. The bacterium Mycobacterium tuberculosis (Mtb) causes more human deaths than any other pathogen. Mtb elicits strong CD8 T cell responses in people and CD8 T cells make an important contribution to protection against virulent Mtb in animal models. Human CD8 T cells kill intracellular Mtb, CD8 depletion in non-human primates leads to severe disseminated TB, and recombinant BCG designed to elicit better CD8 T cell responses is effective in mice and clinical trials have started. CD8 T cells also appear to enforce latency!in both mice and in people. Despite the vigorous immune response, Mtb evades clearance by adapting to its host, an idea originally based on its ability to survive in the phagosome and avoid antibody immunity. We are now learning that Mtb may also avoid T cell immunity. An unexpected finding from the genomic analysis of Mtb is that the genes encoding T cell epitopes are hyper-conserved, which has been interpreted to mean that the host T cell response benefits the survival of Mtb, possibly by creating sufficient inflammation to promote transmission. How does one reconcile T cells as an instrument of TB control, with Mtb benefiting from T cell responses? Our recent data suggests that not all T cell antigens are alike. We hypothesize that TB10 is a decoy antigen. We use the term ?decoy? to describe its ability to elicit a strong CD8 T cell response that poorly recognizes Mtb-infected macrophages. In the context of immune evasion, decoy antigens induce T cells that provoke inflammation, but as they fail to recognize infected cells, do not control Mtb infection. Their immunodominance impairs T cell responses to other antigens, which might be more efficiently presented by Mtb-infected cells and could be targets of protective immunity.
Aim 1 will test the ?decoy? hypothesis, based on the idea that if a decoy antigen is removed, the residual T cell response will be more effective. We will also will determine the cellular and molecular mechanisms for how Mtb avoids sampling of it antigens by MHC I. Although Mtb evades CD8 T cell immunity, ultimately, CD8 promote control of Mtb. The hypothesis of Aim 2 is that a ?protective? function of CD4 T cells is to help CD8 T cells differentiate and express functions that mediate protection against TB. In the absence of CD4 help, we predict that CD8s become dysfunctional and confer suboptimal protection. Our new preliminary data shows that ?helped? CD8 T cells expand, acquire effector function, and mediate host protection better than ?helpless? CD8 T cells. Here we expect to establish that helped CD8s mediate greater protection than helpless CD8s during primary and secondary (i.e., memory) responses against Mtb infection. We will define the molecular differences between helped and helpless CD8 T cells that mediate better protection; and identify the CD4 T cell factors that mediate help during TB. My lab has developed an innovative and productive research program that seeks to understand how CD8 T cells restrict bacterial growth and how Mtb defeats CD8 immunity. Our goal is to elicit protective CD8s and recruit them into beneficial responses as part of an effort to guide vaccine development. !

Public Health Relevance

. Pulmonary tuberculosis, the disease caused by Mycobacterium tuberculosis, is a threat to global health. Infection is usually asymptomatic but disease develops when the immune system is no longer able to contain the infection. This research proposal seeks understand how T cells mediate protection to tuberculosis with the goal of informing vaccine development to prevent tuberculosis.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
5R01AI106725-06
Application #
9694143
Study Section
Host Interactions with Bacterial Pathogens Study Section (HIBP)
Program Officer
Eichelberg, Katrin
Project Start
2013-08-02
Project End
2023-04-30
Budget Start
2019-05-01
Budget End
2020-04-30
Support Year
6
Fiscal Year
2019
Total Cost
Indirect Cost
Name
University of Massachusetts Medical School Worcester
Department
Microbiology/Immun/Virology
Type
Schools of Medicine
DUNS #
603847393
City
Worcester
State
MA
Country
United States
Zip Code
01655
Rothchild, Alissa C; Stowell, Britni; Goyal, Girija et al. (2017) Role of Granulocyte-Macrophage Colony-Stimulating Factor Production by T Cells during Mycobacterium tuberculosis Infection. MBio 8:
Carpenter, Stephen M; Nunes-Alves, Cláudio; Booty, Matthew G et al. (2016) A Higher Activation Threshold of Memory CD8+ T Cells Has a Fitness Cost That Is Modified by TCR Affinity during Tuberculosis. PLoS Pathog 12:e1005380
Smith, Clare M; Proulx, Megan K; Olive, Andrew J et al. (2016) Tuberculosis Susceptibility and Vaccine Protection Are Independently Controlled by Host Genotype. MBio 7:
Booty, Matthew G; Nunes-Alves, Cláudio; Carpenter, Stephen M et al. (2016) Multiple Inflammatory Cytokines Converge To Regulate CD8+ T Cell Expansion and Function during Tuberculosis. J Immunol 196:1822-31
Booty, Matthew G; Barreira-Silva, Palmira; Carpenter, Stephen M et al. (2016) IL-21 signaling is essential for optimal host resistance against Mycobacterium tuberculosis infection. Sci Rep 6:36720
Nunes-Alves, Cláudio; Booty, Matthew G; Carpenter, Stephen M et al. (2015) Human and Murine Clonal CD8+ T Cell Expansions Arise during Tuberculosis Because of TCR Selection. PLoS Pathog 11:e1004849
Martinez, Nuria; Vallerskog, Therese; West, Kim et al. (2014) Chromatin decondensation and T cell hyperresponsiveness in diabetes-associated hyperglycemia. J Immunol 193:4457-68
Behar, Samuel M; Carpenter, Stephen M; Booty, Matthew G et al. (2014) Orchestration of pulmonary T cell immunity during Mycobacterium tuberculosis infection: immunity interruptus. Semin Immunol 26:559-77
Rothchild, Alissa C; Jayaraman, Pushpa; Nunes-Alves, Cláudio et al. (2014) iNKT cell production of GM-CSF controls Mycobacterium tuberculosis. PLoS Pathog 10:e1003805
Nunes-Alves, Cláudio; Booty, Matthew G; Carpenter, Stephen M et al. (2014) In search of a new paradigm for protective immunity to TB. Nat Rev Microbiol 12:289-99

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