Functional properties of a disease mutation for migraine in Kv2.1/6.4 channels
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Abstract
Voltage-gated potassium (Kv) channels are integral to cellular excitability, impacting the resting membrane potential, repolarization, and shaping action potentials in neurons and cardiac myocytes. Structurally, Kv channels are homo or heterotetramers comprising four α-subunits, each with six transmembrane segments (S1-S6). Silent Kv (KvS), includes Kv5.1, Kv6.1-6.4, Kv8.1-8.2, and Kv9.1-9.3, they do not form functional channels on their own but modulate the properties of heteromeric channels. Recent studies have identified the Kv6.4 subunit as a significant modulator within heteromeric channels, such as Kv2.16.4. The Kv2.16.4 heteromer exhibits altered biophysical properties, including a shift in voltage-dependent inactivation and a complex activation. Current genetic studies in migraine patients have revealed a single missense mutation in the Kv6.4 gene. The single missense mutation, L360P is in the highly conserved S4-S5 linker region. This study aims to demonstrate the biophysical effects of the L360P mutation in Kv2.1 6.4 channels with a fixed 2:2 stoichiometry, using monomeric (Kv2.1/6.4) and tandem dimer (Kv2.1_6.4) configurations. Our findings suggest that the L360P mutation significantly impacts the function and regulation of Kv2.1/6.4 channels, providing insights into the molecular mechanisms underlying channel dysfunction in migraine pathology.
Statement of significance
This study elucidates the biophysical properties of the Kv6.4 L360P mutation, providing insights into its role in Kv2.1 6.4 channel function. Given the high conservation of the leucine residue in the Kv channel family and its association with migraine, our findings have significant implications for understanding the molecular basis of migraine pathophysiology. By analyzing channels with a fixed 2:2 stoichiometry, we highlight the impact of the L360P mutation on channel gating and inactivation. This research advances the knowledge of the silent Kv6.4 channel mechanism and its role in pathophysiology.