College of Life Science, Northwest University, Xi'an 710069, China.
College of Life Science, Northwest University, Xi'an 710069, China.
Biophys Chem. 2022 Jan;280:106710. doi: 10.1016/j.bpc.2021.106710. Epub 2021 Oct 30.
Voltage-dependent anion channel-l (VDAC-1) can bind with plasminogen Kringle 5 as the cell surface receptor and induce cell apoptosis, but the detailed information of binding is not clear yet. Thus, the mutual recognition and binding were investigated here utilizing frontal affinity chromatography, surface plasma resonance, mutation analysis combining molecular dynamics simulation. The results showed that Kringle 5 binds with VDAC-1 in equimolar driven mainly by electrostatic force, with 15 amino acid residues participating in Kringle 5 and 21 in VDAC-1. The observed conformational changes indicated the automatic structure regulation providing these two proteins suitable conformations and spatial surroundings for the tighter and stabler binding. Moreover, Glu29 in Kringle 5 was speculated as the key residue maintaining the largest energy contribution. Therefore, this work provided precise information for the recognition and binding of Kringle 5 with VDAC-1 that is valuable for the corresponding treatment of tumours or other angiogenic diseases.
电压门控阴离子通道 1(VDAC-1)可作为细胞表面受体与纤溶酶原kringle5 结合,诱导细胞凋亡,但结合的详细信息尚不清楚。因此,本研究利用前沿亲和层析、表面等离子体共振、突变分析结合分子动力学模拟,研究了两者的相互识别和结合。结果表明,kringle5 与 VDAC-1 以等摩尔结合,主要驱动力为静电力,kringle5 中有 15 个氨基酸残基参与,VDAC-1 中有 21 个氨基酸残基参与。观察到的构象变化表明,结构的自动调节为这两种蛋白质提供了合适的构象和空间环境,从而实现更紧密和稳定的结合。此外,kringle5 中的 Glu29 被推测为维持最大能量贡献的关键残基。因此,本研究为 kringle5 与 VDAC-1 的识别和结合提供了精确的信息,这对于相应的肿瘤或其他血管生成性疾病的治疗具有重要价值。