探索α-葡萄糖苷酶抑制肽:构效关系分析及设计潜在抗糖尿病药物的前景

IF 1 Q4 PHARMACOLOGY & PHARMACY
Ainolsyakira Mohd Rodhi, Pei Gee Yap, Olusegun Abayomi Olalere, Chee Yuen Gan
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引用次数: 0

摘要

背景:α-葡萄糖苷酶(AG)抑制肽是一种很有前途的新型糖尿病治疗剂。然而,有必要进一步了解这些肽的机制和性质。证据获取:在这篇综合综述中,AG抑制肽根据其长度分为三组:短、中、长肽。我们收集了来自BioPEP-UWM数据库和近期出版物的数据,对这些肽进行了结构-活性关系分析,重点是确定它们的活性残基和AG结合位点。结果:通过广泛的检测,鉴定出5个底物类似物(Trp376、Asp404、Ile441、Met519和Phe649)和2个催化残基(Asp518和Asp616)是AG的首选抑制位点。此外,还研究了氨基酸在肽端(N1和C1)、次端(N2和C2)和前端(N3和C3)的偏好及其在不同末端的位置。我们的研究结果表明,这些肽主要是疏水的,并且往往含有疏水的烷基/芳基侧链的疏水氨基酸(如赖氨酸、谷氨酰胺、脯氨酸和/或精氨酸)。为了进一步了解肽- ag相互作用,进行了对接分析,强调了疏水键作为主要相互作用模式的重要性。结论:通过汇总所有研究结果,本综述为设计和发现基于肽的抗糖尿病药物提供了必要和实用的信息。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Exploring α-Glucosidase Inhibitory Peptides: Structure-Activity Relationship Analysis and Perspectives for Designing Potential Anti-Diabetic Agents
Context: α-Glucosidase (AG) inhibitory peptides represent a promising new class of therapeutic agents for the treatment of diabetes. However, there is a need to further understand the mechanisms and properties of these peptides. Evidence Acquisition: In this comprehensive review, AG inhibitory peptides were categorized into three groups based on their length: short, medium, and long peptides. Data from the BioPEP-UWM database and recent publications were gathered to conduct a structure-activity relationship analysis for these peptides, focusing on identifying their reactive residues and AG binding sites. Results: Through extensive examination, five substrate analogs (Trp376, Asp404, Ile441, Met519, and Phe649) and two catalytic residues (Asp518 and Asp616) were identified as the preferred inhibitory sites on AG. Furthermore, amino acid preferences and their positionings at different terminals on peptides, including the ultimate (N1 and C1), penultimate (N2 and C2), and antepenultimate (N3 and C3), were explored. Our findings revealed that these peptides were predominantly hydrophobic and tended to contain hydrophobic amino acids with hydrophobic alkyl/aryl side chains (such as lysine, glutamine, proline, and/or arginine). To gain further insights into peptide-AG interactions, docking analysis was performed, which highlighted the significance of hydrophobic bonds as the primary mode of interaction. Conclusions: By pooling all the findings, this review provided essential and practical information for the design and discovery of peptide-based anti-diabetic agents.
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来源期刊
CiteScore
1.40
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