Department of Biology, Faculty of Science, University of Split, Ruđera Boškovića 33, Split 21000, Croatia.
Department of Life Sciences, University of Trieste, Trieste 34127, Italy.
Acta Biomater. 2022 Jul 1;146:131-144. doi: 10.1016/j.actbio.2022.04.025. Epub 2022 Apr 22.
An infecting and propagating parasite relies on its innate defense system to evade the host's immune response and to survive challenges from commensal bacteria. More so for the nematode Anisakis, a marine parasite that during its life cycle encounters both vertebrate and invertebrate hosts and their highly diverse microbiotas. Although much is still unknown about how the nematode mitigates the effects of these microbiota, its antimicrobial peptides likely play an important role in its survival. We identified anisaxins, the first cecropin-like helical antimicrobial peptides originating from a marine parasite, by mining available genomic and transcriptomic data for Anisakis spp. These peptides are potent bactericidal agents in vitro, selectively active against Gram-negative bacteria, including multi-drug resistant strains, at sub-micromolar concentrations. Their interaction with bacterial membranes was confirmed by solid state NMR (ssNMR) and is highly dependent on the peptide concentration as well as peptide to lipid ratio, as evidenced by molecular dynamics (MD) simulations. MD results indicated that an initial step in the membranolytic mode of action involves membrane bulging and lipid extraction; a novel mechanism which may underline the peptides' potency. Subsequent steps include membrane permeabilization leading to leakage of molecules and eventually cell death, but without visible macroscopic damage, as shown by atomic force microscopy and flow cytometry. This membranolytic antibacterial activity does not translate to cytotoxicity towards human peripheral blood mononuclear cells (HPBMCs), which was minimal at well above bactericidal concentrations, making anisaxins promising candidates for further drug development. STATEMENT OF SIGNIFICANCE: Witnessing the rapid spread of antibiotic resistance resulting in millions of infected and dozens of thousands dying worldwide every year, we identified anisaxins, antimicrobial peptides (AMPs) from marine parasites, Anisakis spp., with potent bactericidal activity and selectivity towards multi-drug resistant Gram-negative bacteria. Anisaxins are membrane-active peptides, whose activity, very sensitive to local peptide concentrations, involves membrane bulging and lipid extraction, leading to membrane permeabilization and bacterial cell death. At the same time, their toxicity towards host cells is negligible, which is often not the case for membrane-active AMPs, therefore making them suitable drug candidates. Membrane bulging and lipid extraction are novel concepts that broaden our understanding of peptide interactions with bacterial functional structures, essential for future design of such biomaterials.
一种感染和传播寄生虫依赖于其先天防御系统来逃避宿主的免疫反应,并在共生细菌的挑战中存活下来。对于海洋寄生虫 Anisakis 来说更是如此,它在生命周期中会遇到脊椎动物和无脊椎动物宿主及其高度多样化的微生物群。尽管我们对线虫如何减轻这些微生物群的影响知之甚少,但它的抗菌肽可能在其生存中发挥重要作用。我们通过挖掘可用的 Anisakis spp. 基因组和转录组数据,鉴定了anisaxins,这是第一种源自海洋寄生虫的 Cecropin 样螺旋抗菌肽。这些肽在体外是有效的杀菌剂,以亚微摩尔浓度选择性地对革兰氏阴性菌,包括多药耐药菌株,具有活性。固态 NMR(ssNMR)证实了它们与细菌膜的相互作用,并且高度依赖于肽浓度以及肽与脂质的比率,这一点通过分子动力学(MD)模拟得到了证明。MD 结果表明,膜裂解作用模式的初始步骤涉及膜膨出和脂质提取;这是一种新的机制,可能是肽活性的基础。随后的步骤包括导致分子泄漏和最终细胞死亡的膜通透性,但是没有明显的宏观损伤,如原子力显微镜和流式细胞术所示。这种膜裂解抗菌活性不会转化为对人外周血单核细胞(HPBMCs)的细胞毒性,在远远高于杀菌浓度时,其细胞毒性极小,这使得 anisaxins 成为进一步药物开发的有前途的候选物。
抗生素耐药性的迅速传播导致全世界每年有数百万人感染和数万人死亡,我们从海洋寄生虫 Anisakis spp. 中鉴定出anisaxins,一种具有强大杀菌活性和对多药耐药革兰氏阴性菌选择性的抗菌肽(AMPs)。Anisaxins 是膜活性肽,其活性对局部肽浓度非常敏感,涉及膜膨出和脂质提取,导致膜通透性和细菌细胞死亡。与此同时,它们对宿主细胞的毒性可以忽略不计,而这通常不是膜活性 AMP 的情况,因此使它们成为合适的药物候选物。膜膨出和脂质提取是拓宽我们对肽与细菌功能结构相互作用的理解的新概念,这对于此类生物材料的未来设计至关重要。
