Laboratório de Tecnologia Biomolecular, Instituto de Ciências Biológicas, Universidade Federal do Pará, Belém, Brazil.
Centro de Inovações Tecnológicas, Instituto Evandro Chagas, Ananindeua, Brazil.
J Biomol Struct Dyn. 2022 Feb;40(3):1064-1073. doi: 10.1080/07391102.2020.1821782. Epub 2020 Sep 29.
Lectins that bind to HIV envelope glycoprotein can inhibit virus-cell fusion and be used for rational drug design. This paper presents the results of an approach to improve affinity interaction between the cyanobacterial lectin microvirin and its ligand Manα(1-2)Man. Comparative modeling and molecular dynamics tools were used. Additionally, the alanine scanning webserver was used to study the importance of protein residues in the binding site and to guide mutant production. The model obtained presented two homologous domains designated as domains A and B, each consisting of a single strand with triple and antiparallel β-sheets of (β1-β3 and β6-β8). Disulfide bonds between the cysteines (Cys60-Cys80, Cys63-Cys78 and Cys8-Cys24) were also found. The highly conserved binding site, including residues Asn44, Ile45, Asp46, Gln54, Asn55, Glu58, Thr59, Gln81, Thr82 and Met83. The RMSD values of the di-mannose and the interaction site were very stable during the molecular dynamics. Calculations of the occupation time of the hydrogen bonds were made for the residues that showed interaction in the complex lectin and ligand. The residue that contributed most to the interaction with Manα(1-2)Man was Asn55. After validation, the model generated remained stable during the entire simulation. Despite its structural similarity with the template we used, our mutant (Thr82Arg) showed a higher affinity interaction with Manα(1-2)Man. Communicated by Ramaswamy H. Sarma.
能够与 HIV 包膜糖蛋白结合的凝集素可以抑制病毒与细胞的融合,可用于合理的药物设计。本文介绍了一种提高蓝藻凝集素 microvirin 与其配体 Manα(1-2)Man 之间亲和力相互作用的方法。使用了比较建模和分子动力学工具。此外,还使用丙氨酸扫描网络服务器研究了蛋白质残基在结合部位的重要性,并指导突变体的产生。得到的模型呈现出两个同源结构域,分别命名为结构域 A 和 B,每个结构域由一条单链组成,具有三链和反平行β-折叠(β1-β3 和 β6-β8)。还发现了半胱氨酸(Cys60-Cys80、Cys63-Cys78 和 Cys8-Cys24)之间的二硫键。包括残基 Asn44、Ile45、Asp46、Gln54、Asn55、Glu58、Thr59、Gln81、Thr82 和 Met83 的高度保守结合位点。在分子动力学过程中,二甘露糖和相互作用位点的 RMSD 值非常稳定。对复合物中表现出相互作用的残基的氢键占据时间进行了计算。对 Manα(1-2)Man 相互作用贡献最大的残基是 Asn55。模型验证后,在整个模拟过程中保持稳定。尽管该模型与我们使用的模板具有结构相似性,但我们的突变体(Thr82Arg)与 Manα(1-2)Man 表现出更高的亲和力相互作用。由 Ramaswamy H. Sarma 传达。
