Abraham Fikru Mechesso, Weiwei Zhang, Yajuan Su, Jingwei Xie, Guangshun Wang
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However, these peptides showed clear activity differences against Gram-negative pathogens with RIK-10 + (i.e., LL-37mini2) being the strongest and LL-10 + the weakest. To understand this activity difference, we characterized peptide toxicity; the effects of salts, pH, and serum on peptide activity; and the mechanism of action and determined the membrane-bound helical structure for RIK-10 + by two-dimensional NMR spectroscopy. By writing an R program, we generated charge density plots for these peptides and uncovered the importance of the N-terminal high-density basic charges for antimicrobial potency. To validate this finding, we reversed the sequences of two peptides. Interestingly, sequence reversal weakened the activity of RIK-10 + but increased the activity of LL-10 + especially against Escherichia coli, Pseudomonas aeruginosa, and Acinetobacter baumannii. Those more active peptides with high cationicity at the N-terminus are also more hydrophobic based on HPLC retention times. A database search found numerous natural sequences that arrange basic amino acids primarily at the N-terminus. 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引用次数: 0
摘要
宿主防御抗菌肽(AMPs)是开发新一代多肽抗生素的公认候选药物。高疏水度的多肽可用于消灭革兰氏阳性细菌,而针对革兰氏阴性病原体的抗菌肽通常具有高阳离子性。本研究探讨了碱性氨基酸的序列分布如何影响肽的活性。为此,我们以人类柔毛球蛋白 LL-37 为模板,设计了四种具有相似长度、净电荷和疏水性的高选择性超短肽。LL-10 +、RK-9 +、KR-8 + 和 RIK-10 + 在体外对耐甲氧西林金黄色葡萄球菌表现出相似的活性,在小鼠伤口模型中的抗生物膜功效也相当。不过,这些肽对革兰氏阴性病原体的活性有明显差异,其中 RIK-10 +(即 LL-37mini2)最强,LL-10 + 最弱。为了了解这种活性差异,我们描述了肽的毒性;盐、pH 值和血清对肽活性的影响;以及作用机制,并通过二维核磁共振光谱确定了 RIK-10 + 的膜结合螺旋结构。通过编写 R 程序,我们生成了这些多肽的电荷密度图,并发现了 N 端高密度碱性电荷对抗菌效力的重要性。为了验证这一发现,我们反转了两种肽的序列。有趣的是,序列反转削弱了 RIK-10 + 的活性,但提高了 LL-10 + 的活性,尤其是对大肠杆菌、铜绿假单胞菌和鲍曼不动杆菌的活性。根据高效液相色谱保留时间,那些 N 端具有高阳离子性的活性肽也更疏水。通过数据库搜索发现了许多主要在 N 端排列碱性氨基酸的天然序列。综上所述,这项研究不仅获得了新的多肽线索,还发现了一种设计新型抗菌剂的有用策略,可用于控制耐药性革兰氏阴性病原体。
Segment-Based Peptide Design Reveals the Importance of N-Terminal High Cationicity for Antimicrobial Activity Against Gram-Negative Pathogens.
Host defense antimicrobial peptides (AMPs) are recognized candidates to develop a new generation of peptide antibiotics. While high hydrophobicity can be deployed in peptides for eliminating Gram-positive bacteria, high cationicity is usually observed in AMPs against Gram-negative pathogen. This study investigates how the sequence distribution of basic amino acids affects peptide activity. For this purpose, we utilized human cathelicidin LL-37 as a template and designed four highly selective ultrashort peptides with similar length, net charge, and hydrophobic content. LL-10 + , RK-9 + , KR-8 + , and RIK-10 + showed similar activity against methicillin-resistant Staphylococcus aureus in vitro and comparable antibiofilm efficacy in a murine wound model. However, these peptides showed clear activity differences against Gram-negative pathogens with RIK-10 + (i.e., LL-37mini2) being the strongest and LL-10 + the weakest. To understand this activity difference, we characterized peptide toxicity; the effects of salts, pH, and serum on peptide activity; and the mechanism of action and determined the membrane-bound helical structure for RIK-10 + by two-dimensional NMR spectroscopy. By writing an R program, we generated charge density plots for these peptides and uncovered the importance of the N-terminal high-density basic charges for antimicrobial potency. To validate this finding, we reversed the sequences of two peptides. Interestingly, sequence reversal weakened the activity of RIK-10 + but increased the activity of LL-10 + especially against Escherichia coli, Pseudomonas aeruginosa, and Acinetobacter baumannii. Those more active peptides with high cationicity at the N-terminus are also more hydrophobic based on HPLC retention times. A database search found numerous natural sequences that arrange basic amino acids primarily at the N-terminus. Combined, this study not only obtained novel peptide leads but also discovered one useful strategy for designing novel antimicrobials to control drug-resistant Gram-negative pathogens.
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.