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RIG-I Signaling Is Critical for Efficient Polyfunctional T Cell Responses during Influenza Virus Infection

PLoS Pathogens (2016) 12(7)
DOI: 10.1371/journal.ppat.1005754
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Abstract

Retinoic acid inducible gene-I (RIG-I) is an innate RNA sensor that recognizes the influenza A virus (IAV) RNA genome and activates antiviral host responses. Here, we demonstrate that RIG-I signaling plays a crucial role in restricting IAV tropism and regulating host immune responses. Mice deficient in the RIG-I-MAVS pathway show defects in migratory dendritic cell (DC) activation, viral antigen presentation, and priming of CD8+ and CD4+ T cell responses during IAV infection. These defects result in decreased frequency of polyfunctional effector T cells and lowered protection against heterologous IAV challenge. In addition, our data show that RIG-I activation is essential for protecting epithelial cells and hematopoietic cells from IAV infection. These diverse effects of RIG-I signaling are likely imparted by the actions of type I interferon (IFN), as addition of exogenous type I IFN is sufficient to overcome the defects in antigen presentation by RIG-I deficient BMDC. Moreover, the in vivo T cell defects in RIG-I deficient mice can be overcome by the activation of MDA5 –MAVS via poly I:C treatment. Taken together, these findings demonstrate that RIG-I signaling through MAVS is critical for determining the quality of polyfunctional T cell responses against IAV and for providing protection against subsequent infection from heterologous or novel pandemic IAV strains.

Figures

  • Fig 1. RIG-I deficient mice demonstrate decreased protection against heterologous IAV challenge. (A-B) RIG-I+/+ and RIG-I-/- mice were infected with 50 PFU of PR8 and monitored for body weight and survival for 14 days. (A) Percentage of body weight loss after PR8 infection (n = 12 in each group). (B) Survival curve comparing RIG-I+/+ and RIG-I-/- mice (n = 12 in each group). (C) Viral titers in the lungs. Viral loads in the lung homogenates were measured by plaque assay. The limit of detection for plaque assay was 10 PFU/ml. (D-F) RIG-I+/+ (N = 14) and RIG-I-/- mice (N = 12) were infected with 100 PFU of X-31 and body weight was monitored for 14days. On day 28 post infection, mice were challenged with lethal dose of PR8 (106 PFU) and body weight loss and survival were monitored (D) Percentage of body weight loss after primary infection with X-31. (E) Percentage of body weight loss and (F) Survival curve comparing RIG-I+/+ and RIG-I-/- mice after challenge with PR8. All the experiments were independently repeated twice. * Denotes statistical significance at p<0.05. ϕ denotes statistical significance at p<0.05 in Fisher’s exact test, *** denotes statistical significance at p<0.001 and **** denotes statistical significance at p<0.001
  • Fig 2. RIG-I deficient mice show impaired T cell response against IAV infection. T cells were isolated from either RIG-I+/+ or RIG-I-/- mice on days 7 and 9 post-infection and co-cultured with infected BMDC isolated from RIG-I+/+ mice. The frequencies of IFNγ, TNFα and Granzyme B producing CD8+ T cells were analyzed by flow cytometry. (A) Bar graphs showing the frequencies of single or polyfunctional CD8+T cells on days 7 (upper panel) or day 9 (lower panel) after PR8 infection. (B) Absolute number of IFNγ+ CD8+T cells in lungs on day 7 (upper panel) or day 9 (lower panel) post infection with PR8. (C) Comparison of frequencies of IFNγ, TNFα and GrB producing CD8+ T cells between RIG-I+/+ and RIG-I-/littermates. The results shown are a representative of three independent experiments with similar results (n = 8–10 mice/group). The values are expressed as mean ± SEM. *Denotes statistical significance at p<0.05., *** denotes statistical significance at p<0.001 and **** denotes statistical significance at p<0.0001.
  • Fig 3. RIG-I deficient BMDC are inefficient in antigen presentation to T cells. T cells were isolated from PR8 infected RIG-I+/+ and RIG-I-/- mice and co-cultured with BMDC generated from RIG-I+/+ and RIG-I-/- mice or vice versa. The levels of IFNγ production in CD8+ T cells were determined by flow cytometry (n = 8/group). (A) Representative dot plots showing IFNγ production. (B) Quantification of panel A. (C) Histograms showing the expression of costimulatory molecules CD86 and MHC-II on RIG-I+/+ or RIG-I-/- mice. BMDC were either mock infected (clear) or with IAV at a MOI of 0.5 (shaded). (D) Quantification of the mean fluorescent intensity (MFI) of CD86 upregulation on PR8 infected BMDC with relative to naïve control. (E) Quantification of MFI of MHC II upregulation on PR8 infected BMDCwith relative to naïve control. (F-G) Susceptibility of RIG-I+/+ or RIG-I-/- BMDC to IAV infection. BMDC were infected overnight with an MOI of 0.5 and the infected population was identified by staining for viral hemagglutinin (HA) protein. (F) Representative dot plots showing HA+ BMDC. (G) Quantification of the frequencies of HA+ BMDC. (H) Comparison of MFI of CD86 upregulation on BMDC infected with different viruses. The upregulation of CD86 expression in infected BMDC was calculated by subtracting the MFI with MFI of naïve state. The data shown in panels A-B is from a representative experiment performed with n = 8 mice/group. The experiments were repeated twice. Data shown in panels C-H is a representative of 2 independent experiments done in triplicates. The values are expressed as mean ± SEM. * Denotes statistical significance at p<0.05 and ** denotes statistical significance at p<0.01.
  • Fig 4. Migratory CD103+ DC in the MLN show decreased expression of CD86 and CD40.RIG-I+/+ and RIG-I-/- mice were infected with 50 PFU of PR8 and CD86 expression on migratory DC present in the mediastinal lymph node and lungs were analyzed by flow cytometry. (A-D) Quantification of MFI of CD86 and CD40 upregulation on migratory DC in PR8 infected mice MLN relative to naïve controls. (A, B) CD103+ DC
  • Fig 5. MAVS deficient mice display decreased polyclonal CD8+ T cell responses and increased viral loads in the lungs.WT or MAVS-/- mice were infected with 50 PFU of PR8. On day 7 and 9 pi, T cell responses and viral titers in the
  • Fig 6. MAVS deficient mice show impaired CD8 and CD4 T cell priming.WT or MAVS-/- mice were adoptively transferred with 2x106 CFSE-labeled OTI CD8+ T cells (A-C) or 3x106 CFSE-labeled OTII CD4+ T cells (D), and their proliferation were determined on day 3 or 4 post infection with 100PFU PR8. Left-A representative plot showing proliferation of CFSE-labeled T cells. Right-Proliferation index of T cells. (A-C) Proliferation of OT-I cells on day 3 post infection. (A) PR8 alone, (B) PR8 with 60μg of LPS free ovalbumin, and (C) PR8-OTI. (D) WT or MAVS-/- mice were adoptively transferred with 3x106 CFSE-labeled OTII CD4+ T cells infected with PR8-OTII in the MLN, on day 4 post-infection. The values are expressed as mean ± SEM. Data presented here is an average of two independent experiments with n = 9 mice/group. * Denotes statistical significance at p<0.05 and ** denotes statistical significance at p<0.01.
  • Fig 7. Poly I/C treatments increases T cell response in RIG-I deficient mice.RIG-I-/- and RIG-I+/+ littermates mice were infected with PR8. At 24h, some of the RIG-I-/- mice were intranasally instilled with 20μg of poly I:C. T cell responses were analyzed on day 9 post infection (A, B) Quantification of the frequencies of IFNγ or IFNγ, GrB and TNFα secreting CD8+ T cells. (D,E) Quantification of the frequencies of cytokine secreting CD4+ T cells. (C, F) Absolute number of IFNγ+ CD8+ and CD4+ T cells in lungs. Data shown here is a representative of two independent experiments performed with n = 7–8 mice/group. The values are expressed as mean ± SEM. * Denotes statistical significance at p<0.05 and ** denotes statistical significance at p<0.01
  • Fig 8. TLR7 deficient mice show impaired CD4+ T cell response.WT or TLR7-/- mice were infected with 50PFU of PR8 and CD86 expression on migratory DC present in the mediastinal lymph node were analyzed by flow cytometry on day 2 and 4 post infection. (A) Representative histograms showing upregulation of CD86 in CD103+ DC (upper panel) and CD11b+ DC (lower panel) in MLN on day 4 post infection. (B) Quantification of MFI of CD86 upregulation on lymph node DC in infected mice with relative to naïve control. (C) Bar graphs showing the frequencies of single or polyfunctional CD4+T cells on day 7 post infection with PR8. (D) Absolute number of IFNγ+ CD4+T cells in lungs on day 7 post infection with PR8. (E-F) Quantification

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CITATION STYLE

APA

Kandasamy, M., Suryawanshi, A., Tundup, S., Perez, J. T., Schmolke, M., Manicassamy, S., & Manicassamy, B. (2016). RIG-I Signaling Is Critical for Efficient Polyfunctional T Cell Responses during Influenza Virus Infection. PLoS Pathogens, 12(7). https://doi.org/10.1371/journal.ppat.1005754

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