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MiR-146a: a key microRNA involved in regulating mast cell survival and T lymphocyte differentiation

Rusca, Nicole-Lily. MiR-146a: a key microRNA involved in regulating mast cell survival and T lymphocyte differentiation. 2013, Doctoral Thesis, University of Basel, Faculty of Science.

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Official URL: http://edoc.unibas.ch/diss/DissB_10591

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Abstract

Mast cells are long-lived, tissue-resident cells of the innate immune system. Since the identification of mechanisms that regulate mast cell proliferation, survival and overall homeostasis in the tissues may have important implications for the treatment of mast cell-related diseases such as asthma, allergy and mastocytosis, we investigated novel molecular mechanisms at the basis of mast cell biology, and in particular the role of two activation-induced miRNAs, miR-221 and miR-146a. We found that miR-221 has important roles in regulating multiple processes in differentiated primary mast cells, such as degranulation, adhesion, migration and cytokine production. Since miR-221 is expressed at basal level in mast cells but it is also inducible upon stimulation, we proposed a model in which miR-221 has a dual role in these cells: at resting state, it contributes to the regulation of the cell cycle and cytoskeleton, an effect probably common also to other cell types that express basal levels of this miRNA. However, in response to stimulation through IgE-antigen complexes, miR-221 effects are mast cell-specific and activation-dependent, contributing to the regulation of degranulation, cytokine production and cell adherence (Chapter 1).
Mice that lack the p50 subunit of NF-kB (p50KO) are unable to mount airway eosinophilic inflammation due to the inability to produce IL-4, IL-5 and IL-13, which play distinct roles in asthma pathogenesis, and to a defect in the polarization of Th2 lymphocytes. Since mast cells are master effector cells in allergic responses, we evaluated whether the asthma-resistant phenotype observed in p50KO mice could be partially due to a defect in mast cell development or function. While our data indicate that p50KO mast cells may only marginally contribute to the airway inflammation defect of p50KO mice through a slight impairment in cytokine production, p50KO mast cells showed a marked increase in their ability to survive in response to withdrawal of essential cytokines, which likely correlated with a strong increase in the percentage of mast cells that was observed in the tissues of p50KO animals. Such improved survival of mast cells lacking p50 was due to altered expression of several molecules involved in regulating cell survival and cell death, such as Bcl2, A1 and BAX. Importantly, we also found that miR-146a, a miRNA known to regulate NF-kB signalling, was not expressed in IgE- or LPS-stimulated p50KO mast cells, and that in the context of mast cell survival, miR-146a acted as a pro-apoptotic factor, identifying therefore a new molecular network that regulates mast cell survival in response to a variety of signals (Chapter 2).
Previous work from our lab also pointed toward a role for miR-146a in the differentiation and/or activation of murine CD4 T lymphocytes. We therefore continued investigating a possible role for this miRNA not only in regulating mast cell survival, but also in the differentiation and function of T cells. We found that miR-146a is expressed at high levels in the effector and effector-memory T cell compartment in both mouse and human, and we provide evidences that miR-146a may regulate T cell expansion upon activation and possibly also memory formation (Chapter 3). A review on the role of miR-146a in immunity and disease is provided in Chapter 4.
Overall our work demonstrates that miR-221 and miR-146a play a key role in regulating mast cell activation, function and survival, and that miR-146a also contributes to the extent of T lymphocyte activation. Finally, we provide novel insights on the role of miRNAs in regulating various functions of mast cells and T lymphocytes in the immune response, contributing to the groundwork for a further understanding of the molecular mechanisms that may lead to immune-related diseases such as asthma, allergy, altered inflammatory responses, and mastocytosis.
Advisors:Pieters, Jean
Committee Members:Monticelli, Silvia and Sallusto, Federica
Faculties and Departments:05 Faculty of Science > Departement Biozentrum > Infection Biology > Biochemistry (Pieters)
UniBasel Contributors:Pieters, Jean
Item Type:Thesis
Thesis Subtype:Doctoral Thesis
Thesis no:10591
Thesis status:Complete
Number of Pages:166 p.
Language:English
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edoc DOI:
Last Modified:22 Jan 2018 15:51
Deposited On:09 Dec 2013 12:28

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