IRF7 drives macrophages to kill bacteria and improves septic outcomes via autophagy
Guiming Chen, Kangxin Li, Haihua Luo, Lianxu Zhao, Yong Jiang
Guiming Chen, Kangxin Li, Haihua Luo, Lianxu Zhao, Yong Jiang
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Research Article Infectious disease Therapeutics

IRF7 drives macrophages to kill bacteria and improves septic outcomes via autophagy

Abstract

Sepsis contributes substantially to mortality rates worldwide, yet clinical trials that have focused on its underlying pathogenesis have failed to demonstrate benefits. Recently, enhancing self-defense has been regarded as an emerging therapeutic approach. Autophagy is a self-defense mechanism that protects septic mice, but its regulatory factor is still unknown. Moreover, the role of interferon regulatory factor 7 (IRF7) in sepsis has been debated. Here, we showed that Irf7 deficiency increased mortality during polymicrobial sepsis. Furthermore, IRF7 drove macrophages to protect against sepsis. Mechanistically, IRF7 is a transcription factor that upregulates the expression of autophagy-related genes responsible for autophagosome formation and autolysosome maturation, induces autophagic killing of bacteria, and ultimately reduces septic organ injury. Recombinant adeno-associated virus 9–Irf7–mediated IRF7 overexpression promoted the autophagic clearance of pathogens and improved sepsis outcomes, which may be the mechanism underlying the observed improvement in bacterial clearance. These findings provide evidence that IRF7 is the underlying regulatory factor that drives autophagy to eliminate pathogens in macrophages during sepsis. Collectively, IRF7 overexpression represents a potential host-directed therapeutic strategy for preclinical sepsis models, operating independently of antibiotic mechanisms.

Authors

Guiming Chen, Kangxin Li, Haihua Luo, Lianxu Zhao, Yong Jiang

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Figure 5

IRF7 triggers macrophages to kill bacteria via autophagy.

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IRF7 triggers macrophages to kill bacteria via autophagy. (A and B) Anal...
(A and B) Analysis of autophagosomes containing bacteria in peritoneal macrophages of WT, Irf7–/–, and Irf7 + rAAV-Irf7 mice that underwent CLP for 16 hours. rAAV9-Irf7, 1 × 1011 vg/mouse. (A) Representative fluorescent pictures. White arrow, LC3-positive vesicles (autophagosomes) packed with smaller DAPI-positive dots (bacteria). Scale bars (main image, 5 μm; inset image, 1 μm). (B) Scatterplot with bar depicts the number of bacteria surrounded with autophagosomes per cell (left panel) and the percentage of bacteria surrounded with autophagosomes of the intracellular bacteria (right panel). Error bars, ± SEM. **P < 0.01, 1-way ANOVA with Bonferroni’s correction. (C and D) Analysis of autophagosomes containing E. coli in BMDMs. IRF7 in BMDMs was silenced by Irf7 siRNA. Then, the BMDMs from the indicated groups were incubated with E. coli for 2 hours. (C) Representative fluorescence pictures. White arrow, LC3-positive vesicles packed with GFP-positive dots (E. coli). Scale bars (main image, 5 μm; inset image, 1 μm). (D) Scatterplot with bar depicts the number of bacteria surrounded with autophagosomes per cell (left panel) and percentage of bacteria surrounded with autophagosomes of the intracellular bacteria (right panel). Error bars, ± SEM. *P < 0.05, **P < 0.01, 1-way ANOVA with Bonferroni’s correction. (E) Representative TEM images of BMDMs treated with E. coli. Red arrows represent autophagosome-contained bacteria. Red arrowhead indicates the double membrane, a classic feature of autophagosome. Green arrows, no- or single-membrane-encapsulated bacteria. Green arrowhead, single membrane. Scale bar, 2 μm. (F) Intracellular killing of E. coli and S. typhimurium by BMDMs. Wortmannin (Wort) was pre-added where indicated (100 nM for 4 hours). *P < 0.05, **P < 0.01.