Multireceptor Analysis for Evaluating the Antidiabetic Efficacy of Karanjin: A Computational Approach

IF 2.6 Q3 ENDOCRINOLOGY & METABOLISM Endocrinology, Diabetes and Metabolism Pub Date : 2024-07-09 DOI:10.1002/edm2.509

Sagnik Nag, B. Stany, Shatakshi Mishra, Sunil Kumar, Sourav Mohanto, Mohammed Gulzar Ahmed, Bijo Mathew, Vetriselvan Subramaniyan

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Abstract

Background

Diabetes mellitus, notably type 2, is a rising global health challenge, prompting the need for effective management strategies. Common medications such as metformin, insulin, repaglinide and sitagliptin can induce side effects like gastrointestinal disturbances, hypoglycemia, weight gain and specific organ risks. Plant-derived therapies like Karanjin from Pongamia pinnata present promising alternatives due to their historical use, holistic health benefits and potentially fewer adverse effects. This study employs in silico analysis to explore Karanjin's interactions with diabetes-associated receptors, aiming to unveil its therapeutic potential while addressing the limitations and side effects associated with conventional medications.

Methodology

The research encompassed the selection of proteins from the Protein Data Bank (PDB), followed by structural refinement processes and optimization. Ligands such as Karanjin and standard drugs were retrieved from PubChem, followed by a comprehensive analysis of their ADMET profiling and pharmacokinetic properties. Protein–ligand interactions were evaluated through molecular docking using AutoDockTools 1.5.7, followed by the analysis of structural stability using coarse-grained simulations with CABS Flex 2.0. Molecular dynamics simulations were performed using Desmond 7.2 and the OPLS4 force field to explore how Karanjin interacts with proteins over 100 nanoseconds, focusing on the dynamics and structural stability.

Results

Karanjin, a phytochemical from Pongamia pinnata, shows superior drug candidate potential compared to common medications, offering advantages in efficacy and reduced side effects. It adheres to drug-likeness criteria and exhibits optimal ADMET properties, including moderate solubility, high gastrointestinal absorption and blood–brain barrier penetration. Molecular docking revealed Karanjin's highest binding energy against receptor 3L2M (Pig pancreatic alpha-amylase) at −9.1 kcal/mol, indicating strong efficacy potential. Molecular dynamics simulations confirmed stable ligand–protein complexes with minor fluctuations in RMSD and RMSF, suggesting robust interactions with receptors 3L2M.

Conclusion

Karanjin demonstrates potential in pharmaceutical expansion for treating metabolic disorders such as diabetes, as supported by computational analysis. Prospects for Karanjin in pharmaceutical development include structural modifications for enhanced efficacy and safety. Nanoencapsulation may improve bioavailability and targeted delivery to pancreatic cells, while combination therapies could optimize treatment outcomes in diabetes management. Clinical trials and experimental studies are crucial to validate its potential as a novel therapeutic agent.

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多受体分析法评估卡拉金的抗糖尿病疗效：一种计算方法。

背景：糖尿病（尤其是 2 型糖尿病）是一个日益严重的全球性健康挑战，因此需要采取有效的管理策略。二甲双胍、胰岛素、瑞格列奈和西他列汀等常见药物会引起副作用，如胃肠道紊乱、低血糖、体重增加和特定器官风险。从植物中提取的疗法，如从羽扇豆中提取的卡朗金，因其历史悠久、具有整体健康益处和潜在的较少不良反应，而成为前景广阔的替代疗法。本研究采用硅学分析方法探索卡兰金与糖尿病相关受体的相互作用，旨在揭示其治疗潜力，同时解决与传统药物相关的局限性和副作用：研究包括从蛋白质数据库（PDB）中选择蛋白质，然后进行结构细化和优化。配体（如卡兰金和标准药物）从 PubChem 中检索，然后对其 ADMET 分析和药代动力学特性进行综合分析。使用 AutoDockTools 1.5.7 进行分子对接，评估蛋白质与配体之间的相互作用，然后使用 CABS Flex 2.0 进行粗粒度模拟，分析结构的稳定性。使用 Desmond 7.2 和 OPLS4 力场进行了分子动力学模拟，以探索 Karanjin 如何在 100 纳秒内与蛋白质相互作用，重点是动力学和结构稳定性：与普通药物相比，卡兰金是一种来自印度芒果的植物化学物质，具有更优越的候选药物潜质，在疗效和减少副作用方面具有优势。它符合药物相似性标准，并表现出最佳的 ADMET 特性，包括中等溶解度、较高的胃肠道吸收率和血脑屏障渗透率。分子对接显示，Karanjin 与受体 3L2M（猪胰腺α-淀粉酶）的最高结合能为 -9.1 kcal/mol，这表明它具有很强的药效潜力。分子动力学模拟证实了稳定的配体-蛋白质复合物，其 RMSD 和 RMSF 波动较小，表明其与受体 3L2M 有很强的相互作用：结论：计算分析表明，Karanjin 在治疗糖尿病等代谢性疾病方面具有医药开发潜力。Karanjin 在药物开发方面的前景包括为提高疗效和安全性而进行的结构调整。纳米封装技术可提高生物利用率，并有针对性地输送到胰腺细胞，而联合疗法可优化糖尿病治疗效果。临床试验和实验研究对于验证其作为新型治疗剂的潜力至关重要。

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