Scott N. Byrne

Mast Cell Migration from the Skin to the Draining Lymph Nodes upon Ultraviolet Irradiation Represents a Key Step in the Induction of Immune Suppression

The UV radiation in sunlight is the primary cause of skin cancer. UV is also immunosuppressive and numerous studies have shown that UV-induced immune suppression is a major risk factor for skin cancer induction. Previous studies demonstrated that dermal mast cells play a critical role in the induction of immune suppression. Mast cell-deficient mice are resistant to the immunosuppressive effects of UV radiation, and UV-induced immune suppression can be restored by injecting bone marrow-derived mast cells into the skin of mast cell- deficient mice. The exact process however, by which mast cells contribute to immune suppression, is not known. In this study, we show that one of the first steps in the induction of immune suppression is mast cell migration from the skin to the draining lymph nodes. UV exposure, in a dose-dependent manner, causes a significant increase in lymph node mast cell numbers. When GFP+ skin was grafted onto mast cell-deficient mice, we found that GFP+ mast cells preferentially migrated into the lymph nodes draining the skin. The mast cells migrated primarily to the B cell areas of the draining nodes. Mast cells express CXCR4+ and UV exposure up-regulated the expression of its ligand CXCL12 by lymph node B cells. Treating UV-irradiated mice with a CXCR4 antagonist blocked mast cell migration and abrogated UV-induced immune suppression. Our findings indicate that UV-induced mast cell migration to draining lymph nodes, mediated by CXCR4 interacting with CXCL12, represents a key early step in UV-induced immune suppression.

The Immune-Modulating Cytokine and Endogenous Alarmin Interleukin-33 Is Upregulated in Skin Exposed to Inflammatory UVB Radiation

The cellular and molecular mechanisms by which UV radiation modulates inflammation and immunity while simultaneously maintaining skin homeostasis is complex and not completely understood. Similar to the effects of UV, IL-33 has potent immune-modulating properties that are mediated by the downstream induction of cytokines and chemokines. We have discovered that exposure of mice in vivo or human skin samples ex vivo to inflammatory doses of UVB induced IL-33 expression within the epidermal and dermal skin layers. Using a combination of murine cell lines and primary human cells, we demonstrate that both UV and the oxidized lipid platelet activating factor induce IL-33 expression in keratinocytes and dermal fibroblasts. Highlighting the significance of these results, we found that administering IL-33 to mice in vivo suppressed the induction of Th1-mediated contact hypersensitivity responses. This may have consequences for skin cancer growth because UV-induced squamous cell carcinomas that evade immunological destruction were found to express significantly higher levels of IL-33. Finally, we demonstrate that dermal mast cells and skin-infiltrating neutrophils closely associate with UV-induced IL-33-expressing fibroblasts. Our results therefore identify and support a role for IL-33 as an important early danger signal produced in response to inflammation-inducing UV radiation.

Dermal dendritic cells, and not langerhans cells, play an essential role in inducing an immune response

Langerhans cells (LCs) serve as epidermal sentinels of the adaptive immune system. Conventional wisdom suggests that LCs encounter Ag in the skin and then migrate to the draining lymph nodes, where the Ag is presented to T cells, thus initiating an immune response. Platelet-activating factor (PAF) is a phospholipid mediator with potent biological effects. During inflammation, PAF mediates recruitment of leukocytes to inflammatory sites. We herein tested a hypothesis that PAF induces LC migration. Applying 2,4-dinitro-1-fluorobenzene (DNFB) to wild-type mice activated LC migration. In contrast, applying DNFB to PAF receptor-deficient mice or mice injected with PAF receptor antagonists failed to induce LC migration. Moreover, after FITC application the appearance of hapten-laden LCs (FITC+, CD11c+, Langerin+) in the lymph nodes of PAF receptor-deficient mice was significantly depressed compared with that found in wild-type mice. LC chimerism indicates that the PAF receptor on keratinocytes but not LCs is responsible for LC migration. Contrary to the diminution of LC migration in PAF receptor-deficient mice, we did not observe any difference in the migration of hapten-laden dermal dendritic cells (FITC+, CD11c+, Langerin−) into the lymph nodes of PAF receptor-deficient mice. Additionally, the contact hypersensitivity response generated in wild-type or PAF receptor-deficient mice was identical. Finally, dermal dendritic cells, but not LCs isolated from the draining lymph nodes after hapten application, activated T cell proliferation. These findings suggest that LC migration may not be responsible for the generation of contact hypersensitivity and that dermal dendritic cells may play a more important role.

The Immunologic Revolution: Photoimmunology

UV radiation targets the skin and is a primary cause of skin cancer (both melanoma and non-melanoma skin cancer). Exposure to UV also suppresses the immune response, and UV-induced immune suppression is a major risk factor for skin cancer induction. The efforts of Dermatologists and Cancer Biologists to understand how UV exposure suppresses the immune response and contributes to skin cancer induction led to the development of the sub-discipline we call photoimmunology. Advances in photoimmunology have generally paralleled advances in immunology. However, there are a number of examples where investigations into the mechanisms underlying UV-induced immune suppression reshaped our understanding of basic immunological concepts. Unconventional immune regulatory roles for Langerhans cells, mast cells, and NKT cells as well as the immune suppressive function of lipid mediators of inflammation and alarmins, are just some examples of how advances in immunodermatology have altered our understanding of basic immunology. In this anniversary issue celebrating 75 years of Cutaneous Science, we will provide examples of how concepts that grew out of efforts by Immunologists and Dermatologists to understand immune regulation by UV radiation impacted on immunology in general.

A Role for Inflammatory Mediators in the Induction of Immunoregulatory B Cells

UV exposure suppresses the immune response to a variety of microbial, fungal, and viral Ags. In addition, UV radiation is a complete carcinogen and the immune suppression induced by UV radiation is a major risk factor for skin cancer induction. In this study, we examined the mechanisms underlying the induction of immune suppression and tolerance induction by UV radiation. Transferring lymph nodes cells from UV-irradiated, FITC-sensitized mice into normal recipients transferred immune tolerance. Contrary to expectations, the cell responsible was an FITC+, IL-10-secreting, CD19+, B220+ B cell. Because the lipid mediator of inflammation, platelet-activating factor (PAF) is released by UV-irradiated keratinocytes and is essential for the induction of immune suppression, we determined its role in tolerance induction. When UV-irradiated mice were injected with PCA 4248, a selective PAF receptor (PAFR) antagonist, transfer of tolerance was suppressed. However, immune suppression was not transferred when FITC+ cells from the draining lymph nodes of UV-irradiated, PAFR-deficient donor mice were injected into the recipients. Because PCA 4248 also blocks serotonin receptor binding, we measured the effect that blocking both serotonin and PAFR binding has on the transfer of immune suppression. Only when both PAF and serotonin binding were blocked could we inhibit tolerance induction. These data identify a novel function for PAF and serotonin in modulating immune function, the activation of immunoregulatory B cells.

Ultraviolet A radiation: its role in immunosuppression and carcinogenesis.

Ultraviolet A (UVA) radiation is immunosuppressive and mutagenic in humans and carcinogenic in animals. UVA suppresses immunity with a bell-shaped dose response. At doses equivalent to 15-20 minutes of sun exposure at noon, UVA contributes to approximately 75% of sunlight-induced immunosuppression. A recent action spectrum, indicating that 360-380 nm but not 320-350 nm UVA suppresses immunity in humans, suggests an important role for reactive oxygen species. UVA also causes an energy crisis in cells, and normalization of adenosine triphosphate with nicotinamide prevents UVA immunosuppression. UVA activation of the alternative complement pathway and defects in memory T-cell development are also involved. Human skin cancers contain mutations in the p53 and BRM genes that are consistent with being induced by UVA. UVA is also mutagenic in human skin equivalents. The basal layer of human skin is more susceptible to UVA-induced mutations than the upper layers. Because skin cancers arise from these basal proliferating cells, this finding is likely to be important and could be attributable to low levels of the DNA repair enzyme OGG1 in basal cells. UVA is therefore likely to make a larger contribution to UVA-induced skin carcinogenesis in humans than is predicted by small animal models as the result of being immunosuppressive and mutagenic for basal keratinocytes.

Ultraviolet B Suppresses Immunity by Inhibiting Effector and Memory T Cells

Contact hypersensitivity is a T-cell-mediated response to a hapten. Exposing C57BL/6 mice to UV B radiation systemically suppresses both primary and secondary contact hypersensitivity responses. The effects of UVB on in vivo T-cell responses during UVB-induced immunosuppression are unknown. We show here that UVB exposure, before contact sensitization, inhibits the expansion of effector CD4+ and CD8+ T cells in skin-draining lymph nodes and reduces the number of CD4+ and IFN-gamma+ CD8+ T cells infiltrating challenged ear skin. In the absence of UVB, at 10 weeks after initial hapten exposure, the ear skin of sensitized mice was infiltrated by dermal effector memory CD8+ T cells at the site of challenge. However, if mice were previously exposed to UVB, this cell population was absent, suggesting an impaired development of peripheral memory T cells. This finding occurred in the absence of UVB-induced regulatory CD4+ T cells and did not involve prostaglandin E2, suggesting that the importance of these two factors in mediating or initiating UVB-induced immunosuppression is dependent on UVB dose. Together these data indicate that in vivo T-cell responses are prone to immunoregulation by UVB, including a novel effect on both the activated T-cell pool size and the development of memory T cells in peripheral compartments.

TGFβ is responsible for skin tumour infiltration by macrophages enabling the tumours to escape immune destruction

Infiltration of skin tumours by macrophages is an important step in tumour progression, although the mechanisms of macrophage recruitment to the tumour mass and the subsequent effects on tumour growth are poorly understood. Transfecting a murine regressing skin tumour with the gene for transforming growth factor (TGF)β enabled the tumours to grow progressively in vivo thus allowing us to study the role of this cytokine in tumour growth. Flow cytometry was used to show that TGFβ‐mediated tumour progression was accompanied by an increase in tumour‐associated macrophages (TAM) and a decrease in tumour‐infiltrating dendritic cells (DCs). TAM in TGFβ‐secreting tumours expressed lower levels of major histocompatibility complex II and CD86 compared to DC in control tumours and had a high phagocytic capacity as measured by uptake of latex beads in vivo. Indeed, TGFβ was directly responsible not only for the enhanced macrophage phagocytosis but also altering the ratio of antigen‐presenting cells to favour macrophages over DC. Our results demonstrate that TGFβ recruitment and retention of macrophages at the tumour site enable effective tumour evasion of the host immune system and reinforces the need to target TGFβ in human cancer immunotherapy trials.

The suppression of immunity by ultraviolet radiation: UVA, nitric oxide and DNA damage

We have examined the mechanism by which solar-simulated ultraviolet radiation (ssUV) suppresses memory immunity to nickel in allergic humans. In initial studies, we used inbred mice to determine the contribution of different wavebands to sunlight-induced immunosuppression. We found that low dose UVA can enhance memory, medium dose UVA (half the amount in one minimum erythemal dose of ssUV) is immunosuppressive, but higher doses protect from UVB. This is genetically dependent, as it is not observed in all mouse strains. UVA caused a similar dose-related change in recall immunity in humans. ssUV dose responses determined the limits of protection provided by sunscreens from immunosuppression in humans. Immune protection factors calculated from these data correlated with UVA protection, but not with sun protection factor, showing that in commercial sunscreens that provide good UVB protection, UVA protection limits prevention of immunosuppression. N(G)-monomethyl-l-arginine acetate (l-NMMA) was used to inhibit nitric oxide (NO) production and T4N5 liposomes containing T4 endonuclease V to enhance DNA repair. Sub-erythemal ssUV caused a dose-related local suppression of recall immunity to nickel in humans. l-NMMA and the liposomes protected the nickel reaction, suggesting that NO and DNA damage are mediators of UV-induced immunosuppression in humans.

Transforming growth factor-β1 immobilises dendritic cells within skin tumours and facilitates tumour escape from the immune system

Human skin tumours often regress spontaneously due to immune rejection. Murine skin tumours model this behaviour; some regress and others progress in syngeneic immunocompetent hosts. Previous studies have shown that progressor but not regressor skin tumours inhibit dendritic cell (DC) migration from the tumour to draining lymph nodes, and transforming growth factor-β1 (TGF-β1) has been identified as a responsible factor. To determine whether increased production of TGF-β1 in the absence of other differences inhibits DC migration from the tumour and enables it to evade immune destruction, a murine regressor squamous cell carcinoma clone was transfected with the gene for TGF-β1. This enhanced growth in vitro and in vivo, causing it to become a progressor. TGF-β1 transfection reduced the number of infiltrating DCs by about 25%. Quantitation of CD11c+ E-cadherin+ (epidermally derived) DCs in lymph nodes determined that TGF-β1 reduced the number of DCs that migrated from the tumour to undetectable levels. This was supported by showing that TGF-β1 reduced DC migration from cultured tumour explants by greater than tenfold. TGF-β1 transfection also reduced the number of infiltrating CD4 and CD8 T cells. Thus, TGF-β1 production by skin tumours is sufficient to immobilise DCs within the tumour, preventing their migration to lymph nodes. This reduces the number of T cells that infiltrate the tumour, preventing regression. Thus, TGF-β1 is a key regulator of whether skin tumours regress or progress.