Immunological memory refers to the dramatic and effective response to previously encountered antigens (Ag) that is largely regulated by T cells. Upon challenge, memory T cells localize in sites of Ag exposure and develop in effector cells that produce cytokines and chemokines that regulate the memory response. Identifying parameters that control memory T cell entry into tissue is crucial for understanding regulation of memory and alterations in T cell migration during disease processes that will be essential for strategies to potential memory in the design of vaccines and to dampen memory in allergic and autoimmune responses. Lymphocyte entry into tissue from blood is orchestrated by multiple adhesion receptors whose expression is modulated by cytokines and whose avidity is regulated by chemokines which exert selective chemoattractant effects on subsets of cells. However, mechanisms that initiate and regulate recruitment of memory T cells to sites of antigen exposure have not yet been identified. We proposed that memory T cells become activated by Ag presented by APC in tissues through which they recirculate, and then acquire the capacity to enter other sites of Ag exposure. Upon reencounter with Ag, activated memory CD4 cells produce mediators which regulate cellular recruitment. The proposed studies will investigate 4 key parameters in regulation of memory T cell migration: Ag, adhesion molecules, cytokines, and chemokines. We will use a defined adoptive transfer model to study Ag-induced recruitment of memory CD4 cells into lymphoid tissues but will also extend our studies to CD8 memory cells, in collaboration with Project 2, since there may be fundamental differences in their regulation. We will use TCR transgenic mice to generate defined memory populations and analyze the kinetics of their activation, division, and death with different conditions of immunization and determine if the recruitment response depends upon inflammation. To define contributions of adhesion receptors, cytokines, and chemokines, we will use blocking reagents at various times with respect to immunization to distinguish roles in the initiation versus progression of the response. We will also take advantage of cytokine and adhesion molecule knock out mice. In collaboration with Project 1 and 2, we have the potential to link these factors that may also affect the induction, expansion, and survival of memory cells with their subsequent ability to respond to Ag upon challenge. By using different CD4 and CD8 transgenics as sources of memory cells which can be identified by Class II and Class I tetramers, respectively, we can test predictions about normal memory responses of heterogeneous populations. These studies address fundamental questions regarding the mechanisms by which memory T cells mediate immune surveillance and provide long lasting immunity.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Program Projects (P01)
Project #
5P01AI046530-03
Application #
6491035
Study Section
Special Emphasis Panel (ZAI1)
Project Start
2001-09-01
Project End
2002-08-31
Budget Start
Budget End
Support Year
3
Fiscal Year
2001
Total Cost
Indirect Cost
Name
Trudeau Institute, Inc.
Department
Type
DUNS #
City
Saranac Lake
State
NY
Country
United States
Zip Code
12983
Tinoco, Roberto; Carrette, Florent; Henriquez, Monique L et al. (2018) Fucosyltransferase Induction during Influenza Virus Infection Is Required for the Generation of Functional Memory CD4+ T Cells. J Immunol 200:2690-2702
Strutt, T M; Dhume, K; Finn, C M et al. (2018) IL-15 supports the generation of protective lung-resident memory CD4 T cells. Mucosal Immunol 11:668-680
Devarajan, Priyadharshini; Jones, Michael C; Kugler-Umana, Olivia et al. (2018) Pathogen Recognition by CD4 Effectors Drives Key Effector and Most Memory Cell Generation Against Respiratory Virus. Front Immunol 9:596
Marshall, Nikki B; Vong, Allen M; Devarajan, Priyadharshini et al. (2017) NKG2C/E Marks the Unique Cytotoxic CD4 T Cell Subset, ThCTL, Generated by Influenza Infection. J Immunol 198:1142-1155
Swain, Susan L; Kugler-Umana, Olivia; Kuang, Yi et al. (2017) The properties of the unique age-associated B cell subset reveal a shift in strategy of immune response with age. Cell Immunol 321:52-60
Strutt, Tara M; McKinstry, Karl Kai; Kuang, Yi et al. (2016) Direct IL-6 Signals Maximize Protective Secondary CD4 T Cell Responses against Influenza. J Immunol 197:3260-3270
Tinoco, Roberto; Carrette, Florent; Barraza, Monique L et al. (2016) PSGL-1 Is an Immune Checkpoint Regulator that Promotes T Cell Exhaustion. Immunity 44:1190-203
Bautista, Bianca L; Devarajan, Priyadharshini; McKinstry, K Kai et al. (2016) Short-Lived Antigen Recognition but Not Viral Infection at a Defined Checkpoint Programs Effector CD4 T Cells To Become Protective Memory. J Immunol 197:3936-3949
Brodeur, Tia Y; Robidoux, Tara E; Weinstein, Jason S et al. (2015) IL-21 Promotes Pulmonary Fibrosis through the Induction of Profibrotic CD8+ T Cells. J Immunol 195:5251-60
Torrado, Egidio; Fountain, Jeffrey J; Liao, Mingfeng et al. (2015) Interleukin 27R regulates CD4+ T cell phenotype and impacts protective immunity during Mycobacterium tuberculosis infection. J Exp Med 212:1449-63

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