TLR2-mediated activation of innate responses in the upper airways confers antiviral protection of the lungs
Georgia Deliyannis, Chinn Yi Wong, Hayley A. McQuilten, Annabell Bachem, Michele Clarke, Xiaoxiao Jia, Kylie Horrocks, Weiguang Zeng, Jason Girkin, Nichollas E. Scott, Sarah L. Londrigan, Patrick C. Reading, Nathan W. Bartlett, Katherine Kedzierska, Lorena E. Brown, Francesca Mercuri, Christophe Demaison, David C. Jackson, Brendon Y. Chua
Georgia Deliyannis, Chinn Yi Wong, Hayley A. McQuilten, Annabell Bachem, Michele Clarke, Xiaoxiao Jia, Kylie Horrocks, Weiguang Zeng, Jason Girkin, Nichollas E. Scott, Sarah L. Londrigan, Patrick C. Reading, Nathan W. Bartlett, Katherine Kedzierska, Lorena E. Brown, Francesca Mercuri, Christophe Demaison, David C. Jackson, Brendon Y. Chua
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Research Article Infectious disease Therapeutics

TLR2-mediated activation of innate responses in the upper airways confers antiviral protection of the lungs

Abstract

The impact of respiratory virus infections on global health is felt not just during a pandemic, but endemic seasonal infections pose an equal and ongoing risk of severe disease. Moreover, vaccines and antiviral drugs are not always effective or available for many respiratory viruses. We investigated how induction of effective and appropriate antigen-independent innate immunity in the upper airways can prevent the spread of respiratory virus infection to the vulnerable lower airways. Activation of TLR2, when restricted to the nasal turbinates, resulted in prompt induction of innate immune–driven antiviral responses through action of cytokines, chemokines, and cellular activity in the upper but not the lower airways. We have defined how nasal epithelial cells and recruitment of macrophages work in concert and play pivotal roles to limit progression of influenza virus to the lungs and sustain protection for up to 7 days. These results reveal underlying mechanisms of how control of viral infection in the upper airways can occur and support the implementation of strategies that can activate TLR2 in nasal passages to provide rapid protection, especially for at-risk populations, against severe respiratory infection when vaccines and antiviral drugs are not always effective or available.

Authors

Georgia Deliyannis, Chinn Yi Wong, Hayley A. McQuilten, Annabell Bachem, Michele Clarke, Xiaoxiao Jia, Kylie Horrocks, Weiguang Zeng, Jason Girkin, Nichollas E. Scott, Sarah L. Londrigan, Patrick C. Reading, Nathan W. Bartlett, Katherine Kedzierska, Lorena E. Brown, Francesca Mercuri, Christophe Demaison, David C. Jackson, Brendon Y. Chua

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Figure 2

Inhibition of viral replication in the respiratory tract after administration of INNA-X to the URT.

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Inhibition of viral replication in the respiratory tract after administr...
(A) Mice (n = 5 or 7/group) were inoculated with 5 nmol of INNA-X prior to challenge with 500 PFU of Udorn IAV. Efficacy of treatment (B) 1 day or (C) 7 days prior to viral challenge was determined by measuring lung viral titers 5 days after infection. The percentage reduction in viral load in each mouse is shown relative to the average viral titer in similarly challenged diluent-treated mice. Results (B and C) are pooled from 2 separate experiments. (D) Mice were inoculated with 1 nmol of INNA-X and challenged 1 day later. Viral titers in (E) nasal turbinates or (F) lungs (n = 7/group) were measured at 1 or 5 days, respectively, after infection. (G) Therapeutic efficacy of treatment with INNA-X was examined by inoculating mice with INNA-X 8 or 24 hours after IAV challenge (postexposure) in comparison to treatment 1 day prior to challenge (preexposure). (H) Reduction in lung viral titers is relative to similarly infected mice treated with diluent at each time point. Statistical analysis was performed using a (B, E, and F) Mann-Whitney or (C) Welch t test. *P < 0.05, **P < 0.01.