A comprehensive understanding of the mechanisms associated with the generation and modulation of immunological T cell memory will lead to a better understanding of how the immune system controls viral infections but also causes immune-mediated pathology. Heterologous immunity occurring as a consequence of T cell cross-reactivity (XR) between unrelated pathogens, such as influenza A (lAV), vaccinia virus, arenaviruses, and murine cytomegalovirus, has been shown by us with animal models to contribute to reduced (beneficial) or enhanced viral loads, and remarkably altered immunopathology (detrimental). We have demonstrated heterologous immunity in human infections with Epstein-Barr virus (EBV), while other investigators have demonstrated its role in influenza, dengue, and hepatitis C viruses. We have identified networks of cross-reactive T cells, which interact with EBV-BMLFI280 in HLA-A2+ patients with acute infectious mononucleosis (AIM) and directly correlated the severity of AIM with the frequency of memory influenza A Miss-specific CD8 T cells cross-reactive with EBV-epitopes. The cross-reactive repertoire appears broader than the non-cross-reactive repertoire to either antigen alone. We have evidence in five EBV-seronegative healthy donors that a unique cross-reactivity between lAV Ml-specific responses and EBV epitopes maybe protective. The overall objective of this proposal is to determine how T cell cross- reactivity impacts T cell selection and function, and changes disease outcome, to the worse or better, as the host is exposed to subsequent acute or persistent infections such as EBV. Insights on these issues are necessary for the intelligent design of modern vaccines that are effective and without unwanted side effects and to develop therapeutic interventions when virus infection induces immunopathology. We are one of the few groups studying heterologous immunity in viral systems and propose to clarify these issues in the following aims: 1) examine the mechanisms which control the balance between protective immunity versus pathology in heterologous immunity during EBV infection;2) examine how XR TcR repertoires influence heterologous protective immunity and immunopathology;3) test the hypothesis that elderly individuals have increased crossreactive responses due to heterologous infections.
These studies address public health-relevant questions such as can one design successful T cell vaccines that will give protection without pathology and under what circumstances do viruses induce severe pathology and are there ways to circumvent it? These studies open new avenues for the development of individualized therapies and vaccines if cross-reactive epitopes are identified or broad spectrum therapy in their absence.
|Gil, Anna; Kenney, Laurie L; Mishra, Rabinarayan et al. (2015) Vaccination and heterologous immunity: educating the immune system. Trans R Soc Trop Med Hyg 109:62-9|
|Gil, Anna; Yassai, Maryam B; Naumov, Yuri N et al. (2015) Narrowing of human influenza A virus-specific T cell receptor Î± and Î² repertoires with increasing age. J Virol 89:4102-16|
|Greenough, Thomas C; Straubhaar, Juerg R; Kamga, Larisa et al. (2015) A Gene Expression Signature That Correlates with CD8+ T Cell Expansion in Acute EBV Infection. J Immunol 195:4185-97|
|Renzette, Nicholas; Somasundaran, Mohan; Brewster, Frank et al. (2014) Epstein-Barr virus latent membrane protein 1 genetic variability in peripheral blood B cells and oropharyngeal fluids. J Virol 88:3744-55|
|Chen, Alex T; Cornberg, Markus; Gras, Stephanie et al. (2012) Loss of anti-viral immunity by infection with a virus encoding a cross-reactive pathogenic epitope. PLoS Pathog 8:e1002633|
|Tracy, Sean I; Kakalacheva, Kristina; Lunemann, Jan D et al. (2012) Persistence of Epstein-Barr virus in self-reactive memory B cells. J Virol 86:12330-40|
|O'Bryan, Joel M; Potts, James A; Bonkovsky, Herbert L et al. (2011) Extended interferon-alpha therapy accelerates telomere length loss in human peripheral blood T lymphocytes. PLoS One 6:e20922|
|Selin, Liisa K; Wlodarczyk, Myriam F; Kraft, Anke R et al. (2011) Heterologous immunity: immunopathology, autoimmunity and protection during viral infections. Autoimmunity 44:328-47|
|Welsh, Raymond M; Che, Jenny W; Brehm, Michael A et al. (2010) Heterologous immunity between viruses. Immunol Rev 235:244-66|
|Greenough, Thomas C; Campellone, Shalyn C; Brody, Robin et al. (2010) Programmed Death-1 expression on Epstein Barr virus specific CD8+ T cells varies by stage of infection, epitope specificity, and T-cell receptor usage. PLoS One 5:e12926|
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