Millions afflicted with Chagas disease and other disorders of aberrant glycosylation suffer symptoms consistent with altered electrical signaling such as arrhythmias, decreased neuronal conduction velocity, and hyporeflexia. Cardiac, neuronal, and muscle electrical signaling is controlled and modulated by changes in voltage-gated ion channel activity that occur through physiological and pathological processes such as development, epilepsy, and cardiomyopathy. Glycans attached to ion channels alter channel activity through isoform-specific mechanisms. Here we show that regulated and aberrant glycosylation modulate cardiac ion channel activity and electrical signaling through a cell-specific mechanism. Data show that nearly half of 239 glycosylation-associated genes (glycogenes) were significantly differentially expressed among neonatal and adult atrial and ventricular myocytes. The N-glycan structures produced among cardiomyocyte types were markedly variable. Thus, the cardiac glycome, defined as the complete set of glycan structures produced in the heart, is remodeled. One glycogene, ST8sia2, a polysialyltransferase, is expressed only in the neonatal atrium. Cardiomyocyte electrical signaling was compared in control and ST8sia2 (؊/؊) neonatal atrial and ventricular myocytes. Action potential waveforms and gating of less sialylated voltage-gated Na ؉ channels were altered consistently in ST8sia2 (؊/؊) atrial myocytes. ST8sia2 expression had no effect on ventricular myocyte excitability. Thus, the regulated (between atrium and ventricle) and aberrant (knockout in the neonatal atrium) expression of a single glycogene was sufficient to modulate cardiomyocyte excitability. A mechanism is described by which cardiac function is controlled and modulated through physiological and pathological processes that involve regulated and aberrant glycosylation. action potentials ͉ cardiomyocyte ͉ glycomics ͉ ion channels ͉ sialic acids
Nerve and muscle action potential repolarization are produced and modulated by the regulated expression and activity of several types of voltage-gated K(+) (K(v)) channels. Here, we show that sialylated N-glycans uniquely impact gating of a mammalian Shaker family K(v) channel isoform, K(v)1.5, but have no effect on gating of a second Shaker isoform, K(v)1.4. Each isoform contains one potential N-glycosylation site located along the S1-S2 linker; immunoblot analyses verified that K(v)1.4 and K(v)1.5 were N-glycosylated. The conductance-voltage (G-V) relationships and channel activation rates for two glycosylation-site deficient K(v)1.5 mutants, K(v)1.5(N290Q) and K(v)1.5(S292A), and for wild-type K(v)1.5 expressed under conditions of reduced sialylation, were each shifted linearly by a depolarizing approximately 18 mV compared to wild-type K(v)1.5 activation. External divalent cation screening experiments suggested that K(v)1.5 sialic acids contribute to an external surface potential that modulates K(v)1.5 activation. Channel availability was unaffected by changes in K(v)1.5 glycosylation or sialylation. The data indicate that sialic acid residues attached to N-glycans act through electrostatic mechanisms to modulate K(v)1.5 activation. The sialic acids fully account for effects of N-glycans on K(v)1.5 gating. Conversely, K(v)1.4 gating was unaffected by changes in channel sialylation or following mutagenesis to remove the N-glycosylation site. Each phenomenon is unique for K(v)1 channel isoforms, indicating that sialylated N-glycans modulate gating of homologous K(v)1 channels through isoform-specific mechanisms. Such modulation is relevant to changes in action potential repolarization that occur as ion channel expression and glycosylation are regulated.
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