Immunopathologic Mechanisms Involved in Inflammatory Skin Diseases
Katz, Stephen I.   
National Cancer Institute Division of Clinical Sciences, United States

This laboratory studies the role of the skin as an immunological organ. We study the mechanisms involved in delayed type hypersensitivity (DTH) reactions in the skin and use this knowledge to better understand lymphocyte-mediated skin diseases. In the past year we have continued to focus our studies on 1) the development of a model that may provide insight into mechanisms involved in autoimmune reactions in skin and in the maintainance of tolerance to epidermally-derived proteins and 2) the identification of the specific precursors of Langerhans cells.

The major project that we are pursuing involves the characterization of a model of skin autoimmunity and peripheral immunological tolerance induction. We have developed transgenic mice that have a K14-ovalbumin (K-14 OVA) encoding gene. We are studying these mice and have also crossed these mice with those that have a TCR transgene that recognizes ovalbumin in association with H-2b (OT-I). These mice have the TCR for ovalbumin and express ovalbumin in the epidermis but have no apparent disease. We are also using the K-14 OVA mice as targets for immunological reactions in the skin. When T cells from OT-I mice are injected into either the single Tg mice or the double Tg mice their role in causing inflammatory skin lesions has been assessed. We have found that the OT-I TCD8+ T cells induce a GvHD-like disease in the single Tg mice....this is characterized by swelling of the feet from days 6-14 and development of redness and scaling of the skin within 7 days. The mice lose weight and die between weeks 2 and 3. The mice probably die because of an esophagitis-they are unable to eat properly. In sharp contrast, the double Tg mice, despite their expressing OVA in the skin, are unaffected when the OT-I CD8+ T cells are injected into them. One of the aims of our current studies is to better understand why there is tolerance in these double Tg mice. We have been unable to clearly delineate a CD4+CD25+ T regulatory cell in the double Tg mice but have identified a CD3+ double negative cell population in these mice and are focussing on the possibility that they are somehow serving as regulatory cells. We have found that in single transgenic (K14/mOVA no.3 mice that are low producers of OVA(K14-mOVAlow) there is tolerance to the adoptively transferred OT-I cells. We have found that IL-15 can enhance the activity of the injected OT-I cells in these mice and induce GvHD. We will attempt to reverse the tolerance in the double Tg mice as well. We have also started focussing on K14-OVA mice that produce soluble OVA (K14-sOVA). When OT-I cells are injected into these mice, almost all mice die after 5-7 days. and this is due to an acute mucositis and esophagitis. We are currently studying the mechanism by which this destruction takes place.

During the past year we found that K14-sOVA crossed with OT-I mice die within 11-17 days of birth. The cause of death is probably due to CD4+ regulatory T cells that are critical for the maintenance of peripheral tolerance and survival in double transgenic (K14-sOVA x OT-I) mice expressing ovalbumin in squamous epithelial tissues. Preliminary data suggest that we can obviate death by injecting the relevant peptide (SIINFEKL) on days 5 and 9 to these double transgenic mice. Finally, in trying to determine the target for the OT-I cytotoxic T cells, we have found, conditional knockout mice (for Langerhans cells [LC]), that even in the absence of LC GvHD occurs. We have also created chimeric mice in which the antigen-presenting cells (APC) cannot present OVA peptides to CD8+ cells because the APC are beta 2 microglobulin deficient and these mice also develop GvHD when OT-I cells are adoptively transferred. In vitro studies have demonstrated that keratinocytes can present antigen to the OT-I cells.