从蜘蛛 Acanthoscurria rondoniae 血淋巴中提取的抗真菌肽 Rondonin 的作用机制相关受体的硅学生物勘探。

In silico pharmacology Pub Date : 2024-06-09 eCollection Date: 2024-01-01 DOI:10.1007/s40203-024-00224-1
Elias Jorge Muniz Seif, Marcelo Yudi Icimoto, Pedro Ismael Silva Júnior
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引用次数: 0

摘要

多种耐药性真菌与疾病的发生有关。因此,需要更有效的药物来治疗这些病原体。Rondonin 是一种从蜘蛛 Acanthoscurria rondoniae 的血液淋巴中分离出来的多肽。以前的研究表明,这种肽对白色念珠菌和三代孢子菌菌株具有抗真菌活性,作用于它们的遗传物质。然而,其生物活性所涉及的分子靶点尚未得到描述。我们使用生物信息学工具来确定参与隆地宁生物活性的可能靶点。PharmMapper 服务器用于搜索隆东宁的微生物靶标。PatchDock 服务器用于进行分子对接。UCSF Chimera 软件用于评估这些分子间相互作用。此外,还使用了 I-TASSER 服务器来预测目标配体位点。然后,将这些预测结果与之前文献中描述的位点进行对比。对对接分析中发现的两个有希望的复合物进行了分子动力学模拟。Rondonin 与以下靶标的配体位点一致:外膜蛋白 F(id:1MPF)和 A(id:1QJP),它们负责促进小分子通过质膜;黄素蛋白富马酸还原酶亚基(id:1D4E)的亚基,它参与含氮碱基的新陈代谢;以及 ATP 依赖性霍利迪 DNA 螺旋酶接头(id: 1IN4),它与包装遗传物质的组蛋白有关。此外,分子动力学结果表明,在 10 毫微秒的模拟过程中,Rondonin 与 1MPF 和 1IN4 的相互作用非常稳定。这些相互作用与之前对 Rondonin 的体外研究相吻合,Rondonin 作用于真菌遗传物质时不会导致质膜破裂。因此,本研究中使用的生物勘探方法与之前通过体外实验获得的结果一致,因此被认为是令人满意的:在线版本包含补充材料,可查阅 10.1007/s40203-024-00224-1。
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In silico bioprospecting of receptors associated with the mechanism of action of Rondonin, an antifungal peptide from spider Acanthoscurria rondoniae haemolymph.

Multiple drug-resistant fungal species are associated with the development of diseases. Thus, more efficient drugs for the treatment of these aetiological agents are needed. Rondonin is a peptide isolated from the haemolymph of the spider Acanthoscurria rondoniae. Previous studies have shown that this peptide has antifungal activity against Candida sp. and Trichosporon sp. strains, acting on their genetic material. However, the molecular targets involved in its biological activity have not yet been described. Bioinformatics tools were used to determine the possible targets involved in the biological activity of Rondonin. The PharmMapper server was used to search for microorganismal targets of Rondonin. The PatchDock server was used to perform the molecular docking. UCSF Chimera software was used to evaluate these intermolecular interactions. In addition, the I-TASSER server was used to predict the target ligand sites. Then, these predictions were contrasted with the sites previously described in the literature. Molecular dynamics simulations were conducted for two promising complexes identified from the docking analysis. Rondonin demonstrated consistency with the ligand sites of the following targets: outer membrane proteins F (id: 1MPF) and A (id: 1QJP), which are responsible for facilitating the passage of small molecules through the plasma membrane; the subunit of the flavoprotein fumarate reductase (id: 1D4E), which is involved in the metabolism of nitrogenous bases; and the ATP-dependent Holliday DNA helicase junction (id: 1IN4), which is associated with histone proteins that package genetic material. Additionally, the molecular dynamics results indicated the stability of the interaction of Rondonin with 1MPF and 1IN4 during a 10 ns simulation. These interactions corroborate with previous in vitro studies on Rondonin, which acts on fungal genetic material without causing plasma membrane rupture. Therefore, the bioprospecting methods used in this research were considered satisfactory since they were consistent with previous results obtained via in vitro experimentation.

Supplementary information: The online version contains supplementary material available at 10.1007/s40203-024-00224-1.

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