Diverse cell types of the blood are generated from the hematopoietic stem cell. The molecular mechanism by which a stem cell is permitted to differentiate towards one cell type versus another is undefined. This lineage commitment process involves a precise control of gene expression such that two daughter cells generated from a common precursor exhibit distinct global gene expression pattern from each other as well as from the parent. A breakdown in the gene expression network results in cell death or abnormal cell growth and cancer. Hence, identification and characterization of regulators of cell fate are essential for elucidating the origin of tumors and development of highly specific and novel drugs against cancer. This project is aimed at understanding the molecular mechanism of T cell lineage commitment. During T cell development two distinct classes of T cells, gamma-delta and alpha-beta T cells, are generated from a common precursor. We have identified a panel of gamma-delta or alpha-beta lineage-specific genes by global gene expression profiling of developing T cell subsets. One gamma-delta lineage specific gene called Sox13 has been found to differentially influence the development of alpha-beta and gamma-delta cells. In mice, Sox13 misexpression in alpha-beta cells can partly convert these cells to adopt a gamma-delta-lineage specific molecular program. Sox13 is the first lineage specific gene identified that modulates T cell lineage development. One of its functions during T cell development appears to be to inhibit cell proliferation. We will further define Sox13 function by purifying Sox13 expressing and non-expressing T precursor cells, and comparing how these subpopulations differentiate in vivo. This experiment will constitute the first direct examination of the existence of gamma-delta or alpha-beta lineage committed precursor subset. The mechanism of Sox13 function will be determined by testing Sox13's ability to inhibit critical biochemical pathways controlling alpha-beta lineage proliferation and by analyzing T cell developmental defects in Sox13-deficient mice that are currently under development. Finally, this proposal will identify cell-extrinsic signals that establish Sox 13 expression pattern as well as intracellular cofactors necessary for SOX 13 function. Collectively, the genetic program controlling T cell lineage commitment and maturation will be determined, allowing a better understanding of leukemogenesis.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
1R01CA100382-01A2
Application #
6870592
Study Section
Cellular and Molecular Immunology - B (CMI)
Program Officer
Mccarthy, Susan A
Project Start
2005-03-01
Project End
2010-02-28
Budget Start
2005-03-01
Budget End
2006-02-28
Support Year
1
Fiscal Year
2005
Total Cost
$319,950
Indirect Cost
Name
University of Massachusetts Medical School Worcester
Department
Pathology
Type
Schools of Medicine
DUNS #
603847393
City
Worcester
State
MA
Country
United States
Zip Code
01655
Spidale, Nicholas A; Sylvia, Katelyn; Narayan, Kavitha et al. (2018) Interleukin-17-Producing ?? T Cells Originate from SOX13+ Progenitors that Are Independent of ??TCR Signaling. Immunity 49:857-872.e5
Kang, Joonsoo; Malhotra, Nidhi (2015) Transcription factor networks directing the development, function, and evolution of innate lymphoid effectors. Annu Rev Immunol 33:505-38
Narayan, Kavitha; Waggoner, Lisa; Pham, Serena T et al. (2014) TRIM13 is a negative regulator of MDA5-mediated type I interferon production. J Virol 88:10748-57
Shay, Tal; Kang, Joonsoo (2013) Immunological Genome Project and systems immunology. Trends Immunol 34:602-9
Malhotra, Nidhi; Kang, Joonsoo (2013) SMAD regulatory networks construct a balanced immune system. Immunology 139:1-10
Yin, Catherine C; Cho, Ok Hyun; Sylvia, Katelyn E et al. (2013) The Tec kinase ITK regulates thymic expansion, emigration, and maturation of ?? NKT cells. J Immunol 190:2659-69
Malhotra, Nidhi; Narayan, Kavitha; Cho, Ok Hyun et al. (2013) A network of high-mobility group box transcription factors programs innate interleukin-17 production. Immunity 38:681-93
Kang, Joonsoo; Coles, Mark (2012) IL-7: the global builder of the innate lymphoid network and beyond, one niche at a time. Semin Immunol 24:190-7
Narayan, Kavitha; Sylvia, Katelyn E; Malhotra, Nidhi et al. (2012) Intrathymic programming of effector fates in three molecularly distinct ?? T cell subtypes. Nat Immunol 13:511-8
Narayan, Kavitha; Kang, Joonsoo (2010) Disorderly conduct in gammadelta versus alphabeta T cell lineage commitment. Semin Immunol 22:222-7

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