Abstract
KCNMA1, encoding the voltage- and calcium-activated potassium channel, has a pivotal role in brain physiology. Mutations in KCNMA1 are associated with epilepsy and/or dyskinesia (PNKD3). Two KCNMA1 mutations correlated with these phenotypes, D434G and N999S, were previously identified as producing gain-of-function (GOF) effects on BK channel activity. Three new patients have been reported harboring N999S, one carrying a second mutation, R1128W, but the effects of these mutations have not yet been reported under physiological K+ conditions or compared to D434G. In this study, we characterize N999S, the novel N999S/R1128W double mutation, and D434G in a brain BK channel splice variant, comparing the effects on BK current properties under a physiological K+ gradient with action potential voltage commands. N999S, N999S/R1128W, and D434G cDNAs were expressed in HEK293T cells and characterized by patch-clamp electrophysiology. N999S BK currents were shifted to negative potentials, with faster activation and slower deactivation compared with wild type (WT) and D434G. The double mutation N999S/R1128W did not show any additional changes in current properties compared with N999S alone. The antiepileptic drug acetazolamide was assessed for its ability to directly modulate WT and N999S channels. Neither the WT nor N999S channels were sensitive to the antiepileptic drug acetazolamide, but both were sensitive to the inhibitor paxilline. We conclude that N999S is a strong GOF mutation that surpasses the D434G phenotype, without mitigation by R1128W. Acetazolamide has no direct modulatory action on either WT or N999S channels, indicating that its use may not be contraindicated in patients harboring GOF KCNMA1 mutations.NEW & NOTEWORTHY KCNMA1-linked channelopathy is a new neurological disorder characterized by mutations in the BK voltage- and calcium-activated potassium channel. The epilepsy- and dyskinesia-associated gain-of-function mutations N999S and D434G comprise the largest number of patients in the cohort. This study provides the first direct comparison between D434G and N999S BK channel properties as well as a novel double mutation, N999S/R1128W, from another patient, defining the functional effects during an action potential stimulus.
Highlights
Channelopathy disorders are caused by the abnormal functioning of ion channel subunits (Kim 2014; Meredith 2015)
Because of the lack of a Big Kϩ” (BK) channel splice variant with known physiological function cloned from human tissue, in this study the effects of WT and patient KCNMA1 mutations were examined within the context of a brain variant cloned from mouse hypothalamus that was humanized (MG279689) (Shelley et al 2013)
Because the differences in biophysical properties between N999S and D434G manifest in this range of voltages, we evaluated the action potential (AP)-evoked BK currents generated by these two mutations
Summary
Channelopathy disorders are caused by the abnormal functioning of ion channel subunits (Kim 2014; Meredith 2015). Each BK␣ subunit comprises seven transmembrane segments (TM0 –TM6) and a large intracellular COOH terminus (Fig. 1A) (Meera et al 1997) Within these regions, three domains are essential to activate and regulate channel activity. The third domain is the accessory subunit binding interface formed by the NH2 terminus and TM0, which is necessary for interaction with the accessory beta (1– 4) and/or gamma (␥1Ϫ4) subunits (Morrow et al 2006; Wallner et al 1996) These three domains work together allosterically to open the pore gating domain (PGD) located between TM5 and TM6 and allow the Kϩ efflux from the cell (Horrigan and Aldrich 2002; Latorre et al 2010)
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