Max Planck Institute for Terrestrial Microbiology, Marburg, Germany.
Department of Biological Sciences, Dartmouth College, Hanover, NH, USA.
Nat Microbiol. 2018 Jan;3(1):26-31. doi: 10.1038/s41564-017-0050-1. Epub 2017 Oct 30.
In nature, bacteria primarily live in surface-attached, multicellular communities, termed biofilms . In medical settings, biofilms cause devastating damage during chronic and acute infections; indeed, bacteria are often viewed as agents of human disease . However, bacteria themselves suffer from diseases, most notably in the form of viral pathogens termed bacteriophages , which are the most abundant replicating entities on Earth. Phage-biofilm encounters are undoubtedly common in the environment, but the mechanisms that determine the outcome of these encounters are unknown. Using Escherichia coli biofilms and the lytic phage T7 as models, we discovered that an amyloid fibre network of CsgA (curli polymer) protects biofilms against phage attack via two separate mechanisms. First, collective cell protection results from inhibition of phage transport into the biofilm, which we demonstrate in vivo and in vitro. Second, CsgA fibres protect cells individually by coating their surface and binding phage particles, thereby preventing their attachment to the cell exterior. These insights into biofilm-phage interactions have broad-ranging implications for the design of phage applications in biotechnology, phage therapy and the evolutionary dynamics of phages with their bacterial hosts.
在自然界中,细菌主要生活在表面附着的多细胞群落中,称为生物膜。在医疗环境中,生物膜会在慢性和急性感染期间造成毁灭性的破坏;事实上,细菌通常被视为人类疾病的病原体。然而,细菌本身也会患病,最明显的是以噬菌体形式出现的病毒病原体,噬菌体是地球上数量最多的复制实体。噬菌体-生物膜的接触在环境中无疑是常见的,但决定这些接触结果的机制尚不清楚。我们使用大肠杆菌生物膜和裂解噬菌体 T7 作为模型,发现 CsgA(卷曲聚合物)的淀粉样纤维网络通过两种独立的机制保护生物膜免受噬菌体攻击。首先,通过抑制噬菌体进入生物膜,实现了细胞的集体保护,我们在体内和体外都证明了这一点。其次,CsgA 纤维通过覆盖细胞表面并结合噬菌体颗粒来保护单个细胞,从而防止它们附着在细胞外部。这些对生物膜-噬菌体相互作用的深入了解对生物技术中噬菌体应用的设计、噬菌体治疗以及噬菌体与其细菌宿主的进化动态具有广泛的意义。
