<i>Francisella tularensis</i>
            disrupts TLR2-MYD88-p38 signaling early during infection to delay apoptosis of macrophages and promote virulence in the host

Benziger, Peter Todd; Kopping, Erik; McLaughlin, Patrick A.; Thanassi, David G.

doi:10.1128/mbio.01136-23

Cited by 2 publications

References 67 publications

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Methylglyoxal is an antibacterial effector produced by macrophages during infection

Anaya-Sanchez,

Berry,

Espich

et al. 2024

Preprint

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Infected macrophages transition into aerobic glycolysis, a metabolic program crucial for control of bacterial infection. However, antimicrobial mechanisms supported by aerobic glycolysis are unclear. Methylglyoxal is a highly toxic aldehyde that modifies proteins and DNA and is produced as a side-product of glycolysis. Here we show that despite the toxicity of this aldehyde, infected macrophages generate high levels of methylglyoxal during aerobic glycolysis while downregulating the detoxification system. We use targeted mutations in mice to modulate methylglyoxal generation and show that reducing methylglyoxal production by the host promotes survival of Listeria monocytogenes and Mycobacterium tuberculosis, whereas increasing methylglyoxal levels improves control of bacterial infection. Furthermore, we show that bacteria that are unable to detoxify methylglyoxal are avirulent and experience up to 1000- fold greater genomic mutation frequency during infection. Taken together, these results suggest that methylglyoxal is an antimicrobial innate immune effector that defends the host against bacterial pathogens.

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Methylglyoxal is an antibacterial effector produced by macrophages during infection

Anaya-Sanchez,

Berry,

Espich

et al. 2024

Preprint

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TolC and EmrA1 contribute to Francisella novicida multidrug resistance and modulation of host cell death

Kopping,

Benziger,

Thanassi

2024

J Bacteriol

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Francisella spp. are Gram-negative, facultative intracellular pathogens. Francisella tularensis causes the human disease tularemia and is considered a biological threat agent due to its high infectivity and virulence. A central aspect of Francisella virulence is its ability to dampen host immune responses. We previously identified the outer membrane channel (OMC) protein TolC as a critical F. tularensis virulence factor required for suppression of apoptotic and proinflammatory responses during macrophage infection. TolC functions as part of multidrug efflux systems and the type I secretion pathway that exports bacterial effector proteins. In these systems, TolC forms tripartite complexes together with an inner membrane transporter and periplasmic membrane fusion protein (MFP). To advance understanding of TolC function in Francisella , we analyzed OMC and MFP homologs in Francisella novicida , a widely used model species that causes a tularemia-like disease in mice. In agreement with the previous F. tularensis studies, all three OMCs present in F. novicida contributed to multidrug resistance, but only TolC was important for suppressing macrophage cell death. In addition, we identified the EmrA1 MFP as important for resisting antimicrobial compounds and dampening host cell death. In contrast to results obtained with F. tularensis , the cell death triggered during infection with the F. novicida tolC and emrA1 mutants was dominated by pyroptosis rather than apoptosis. These data expand our understanding of TolC function in Francisella and underscore both conserved and differential aspects of F. novicida and F. tularensis . IMPORTANCE Francisella tularensis is a Gram-negative intracellular bacterial pathogen and causative agent of tularemia. We previously identified the outer membrane channel protein TolC as contributing to antimicrobial resistance and subversion of host responses by F. tularensis . To advance understanding of TolC function in Francisella and to identify components that might work together with TolC, we took advantage of a transposon mutant library in F. novicida , a model species that causes a tularemia-like disease in mice. Our findings identify TolC and the membrane fusion protein EmrA1 as important for both antimicrobial resistance and suppression of macrophage cell death. This study also revealed differences in cell death pathways triggered by F. novicida versus F. tularensis infection that may relate to differences in virulence.

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Francisella tularensis disrupts TLR2-MYD88-p38 signaling early during infection to delay apoptosis of macrophages and promote virulence in the host

Cited by 2 publications

References 67 publications

Methylglyoxal is an antibacterial effector produced by macrophages during infection

Methylglyoxal is an antibacterial effector produced by macrophages during infection

TolC and EmrA1 contribute to Francisella novicida multidrug resistance and modulation of host cell death

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