Previously published online as an Autophagy E-publication: http://www.landesbioscience.com/journals/autophagy/abstract.php?id=4450
KEY worDsListeria monocytogenes, bacterial invasion, autophagy, innate immunity, lysosome, macrophage.
ABBrEViATions
ABsTrACTListeria monocytogenes is an intracellular pathogen that is able to colonize the cytosol of macrophages. Here we examined the interaction of this pathogen with autophagy, a host cytosolic degradative pathway that constitutes an important component of innate immunity towards microbial invaders. L. monocytogenes infection induced activation of the autophagy system in macrophages. At 1 h post infection (p.i.), a population of intracellular bacteria (~37%) colocalized with the autophagy marker LC3. These bacteria were within vacuoles and were targeted by autophagy in an LLO-dependent manner. At later stages in infection (by 4 h p.i.), the majority of L. monocytogenes escaped into the cytosol and rapidly replicated. At these times, less than 10% of intracellular bacteria colocalized with LC3. We found that ActA expression was sufficient to prevent autophagy of bacteria in the cytosol of macrophages. Surprisingly, ActA expression was not strictly necessary, indicating that other virulence factors were involved. Accordingly, we also found a role for the bacterial phospholipases, PI-PLC and PC-PLC, in autophagy evasion, as bacteria lacking phospholipase expression were targeted by autophagy at later times in infection. Together, our results demonstrate that L. monocytogenes utilizes multiple mechanisms to avoid destruction by the autophagy system during colonization of macrophages.
SUMMARY
IL-17 cytokine production by the Th17 T-cell subset is regulated by intestinal commmensals. We show microbial colonization also regulates innate IL-17 production. A population of CD62L− γ/δ T cells, in particular a lineage expressing the IL-1 receptor 1 (IL-1R1), can be quickly activated by microbes to produce IL-17. Antibiotic-treatment and monocolonization of mice suggest specific commensals—but not metronidazole-sensitive anaerobes like Bacteroides species—are required for maintaining IL-1R1+ γ/δ T cells. Signaling through the guanine nucleotide exchange factor VAV1 but not through Toll-like receptors or antigen presentation pathways is essential for inducing IL-1R1+ γ/δ T cells. Furthermore, IL-1R1+ γ/δ T cells are a potential source of IL-17 that can be activated by IL-23 and IL-1 in both infectious and noninfectious settings in vitro and in vivo. Thus, commensals orchestrate the expansion of phenotypically distinct γδ T cells and innate immunity is a three-way interaction between host, pathogens and microbiota.
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