Characterization of two pathological gating-charge substitutions in Cav1.4 L-type calcium channels.

Thomas Heigl, Michael A Netzer, Lucia Zanetti, Matthias Ganglberger, Monica L Fernández-Quintero, Alexandra Koschak
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Abstract

Cav1.4 L-type calcium channels are predominantly expressed at the photoreceptor terminals and in bipolar cells, mediating neurotransmitter release. Mutations in its gene, CACNA1F, can cause congenital stationary night-blindness type 2 (CSNB2). Due to phenotypic variability in CSNB2, characterization of pathological variants is necessary to better determine pathological mechanism at the site of action. A set of known mutations affects conserved gating charges in the S4 voltage sensor, two of which have been found in male CSNB2 patients. Here, we describe two disease-causing Cav1.4 mutations with gating charge neutralization, exchanging an arginine 964 with glycine (RG) or arginine 1288 with leucine (RL). In both, charge neutralization was associated with a reduction channel expression also reflected in smaller ON gating currents. In RL channels, the strong decrease in whole-cell current densities might additionally be explained by a reduction of single-channel currents. We further identified alterations in their biophysical properties, such as a hyperpolarizing shift of the activation threshold and an increase in slope factor of activation and inactivation. Molecular dynamic simulations in RL substituted channels indicated water wires in both, resting and active, channel states, suggesting the development of omega (ω)currents as a new pathological mechanism in CSNB2. This sum of the respective channel property alterations might add to the differential symptoms in patients beside other factors, such as genomic and environmental deviations.

Abstract Image

Abstract Image

Abstract Image

Cav1.4 l型钙通道中两种病理性门控电荷取代的表征。
Cav1.4 L型钙通道主要在感光细胞末端和双极细胞中表达,介导神经递质的释放。其基因CACNA1F的突变可导致先天性2型静止性夜盲症(CSNB2)。由于CSNB2的表型变异性,有必要对病理变异进行表征,以更好地确定作用位点的病理机制。一组已知的突变影响S4电压传感器中保守的门控电荷,其中两个已在男性CSNB2患者中发现。在这里,我们描述了两种具有门控电荷中和的致病Cav1.4突变,即用甘氨酸(RG)交换精氨酸964或用亮氨酸(RL)交换精精氨酸1288。在两者中,电荷中和与还原通道表达有关,还原通道表达也反映在较小的ON门控电流中。在RL沟道中,整个电池电流密度的强烈降低可以另外通过单沟道电流的减少来解释。我们进一步确定了它们的生物物理性质的变化,例如激活阈值的超极化偏移以及激活和失活的斜率因子的增加。RL取代通道中的分子动力学模拟表明,水管线处于静息和活动通道状态,这表明ω电流的发展是CSNB2的一种新的病理机制。除了其他因素(如基因组和环境偏差)外,各个通道特性变化的总和可能会增加患者的不同症状。
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