糖激酶与羧酰胺活化剂S41的氧、硫和硒衍生物的对接

Glodi M. Ndefi, Albert S. Lundemba, Dikima D. Bibelayi, J. T. Kilembe, Eliakim M. Kambale, Celine W. Kadima, Zéphyrin G. Yav
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引用次数: 0

摘要

葡萄糖激酶(GK)失活与糖尿病有关。因此,针对GK激活位点的药物设计目前已纳入糖尿病治疗策略。本工作使用Gold 5.6程序基于分子对接研究了30个配体对GK的亲和力。葡萄糖激酶的结构来源于蛋白质数据库(PDB代码3S41),而配体是共结晶的羧酰胺激活剂的硒代、磺基和氧代衍生物(PDB编码:S41)。配体-蛋白质对接的结果表明,GK与所有配体形成热力学稳定的配合物。稳定配合物的主要力量是亲脂性相互作用,通过氢键增强。分子静电电位(MEP)证明了负责与GK变构位点中的氨基酸残基亲脂性和氢键接触的配体分子区域。有趣的是,S41衍生物中的12种与GK的相互作用比共结晶激活剂更强,同时保持与关键氨基酸残基(如Arg63)的亲脂性接触,Arg63对GK激活剂(GKAs)的治疗特性具有催化作用。值得注意的是,二价Se和S原子也参与了GKA位点中的硫族键。这些键几乎像氢键一样是线性的。这种键的方向性应该指导含有硫族元素原子的药效配体的设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Docking of Glycokinase with Oxo, Sulfo, and Seleno Derivatives of the Carboxamide Activator S41
Inactivation of Glucokinase (GK) is associated with diabetes. Therefore, design of drugs targeting the GK activator site is currently integrated in the strategy of the diabetes treatment. The present work investigated the affinity of 30 ligands to GK based on molecular docking using the Gold 5.6 program. Glucokinase’s structure was derived from the Protein Data Bank (PDB Code 3S41), while the ligands were seleno, sulfo and oxo derivatives of the co-crystallized carboxamide activator (PDB code: S41). The results of the ligand-protein docking revealed that GK formed thermodynamically stable complexes with all ligands. The main forces stabilizing the complexes are lipophilic interactions, enhanced by hydrogen bonds. Ligand molecular areas responsible for lipophilic and hydrogen bonding contacts with amino acid residues in the allosteric site of GK were evidenced by molecular electrostatic potentials (MEPs). Interestingly, twelve of the S41 derivatives interacted with GK more strongly than the co-crystallized activator, while maintaining the lipophilic contacts with key amino acid residues like Arg63, which are catalytically crucial for therapeutic properties of GK activators (GKAs). It is noteworthy that divalent Se and S atoms were also involved in chalcogen bonds in the GKA site. Those bonds were nearly linear like hydrogen bonds. Such bond directionality should guide the design of pharmacophoric ligands containing chalcogen atoms.
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