The RNA receptor RIG-I binding synthetic oligodeoxynucleotide promotes pneumonia survival
Yongxing Wang, Vikram V. Kulkarni, Jezreel PantaleónGarcía, Michael K. Longmire, Mathilde Lethier, Stephen Cusack, Scott E. Evans
Yongxing Wang, Vikram V. Kulkarni, Jezreel PantaleónGarcía, Michael K. Longmire, Mathilde Lethier, Stephen Cusack, Scott E. Evans
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Research Article Cell biology Immunology

The RNA receptor RIG-I binding synthetic oligodeoxynucleotide promotes pneumonia survival

Abstract

Pneumonia is a worldwide threat to public health, demanding novel preventative and therapeutic strategies. The lung epithelium is a critical environmental interface that functions as a physical barrier to pathogen invasion while also actively sensing and responding to pathogens. We have reported that stimulating lung epithelial cells with a combination therapeutic consisting of a diacylated lipopeptide and a synthetic CpG oligodeoxynucleotide (ODN) induces synergistic pneumonia protection against a wide range of pathogens. We report here that mice deficient in TLR9, the previously described receptor for ODN, still displayed partial ODN-induced protection. This prompted us to seek an alternate ODN receptor, and we discovered by mass spectroscopy that the RNA sensor RIG-I could also bind DNA-like ODN. ODN binding by RIG-I resulted in MAVS-dependent pneumonia-protective signaling events. While RIG-I is essential to native defenses against viral infections, we report that therapeutic RIG-I activation with ODN promoted pathogen killing and host survival following both viral and bacterial challenges. These data indicate that maximal ODN-induced pneumonia protection requires activation of both the TLR9/MyD88 and RIG-I/MAVS signaling pathways. These findings not only identify what we believe to be a novel pattern recognition receptor for DNA-like molecules, but reveal a potential therapeutic strategy to protect susceptible individuals against lethal pneumonias during periods of peak vulnerability.

Authors

Yongxing Wang, Vikram V. Kulkarni, Jezreel PantaleónGarcía, Michael K. Longmire, Mathilde Lethier, Stephen Cusack, Scott E. Evans

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Figure 4

RIG-I is required for Pam2ODN-inducible lung epithelial resistance in vitro.

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RIG-I is required for Pam2ODN-inducible lung epithelial resistance in vi...
(A) Efficacy of RIG-I shRNA knockdown. HBEC3-KT cells were transduced with the indicated shRNA and then immunoblotted for RIG-I. Stable knockdown no. 4 (KD4) was used in subsequent pathogen killing assays. (BD) Viral burden of RIG-I shRNA–knockdown HEBC3-KT cells was assessed 24 hours after infection with influenza A virus by (B) qPCR of viral nucleocapsid NP gene expression or (C and D) viral M2 protein immunofluorescence staining. Original magnification, ×10. (E) Bacterial burden 6 hours after P. aeruginosa challenge in RIG-I–knockdown cells was measured by counting CFUs. (F) RIG-I shRNA–knockdown HBEC3-KT cells were transduced with a tetracycline-inducible human RIGI cDNA construct containing silent mutations in the shRNA targeting sequence. Efficiency of doxycycline-induced RIG-I rescue was determined by immunoblotting. (G) Influenza viral burden in doxycycline-treated scrambled or RIG-I shRNA–knockdown or RIG-I–rescued cells with or without Pam2ODN treatment by NP qPCR. P values indicate comparison by 1-way ANOVA (Holm-Šidák method). Tet-On RIGI, tetracycline-inducible RIGI construct; Scr, scrambled shRNA.