A critical role for Fas ligand in the active suppression of systemic immune responses by ultraviolet radiation.

Induction of antigen-specific suppression elicited by environmental insults, such as ultraviolet (UV)-B radiation in sunlight, can inhibit an effective immune response in vivo and may contribute to the outgrowth of UV-induced skin cancer. Although UV-induced DNA damage is known to be an initiating event in the immune suppression of most antigen responses, the underlying mechanism(s) of such suppression remain undefined. In this report, we document that Fas ligand (FasL) is critical for UV-induced systemic immune suppression. Normal mice acutely exposed to UV exhibit a profound suppression of both contact hypersensitivity and delayed type hypersensitivity (DTH) reactions and the development of transferable antigen-specific suppressor cells. FasL-deficient mice exposed to UV lack both transferable suppressor cell activity and primary suppression to all antigens tested, with the exception of the DTH response to allogeneic spleen cells. Interestingly, suppression of this response is also known to occur independently of UV-induced DNA damage. Delivery of alloantigen as protein, rather than intact cells, restored the requirement for FasL in UV-induced immune suppression of this response. These results substantiate that FasL/Fas interactions are essential for systemic UV-induced suppression of immune responses that involve host antigen presentation and suggest an interrelationship between UV-induced DNA damage and FasL in this phenomenon. Collectively, our results suggest a model whereby UV-induced DNA damage disarms the immune system in a manner similar to that observed in immunologically privileged sites.

HindIII liposomes suppress delayed-type hypersensitivity responses in vivo and induce epidermal IL-10 in vitro.

Considerable evidence suggests that ultraviolet-B (UV-B) radiation suppresses certain immune responses through the induction of cyclobutane pyrimidine dimers in DNA. To determine whether induction of other forms of DNA damage in the skin mimicked the immunosuppressive effects of UV-B radiation, we produced double-strand breaks in the DNA of epidermal cells with HindIII restriction endonuclease encapsulated in liposomes. Application of these liposomes, but not liposomes containing inactive HindIII or an irrelevant endonuclease, to the skin of C3H mice suppressed the induction of delayed-type hypersensitivity responses to Candida albicans and alloantigen and induced IL-10 production in the epidermis. Treatment of the Pam212 murine keratinocyte cell line with these liposomes in vitro induced immunosuppressive activity and IL-10 in culture supernatants. Unlike UV-B irradiation, however, HindIII in liposomes failed to induce suppressor T cell activity in vivo or in vitro. We conclude that double-strand breaks in DNA of epidermal cells can induce immunosuppression and up-regulate the production of immunomodulatory cytokines; however, either DNA damage alone does not account for all the immunosuppressive properties of UV-B irradiation, or cyclobutane pyrimidine dimers differ qualitatively from double-strand breaks in their biologic consequences. These studies raise the possibility that drugs causing DNA damage may induce cytokine dysregulation and immune suppression in addition to cytotoxicity.

Origin and characteristics of ultraviolet-B radiation-induced suppressor T lymphocytes.

Cutaneous exposure to low dose (2 kJ/m2) ultraviolet B radiation impairs the induction of contact hypersensitivity (CHS) responses to haptens applied to UV-irradiated skin and induces hapten-specific suppressor T lymphocytes (Ts). Cells collected from the draining lymph nodes of UV-irradiated, FITC-sensitized mice have impaired Ag-presenting activity and induce Ts cells upon injection into syngeneic recipients. This study investigates whether Ts cells originate in the UV-irradiated donor mice or are induced in lymph node cell recipients and the mechanism of suppression. Using congenic mice, we determined that the Ts cells in recipient animals were derived from T cells in the draining lymph nodes of the UV-irradiated donors. Cell lines and clones established from unirradiated and UV-irradiated, FITC-sensitized mice were CD4+, CD8-, TCR-alpha/beta+, MHC restricted, and hapten specific. The T cells proliferated in response to APC sensitized in vivo, but not to APC coupled in vitro with FITC. Cell lines from unirradiated mice were Th1 like, producing large amounts of IFN-gamma, but little IL-4 or IL-10, whereas cloned Ts cells from UV-irradiated mice produced IL-10, but no IL-4 or IFN-gamma. Ts cells blocked APC functions and IL-12 production in vitro. Injection of 5 x 10(4) cloned Ts cells into untreated recipients suppressed the induction of CHS. These results suggest that UV radiation can induce a distinct T regulatory type 1-like Ts population that may block the activation of Th1 cell-mediated immune responses.