Structural Analysis of a New Saccharomyces cerevisiae α-glucosidase Homology Model and Identification of Potential Inhibitor Enzyme Docking Sites

J. Turner, L. Thomas, S. Kennedy
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引用次数: 2

Abstract

Publication date: October 2020 (Robinson et al., 1991). There have been countless studies on inhibition of the active site in α-glucosidase using sugar mimics, which lead to the creation of Acarbose and Miglitol medications (Clissold and Edwards, 1988; Laube, 2002; Scott and Spencer, 2000; Sels et. al., 1999). However, these drugs induce side effects, including gastrointestinal pain, and constipation/diarrhea (Aoki et. al., 2010). The use of sugar mimicking drugs brings about the complication of interaction with other naturally occurring sugar-binding enzymes, which can lead to gastrointestinal distress. The identification of natural allosteric inhibitors, which do not mimic sugars and bind to an area on the enzyme distinct from the active site, may reveal more potent inhibitors with fewer adverse effects; the inhibition studies of α-glucosidase in vitro and in vivo have created a pool of known and potential inhibitors with a specific flavonoid scaffold (Kim et. al., 2000; Singh et. al., 2014; Tadera et. al., 2006; Xu, 2010). Flavonoids consist of two specific chemical moieties: a benzopyran containing the A and C-rings, and a phenyl group referred to as the B-ring (Figure 1) (Panche et. al., 2016). Several flavonoids have previously been studied for inhibitory effects on α-glucosidase (Proença et al., 2017). Our goal is to identify and confirm how and where these compounds are binding to α-glucosidase as well as to verify their inhibitory mechanism because this will broaden the understanding of how allosteric inhibition of α-glucosidase works at the molecular level and inform future drug design. After investigating published research and compiling a list of natural inhibitors with IC50 values similar to acarbose, we decided on a series of flavonoids was identified for docking INTRODUCTION α-glucosidase (EC 3.2.1.20) is a digestive enzyme which aids in the hydrolysis of α(1-4)-linked α-D-glucose molecules at the terminal end of polysaccharides (Jeske et. al., 2018). Inhibiting this protein slows the release of free glucose in the small intestines. The therapeutic advantage of inhibiting α-glucosidase is that it can be used to treat certain diseases associated with abnormally high blood glucose concentrations, such as Type II diabetes (diabetes mellitus). Those with diabetes mellitus do not secrete enough insulin following a meal, resulting in post-prandial hyperglycemia (Alberti and Zimmet, 1998). Inhibiting α-glucosidase can stop the body from entering a state of hyperglycemia by slowing the initial absorption of glucose in the blood stream, giving insulin a more manageable increase in blood-glucose levels Structural Analysis of a New Saccharomyces cerevisiae α-glucosidase Homology Model and Identification of Potential Inhibitor Enzyme Docking Sites
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一种新的酿酒酵母α-葡萄糖苷酶同源性模型的结构分析及潜在抑制剂酶对接位点的鉴定
出版日期:2020年10月(Robinson et al., 1991)。利用糖模拟物抑制α-葡萄糖苷酶活性位点的研究不计其数,由此产生了阿卡波糖和米格列醇类药物(Clissold and Edwards, 1988;Laube, 2002;Scott and Spencer, 2000;Sels等人,1999)。然而,这些药物会产生副作用,包括胃肠道疼痛和便秘/腹泻(Aoki et. al., 2010)。使用糖模拟药物会带来与其他天然存在的糖结合酶相互作用的复杂性,这可能导致胃肠道不适。天然变构抑制剂的鉴定,不模仿糖和结合酶的活性部位不同的区域,可能揭示更有效的抑制剂和更少的不良反应;体外和体内对α-葡萄糖苷酶的抑制研究已经创建了一个已知的和潜在的抑制剂库,具有特定的类黄酮支架(Kim et. al., 2000;Singh等人,2014;Tadera et al., 2006;徐,2010)。类黄酮由两个特定的化学成分组成:含有a环和c环的苯并吡喃,以及被称为b环的苯基(图1)(Panche等人,2016)。之前已经研究了几种黄酮类化合物对α-葡萄糖苷酶的抑制作用(proenpada et al., 2017)。我们的目标是确定和确认这些化合物如何以及在哪里与α-葡萄糖苷酶结合,并验证它们的抑制机制,因为这将扩大对α-葡萄糖苷酶变构抑制如何在分子水平上起作用的理解,并为未来的药物设计提供信息。介绍α-葡萄糖苷酶(EC 3.2.1.20)是一种帮助水解多糖末端α(1-4)-连接的α- d -葡萄糖分子的消化酶(Jeske et. al., 2018)。抑制这种蛋白质会减缓小肠中游离葡萄糖的释放。抑制α-葡萄糖苷酶的治疗优势是可用于治疗与异常高血糖浓度相关的某些疾病,如II型糖尿病(糖尿病)。糖尿病患者进餐后分泌的胰岛素不足,导致餐后高血糖(Alberti and Zimmet, 1998)。抑制α-葡萄糖苷酶可以通过减缓血液中葡萄糖的初始吸收来阻止机体进入高血糖状态,使胰岛素更易控制血糖水平的升高。一种新的酿酒酵母α-葡萄糖苷酶同源性模型的结构分析及潜在抑制剂酶对接位点的鉴定
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