Department of Food Safety and Analytical Quality Control Laboratory, Central Food Technological Research Institute, Council of Scientific and Industrial Research, Mysuru, India.
Academy of Scientific and Innovative Research (AcSIR), Ghaziabad, India.
J Biomol Struct Dyn. 2024 Apr;42(7):3472-3491. doi: 10.1080/07391102.2023.2212795. Epub 2023 May 18.
Pancreatic lipase (PL) is a keen target for anti-obesity therapy that reduces dietary fat absorption. Here, we investigated the binding patterns of 220 PL inhibitors having experimental IC values, using molecular docking and binding energy calculations. Screening of these compounds illustrated most of them bound at the catalytic site (S1-S2 channel) and a few compounds are at the non-catalytic site (S2-S3 channel/S1-S3 channel) of PL. This binding pattern could be due to structural uniqueness or bias in conformational search. A strong correlation of pIC values with SP/XP docking scores, binding energies (ΔG) assured the binding poses are more true positives. Further, understanding of each class and subclasses of polyphenols indicated tannins preferred non-catalytic site wherein binding energies are underestimated due to huge desolvation energy. In contrast, most of the flavonoids and furan-flavonoids have good binding energies due to strong interactions with catalytic residues. While scoring functions limited the understanding of sub-classes of flavonoids. Hence, focused on 55 potent PL inhibitors of IC < 5 µM for better efficacy. The prediction of bioactivity, drug-likeness properties, led to 14 bioactive compounds. The low root mean square deviation (0.1-0.2 nm) of these potent flavonoids and non-flavonoid/non-polyphenols PL-inhibitor complexes during 100 ns molecular dynamics runs (MD) as well as binding energies obtained from both MD and well-tempered metadynamics, support strong binding to catalytic site. Based on the bioactivity, ADMET properties, and binding affinity data of MD and wt-metaD of potent PL-inhibitors suggests Epiafzelechin 3-O-gallate, Sanggenon C, and Sanggenofuran A shall be promising inhibitors at conditions.Communicated by Ramaswamy H. Sarma.
胰脂肪酶(PL)是一种用于减少饮食脂肪吸收的抗肥胖治疗的靶点。在这里,我们使用分子对接和结合能计算研究了具有实验 IC 值的 220 种 PL 抑制剂的结合模式。对这些化合物的筛选表明,它们中的大多数结合在催化部位(S1-S2 通道),少数化合物结合在非催化部位(S2-S3 通道/S1-S3 通道)。这种结合模式可能是由于结构的独特性或构象搜索的偏向。pIC 值与 SP/XP 对接分数、结合能(ΔG)之间存在很强的相关性,这保证了结合构象是更真实的阳性结果。此外,对多酚的每个类别和子类的理解表明,单宁更喜欢非催化部位,其中结合能由于巨大的去溶剂化能而被低估。相比之下,大多数黄酮类化合物和呋喃类黄酮具有良好的结合能,因为它们与催化残基之间存在强烈的相互作用。虽然评分函数限制了对黄酮类化合物子类的理解。因此,我们专注于 55 种具有 IC < 5 μM 的强效 PL 抑制剂,以提高疗效。生物活性和药物相似性的预测导致了 14 种生物活性化合物。在 100 ns 分子动力学运行(MD)期间,这些强效黄酮类化合物和非黄酮类/非多酚类 PL 抑制剂复合物的均方根偏差(0.1-0.2 nm)较低,以及从 MD 和 well-tempered metadynamics 获得的结合能,支持它们与催化部位的强结合。基于 MD 和 wt-metaD 的生物活性、ADMET 特性和结合亲和力数据,提示 Epiafzelechin 3-O-gallate、Sanggenon C 和 Sanggenofuran A 在条件下可能是有前途的抑制剂。由 Ramaswamy H. Sarma 传达。
