Center for Infectious Diseases and Vaccinology, the Biodesign Institute, Arizona State Universitygrid.215654.1, Tempe, Arizona, USA.
School of Life Sciences, Arizona State Universitygrid.215654.1, Tempe, Arizona, USA.
mSphere. 2022 Aug 31;7(4):e0021022. doi: 10.1128/msphere.00210-22. Epub 2022 Aug 1.
The discovery that biomechanical forces regulate microbial virulence was established with the finding that physiological low fluid shear (LFS) forces altered gene expression, stress responses, and virulence of the enteric pathogen Salmonella enterica serovar Typhimurium during the log phase. These log phase LFS-induced phenotypes were independent of the master stress response regulator, RpoS (σ). Given the central importance of RpoS in regulating stationary-phase stress responses of S. Typhimurium cultured under conventional shake flask and static conditions, we examined its role in stationary-phase cultures grown under physiological LFS. We constructed an isogenic mutant derivative of wild-type S. Typhimurium and compared the ability of these strains to survive pathogenesis-related stresses that mimic those encountered in the infected host and environment. We also compared the ability of these strains to colonize (adhere, invade, and survive within) human intestinal epithelial cell cultures. Unexpectedly, LFS-induced resistance of stationary-phase S. Typhimurium cultures to acid and bile salts stresses did not rely on RpoS. Likewise, RpoS was dispensable for stationary-phase LFS cultures to adhere to and survive within intestinal epithelial cells. In contrast, the resistance of these cultures to challenges of oxidative and thermal stresses, and their invasion into intestinal epithelial cells was influenced by RpoS. These findings expand our mechanistic understanding of how physiological fluid shear forces modulate stationary-phase S. Typhimurium physiology in unexpected ways and provide clues into microbial mechanobiology and nuances of Salmonella responses to microenvironmental niches in the infected host. Bacterial pathogens respond dynamically to a variety of stresses in the infected host, including physical forces of fluid flow (fluid shear) across their surfaces. While pathogens experience wide fluctuations in fluid shear during infection, little is known about how these forces regulate microbial pathogenesis. This is especially important for stationary-phase bacterial growth, which is a critical period to understand microbial resistance, survival, and infection potential, and is regulated in many bacteria by the general stationary-phase stress response protein RpoS. Here, we showed that, unlike conventional culture conditions, several stationary-phase Salmonella pathogenic stress responses were not impacted by RpoS when bacteria were cultured under fluid shear conditions relevant to those encountered in the intestine of the infected host. These findings offer new insight into how physiological fluid shear forces encountered by Salmonella during infection might impact pathogenic responses in unexpected ways that are relevant to their disease-causing ability.
生物力学力调节微生物毒力的发现是通过发现生理低流体剪切 (LFS) 力改变肠病原体鼠伤寒沙门氏菌的基因表达、应激反应和毒力而确立的。在对数期,这些对数期 LFS 诱导的表型与主应激反应调节剂 RpoS (σ) 无关。鉴于 RpoS 在调节常规摇瓶和静态条件下培养的鼠伤寒沙门氏菌的静止期应激反应中的核心重要性,我们研究了它在生理 LFS 下培养的静止期培养物中的作用。我们构建了野生型鼠伤寒沙门氏菌的同源缺失突变体衍生物,并比较了这些菌株在模拟感染宿主和环境中遇到的与发病相关的应激下生存的能力。我们还比较了这些菌株在定植(附着、侵入和在人肠上皮细胞培养物中存活)方面的能力。出乎意料的是,静止期鼠伤寒沙门氏菌培养物对酸和胆盐应激的 LFS 诱导抗性不依赖于 RpoS。同样,RpoS 对于静止期 LFS 培养物附着到并在肠上皮细胞内存活是可有可无的。相比之下,这些培养物对氧化和热应激的抗性以及它们侵入肠上皮细胞的能力受到 RpoS 的影响。这些发现扩展了我们对生理流体剪切力以意想不到的方式调节静止期鼠伤寒沙门氏菌生理学的机制理解,并为微生物机械生物学和沙门氏菌对感染宿主微环境小生境的反应提供了线索。 细菌病原体在感染宿主时会动态响应多种应激,包括其表面的流体流动(流体剪切)的物理力。虽然病原体在感染过程中经历流体剪切力的广泛波动,但对这些力如何调节微生物发病机制知之甚少。这对于静止期细菌生长尤其重要,因为这是了解微生物抗性、存活和感染潜力的关键时期,并且在许多细菌中由一般静止期应激反应蛋白 RpoS 调节。在这里,我们表明,与传统培养条件不同,当细菌在与感染宿主肠道中遇到的条件相关的流体剪切条件下培养时,几种静止期沙门氏菌致病应激反应不受 RpoS 影响。这些发现为生理流体剪切力在感染过程中遇到的沙门氏菌如何以意想不到的方式影响致病反应提供了新的见解,这些反应与它们的致病能力有关。
