含唾液酸的鞘糖脂:神经节苷脂在疼痛信号传导中的功能作用

Pain Research Pub Date : 2018-03-30 DOI:10.11154/PAIN.33.32
Shun Watanabe, M. Tanabe
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引用次数: 0

摘要

神经节苷是一种含唾液酸的鞘糖脂,其糖链变化很大,存在于生物膜中。根据它们的生物合成途径和在神经酰胺的第二位置的半乳糖残基上存在的唾液酸的数量,神经节苷类被分为四类(asialo -, a -, b -, c系列)。复杂神经节苷——含有长乙二醇链的神经节苷——在神经组织中尤其丰富,这表明它们参与神经功能,如轴突生长、髓磷脂的保存和神经传递。我们观察到足底注射gt1 b神经节苷脂(b系列复杂神经节侧)诱导伤害性行为,痛觉过敏对0。05%福尔马林和机械异常性疼痛。这种痛觉过敏可被NMDA受体拮抗剂或mGluR - 1拮抗剂阻断,并通过谷氨酸脱氢酶联合注射抑制。此外,gb1可提高皮肤中的谷氨酸浓度。这些结果表明,痛觉过敏是由皮肤中谷氨酸升高引起的。这导致我们假设神经节苷通过调节皮肤中的谷氨酸积累来调节疼痛信号。有趣的是,a系列神经节苷脂对伤害性行为没有影响。我们推测这种差异与唾液酸在a系列和b系列神经节苷中的不同位置有关。因此,我们研究了唾液酸酶(一种从寡糖中去除α -连接唾液酸残基的酶)是否会影响足底注射完全弗氏佐剂产生的小鼠炎症性疼痛模型中的伤害性行为。关节杆菌唾液酸酶注射到发炎的爪子减少机械异常性痛,而注射热灭活酶没有。这支持了我们的假设,即皮肤中的唾液酸偶联物(如神经节苷脂)与疼痛信号有关。虽然gb1调节皮肤谷氨酸浓度的机制尚不清楚,但它可能与膜中脂筏的形成有关。许多研究报道鞘脂,包括神经节侧,在膜上形成脂筏,调节蛋白-蛋白相互作用,进而产生细胞内信号转导、蛋白定位和囊泡运输的变化。未来的研究需要阐明神经节苷如何通过脂质筏理论调节谷氨酸浓度。由于神经节苷类与疼痛信号的关系,它们可能会在未来作为疼痛管理的潜在治疗靶点受到更多的关注。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Sialic acid–containing glycosphingolipids: functional roles of gangliosides in pain signaling
Gangliosides are sialic acid–containing glycosphingolipids that vary greatly in their glyco–chains and are present in biomembranes. Gangliosides are classified into four groups (asialo–, a–, b–, c–series) based on their biosynthetic pathway and on the number of sialic acids present on galactose residues in the second position from the ceramide. Complex gangliosides —gangliosides containing long glycol–chains— are especially abundant in neural tissues, suggesting that they are involved in neural functions such as axonal outgrowth, the preservation of myelin, and neural transmis-sion. We observed that intraplantar injection of GT 1 b ganglioside (b–series complex ganglio side) induces nociceptive behavior, hyperalgesia against 0 . 05 % formalin, and mechanical allodynia. This hyperalgesia is blocked by NMDA receptor antagonists or mGluR 1 antagonists, and is suppressed by co–injection of glutamate dehydrogenase. Furthermore, GT 1 b raises glutamate concentration in skin. These results suggest that hyperalgesia results from the GT 1 b–enhanced elevation of glutamate in skin. This led us to hypothesize that gangliosides modulate pain signaling by regulating glutamate accumulation in skin. Interestingly, a–series gangliosides have no effect on nociceptive behavior. We surmised that this difference that are related to the different positions of sialic acid in a– and b–series gangliosides. Thus, we investigated whether sialidase, an enzyme that removes α –linked sialic acid residues from oligosaccharides, affects nociceptive behavior in a mouse inflammatory pain model produced by intraplantar injec-tions of complete Freund’s adjuvant. Arthrobacter ureafaciens sialidase injection into inflamed paws reduced mechanical allodynia, whereas injection of heat–inactivated enzyme did not. This supports our hypothesis that sialic acid conjugates (e.g., gangliosides) in skin are involved in pain signaling. Although the mechanism by which GT 1 b regulates skin glutamate concentrations remains unclear, it may involve the formation of lipid rafts in membranes. Many studies report that sphingolipids, including ganglio sides, form lipid rafts in membranes that regulate protein–protein interactions, which in turn produce changes in intracellular signal transduction, protein localiza-tion, and vesicular transport. Future studies are required to clarify how gangliosides regulate glutamate concentration via the lipid raft theory. Gangliosides might receive more attention in the future as potential therapeutic targets for pain management, because of their relationship with pain signaling.
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来源期刊
Pain Research
Pain Research CLINICAL NEUROLOGY-
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