心脏线粒体呼吸和活性氧生成的性别差异可能使 Scn1a-/+ 小鼠易患心律失常和癫痫性意外猝死

Jessa L. Aldridge, Emily Davis Alexander, Allison A. Franklin, Elizabeth Harrington, Farah Al-Ghzawi, Chad R. Frasier
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引用次数: 0

摘要

德雷维特综合征(Dravet Syndrome,DS)是一种儿科发病型癫痫,发生癫痫意外猝死(SUDEP)的风险较高。大多数 DS 患者的电压门控钠通道基因 Scn1a 发生突变,该基因在大脑和心脏中均有表达。以前,Scn1a 基因突变与心律失常有关。我们使用 Scn1a-/+ DS 小鼠模型来研究可能导致心律失常和 SUDEP 的心脏线粒体功能变化。我们检测到线粒体生物能发生了明显的改变,这种改变具有性别特异性。雄性 Scn1a-/+ 心脏的线粒体在最大呼吸(p = 0.02)和与复合体 II 相联系的呼吸(p = 0.03)方面存在缺陷。雄性 Scn1a-/+ 小鼠在工作负荷增加的情况下也更容易发生心律失常。当离体心肌细胞受到二酰胺作用时,雄性 Scn1a-/+ 小鼠心脏的心肌细胞对硫醇氧化的抵抗力较弱。与 Scn1a+/+ 相比,它们的存活率降低(p = 0.02),尽管整个心脏没有差异。最后,在基础条件下,DS 和野生型线粒体产生的 ROS 没有变化,但在缺氧/再灌注过程中,Scn1a-/+ 线粒体积累了更多的 ROS。这项研究确定了Scn1a连锁DS线粒体和抗氧化功能的新型性别差异。重要的是,我们发现雄性 Scn1a-/+ 小鼠比雌性 Scn1a-/+ 小鼠更容易发生心律失常。在开发新的治疗方法以应对DS的SUDEP风险时,应考虑性别因素。
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Sex differences in cardiac mitochondrial respiration and reactive oxygen species production may predispose Scn1a−/+ mice to cardiac arrhythmias and Sudden Unexpected Death in Epilepsy

Dravet Syndrome (DS) is a pediatric-onset epilepsy with an elevated risk of Sudden Unexpected Death in Epilepsy (SUDEP). Most individuals with DS possess mutations in the voltage-gated sodium channel gene Scn1a, expressed in both the brain and heart. Previously, mutations in Scn1a have been linked to arrhythmia. We used a Scn1a−/+ DS mouse model to investigate changes to cardiac mitochondrial function that may underlie arrhythmias and SUDEP. We detected significant alterations in mitochondrial bioenergetics that were sex-specific. Mitochondria from male Scn1a−/+ hearts had deficits in maximal (p = 0.02) and Complex II-linked respiration (p = 0.03). Male Scn1a−/+ mice were also more susceptible to cardiac arrhythmias under increased workload. When isolated cardiomyocytes were subjected to diamide, cardiomyocytes from male Scn1a−/+ hearts were less resistant to thiol oxidation. They had decreased survivability compared to Scn1a+/+ (p = 0.02) despite no whole-heart differences. Lastly, there were no changes in mitochondrial ROS production between DS and wild-type mitochondria at basal conditions, but Scn1a−/+ mitochondria accumulated more ROS during hypoxia/reperfusion. This study determines novel sex-linked differences in mitochondrial and antioxidant function in Scn1a-linked DS. Importantly, we found that male Scn1a−/+ mice are more susceptible to cardiac arrhythmias than female Scn1a−/+ mice. When developing new therapeutics to address SUDEP risk in DS, sex should be considered.

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Journal of molecular and cellular cardiology plus
Journal of molecular and cellular cardiology plus Cardiology and Cardiovascular Medicine
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