Institut NeuroMyoGene, Université Lyon 1, Université de Lyon, UMR CNRS 5310, Inserm U1217, 43 bd du 11 Novembre 1918, 69622, Villeurbanne, France.
J Physiol. 2017 Oct 15;595(20):6417-6428. doi: 10.1113/JP274638. Epub 2017 Sep 24.
Missense mutations in the gene encoding the α1 subunit of the skeletal muscle voltage-gated Ca channel induce type 1 hypokalaemic periodic paralysis, a poorly understood neuromuscular disease characterized by episodic attacks of paralysis associated with low serum K . Acute expression of human wild-type and R1239H HypoPP1 mutant α1 subunits in mature mouse muscles showed that R1239H fibres displayed Ca currents of reduced amplitude and larger resting leak inward current increased by external acidification. External acidification also produced intracellular acidification at a higher rate in R1239H fibres and inhibited inward rectifier K currents. These data suggest that the R1239H mutation induces an elevated leak H current at rest flowing through a gating pore and could explain why paralytic attacks preferentially occur during the recovery period following muscle exercise.
Missense mutations in the gene encoding the α1 subunit of the skeletal muscle voltage-gated Ca channel induce type 1 hypokalaemic periodic paralysis, a poorly understood neuromuscular disease characterized by episodic attacks of paralysis associated with low serum K . The present study aimed at identifying the changes in muscle fibre electrical properties induced by acute expression of the R1239H hypokalaemic periodic paralysis human mutant α1 subunit of Ca channels in a mature muscle environment to better understand the pathophysiological mechanisms involved in this disorder. We transferred genes encoding wild-type and R1239H mutant human Ca channels into hindlimb mouse muscle by electroporation and combined voltage-clamp and intracellular pH measurements on enzymatically dissociated single muscle fibres. As compared to fibres expressing wild-type α1 subunits, R1239H mutant-expressing fibres displayed Ca currents of reduced amplitude and a higher resting leak inward current that was increased by external acidification. External acidification also produced intracellular acidification at a higher rate in R1239H fibres and inhibited inward rectifier K currents. These data indicate that the R1239H mutation induces an elevated leak H current at rest flowing through a gating pore created by the mutation and that external acidification favours onset of muscle paralysis by potentiating H depolarizing currents and inhibiting resting inward rectifier K currents. Our results could thus explain why paralytic attacks preferentially occur during the recovery period following intense muscle exercise.
骨骼肌电压门控钙通道 α1 亚基编码基因中的错义突变导致 1 型低钾周期性麻痹,这是一种了解甚少的神经肌肉疾病,其特征是周期性瘫痪发作与血清 K 降低有关。在成熟的小鼠肌肉中,急性表达人野生型和 R1239H HypoPP1 突变体 α1 亚基表明,R1239H 纤维显示出幅度减小的 Ca 电流和更大的静息内向漏电流,这是由外部酸化引起的。外部酸化还以更高的速率在 R1239H 纤维中产生细胞内酸化,并抑制内向整流钾电流。这些数据表明,R1239H 突变诱导静息时通过门控孔流动的升高的漏 H 电流,这可以解释为什么瘫痪发作在肌肉运动后恢复期间更容易发生。
骨骼肌电压门控钙通道 α1 亚基编码基因中的错义突变导致 1 型低钾周期性麻痹,这是一种了解甚少的神经肌肉疾病,其特征是周期性瘫痪发作与血清 K 降低有关。本研究旨在鉴定急性表达骨骼肌电压门控钙通道 R1239H 低钾周期性麻痹人突变体 α1 亚基在成熟肌肉环境中引起的纤维电特性变化,以更好地理解该疾病中涉及的病理生理机制。我们通过电穿孔将编码野生型和 R1239H 突变型人钙通道的基因转入后肢小鼠肌肉,并对酶解分离的单个肌纤维进行电压钳和细胞内 pH 测量。与表达野生型 α1 亚基的纤维相比,表达 R1239H 突变体的纤维显示出幅度减小的 Ca 电流和更高的静息内向漏电流,该电流在外酸化时增加。外部酸化还以更高的速率在 R1239H 纤维中产生细胞内酸化,并抑制内向整流钾电流。这些数据表明,R1239H 突变诱导静息时通过突变形成的门控孔流动的升高的漏 H 电流,并且外部酸化通过增强 H 去极化电流和抑制静息内向整流钾电流来促进肌肉麻痹的发生。因此,我们的结果可以解释为什么瘫痪发作在剧烈肌肉运动后恢复期间更容易发生。
