Computational and Structural Biology Laboratory, Department of Biological Sciences and Engineering, Netaji Subhas University of Technology, New Delhi, India.
Mammalian Cell Culture Laboratory, Department of Biological Sciences and Engineering, Netaji Subhas University of Technology, New Delhi, India.
SAR QSAR Environ Res. 2024 Aug;35(8):729-756. doi: 10.1080/1062936X.2024.2394498. Epub 2024 Sep 9.
Human neutrophil elastase (HNE) plays a key role in initiating inflammation in the cardiopulmonary and systemic contexts. Pathological auto-proteolysed two-chain (tc) HNE exhibits reduced binding affinity with inhibitors. Using AutoDock Vina v1.2.0, 66 flavonoid inhibitors, sivelestat and alvelestat were docked with single-chain (sc) HNE and tcHNE. Schrodinger PHASE v13.4.132 was used to generate a 3D-QSAR model. Molecular dynamics (MD) simulations were conducted with AMBER v18. The 3D-QSAR model for flavonoids with scHNE showed = 0.95 and = 0.91. High-activity compounds had hydrophobic A/A2 and C/C2 rings in the S1 subsite, with hydrogen bond donors at C5 and C7 positions of the A/A2 ring, and the C4' position of the B/B1 ring. All flavonoids except robustaflavone occupied the S1'-S2' subsites of tcHNE with decreased AutoDock binding affinities. During MD simulations, robustaflavone remained highly stable with both HNE forms. Principal Component Analysis suggested that robustaflavone binding induced structural stability in both HNE forms. Cluster analysis and free energy landscape plots showed that robustaflavone remained within the sc and tcHNE binding site throughout the 100 ns MD simulation. The robustaflavone scaffold likely inhibits both tcHNE and scHNE. It is potentially superior to sivelestat and alvelestat and can aid in developing therapeutics targeting both forms of HNE.
人中性粒细胞弹性蛋白酶 (HNE) 在心肺和全身炎症的启动中起着关键作用。病理性自身蛋白水解的双链 (tc) HNE 表现出与抑制剂结合亲和力降低。使用 AutoDock Vina v1.2.0,对 66 种黄酮类抑制剂、西维来司他和阿维来司他与单链 (sc) HNE 和 tcHNE 进行了对接。Schrodinger PHASE v13.4.132 用于生成 3D-QSAR 模型。使用 AMBER v18 进行分子动力学 (MD) 模拟。与 scHNE 的黄酮类化合物的 3D-QSAR 模型显示 = 0.95 和 = 0.91。高活性化合物在 S1 亚位点具有疏水性的 A/A2 和 C/C2 环,A/A2 环的 C5 和 C7 位置以及 B/B1 环的 C4'位置具有氢键供体。除了罗伯士黄酮外,所有黄酮类化合物都占据了 tcHNE 的 S1'-S2'亚位点,与 AutoDock 结合亲和力降低。在 MD 模拟过程中,罗伯士黄酮与两种 HNE 形式都保持高度稳定。主成分分析表明,罗伯士黄酮结合诱导两种 HNE 形式的结构稳定性。聚类分析和自由能景观图表明,罗伯士黄酮在整个 100 ns MD 模拟过程中都保留在 sc 和 tcHNE 结合位点内。罗伯士黄酮骨架可能抑制 tcHNE 和 scHNE。它可能优于西维来司他和阿维来司他,并有助于开发针对两种 HNE 形式的治疗药物。
