Abstract

Francisella tularensis is classified as a Tier 1 select agent by the CDC due to its low infectious dose and the possibility that the organism can be used as a bioweapon. The low dose of infection suggests that Francisella is unusually efficient at evading host defenses. Although ~50 cfu are necessary to cause human respiratory infection, the early interactions of virulent Francisella with the lung environment are not well understood. To provide additional insights into these interactions during early Francisella infection of mice, we performed TEM analysis on mouse lungs infected with F. tularensis strains Schu S4, LVS and the O-antigen mutant Schu S4 waaY::TrgTn. For all three strains, the majority of the bacteria that we could detect were observed within alveolar type II epithelial cells at 16 hours post infection. Although there were no detectable differences in the amount of bacteria within an infected cell between the three strains, there was a significant increase in the amount of cellular debris observed in the air spaces of the lungs in the Schu S4 waaY::TrgTn mutant compared to either the Schu S4 or LVS strain. We also studied the interactions of Francisella strains with human AT-II cells in vitro by characterizing the ability of these three strains to invade and replicate within these cells. Gentamicin assay and confocal microscopy both confirmed that F. tularensis Schu S4 replicated robustly within these cells while F. tularensis LVS displayed significantly lower levels of growth over 24 hours, although the strain was able to enter these cells at about the same level as Schu S4 (1 organism per cell), as determined by confocal imaging. The Schu S4 waaY::TrgTn mutant that we have previously described as attenuated for growth in macrophages and mouse virulence displayed interesting properties as well. This mutant induced significant airway inflammation (cell debris) and had an attenuated growth phenotype in the human AT-II cells. These data extend our understanding of early Francisella infection by demonstrating that Francisella enter significant numbers of AT-II cells within the lung and that the capsule and LPS of wild type Schu S4 helps prevent murine lung damage during infection. Furthermore, our data identified that human AT-II cells allow growth of Schu S4, but these same cells supported poor growth of the attenuated LVS strain in vitro. Collectively, these data further our understanding of the role of AT-II cells in Francisella infections.

Highlights

  • Francisella tularensis is a highly virulent intracellular bacterial pathogen that causes the human infectious disease tularemia [1, 2]

  • The lung is protected from microbial insult by both alveolar macrophages that reside in the extracellular alveolar air spaces and by the physical barrier composed of alveolar epithelial cells

  • In order to better understand the interactions of Francisella with alveolar epithelial type II cells (AT-II) cells, we conducted experiments with recently immortalized primary human AT-II cells, to compare the interactions of virulent F. tularensis Schu S4, and the F. tularensis LVS strain in these cells

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Summary

Introduction

Francisella tularensis is a highly virulent intracellular bacterial pathogen that causes the human infectious disease tularemia [1, 2]. Upon engulfment of a particle or bacterium, alveolar macrophages increase their phagocytic activity, oxidative burst capacity and production of pro-inflammatory cytokines [7]. These induced protective responses lead to the release of alveolar macrophages from the airway epithelium, where they (along with their engulfed cargo) are removed from the lung air spaces via the mucociliary escalator [8]. Since interactions with alveolar macrophages are likely to result in the removal of Francisella organisms from airway epithelial environment, it seems likely that the bacteria must productively interact with other cell types in order to breach the respiratory epithelium and gain access to deeper tissue and the bloodstream

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