The impact of robust memory T cell responses against respiratory syncytial virus

Knudson, Cory James

01 May 2015

Respiratory syncytial virus (RSV) is the most common cause of bronchiolitis-induced hospitalization in young children. A natural RSV infection fails to elicit long-lasting immunity, further increasing the need for an effective vaccine. Despite the significant healthcare burden, there is no licensed RSV vaccine currently available. While most RSV vaccine strategies focus on the induction of humoral immunity, high antibody titers do not prevent RSV infection. It remains unclear if protective immunity can be achieved through robust cellular immunity. Previous work has indicated that a relatively low frequency of virus-specific CD8 T cells is induced following an RSV infection in human infants. In addition, RSV-specific memory CD8 T cells diminish to almost undetectable frequencies in the blood of the elderly. The lack of long-lasting immunity against RSV may be explained by an absence or low frequency of memory CD8 T cells within the lung following infection. However, I determined that the majority of effector CD8 T cells reside within the lung tissue following infection with either RSV or influenza A virus (IAV), both of which replicate primarily in the airways. In addition, approximately 70% of antigen-experienced memory CD8 T cells persist in the lung tissue at day 30 following RSV infection. In contrast, the majority of CD8 T cells remain in the pulmonary vasculature following intranasal infection with either of the systemically replicating viruses lymphocytic choriomeningitis virus or vaccinia virus. Therefore, the tissue tropism of a virus will determine if CD8 T cells preferentially accumulate in the lung tissue following infection of the respiratory tract. An experimental formalin-inactivated RSV (FI-RSV) vaccine caused enhanced respiratory disease in vaccinated children following a natural RSV infection. Incomplete knowledge of the underlying immunological mechanisms that were responsible for mediating the enhanced disease has greatly hampered vaccine development. Previous studies have indicated that eosinophils, non-neutralizing antibodies, and CD4 T cells may be required to elicit FI-RSV vaccine-enhanced disease. I determined that distinct CD4 T cell subsets mediate individual disease parameters. The Th2-biased immune response, but not eosinophils specifically, was responsible for induction of airway hyperresponsiveness and mucus hypersecretion. On the other hand, the Th1-associated pro-inflammatory cytokine TNF-α was required to mediate baseline pulmonary dysfunction and weight loss. Lastly, while depletion of CD4 T cells ameliorated all disease parameters evaluated, the antibody titers remained unaltered in depleted mice. Thus, antibodies induced by FI-RSV immunization were not required for vaccine-enhanced disease. My data demonstrate that discrete disease manifestations associated with FI-RSV immunization are orchestrated by distinct subsets of CD4 T cells. The CD8 T cell response is believed to contribute to both pathogen clearance and immunopathology following an acute RSV infection. However, it is unclear if robust memory CD8 T cell responses will protect against an RSV infection. I determined that induction of a high-magnitude, epitope-specific memory CD8 T cell pool mediated increased viral clearance following RSV challenge. However, mice with robust secondary CD8 T cell responses exhibit increased airway dysfunction, weight loss, and mortality as compared to mock-immunized mice undergoing an acute RSV infection. The enhanced disease severity was unique to the context of an RSV infection as similarly immunized mice were protected from chge with a lethal dose of a recombinant IAV engineered to express an RSV-derived epitope. In addition, the increased morbidity and mortality was associated with an elevated amount of both IFN-γ and TNF-α in the serum of immunized mice. Neutralization of either IFN-γ or TNF-α led to a significant reduction in disease severity and survival of all mice. These results demonstrate that robust memory CD8 T cell responses enhance viral clearance, but also lead to severe pulmonary immunopathology following RSV infection. Overall, I establish that the majority of effector CD8 T cells are localized within the lung tissue following a respiratory infection, and determine that either memory CD4 or CD8 T cell responses elicits severe immunopathology following a RSV infection.

publicabstract

Intravascular staining

Lung

Respiratory syncytial virus

T cell

Vaccine-enhanced disease

Immunology of Infectious Disease