Ravichellam Sangavi, Sankar Muthumanickam, Nambiraman Malligarjunan, Ravi Jothi, Pandi Boomi, Seenichamy Arivudainambi, Muthusamy Raman, Chaitanya G Joshi, Shunmugiah Karutha Pandian, Shanmugaraj Gowrishankar
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引用次数: 0
Abstract
Globally, dental caries is a prevalent oral disease caused by cariogenic bacteria, primarily Streptococcus mutans. It establishes caries either through sucrose-dependent (via glycosyltransferases) or through sucrose-independent (via surface adhesins Antigen I/II) mechanism. Sortase A (srtA) attaches virulence-associated adhesins to host tissues. Because of their importance in the formation of caries, targeting these proteins is decisive in the development of new anticariogenic drugs. High-throughput virtual screening with LIPID MAPS -a fatty acid database was performed. The selected protein-ligand complexes were subjected to molecular dynamics simulation (MDs). The Binding Free Energy of complexes was predicted using MM/PBSA. Further, the drug-likeness and pharmacokinetic properties of ligands were also analyzed. Out of 46,200 FAs scrutinized virtually against the three protein targets (viz., GtfC, Ag I/II and srtA), top 5 FAs for each protein were identified as the best hit based on interaction energies viz., hydrogen bond numbers and hydrophobic interaction. Further, two common FAs (LMFA01050418 and LMFA01040045) that showed high binding affinity against Ag I/II and srtA were selected for MDs analysis. A 100ns MDs unveiled a stable conformation. Results of Rg signified that FAs does not induce significant structural & conformational changes. SASA indicated that the complexes maintain higher thermodynamic stability during MDs. The predicted binding free energy (MM/PBSA) of complexes elucidated their stable binding interaction. ADME analysis suggested the FAs are biologically feasible as therapeutic candidates. Overall, the presented in silico data is the first of its kind in delineating FAs as promising anticaries agents of future.Communicated by Ramaswamy H. Sarma.
在全球范围内,龋齿是一种常见的口腔疾病,由致龋细菌引起,主要是变形链球菌。它通过蔗糖依赖性(通过糖基转移酶)或蔗糖非依赖性(通过表面粘附素抗原I/II)机制建立龋。排序酶A (srtA)将毒力相关的粘附素附着到宿主组织上。由于它们在龋齿形成中的重要性,靶向这些蛋白在开发新的抗肿瘤药物中具有决定性作用。使用脂质地图-脂肪酸数据库进行高通量虚拟筛选。选择的蛋白质配体复合物进行分子动力学模拟(MDs)。用MM/PBSA预测了配合物的结合自由能。此外,还分析了配体的药物相似性和药代动力学性质。在针对三种蛋白质靶标(即GtfC, Ag I/II和srtA)的46,200个FAs中,基于相互作用能(即氢键数和疏水相互作用),每种蛋白质的前5个FAs被确定为最佳命中。此外,我们选择了对Ag I/II和srtA具有高结合亲和力的两个常见FAs (LMFA01050418和LMFA01040045)进行MDs分析。一个100ns的MDs揭示了一个稳定的构象。Rg结果表明,FAs不会引起显著的结构和构象变化。SASA表明配合物在MDs过程中保持较高的热力学稳定性。预测的结合自由能(MM/PBSA)表明配合物具有稳定的结合相互作用。ADME分析表明,FAs作为候选治疗药物在生物学上是可行的。总的来说,在计算机数据中提出的是第一个描述FAs作为未来有前途的抗药物的类型。由Ramaswamy H. Sarma传达。
期刊介绍:
The Journal of Biomolecular Structure and Dynamics welcomes manuscripts on biological structure, dynamics, interactions and expression. The Journal is one of the leading publications in high end computational science, atomic structural biology, bioinformatics, virtual drug design, genomics and biological networks.
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