10.3.3E: Invarient Natural Killer T-Lymphocytes (iNKT Cells)

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Describe the overall function of iNKT cells and their activation in terms of the following:

the role of their TCRs

how they are activated by antigen-presenting cells

how they promote both innate and adaptive immunity and may also help to regulate the immune responses

Figure \(\PageIndex{1}\): An iNKT-Lymphocyte Recognizing Microbial Glycolipid Antigen Bound to a CD1d Molecule on a Dendritic Cell. 1. Antigen-presenting dendritic cells engulf certain microbes or microbial glycolipids (exogenous glycolipids). 2. The glycolipids are degrade into epitopes by lysosomes. 3. The glycolipid epitopes are then bound to CD1d molecules produced in the endoplasmic reticulum by the dendritic cell. 4. The glycolipid epitope/CD1d complexs are transported by the Golgi apparatus to the surface of the dendritic cell. 5. Here the glycolipid epitope can be presented to theTCR of iNKT cells to induce iNKT cell activation.

Once activated, the iNKT cells rapidly produce large quantities of both T_H1 cell and T_H2 cell cytokines, including interferon-gamma (IFN-?), interleukin-4 (IL-4), interleukin-2 (IL-2), interleukin-10 (IL-10), tumor necrosis factor-alpha (TNF-a), interleukin-13 (IL-13), and chemokines. Through the rapid productions of such cytokines, iNKT cells are able to promote and suppress different innate and adaptive immune responses. For example, large amounts of IFN-? are produced by activated iNKT cells. IFN-? activates NK cells and macrophages as a part of innate immunity; it also promotes the maturation of dendritic cells so that they induce a T_H1 cell response to induce adaptive immunity.

It has been proposed that if the iNKT cell is repeatedly stimulated by the body's own glycolipids in the ab sense of microbes that this might stimulate the iNKT cell /dendritic cell interaction to produce tolerizing signals that inhibit the T_H1 cell response and possibly stimulate the production of regulatory T-lymphocytes (T_reg cells). In this way it might suppress autoimmune responses and prevent tissue damage.

There is also growing evidence that early childhood exposure to microbes is associated with protection against allergic diseases, asthma, and inflammatory diseases such as ulcerative colitis. It has been found that germ-free mice have large accumulations of mucosal iNKT cells in the lungs and intestines and increased morbidity from allergic asthma and inflammatory bowel disease. However, colonization of neonatal germ-free mice with normal microbiota resulted in mucosal iNKT cell tolerance to these diseases. It has been proposed that microbes the human body has been traditionally exposed to from early childhood throughout most of human history might play a role in developing normal iNKT cell numbers and iNKT cell responses.

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