A chronic Acinetobacter baumannii pneumonia model to study long-term virulence factors, antibiotic treatments, and polymicrobial infections

Jackson-Litteken, Clay D.; Venanzio, Gisela Di; Janet-Maitre, Manon; Castro, Ítalo A.; Mackel, Joseph J.; Wilson, Leslie D.; Rosen, David A.; López, Carolina B.; Feldman, Mario F.

A chronic Acinetobacter baumannii pneumonia model to study long-term virulence factors, antibiotic treatments, and polymicrobial infections

Clay D. Jackson-Litteken, Gisela Di Venanzio, Manon Janet-Maitre, Ítalo A. Castro, Joseph J. Mackel, Leslie D. Wilson, David A. Rosen, Carolina B. López and Mario F. Feldman ()
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Clay D. Jackson-Litteken: Washington University School of Medicine
Gisela Di Venanzio: Washington University School of Medicine
Manon Janet-Maitre: Washington University School of Medicine
Ítalo A. Castro: Washington University School of Medicine
Joseph J. Mackel: Washington University School of Medicine
Leslie D. Wilson: Washington University School of Medicine
David A. Rosen: Washington University School of Medicine
Carolina B. López: Washington University School of Medicine
Mario F. Feldman: Washington University School of Medicine

Nature Communications, 2025, vol. 16, issue 1, 1-14

Abstract: Abstract Acinetobacter baumannii causes prolonged infections that disproportionately affect immunocompromised populations. Our understanding of A. baumannii respiratory pathogenesis relies on an acute murine infection model with limited clinical relevance that employs an unnaturally high number of bacteria and requires assessment of bacterial load at 24-36 h post-infection. Here, we demonstrate that low intranasal inoculums in tlr4 mutant mice allows for infections lasting at least 3 weeks. Using this “chronic infection model” we determine the adhesin InvL is a virulence factor required during later stages of infection, despite being dispensable in the early phase. We also demonstrate that the chronic model enables distinction between antibiotics that, although initially reduce bacterial burden, either lead to clearance or result in the formation of potential bacterial persisters. To illustrate how our model can be applied to study polymicrobial infections, we inoculate mice with an active A. baumannii infection with Staphylococcus aureus or Klebsiella pneumoniae. We find that S. aureus exacerbates infection, while K. pneumoniae enhances A. baumannii clearance. In all, the chronic model overcomes some limitations of the acute pulmonary model, expanding our capabilities to study A. baumannii pathogenesis and lays the groundwork for the development of similar models for other opportunistic pathogens.

Date: 2025
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DOI: 10.1038/s41467-025-62655-4

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