Computational screening and molecular dynamics of natural compounds targeting the SH2 domain of STAT3: a multitarget approach using network pharmacology.

IF 3.9 2区化学 Q2 CHEMISTRY, APPLIED

Molecular Diversity Pub Date : 2025-01-09 DOI:10.1007/s11030-024-11075-5

Sachindra Kumar, B Harish Kumar, Raksha Nayak, Samyak Pandey, Nitesh Kumar, K Sreedhara Ranganath Pai

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引用次数: 0

Abstract

SH2 (Src Homology 2) domains play a crucial role in phosphotyrosine-mediated signaling and have emerged as promising drug targets, particularly in cancer therapy. STAT3 (Signal Transducer and Activator of Transcription 3), which contains an SH2 domain, plays a pivotal role in cancer progression and immune evasion because it facilitates the dimerization of STAT3, which is essential for their activation and subsequent nuclear translocation. SH2 domain-mediated STAT3 inhibition disrupts this binding, reduces phosphorylation of STAT3, and impairs dimerization. This study employed an in silico approach to screen potential natural compounds that could target the SH2 domain of STAT3 and inhibit its function. The phytomolecules (182455) were retrieved from the ZINC 15 database and were docked using various modes like HTVS, SP, and XP. The phytomolecules exhibiting higher binding affinity were selected. MM-GBSA was performed to determine binding free energy, and the QikProp tool was utilized to assess the pharmacokinetic properties of potential hit compounds, narrowing down the list of candidates. Molecular dynamics simulations, thermal MM-GBSA, and WaterMap analysis were performed on compounds that exhibited favorable binding affinities and pharmacokinetic characteristics. Based on docking scores and binding interactions, ZINC255200449, ZINC299817570, ZINC31167114, and ZINC67910988 were identified as potential STAT3 inhibitors. ZINC67910988 demonstrated superior stability in molecular dynamics simulation and WaterMap analysis. Furthermore, DFT was performed to determine energetic and electronic properties, and HOMO and LUMO sites were predicted for electronic structure calculation. Additionally, network pharmacology was performed to map the compounds' interactions within biological networks, highlighting their multitarget potential. Compound-target networks elucidate the relationships between compounds and multiple targets, along with their associated pathways and help to minimize off-target effects. The identified lead compound showed strong potential as a STAT3 inhibitor, warranting further validation through in vitro and in vivo studies.

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针对STAT3 SH2结构域的天然化合物的计算筛选和分子动力学：使用网络药理学的多靶点方法。

SH2 （Src同源性2）结构域在磷酸酪氨酸介导的信号传导中起着至关重要的作用，并已成为有希望的药物靶点，特别是在癌症治疗中。STAT3（信号换能器和转录激活因子3），包含一个SH2结构域，在癌症进展和免疫逃避中起关键作用，因为它促进STAT3的二聚化，这是它们的激活和随后的核易位所必需的。SH2结构域介导的STAT3抑制会破坏这种结合，降低STAT3的磷酸化，并损害二聚化。本研究采用计算机方法筛选可能靶向STAT3的SH2结构域并抑制其功能的潜在天然化合物。从ZINC 15数据库中检索到植物分子（182455），并使用HTVS、SP和XP等多种模式进行对接。选择具有较高结合亲和力的植物分子。利用MM-GBSA测定结合自由能，利用QikProp工具评估潜在命中化合物的药代动力学性质，缩小候选化合物的范围。分子动力学模拟、热MM-GBSA和水图分析对具有良好结合亲和力和药代动力学特征的化合物进行了分析。基于对接评分和结合相互作用，ZINC255200449、ZINC299817570、ZINC31167114和ZINC67910988被鉴定为潜在的STAT3抑制剂。ZINC67910988在分子动力学模拟和水图分析中表现出优异的稳定性。此外，利用DFT确定了能量和电子性质，并预测了HOMO和LUMO位点用于电子结构计算。此外，网络药理学被用于绘制化合物在生物网络中的相互作用，突出了它们的多靶点潜力。化合物靶标网络阐明了化合物和多个靶标之间的关系，以及它们的相关途径，并有助于减少脱靶效应。所鉴定的先导化合物显示出作为STAT3抑制剂的强大潜力，需要通过体外和体内研究进一步验证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Molecular Diversity 化学-化学综合

CiteScore

7.30

自引率

7.90%

发文量

219

审稿时长

2.7 months

期刊介绍： Molecular Diversity is a new publication forum for the rapid publication of refereed papers dedicated to describing the development, application and theory of molecular diversity and combinatorial chemistry in basic and applied research and drug discovery. The journal publishes both short and full papers, perspectives, news and reviews dealing with all aspects of the generation of molecular diversity, application of diversity for screening against alternative targets of all types (biological, biophysical, technological), analysis of results obtained and their application in various scientific disciplines/approaches including: combinatorial chemistry and parallel synthesis; small molecule libraries; microwave synthesis; flow synthesis; fluorous synthesis; diversity oriented synthesis (DOS); nanoreactors; click chemistry; multiplex technologies; fragment- and ligand-based design; structure/function/SAR; computational chemistry and molecular design; chemoinformatics; screening techniques and screening interfaces; analytical and purification methods; robotics, automation and miniaturization; targeted libraries; display libraries; peptides and peptoids; proteins; oligonucleotides; carbohydrates; natural diversity; new methods of library formulation and deconvolution; directed evolution, origin of life and recombination; search techniques, landscapes, random chemistry and more;