山奈酚糖苷作为胰岛素模拟物的研究表明,糖基是关键的活性结构。
Study of kaempferol glycoside as an insulin mimic reveals glycon to be the key active structure.
作者信息
Yamasaki Kazuaki, Hishiki Ryogo, Kato Eisuke, Kawabata Jun
机构信息
Laboratory of Food Biochemistry, Division of Applied Bioscience, Graduate School of Agriculture.
Laboratory of Food Biochemistry, Department of Bioscience and Chemistry, Faculty of Agriculture.
出版信息
ACS Med Chem Lett. 2010 Oct 11;2(1):17-21. doi: 10.1021/ml100171x. eCollection 2011 Jan 13.
Abstract
Diabetes mellitus is increasing in prevalence with patient numbers rising throughout the world. Current treatments for diabetes mellitus focus on control of blood glucose levels. Certain kinds of flavonoids or their glycosides stimulate cells to improve glucose uptake and lower blood glucose levels. We synthesized kaempferol 3-O-neohesperidoside (1), a naturally occurring substance present in Cyathea phalerata Mart., reported to mimic the action of insulin. Synthetic 1 promoted glucose uptake in the cultured cell line, L6. Further studies to determine the core structure responsible for this activity using synthetic compounds revealed neohesperidose to be the primary pharmacophore. These findings support the use of certain saccharides as a potential novel treatment for diabetes mellitus by replacing or supporting insulin.
摘要
糖尿病的患病率正在上升,全球患者数量不断增加。目前糖尿病的治疗重点是控制血糖水平。某些类黄酮或其糖苷可刺激细胞,从而改善葡萄糖摄取并降低血糖水平。我们合成了山奈酚3 - O - 新橙皮糖苷(1),这是一种存在于燕尾桫椤中的天然物质,据报道它能模拟胰岛素的作用。合成的1促进了培养细胞系L6对葡萄糖的摄取。使用合成化合物进一步研究确定负责此活性的核心结构,结果表明新橙皮糖是主要药效基团。这些发现支持使用某些糖类作为糖尿病的潜在新疗法,以替代或辅助胰岛素。
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