Department of Chemical Science and Technologies, University of Rome Tor Vergata, Rome, Italy.
Laboratory affiliated to Pasteur Italia-Fondazione Cenci Bolognetti, Department of Biochemical Sciences, Sapienza University of Rome, Rome, Italy.
Biochim Biophys Acta Biomembr. 2020 Aug 1;1862(8):183291. doi: 10.1016/j.bbamem.2020.183291. Epub 2020 Mar 28.
Antimicrobial peptides (AMPs) selectively kill bacteria by disrupting their cell membranes, and are promising compounds to fight drug-resistant microbes. Biophysical studies on model membranes have characterized AMP/membrane interactions and the mechanism of bilayer perturbation, showing that accumulation of cationic peptide molecules in the external leaflet leads to the formation of pores ("carpet" mechanism). However, similar quantitative studies on real cells are extremely limited. Here, we investigated the interaction of the dansylated PMAP23 peptide (DNS-PMAP23) with a Gram-positive bacterium, showing that 10 bound peptide molecules per cell are needed to kill it. This result is consistent with our previous finding for Gram-negative strains, where a similar high threshold for killing was determined, demonstrating the general relevance of the carpet model for real bacteria. However, in the case of the Gram-positive strain, this number of molecules even exceeds the total surface available on the bacterial membrane. The high affinity of DNS-PMAP23 for the anionic teichoic acids of the Gram-positive cell wall, but not for the lipopolysaccharides of Gram-negative bacteria, provides a rationale for this finding. To better define the role of anionic lipids in peptide/cell association, we studied DNS-PMAP23 interaction with E. coli mutant strains lacking phosphatidylglycerol and/or cardiolipin. Surprisingly, these strains showed a peptide affinity similar to that of the wild type. This finding was rationalized by observing that these bacteria have an increased content of other anionic lipids, thus maintaining the total membrane charge essentially constant. Finally, studies of DNS-PMAP23 association to dead bacteria showed an affinity an order of magnitude higher compared to that of live cells, suggesting strong peptide binding to intracellular components that become accessible after membrane perturbation. This effect could play a role in population resistance to AMP action, since dead bacteria could protect the surviving cells by sequestering significant amounts of peptide molecules. Overall, our data indicate that quantitative studies of peptide association to bacteria can lead to a better understanding of the mechanism of action of AMPs.
抗菌肽(AMPs)通过破坏细菌的细胞膜选择性地杀死细菌,是对抗耐药微生物的有前途的化合物。对模型膜的生物物理研究已经描述了 AMP/膜相互作用和双层扰动的机制,表明阳离子肽分子在外部小叶中的积累导致孔的形成(“地毯”机制)。然而,对真实细胞的类似定量研究极为有限。在这里,我们研究了dansylated PMAP23 肽(DNS-PMAP23)与革兰氏阳性菌的相互作用,结果表明每个细胞需要 10 个结合的肽分子才能杀死它。这一结果与我们之前对革兰氏阴性菌株的发现一致,在革兰氏阴性菌株中,确定了类似的高致死阈值,证明了地毯模型对真实细菌的普遍相关性。然而,在革兰氏阳性菌株的情况下,这个分子数量甚至超过了细菌膜上可用的总表面积。DNS-PMAP23 对革兰氏阳性细胞壁中阴离子磷壁酸的高亲和力,而不是对革兰氏阴性细菌中脂多糖的亲和力,为这一发现提供了依据。为了更好地定义阴离子脂质在肽/细胞结合中的作用,我们研究了 DNS-PMAP23 与缺乏磷脂酰甘油和/或心磷脂的大肠杆菌突变菌株的相互作用。令人惊讶的是,这些菌株显示出与野生型相似的肽亲和力。通过观察到这些细菌具有增加的其他阴离子脂质含量,从而使总膜电荷基本保持不变,这一发现得到了合理化。最后,DNS-PMAP23 与死细菌的结合研究显示,与活细胞相比,其亲和力高出一个数量级,这表明肽与细胞膜扰动后变得可及的细胞内成分有强烈的结合。这种效应可能在群体对 AMP 作用的抗性中起作用,因为死细菌可以通过隔离大量肽分子来保护存活的细胞。总的来说,我们的数据表明,对肽与细菌结合的定量研究可以更好地理解 AMP 的作用机制。
