α螺旋和半胱氨酸-半胱氨酸二硫键对细菌粘附菌毛抗逆性的影响

Joseph L. Baker, Tobias Dahlberg, E. Bullitt, Magnus Andersson
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引用次数: 5

摘要

黏附菌毛是病原菌在特定环境中附着的重要毒力因子。我们提供的机制细节结构差异影响毛的生物物理性质发现细菌在泌尿和肠道。首先,我们发现来自尿路细菌的P菌毛比产肠毒素细菌表达的CFA/I菌毛承受更高的力,这是由于二硫键限制了亚基的展开。其次,毛菌具有更大的弹性是由于α-螺旋基序可以展开,吸收可能导致细菌脱离的力。我们的工作提供了对菌毛结构和生物物理特性的核心作用的深入了解,这些特性对于启动疾病所需的持续细菌粘附是必要的。大肠杆菌表达黏附毛,介导附着于宿主细胞表面,并暴露于尿道和胃肠道的体液中。Pilin亚基被组织成螺旋状聚合物,顶端有一个粘附素用于特定的宿主结合。当暴露于流体流动力时,毛毛可以弹性舒展,减少粘附素负荷,从而促进持续附着。在这里,我们研究了毛的生物物理和结构上的差异,毛通常表达在细菌栖息在泌尿道和肠道。光学镊子测量显示,尿路致病性大肠杆菌(UPEC)的1a类菌毛,以及产肠毒素大肠杆菌(ETEC)的1b类菌毛,除了菌毛展开外,还经历了额外的构象变化,比ETEC 5类菌毛的结构提供了更大的弹性。通过分析结构和定向分子动力学模拟数据,我们发现1类菌毛亚基行为的差异源于α-螺旋基序,该基序在外力作用下可以展开。1类菌毛中的二硫键交联β-链稳定了亚基,使它们比缺乏共价键的5类菌毛承受更高的力。我们认为,这些对菌毛弹性的额外贡献与UPEC生态位有关,因为与肠道粘膜中的ETEC细菌相比,常驻细菌暴露于更强、更短暂的阻力。有趣的是,1b类ETEC菌毛包括与UPEC菌毛相同的结构特征,同时需要更低的解绕力,与5类ETEC菌毛更相似。
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Impact of an alpha helix and a cysteine–cysteine disulfide bond on the resistance of bacterial adhesion pili to stress
Significance Adhesion pili are often essential virulence factors for attachment of pathogenic bacteria in specific environmental niches. We provide mechanistic details of structural differences impacting the biophysical properties of pili found on bacteria in the urinary and intestinal tracts. First, we see that P pili from urinary tract bacteria withstand higher forces than CFA/I pili expressed on enterotoxigenic bacteria, due to a disulfide bond that limits subunit unraveling. Second, the greater elasticity of P pili is due to an α-helical motif that can unfold, absorbing force that could otherwise lead to bacteria detachment. Our work provides insight into the central role of pilus structural and biophysical properties for the sustained bacterial adherence necessary to initiate disease. Escherichia coli express adhesion pili that mediate attachment to host cell surfaces and are exposed to body fluids in the urinary and gastrointestinal tracts. Pilin subunits are organized into helical polymers, with a tip adhesin for specific host binding. Pili can elastically unwind when exposed to fluid flow forces, reducing the adhesin load, thereby facilitating sustained attachment. Here we investigate biophysical and structural differences of pili commonly expressed on bacteria that inhabit the urinary and intestinal tracts. Optical tweezers measurements reveal that class 1a pili of uropathogenic E. coli (UPEC), as well as class 1b of enterotoxigenic E. coli (ETEC), undergo an additional conformational change beyond pilus unwinding, providing significantly more elasticity to their structure than ETEC class 5 pili. Examining structural and steered molecular dynamics simulation data, we find that this difference in class 1 pili subunit behavior originates from an α-helical motif that can unfold when exposed to force. A disulfide bond cross-linking β-strands in class 1 pili stabilizes subunits, allowing them to tolerate higher forces than class 5 pili that lack this covalent bond. We suggest that these extra contributions to pilus resiliency are relevant for the UPEC niche, since resident bacteria are exposed to stronger, more transient drag forces compared to those experienced by ETEC bacteria in the mucosa of the intestinal tract. Interestingly, class 1b ETEC pili include the same structural features seen in UPEC pili, while requiring lower unwinding forces that are more similar to those of class 5 ETEC pili.
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