Mortezaei Narges, Singh Bhupender, Zakrisson Johan, Bullitt Esther, Andersson Magnus
Department of Physics, Umeå University, Umeå, Sweden.
Department of Physics, Umeå University, Umeå, Sweden; Umeå Centre for Microbial Research (UCMR), Umeå University, Umeå, Sweden.
Biophys J. 2015 Jul 7;109(1):49-56. doi: 10.1016/j.bpj.2015.05.022.
Enterotoxigenic Escherichia coli (ETEC) are a major cause of diarrhea worldwide, and infection of children in under-developed countries often leads to high mortality rates. Isolated ETEC expresses a plethora of colonization factors (fimbriae/pili), of which CFA/I and CFA/II, which are assembled via the alternate chaperone pathway (ACP), are among the most common. Fimbriae are filamentous structures whose shafts are primarily composed of helically arranged single pilin-protein subunits, with a unique biomechanical ability to unwind and rewind. A sustained ETEC infection, under adverse conditions of dynamic shear forces, is primarily attributed to this biomechanical feature of ETEC fimbriae. Recent understanding about the role of fimbriae as virulence factors points to an evolutionary adaptation of their structural and biomechanical features. In this work, we investigated the biophysical properties of CS2 fimbriae from the CFA/II group. Homology modeling of its major structural subunit, CotA, reveals structural clues related to the niche in which they are expressed. Using optical-tweezers force spectroscopy, we found that CS2 fimbriae unwind at a constant force of 10 pN and have a corner velocity (i.e., the velocity at which the force required for unwinding rises exponentially with increased speed) of 1300 nm/s. The biophysical properties of CS2 fimbriae assessed in this work classify them into a low-force unwinding group of fimbriae together with the CFA/I and CS20 fimbriae expressed by ETEC strains. The three fimbriae are expressed by ETEC, colonize in similar gut environments, and exhibit similar biophysical features, but differ in their biogenesis. Our observation suggests that the environment has a strong impact on the biophysical characteristics of fimbriae expressed by ETEC.
产肠毒素大肠杆菌(ETEC)是全球腹泻的主要病因,在欠发达国家,儿童感染ETEC往往导致高死亡率。分离出的ETEC表达多种定植因子(菌毛),其中通过替代伴侣途径(ACP)组装的CFA/I和CFA/II是最常见的。菌毛是丝状结构,其杆主要由螺旋排列的单个菌毛蛋白亚基组成,具有独特的生物力学能力,能够展开和重新缠绕。在动态剪切力的不利条件下,ETEC持续感染主要归因于ETEC菌毛的这种生物力学特性。最近对菌毛作为毒力因子作用的认识表明,其结构和生物力学特性存在进化适应性。在这项工作中,我们研究了CFA/II组CS2菌毛的生物物理特性。其主要结构亚基CotA的同源建模揭示了与其表达位点相关的结构线索。使用光镊力谱,我们发现CS2菌毛在10 pN的恒定力下展开,拐角速度(即展开所需力随速度增加呈指数上升的速度)为1300 nm/s。在这项工作中评估的CS2菌毛的生物物理特性将它们与ETEC菌株表达的CFA/I和CS20菌毛一起归类为低力展开菌毛组。这三种菌毛由ETEC表达,在相似的肠道环境中定植,并表现出相似的生物物理特征,但它们的生物发生不同。我们的观察表明,环境对ETEC表达的菌毛的生物物理特性有强烈影响。