Background <p>Food-borne pathogens, particularly belonging to the <i>Enterobacteriaceae</i> family, are a major cause of gastrointestinal infections in humans. While <i>Drosophila melanogaster</i> has been widely explored to study antimicrobial responses, most studies rely on septic injury or direct injection routes that bypass the gut. A coordinated set of antimicrobial defenses acts to counteract the invading bacteria, with some variations depending on the entry route into the host. Herein, we tracked the dynamics of <i>Enterobacteriaceae</i> pathogens in <i>Drosophila</i> using a natural infection route.</p> Results <p>Most bacterial species were cleared within 48&#xa0;h post-infection (hpi). We did not observe any significant mortality, indicating robust infection control. At 4 hpi, a substantial increase in reactive oxygen species (ROS) production was observed, followed by a decrease at 24 hpi and a resurgence at 48 hpi. We further show that bacteria were expelled by the fly, possibly due to <i>TRPA1</i> induction, a ROS-sensing receptor. Although the infected dual oxidase (Duox) knockdown flies showed no difference in survival rate compared to the uninfected ones, they showed differential <i>TRPA1</i> induction and pathogen expulsion, suggesting that ROS alone is insufficient for <i>TRPA1</i> induction and infection control.</p> Conclusions <p>Our findings reveal that the host can distinguish and respond to various bacterial species in a well-synchronized, gut-localized, and pathogen-specific manner. This also illustrates the reliability of natural infection route models in unravelling and understanding the complexities of host–pathogen interaction.</p>

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Drosophila melanogaster mitigates gastro-oral infections by stimulating pathogen expulsion

  • Shreya Verma,
  • Sushovan Bhattacharyya,
  • Meghana Tare,
  • Sandhya Amol Marathe

摘要

Background

Food-borne pathogens, particularly belonging to the Enterobacteriaceae family, are a major cause of gastrointestinal infections in humans. While Drosophila melanogaster has been widely explored to study antimicrobial responses, most studies rely on septic injury or direct injection routes that bypass the gut. A coordinated set of antimicrobial defenses acts to counteract the invading bacteria, with some variations depending on the entry route into the host. Herein, we tracked the dynamics of Enterobacteriaceae pathogens in Drosophila using a natural infection route.

Results

Most bacterial species were cleared within 48 h post-infection (hpi). We did not observe any significant mortality, indicating robust infection control. At 4 hpi, a substantial increase in reactive oxygen species (ROS) production was observed, followed by a decrease at 24 hpi and a resurgence at 48 hpi. We further show that bacteria were expelled by the fly, possibly due to TRPA1 induction, a ROS-sensing receptor. Although the infected dual oxidase (Duox) knockdown flies showed no difference in survival rate compared to the uninfected ones, they showed differential TRPA1 induction and pathogen expulsion, suggesting that ROS alone is insufficient for TRPA1 induction and infection control.

Conclusions

Our findings reveal that the host can distinguish and respond to various bacterial species in a well-synchronized, gut-localized, and pathogen-specific manner. This also illustrates the reliability of natural infection route models in unravelling and understanding the complexities of host–pathogen interaction.