School of Biomedical Sciences, University of Queensland, St Lucia, Queensland, Australia.
Epilepsia. 2024 Aug;65(8):2213-2226. doi: 10.1111/epi.18013. Epub 2024 May 20.
In glucose transporter 1 deficiency syndrome (Glut1DS), glucose transport into brain is reduced due to impaired Glut1 function in endothelial cells at the blood-brain barrier. This can lead to shortages of glucose in brain and is thought to contribute to seizures. Ketogenic diets are the first-line treatment and, among many beneficial effects, provide auxiliary fuel in the form of ketone bodies that are largely metabolized by neurons. However, Glut1 is also the main glucose transporter in astrocytes. Here, we review data indicating that glucose shortage may also impact astrocytes in addition to neurons and discuss the expected negative biochemical consequences of compromised astrocytic glucose transport for neurons. Based on these effects, auxiliary fuels are needed for both cell types and adding medium chain triglycerides (MCTs) to ketogenic diets is a biochemically superior treatment for Glut1DS compared to classical ketogenic diets. MCTs provide medium chain fatty acids (MCFAs), which are largely metabolized by astrocytes and not neurons. MCFAs supply energy and contribute carbons for glutamine and γ-aminobutyric acid synthesis, and decanoic acid can also block α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid glutamate receptors. MCTs do not compete with metabolism of ketone bodies mostly occurring in neurons. Triheptanoin, an anaplerotic but also gluconeogenic uneven MCT, may be another potential addition to ketogenic diets, although maintenance of "ketosis" can be difficult. Gene therapy has also targeted both endothelial cells and astrocytes. Other approaches to increase fuel delivery to the brain currently investigated include exchange of Glut1DS erythrocytes with healthy cells, infusion of lactate, and pharmacological improvement of glucose transport. In conclusion, although it remains difficult to assess impaired astrocytic energy metabolism in vivo, astrocytic energy needs are most likely not met by ketogenic diets in Glut1DS. Thus, we propose prospective studies including monitoring of blood MCFA levels to find optimal doses for add-on MCT to ketogenic diets and assessing of short- and long-term outcomes.
在葡萄糖转运蛋白 1 缺乏综合征 (Glut1DS) 中,由于血脑屏障内皮细胞中 Glut1 功能受损,葡萄糖向大脑的转运减少。这可能导致大脑中葡萄糖短缺,并被认为有助于癫痫发作。生酮饮食是一线治疗方法,除了许多有益的作用外,还以酮体的形式提供辅助燃料,这些酮体主要由神经元代谢。然而,Glut1 也是星形胶质细胞中主要的葡萄糖转运蛋白。在这里,我们回顾了表明葡萄糖短缺除了神经元之外还可能影响星形胶质细胞的数据,并讨论了星形胶质细胞葡萄糖转运受损对神经元的预期生化后果。基于这些影响,两种细胞类型都需要辅助燃料,与经典生酮饮食相比,在生酮饮食中添加中链甘油三酯 (MCT) 是治疗 Glut1DS 的一种生化上更优越的方法。MCT 提供中链脂肪酸 (MCFA),这些脂肪酸主要由星形胶质细胞代谢,而不是神经元代谢。MCFA 提供能量,并为谷氨酰胺和 γ-氨基丁酸的合成贡献碳,癸酸还可以阻断 α-氨基-3-羟基-5-甲基-4-异恶唑丙酸谷氨酸受体。MCT 不会与主要发生在神经元中的酮体代谢竞争。三庚酸,一种生酮和生糖不均匀的 MCT,也可能是生酮饮食的另一种潜在添加物,尽管维持“酮症”可能很困难。基因治疗也针对内皮细胞和星形胶质细胞。目前正在研究的其他增加大脑燃料供应的方法包括用健康细胞交换 Glut1DS 红细胞、输注乳酸和改善葡萄糖转运的药理学方法。总之,尽管评估 Glut1DS 中星形胶质细胞能量代谢障碍仍然很困难,但在 Glut1DS 中,生酮饮食可能无法满足星形胶质细胞的能量需求。因此,我们建议进行前瞻性研究,包括监测血液 MCFA 水平,以找到添加 MCT 到生酮饮食的最佳剂量,并评估短期和长期结果。
