Exploring Antimicrobial Potency, ADMET, and Optimal Drug Target of a Non-ribosomal Peptide Sevadicin from Bacillus pumilus, through In Vitro Assay and Molecular Dynamics Simulation.

IF 4.4 2区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Sajid Iqbal, Farida Begum, Mohammad Y Alfaifi, Serag Eldin I Elbehairi, Abubakar Siddique, Peter Shaw
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Abstract

The current study was designed to explore the biosynthetic potential of sevadicin in Bacillus pumilus species and its interaction with bacterial drug target molecules. The non-ribosomal peptide (NRP) cluster in B. pumilus SF-4 was preliminarily confirmed using PCR-based screening, and the bioactivity of strain SF-4 culture extract was assessed against a set of human pathogenic strains. The susceptibility assay showed that strain SF-4 extract had higher inhibitory concentrations (312-375 µg/mL) than ciprofloxacin. Genome mining of B. pumilus strains (n = 22) using AntiSMASH and BAGEL identified sevadicin coding biosynthetic gene cluster only in strain SF-4, constitutes of two core biosynthetic genes, three additional biosynthetic genes, two transport-related genes, and one regulatory gene. The molecular docking of sevadicin with various putative bacterial drug targets such as dihydropteroate, muramyl ligase E, topoisomerase, penicillin-binding protein, and in vitro safety analyses were conducted with detailed ADMET screening. The results showed that sevadicin makes hydrophobic interaction with MurE (PDB ID: 1E8C and 4C13) via hydrogen bonding, suggesting bacterial growth inhibition by disrupting the cell wall synthesis pathway and exhibiting a secure biosafety profile. The stability and compactness of sevadicin/MurE complexes were assessed via molecular dynamic simulation using RMSD, RMSF, and Rg. The simulation results revealed the binding stability of sevadicin/MurE complexes and indicated that the complexes can't be easily deformed. In conclusion, the current study explored the biosynthesis of sevadicin in B. pumilus for the first time and found that sevadicin inhibits bacterial growth by inhibiting cell wall synthesis via targeting the MurE enzyme and exhibits no toxicity.

通过体外试验和分子动力学模拟探索普米氏芽孢杆菌非核糖体肽 Sevadicin 的抗菌效力、ADMET 和最佳药物靶点
本研究旨在探索七叶皂苷(sevadicin)在枯草芽孢杆菌(Bacillus pumilus)中的生物合成潜力及其与细菌药物靶分子的相互作用。通过基于 PCR 的筛选初步确认了枯草芽孢杆菌 SF-4 中的非核糖体肽(NRP)簇,并评估了菌株 SF-4 培养物提取物对一组人类致病菌株的生物活性。药敏试验显示,菌株 SF-4 提取物的抑菌浓度(312-375 µg/mL)高于环丙沙星。利用 AntiSMASH 和 BAGEL 对布氏杆菌菌株(n = 22)进行基因组挖掘,发现仅 SF-4 菌株中存在七叶皂苷编码生物合成基因簇,由两个核心生物合成基因、三个附加生物合成基因、两个转运相关基因和一个调控基因组成。通过详细的 ADMET 筛选,进行了七叶皂苷与多种假定细菌药物靶标(如二氢蝶酸酯、氨甲酰连接酶 E、拓扑异构酶、青霉素结合蛋白等)的分子对接和体外安全性分析。结果表明,sevadicin 可通过氢键与 MurE(PDB ID:1E8C 和 4C13)发生疏水作用,通过破坏细胞壁合成途径抑制细菌生长,生物安全性高。利用 RMSD、RMSF 和 Rg 进行分子动力学模拟,评估了西伐丁/MurE 复合物的稳定性和紧密性。模拟结果表明,蟛蜞菊素/MurE 复合物的结合稳定性很好,复合物不易变形。总之,本研究首次探索了sevadicin在布氏杆菌中的生物合成,发现sevadicin通过靶向MurE酶抑制细胞壁合成,从而抑制细菌生长,且无毒性。
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来源期刊
Probiotics and Antimicrobial Proteins
Probiotics and Antimicrobial Proteins BIOTECHNOLOGY & APPLIED MICROBIOLOGYMICROB-MICROBIOLOGY
CiteScore
11.30
自引率
6.10%
发文量
140
期刊介绍: Probiotics and Antimicrobial Proteins publishes reviews, original articles, letters and short notes and technical/methodological communications aimed at advancing fundamental knowledge and exploration of the applications of probiotics, natural antimicrobial proteins and their derivatives in biomedical, agricultural, veterinary, food, and cosmetic products. The Journal welcomes fundamental research articles and reports on applications of these microorganisms and substances, and encourages structural studies and studies that correlate the structure and functional properties of antimicrobial proteins.
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