与肌强直相关的S6片段错义突变导致的人类钠通道门控缺陷:S804F和V1293I。
Human sodium channel gating defects caused by missense mutations in S6 segments associated with myotonia: S804F and V1293I.
作者信息
Green D S, George A L, Cannon S C
机构信息
Department of Neurobiology, Harvard Medical School, Boston, MA 02115, USA.
出版信息
J Physiol. 1998 Aug 1;510 ( Pt 3)(Pt 3):685-94. doi: 10.1111/j.1469-7793.1998.685bj.x.
Abstract
- Missense mutations in the alpha-subunit of the human skeletal muscle sodium channel (hSkM1) have been detected in some heritable forms of myotonia. By recording Na+ currents from cells transfected with cDNA encoding either wild-type or mutant hSkM1, we characterized the functional consequences of two myotonia-associated mutations that lie at the cytoplasmic end of the sixth transmembrane segment in domain II (S804F) or domain III (V1293I). 2. Both mutations caused modest, but unequivocal, alterations in the voltage-dependent gating behaviour of hSkM1. For S804F, the abnormalities were limited to fast inactivation: the persistent Na+ current at the end of a 50 ms depolarization was increased 3-fold, the rate of inactivation from the open state was slowed 2-fold, and the voltage dependence of fast inactivation (h) was shifted by +3 mV. V1293I also disrupted fast inactivation, as evidenced by a 3-fold faster rate of recovery at hyperpolarized potentials (-70 mV). Activation was altered as well for V1293I: the voltage dependence was shifted by -6 mV (hyperpolarized). 3. Slow inactivation was not altered by S804F or V1293I. 4. We conclude that S804F and V1293I are not benign polymorphisms. Either mutation causes detectable alterations in channel gating and, in model simulations, the magnitude of the defects is sufficient to produce runs of myotonic discharges.
摘要
- 在某些遗传性肌强直形式中已检测到人类骨骼肌钠通道(hSkM1)α亚基的错义突变。通过记录转染了编码野生型或突变型hSkM1的cDNA的细胞的Na⁺电流,我们表征了位于结构域II(S804F)或结构域III(V1293I)中第六个跨膜片段胞质端的两个与肌强直相关的突变的功能后果。2. 两种突变均导致hSkM1的电压依赖性门控行为发生适度但明确的改变。对于S804F,异常仅限于快速失活:50 ms去极化结束时的持续性Na⁺电流增加了3倍,从开放状态的失活速率减慢了2倍,快速失活(h)的电压依赖性向正3 mV偏移。V1293I也破坏了快速失活,在超极化电位(-70 mV)下恢复速率快3倍证明了这一点。V1293I的激活也发生了改变:电压依赖性向负6 mV(超极化)偏移。3. S804F或V1293I未改变缓慢失活。4. 我们得出结论,S804F和V1293I不是良性多态性。任何一种突变都会导致通道门控发生可检测到的改变,并且在模型模拟中,缺陷的程度足以产生一连串的肌强直放电。
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