Department of Physiology, Neurology, Hallym University, College of Medicine, 1-Okcheon Dong, 39 Hallymdaehak-gil, Chuncheon 200-708, Republic of Korea.
Neuroregeneration and Stem Cell Programs, Institute for Cell Engineering, Johns Hopkins University School of Medicine, Baltimore, MD 21205, USA; Department of Neurology, Johns Hopkins University School of Medicine, Baltimore, MD 21205, USA.
Neurotherapeutics. 2024 Jul;21(4):e00357. doi: 10.1016/j.neurot.2024.e00357. Epub 2024 Apr 16.
Epilepsy, a complex neurological disorder, is characterized by recurrent seizures caused by aberrant electrical activity in the brain. Central to this study is the role of lysosomal dysfunction in epilepsy, which can lead to the accumulation of toxic substrates and impaired autophagy in neurons. Our focus is on phosphodiesterase-4 (PDE4), an enzyme that plays a crucial role in regulating intracellular cyclic adenosine monophosphate (cAMP) levels by converting it into adenosine monophosphate (AMP). In pathological states, including epilepsy, increased PDE4 activity contributes to a decrease in cAMP levels, which may exacerbate neuroinflammatory responses. We hypothesized that amlexanox, an anti-inflammatory drug and non-selective PDE4 inhibitor, could offer neuroprotection by addressing lysosomal dysfunction and mitigating neuroinflammation, ultimately preventing neuronal death in epileptic conditions. Our research utilized a pilocarpine-induced epilepsy animal model to investigate amlexanox's potential benefits. Administered intraperitoneally at a dose of 100 mg/kg daily following the onset of a seizure, we monitored its effects on lysosomal function, inflammation, neuronal death, and cognitive performance in the brain. Tissue samples from various brain regions were collected at predetermined intervals for a comprehensive analysis. The study's results were significant. Amlexanox effectively improved lysosomal function, which we attribute to the modulation of zinc's influx into the lysosomes, subsequently enhancing autophagic processes and decreasing the release of inflammatory factors. Notably, this led to the attenuation of neuronal death in the hippocampal region. Additionally, cognitive function, assessed through the modified neurological severity score (mNSS) and the Barnes maze test, showed substantial improvements after treatment with amlexanox. These promising outcomes indicate that amlexanox has potential as a therapeutic agent in the treatment of epilepsy and related brain disorders. Its ability to combat lysosomal dysfunction and neuroinflammation positions it as a potential neuroprotective intervention. While these findings are encouraging, further research and clinical trials are essential to fully explore and validate the therapeutic efficacy of amlexanox in epilepsy management.
癫痫是一种复杂的神经障碍,其特征是大脑异常电活动引起的反复发作。本研究的核心是溶酶体功能障碍在癫痫中的作用,它可导致有毒底物的积累和神经元自噬受损。我们的重点是磷酸二酯酶 4(PDE4),这是一种酶,通过将其转化为单磷酸腺苷(AMP)来调节细胞内环磷酸腺苷(cAMP)水平,在调节细胞内 cAMP 水平方面起着至关重要的作用。在包括癫痫在内的病理状态下,PDE4 活性的增加导致 cAMP 水平下降,这可能会加剧神经炎症反应。我们假设,氨苯砜,一种抗炎药物和非选择性 PDE4 抑制剂,通过解决溶酶体功能障碍和减轻神经炎症,最终防止癫痫状态下的神经元死亡,从而提供神经保护作用。我们的研究利用匹鲁卡品诱导的癫痫动物模型来研究氨苯砜的潜在益处。在癫痫发作后,每天通过腹膜内注射 100mg/kg 的剂量给予氨苯砜,我们监测其对溶酶体功能、炎症、神经元死亡和大脑认知表现的影响。在预定的时间间隔内从不同的脑区采集组织样本进行全面分析。研究结果意义重大。氨苯砜有效改善了溶酶体功能,这归因于锌流入溶酶体的调节,从而增强了自噬过程并减少了炎症因子的释放。值得注意的是,这导致海马区神经元死亡的减少。此外,通过改良神经损伤评分(mNSS)和巴恩斯迷宫测试评估的认知功能在氨苯砜治疗后有显著改善。这些有希望的结果表明,氨苯砜具有作为癫痫和相关脑疾病治疗药物的潜力。它对抗溶酶体功能障碍和神经炎症的能力使其成为一种潜在的神经保护干预措施。虽然这些发现令人鼓舞,但需要进一步的研究和临床试验来充分探索和验证氨苯砜在癫痫管理中的治疗效果。
