Discovery, characterization, and redesign of potent antimicrobial thanatin orthologs from Chinavia ubica and Murgantia histrionica targeting E. coli LptA

IF 3.5 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY
Kelly Huynh , Amanuel Kibrom , Bruce R. Donald , Pei Zhou
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Abstract

Podisus maculiventris thanatin has been reported as a potent antimicrobial peptide with antibacterial and antifungal activity. Its antibiotic activity has been most thoroughly characterized against E. coli and shown to interfere with multiple pathways, such as the lipopolysaccharide transport (LPT) pathway comprised of seven different Lpt proteins. Thanatin binds to E. coli LptA and LptD, thus disrupting the LPT complex formation and inhibiting cell wall synthesis and microbial growth. Here, we performed a genomic database search to uncover novel thanatin orthologs, characterized their binding to E. coli LptA using bio-layer interferometry, and assessed their antimicrobial activity against E. coli. We found that thanatins from Chinavia ubica and Murgantia histrionica bound tighter (by 3.6- and 2.2-fold respectively) to LptA and exhibited more potent antibiotic activity (by 2.1- and 2.8-fold respectively) than the canonical thanatin from P. maculiventris. We crystallized and determined the LptA-bound complex structures of thanatins from C. ubica (1.90 Å resolution), M. histrionica (1.80 Å resolution), and P. maculiventris (2.43 Å resolution) to better understand their mechanism of action. Our structural analysis revealed that residues A10 and I21 in C. ubica and M. histrionica thanatin are important for improving the binding interface with LptA, thus overall improving the potency of thanatin against E. coli. We also designed a stapled variant of thanatin that removes the need for a disulfide bond but retains the ability to bind LptA and antibiotic activity. Our discovery presents a library of novel thanatin sequences to serve as starting scaffolds for designing more potent antimicrobial therapeutics.

Abstract Image

针对大肠杆菌LptA的强效抑菌同源物的发现、鉴定和重新设计
据报道,黄斑足素是一种有效的抗菌肽,具有抗菌和抗真菌活性。其对大肠杆菌的抗生素活性已被彻底表征,并显示出对多种途径的干扰,例如由七种不同的LPT蛋白组成的脂多糖运输(LPT)途径。Thanatin结合大肠杆菌LptA和LptD,从而破坏LPT复合物的形成,抑制细胞壁合成和微生物生长。在这里,我们进行了基因组数据库搜索以发现新的thanatin同源物,使用生物层干涉法表征了它们与大肠杆菌LptA的结合,并评估了它们对大肠杆菌的抗菌活性。我们发现来自中国的ubica和Murgantia histrionica的thanatins与LptA结合更紧密(分别是3.6倍和2.2倍),并且比来自P. maculventris的典型thanatins表现出更强的抗生素活性(分别是2.1倍和2.8倍)。为了更好地了解它们的作用机制,我们对C. ubica (1.90 Å分辨率)、M. histrionica (1.80 Å分辨率)和P. maculventris (2.43 Å分辨率)中thanatins的lpta结合复合物结构进行了结晶和测定。我们的结构分析表明,C. ubica和M. histrionica thanatin中的残基A10和I21对改善与LptA的结合界面很重要,从而总体上提高了thanatin对大肠杆菌的效力。我们还设计了一种订钉变体的thanatin,它消除了对二硫键的需要,但保留了结合LptA和抗生素活性的能力。我们的发现提供了一个新的thanatin序列库,作为设计更有效的抗菌药物的起始支架。
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来源期刊
Journal of Structural Biology: X
Journal of Structural Biology: X Biochemistry, Genetics and Molecular Biology-Structural Biology
CiteScore
6.50
自引率
0.00%
发文量
20
审稿时长
62 days
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