T cell is central to maintaining health. Over-exuberant T cell function leads to debilitating and fatal inflammatory disease. Activated T cells have to grow, exit quiescence, proliferate and differentiate in order to function. Therefore, one of the main goals for T cell research is to reveal the factors critical for the growth, proliferation and differentiation of activated T cells. Genome-wide high-throughput approaches have been quite powerful to reveal genes and pathways critical for T cell function. Most of the T cell high- throughput studies performed in the past used mRNA-based analysis, with the notion that mRNA expression will reflect the protein expression. However, accumulating evidence supports that protein and mRNA expression does not entirely correlate and can be quite different at times. In addition, the post- translational modifications of a protein and the factors a protein associating with can profoundly influence the function of a protein. Thus, to appreciate how the function of activated T cells is controlled, we need to know the protein-networks underlying T cell function in a systemic fashion, the knowledge we grossly lack to date. The recent advance of proteomic technology afforded high-speed, high-throughput, high-sensitivity and high-resolution protein analysis with microgram-scale protein samples. We have established robust experimental system to evaluate functional protein-networks in T cells. This system aided us to successfully identify new factors critical for the function of activated T cells. Encouraged by the results, we set the overarching goal of this study to reveal the protein networks underlying the function of activated T cells. A particular focus of this proposal is to reveal and assess the function of factors whose protein and mRNA are discretely regulated, aiming to identify novel molecular mechanisms that could not be revealed by classic mRNA-based analysis. By combining cutting edge MS/proteomics approach with innovative mouse model and genomic editing/genetic methods, we strive to reach the following research aims:
Aim 1 : Systemically analyze the protein expression dynamics during T cell growth, quiescence exit, and proliferation.
Aim 2 : Investigate the differential protein expression and its biological significance for Th cell differentiation. Systemic analysis of the protein expression and interaction in various stages of T cell function will, for the first time, provide an atlas for the protein networks underlying T cell biology. In combination and comparison with mRNA-based genomic analysis, it will establish a molecular map for the normal function of activated T cells. This map will help us to identify new factors and pathways critical for specific T cell functions and to reveal the deregulated factors in T cells in immune diseases including cancer, SCID, inflammation and autoimmunity, aiding the efforts to discover the bio-markers for disease diagnosis and prognosis and to find strategies and drug targets for disease treatment.

Public Health Relevance

T cell is central to maintaining health. Over-exuberant T cell function leads to debilitating and fatal inflammatory disease. Activated T cells have to grow, exit quiescence, proliferate and differentiate in order to function. Using cutting-edge protein-based functional omics analysis and innovative genetic approaches, the proposed study aims to reveal previously uncharacterized protein-expression networks controlling activation- induced T cell growth, quiescence exit, proliferation and differentiation, to shed new lights on how protein and mRNA expression correlate during T cell function, and to discover novel mechanisms underlying the function of critical T cell regulators. The success of this study will, for the first time, provide an atlas for the protein networks underlying T cell function. It will establish a molecular map for the normal function of activated T cells. It will identify new factors and pathways controlling specific T cell functions. It will aid our effectors to reveal the deregulated factors in T cells in immune diseases including cancer, SCID, inflammation and autoimmunity, and the efforts to discover the bio-markers for diseases and to devise strategies and find drug targets to treat diseases.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
5R01AI123193-05
Application #
10064572
Study Section
Cellular and Molecular Immunology - B Study Section (CMIB)
Program Officer
Jiang, Chao
Project Start
2016-12-12
Project End
2021-11-30
Budget Start
2020-12-01
Budget End
2021-11-30
Support Year
5
Fiscal Year
2021
Total Cost
Indirect Cost
Name
University of North Carolina Chapel Hill
Department
Microbiology/Immun/Virology
Type
Schools of Medicine
DUNS #
608195277
City
Chapel Hill
State
NC
Country
United States
Zip Code
27599
Zhu, Ying; Zhou, Jie; Feng, Yi et al. (2018) Control of Intestinal Inflammation, Colitis-Associated Tumorigenesis, and Macrophage Polarization by Fibrinogen-Like Protein 2. Front Immunol 9:87
Wu, Bing; Zhang, Song; Guo, Zengli et al. (2018) RAS P21 Protein Activator 3 (RASA3) Specifically Promotes Pathogenic T Helper 17 Cell Generation by Repressing T-Helper-2-Cell-Biased Programs. Immunity 49:886-898.e5
Zhang, Song; Takaku, Motoki; Zou, Liyun et al. (2017) Reversing SKI-SMAD4-mediated suppression is essential for TH17 cell differentiation. Nature 551:105-109
Brockmann, Leonie; Gagliani, Nicola; Steglich, Babett et al. (2017) IL-10 Receptor Signaling Is Essential for TR1 Cell Function In Vivo. J Immunol 198:1130-1141
Wu, Bing; Wang, Yunqi; Wang, Chaojun et al. (2016) BPTF Is Essential for T Cell Homeostasis and Function. J Immunol 197:4325-4333