Richard Boismenu

The role played in immune surveillance by gamma delta T cells residing in various epithelia has not been clear. It is shown here that activated gamma delta T cells obtained from skin and intestine express the epithelial cell mitogen keratinocyte growth factor (KGF). In contrast, intraepithelial alpha beta T cells, as well as all lymphoid alpha beta and gamma delta T cell populations tested, did not produce KGF or promote the growth of cultured epithelial cells. These results suggest that intraepithelial gamma delta T cells function in surveillance and in repair of damaged epithelial tissues.

Gammadelta T cell receptor-bearing dendritic epidermal T cells (DETCs) found in murine skin recognize antigen expressed by damaged or stressed keratinocytes. Activated DETCs produce keratinocyte growth factors (KGFs) and chemokines, raising the possibility that DETCs play a role in tissue repair. We performed wound healing studies and found defects in keratinocyte proliferation and tissue reepithelialization in the absence of wild-type DETCs. In vitro skin organ culture studies demonstrated that adding DETCs or recombinant KGF restored normal wound healing in gammadelta DETC-deficient skin. We propose that DETCs recognize antigen expressed by injured keratinocytes and produce factors that directly affect wound repair.

gammadelta intraepithelial T lymphocytes (IEL) represent a major T cell population within the intestine of unclear functional relevance. The role of intestinal gammadelta IEL was evaluated in the dextran sodium sulfate (DSS) induced mouse colitis model system. Large numbers of gammadelta T cells, but not alphabeta T cells, were localized at sites of DSS-induced epithelial cell damage. gammadelta IEL in DSS treated mice expressed keratinocyte growth factor (KGF), a potent intestinal epithelial cell mitogen. gammadelta cell-deficient mice (TCRdelta(-/-)) and KGF-deficient mice (KGF(-/-)), but not alphabeta cell-deficient mice (TCRalpha(-/-)), were more prone than wild-type mice to DSS-induced mucosal injury and demonstrated delayed tissue repair after termination of DSS treatment. Termination of DSS treatment resulted in vigorous epithelial cell proliferation in wild-type mice but not in TCRdelta(-/-) mice or KGF(-/-) mice. These results suggest that gammadelta IEL help preserve the integrity of damaged epithelial surfaces by providing the localized delivery of an epithelial cell growth factor.

T cells expressing gamma delta TCR may have evolved to recognize Ag in a different manner as well as perform a broader set of functions than T cells with alpha beta TCR. In this study, we tested the hypothesis that dendritic epidermal T cells (DETC) bearing the invariant V gamma 3V delta 1 TCR may be able to signal the migration of peripheral alpha beta T cells to the epidermis by secreting specific chemokines. Expression of macrophage inflammatory protein (MIP)-1 alpha, MIP-1 beta, RANTES, and lymphotactin was inducible in DETC 7-17 cells, whereas mRNA for monocyte chemoattractant protein (MCP)-1 could not be detected. Strikingly, lymphotactin was the most abundant chemokine produced by activated DETC 7-17 cells. Activated primary DETC cultures also produced copious amounts of lymphotactin mRNA. Similarly, freshly isolated and activated intestinal intraepithelial T cells (i-IEL) with gamma delta TCR expressed high levels of lymphotactin mRNA. In contrast, lymphotactin mRNA was present in activated spleen gamma delta T cells at low basal levels. Migration of CD8+ T cells induced by culture supernatants from stimulated DETC 7-17 cells was strongly reduced in the presence of a neutralizing anti-lymphotactin antiserum and to a lesser extent by neutralizing anti-MIP-1 alpha, anti-MIP-1 beta, or anti-RANTES antiserum. The presence of lymphotactin in supernatants from activated DETC 7-17 cultures was directly demonstrated by Western blot analysis. These observations are consistent with a model in which gamma delta IEL play an active multi-faceted role in the maintenance of epithelia homeostasis.

Emerging studies using mouse models of experimental colitis are defining the nature of the immunological disturbances that initiate inflammation and destruction of the intestine. A better understanding of disease-promoting and -suppressing CD4+ T cells is providing insight into the mechanisms controlling immune responses within the intestinal compartment. Moreover, a role for distinct T cell populations, including intraepithelial gammadelta T cells, in maintaining the physical integrity of the intestine was suggested by recent studies. Cytokine gene-knockout mice and anti-cytokine treatments remain important tools to define the pro- and anti-inflammatory functions of cytokines. These advances are fostering the design and evaluation of new therapeutic approaches that may eventually be applied to treat human inflammatory bowel disease.