsible for initiation and propagation of nerve, skeletal muscle, and cardiac action potentials. Nav are composed of a pore-forming alpha subunit and often one to several modulating beta subunits. Previous work showed that terminal sialic acid residues attached to alpha subunits affect channel gating. Here we show that the fully sialylated beta1 subunit induces a uniform, hyperpolarizing shift in steady state and kinetic gating of the cardiac and two neuronal alpha subunit isoforms. Under conditions of reduced sialylation, the beta1-induced gating effect was eliminated. Consistent with this, mutation of beta1 N-glycosylation sites abolished all effects of beta1 on channel gating. Data also suggest an interaction between the cis effect of alpha sialic acids and the trans effect of beta1 sialic acids on channel gating. Thus, beta1 sialic acids had no effect gating on the of the heavily glycosylated skeletal muscle alpha subunit. However, when glycosylation of the skeletal muscle alpha subunit was reduced through chimeragenesis such that alpha sialic acids did not impact gating, beta1 sialic acids caused a significant hyperpolarizing shift in channel gating. Together, the data indicate that beta1 N-linked sialic acids can modulate Nav gating through an apparent saturating electrostatic mechanism. A model is proposed in which a spectrum of differentially sialylated Nav can directly modulate channel gating, thereby impacting cardiac, skeletal muscle, and neuronal excitability.
Highlights
The importance of voltage-gated sodium channels (Nav)1 in action potential initiation and propagation is well established
When glycosylation of the skeletal muscle ␣ subunit was reduced through chimeragenesis such that ␣ sialic acids did not impact gating, 1 sialic acids caused a significant hyperpolarizing shift in channel gating
Our data indicate a novel mechanism by which 1 can modulate Nav gating in a saturating, sialic acid-dependent manner and that 1 sialic acids account for all effects of 1 on sodium channel gating
Summary
Voltage-gated sodium channel; CHO, Chinese hamster ovary; ORF, open reading frame; GFP, green fluorescent protein; SA, sialic acid residue. If 1 glycosylation alters ␣ subunit gating, channel gating might be modulated differently by various levels of 1 sialic acid among excitable tissues and from one developmental stage to another. Given that ␣ subunit sialic acids impact channel gating, we wished to test the hypothesis that sialic acids attached to the 1 subunit are involved in modulating channel function To this end, we expressed four different Nav ␣ subunit isoforms in the presence or absence of 1 in a CHO cell line (Pro5) that essentially fully sialylates proteins, and in a mutant daughter cell line (Lec2) that is unable to sialylate proteins. Our data indicate a novel mechanism by which 1 can modulate Nav gating in a saturating, sialic acid-dependent manner and that 1 sialic acids account for all effects of 1 on sodium channel gating. The data indicate for the first time that within a single membrane, transmembrane protein function is modulated by sialic acid residues attached to a second membrane protein
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