Lower levels of interleukin-1ß gene expression are associated with impaired Langerhans' cell migration in aged human skin.

Langerhans' cells (LC) play pivotal roles in skin immune responses, linking innate and adaptive immunity. In aged skin there are fewer LC and migration is impaired compared with young skin. These changes may contribute to declining skin immunity in the elderly, including increased skin infections and skin cancer. Interleukin-1ß (IL-1ß) and tumour necrosis factor-α (TNF-α) are mandatory signals for LC migration and previous studies suggest that IL-1ß signalling may be dysregulated in aged skin. Therefore, we sought to explore the mechanisms underlying these phenomena. In skin biopsies of photoprotected young (< 30 years) and aged (> 70 years) human skin ex vivo, we assessed the impact of trauma, and mandatory LC mobilizing signals on LC migration and gene expression. Biopsy-related trauma induced LC migration from young epidermis, whereas in aged skin, migration was greatly reduced. Interleukin-1ß treatment restored LC migration in aged epidermis whereas TNF-α was without effect. In uncultured, aged skin IL-1ß gene expression was lower compared with young skin; following culture, IL-1ßmRNA remained lower in aged skin under control and TNF-α conditions but was elevated after culture with IL-1ß. Interleukin-1 receptor type 2 (IL1R2) gene expression was significantly increased in aged, but not young skin, after cytokine treatment. Keratinocyte-derived factors secreted from young and aged primary cells did not restore or inhibit LC migration from aged and young epidermis, respectively. These data suggest that in aged skin, IL-1ß signalling is diminished due to altered expression of IL1B and decoy receptor gene IL1R2.

Skin sensitization induced Langerhans' cell mobilization: variable requirements for tumour necrosis factor-α.

Upon antigen/allergen recognition, epidermal Langerhans' cells (LC) are mobilized and migrate to the local lymph node where they play a major role in initiating or regulating immune responses. It had been proposed that all chemical allergens induce LC migration via common cytokine signals delivered by TNF-α and IL-1ß. Here the dependence of LC migration on TNF-α following treatment of mice with various chemical allergens has been investigated. It was found that under standard conditions the allergens oxazolone, paraphenylene diamine, and trimellitic anhydride, in addition to the skin irritant sodium lauryl sulfate, were unable to trigger LC mobilization in the absence of TNF-α signalling. In contrast, two members of the dinitrohalobenezene family (2,4-dinitrochlorobenzene [DNCB] and 2,4-dinitrofluorobenzene [DNFB]) promoted LC migration independently of TNF-R2 (the sole TNF-α receptor expressed by LC) and TNF-α although the presence of IL-1ß was still required. However, increasing doses of oxazolone overcame the requirement of TNF-α for LC mobilization, whereas lower doses of DNCB were still able to induce LC migration in a TNF-α-independent manner. These novel findings demonstrate unexpected heterogeneity among chemical allergens and furthermore that LC can be induced to migrate from the epidermis via different mechanisms that are either dependent or independent of TNF-α. Although the exact mechanisms with regard to the signals that activate LC have yet to be elucidated, these differences may translate into functional speciation that will likely impact on the extent and quality of allergic sensitization.

The XS106 cell: a Langerhans' cell surrogate with a selective type 2 phenotype.

Epidermal Langerhans' cells (LC) play important roles in initiating and regulating cutaneous immune responses. However, LC comprise less than 3% of all epidermal cells and consequently are difficult to study ex vivo. In the current investigations, we have examined the utility of the XS106 cell line, a dendritic cell (DC) line derived from mouse epidermis, as a surrogate for LC. Membrane marker expression, type 1- and type 2-associated chemokine production, and migration patterns have been characterised following treatment of XS106 cells with a range of toll-like receptor (TLR) ligands. Comparisons have been made with mouse bone marrow-derived DC- and LC-derived ex vivo. Like BMDC, XS106 cells expressed generic DC markers, in addition to displaying higher levels of skin DC markers compared with BMDC. XS106 cells and LC-enriched epidermal fractions both displayed higher constitutive expression of type 2-associated chemokines than type 1 chemokines. Furthermore, although treatment with a range of TLR ligands induced cytokine secretion by XS106 cells, only type 2 TLR ligands increased membrane marker expression of major histocompatibility complex class II and co-stimulatory molecules. Moreover, type 1-associated TLR ligands failed to induce selective type 1 chemokine secretion by XS106 cells. XS106 cells also displayed functional similarity to LC, migrating in response to chemokines that are known to induce the migration of LC. On the basis of membrane marker expression and selective type 2 polarisation XS106 cells provide a useful surrogate for LC.