研究大麻二酚在人类诱导多能干细胞(iPSC)模型中的治疗机制。

Yishan Sun, Ricardo E Dolmetsch
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引用次数: 14

摘要

Dravet综合征是一种主要由SCN1A基因功能丧失变异引起的婴儿癫痫性脑病,标准治疗方案在对抗危及生命的Dravet综合征发作或该疾病的行为-认知合共病方面的疗效非常有限。最近,在开发治疗这种疾病的新方法方面取得了令人鼓舞的进展。其中一项临床进展是大麻二酚(CBD),这是一种天然存在于大麻中的化合物,与现有药物方案一起使用时,可以进一步减少患者的惊厥发作。像许多其他天然产品一样,CBD的确切治疗机制仍不清楚。先前,我们通过将患者来源的诱导多能干细胞(iPSCs)分化为端脑抑制性和兴奋性神经元,建立了Dravet综合征的人类细胞模型。在这里,我们应用该模型在细胞水平上研究CBD的抗癫痫机制。我们首先通过原代培养大鼠皮质神经元,确定了CBD浓度升高对神经元兴奋性的影响。我们发现亚微摩尔浓度对兴奋性有调节作用,高浓度(15µM)对兴奋性有毒性作用。然后,我们在来自患者iPSC系和对照细胞系H9的端脑神经元中测试了50 nM的CBD浓度,这一浓度与估计的人类临床暴露量相对应。这50 nM的CBD增加了抑制性神经元的兴奋性,但降低了兴奋性神经元的兴奋性,而没有改变两种细胞类型的钠电流幅度。我们的研究结果表明,CBD在Dravet综合征中治疗作用的细胞类型依赖机制与钠通道活性无关。
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Investigating the Therapeutic Mechanism of Cannabidiol in a Human Induced Pluripotent Stem Cell (iPSC)-Based Model of Dravet Syndrome.

Dravet syndrome is an infantile epileptic encephalopathy primarily caused by loss-of-function variants of the gene SCN1A Standard treatment regimens have very limited efficacy to combat the life-threatening seizures in Dravet syndrome or the behavioral-cognitive comorbidities of the disease. Recently there has been encouraging progress in developing new treatments for this disorder. One of the clinical advances is cannabidiol (CBD), a compound naturally found in cannabis and shown to further reduce convulsive seizures in patients when used together with existing drug regimens. Like many other natural products, the exact therapeutic mechanism of CBD remains undefined. Previously we have established a human cellular model of Dravet syndrome by differentiating patient-derived induced pluripotent stem cells (iPSCs) into telencephalic inhibitory and excitatory neurons. Here we have applied this model to investigate the antiepileptic mechanism(s) of CBD at the cellular level. We first determined the effect of escalating the concentrations of CBD on neuronal excitability, using primary culture of rat cortical neurons. We found modulatory effects on excitability at submicromolar concentrations and toxic effects at high concentrations (15 µM). We then tested CBD at 50 nM, a concentration that corresponds to the estimated human clinical exposure, in telencephalic neurons derived from a patient iPSC line and control cell line H9. This 50 nM of CBD increased the excitability of inhibitory neurons but decreased the excitability of excitatory neurons, without changing the amplitude of sodium currents in either cell type. Our findings suggest a cell type-dependent mechanism for the therapeutic action of CBD in Dravet syndrome that is independent of sodium channel activity.

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