IL‐17A synergistically enhances TLR3‐mediated IL‐36γ production by keratinocytes: A potential role in injury‐amplified psoriatic inflammation

Skin injury can trigger formation of new lesions in psoriasis (Koebner phenomenon). The mechanisms through which injury exacerbates psoriasis are unclear. During wound repair, epidermal keratinocytes are activated and produce abundant IL‐36γ, further promoting the skin inflammation. IL‐17A is the cornerstone cytokine in the pathogenesis of psoriasis. We sought to investigate the effects of IL‐17A on injury‐induced keratinocyte activation and IL‐36γ production. Here, we demonstrated that dsRNA released from necrotic keratinocytes induced the expression of IL‐36γ. Silencing of TLR3 by siRNA decreased the IL‐36γ induction by necrotic keratinocyte supernatant. Co‐stimulation with dsRNA and IL‐17A synergistically increased the expression of IL‐36γ and other proinflammatory mediators (CCL20, CXCL8, DEFB4 and LCN2) in keratinocytes. The synergistic effects were not dependent on TLR3 upregulation, TNF receptor signalling and mRNA stabilization. Co‐stimulation with dsRNA and IL‐17A resulted in an accumulation of IκBζ. The synergistic upregulation of IL‐36γ and proinflammatory mediators were inhibited by IκBζ siRNA. Co‐stimulation with IL‐17A and poly(I:C) markedly activated the p38 MAPK and NF‐κB pathway, compared with poly(I:C). Blockade of p38 MAPK and NF‐κB suppressed dsRNA/IL‐17A–mediated IκBζ and IL‐36γ induction. These findings demonstrated that IL‐17A synergistically enhanced the dsRNA‐mediated IL‐36γ production through a p38 MAPK‐, NF‐κB–, and IκBζ‐dependent mechanism.     

Interleukin (IL)‐22, IL‐17, IL‐23, IL‐8, vascular endothelial growth factor and tumour necrosis factor‐α levels in patients with psoriasis before,during and after psoralen–ultraviolet A and narrowband ultraviolet B therapy

Background Several cross‐sectional studies have shown that different cytokines and growth factors are enhanced in psoriasis. Objectives We aimed to understand the role/relation of interleukin (IL)‐22, IL‐17, IL‐23, IL‐8, vascular endothelial growth factor (VEGF) and tumour necrosis factor (TNF)‐α in psoriasis vulgaris, addressing their levels and changes before, during and after psoralen–ultraviolet A (PUVA) and narrowband ultraviolet B (NB‐UVB) treatment. Methods A cross‐sectional and a longitudinal study (n = 34) – before (T0) and at 3 (T3), 6 (T6) and 12 (T12) weeks of NB‐UVB and PUVA therapy – were performed; 17 patients started NB‐UVB and 17 PUVA, and IL‐22, IL‐17, IL‐23, IL‐8, TNF‐α and VEGF levels were evaluated. Results At T0, compared with controls (n = 20), all the parameters were significantly higher in patients, except for TNF‐α. Both NB‐UVB and PUVA treatment gave, at T3, a significant decrease in TNF‐α and IL‐23; IL‐22 and IL‐17 decreased significantly at T6; all parameters and Psoriasis Area and Severity Index decreased significantly at T12. However, in both groups, at T12, VEGF was still significantly higher than control. Conclusions Psoriasis seems to be a complex disease in which the cytokine network is disturbed, namely in levels of IL‐22, IL‐17, IL‐23, IL‐8, TNF‐α and VEGF. NB‐UVB and PUVA follow‐up studies suggested that the reduction in the IL‐23/Th17 axis might be important in the pathogenic mechanisms of psoriasis. Further follow‐up studies of patients with psoriasis treated with these and other therapies could be very helpful for the understanding of the disturbance in the cytokine network in psoriasis and indirectly in its pathogenesis.     

Continuous high‐dose antigen exposure preferentially induces IL‐10, but intermittent antigen exposure induces IL‐4

IL‐10 plays a critical role in the induction of specific T‐cell tolerance. To date, whether IL‐10 induction by antigen application is dose‐ or time‐dependent remains unclear. In this study, IL‐10 induction by allergen exposure was investigated in the several schedules. Oxazolone was repeatedly applied to mouse ear, and mRNA of inflammatory cytokines in lesional skins was measured. The results indicated that continuous high‐dose antigen exposure induces IL‐4 as well as abundant IL‐10 production. Monocytes/dendritic cells and T cells are major source of IL‐10. Allergen‐specific immunotherapy is resumed before antigen scattering: preseason. We evaluated safe‐loading dose of allergens in preseasonal therapy focusing Tr1 induction. Restarting immunotherapy with high dose effectively augmented IL‐10 expression accompanied with further induction of IL‐4 and inflammatory cytokines. Therefore, the protocol restarting with low‐dose antigen is preferential to obviate the risk of exacerbation or anaphylaxis.     

Role of IL‐10 and TGF‐β in melanoma

IL‐10 and TGF‐β are immunosuppressive cytokines expressed in tumors including melanoma and, therefore, deemed major cause for failing antitumor immune responses. Re‐evaluating their role, we compared their expression by quantitative RT‐PCR in melanoma and skin of healthy individuals, tested their induction in dendritic cells and T cells co‐cultured with tumor cells, and their effects on the immune cells. Both cytokines as well as their receptors were expressed in melanoma at significantly lower levels than in healthy skin. Consequently, the expressions of IL‐10‐responsive SOCS‐3 and TGF‐β‐responsive Smad‐7 were low in tumors but high in healthy skin. T cells co‐cultured with tumor cells developed an anergic state without increased IL‐10 or TGF‐β expression. In vitro tumor‐induced immature dendritic cells produced high IL‐10 levels and less efficiently induced T‐cell proliferation. Nonetheless, they could be induced to mature, and blocking IL‐10 did not alter the capacity of the resulting mature dendritic cells to stimulate T cells. Mature dendritic cells co‐cultured with tumor cells produced increased IL‐10 but decreased TGF‐β and more efficiently induced T‐cell proliferation. The lack of correlation of IL‐10 and TGF‐β with immune deficits in situ and in vitro suggests re‐evaluating their roles in cancer.     

IL‐17F regulates psoriasis‐associated genes through IκBζ

Psoriasis is a common chronic inflammatory and immune‐mediated skin disease. Antagonists of TNF‐α and, recently, IL‐17 have proven to be highly effective in the treatment for psoriasis; however, the molecular mechanisms involved in the pathogenesis of psoriasis are poorly understood. Recently, we presented evidence that IκBζ is a key regulator in the development of psoriasis through its role in mediating IL‐17A‐driven effects. Like IL‐17A, IL‐17F is produced by a variety of immune cells, and the expression of IL‐17F is increased in psoriatic skin. The purpose of this study was to characterize the role of IL‐17F in the regulation of IκBζ expression and to investigate whether IL‐17F regulates psoriasis‐associated genes in human keratinocytes through IκBζ. Here, we demonstrate that IL‐17F stimulation induces IκBζ expression at both the mRNA and the protein levels in normal human keratinocytes. Moreover, silencing IκBζ by siRNA revealed that IκBζ is a key regulator of specific IL‐17F‐inducible psoriasis‐associated genes and proteins, including DEFB4/hBD2, S100A7, CCL20, IL‐8 and CHI3L1. In addition, IL‐17F‐induced IκBζ expression is mediated by a mechanism involving the p38 MAPK and NF‐κB signalling pathways, as shown by the clear reduction in IL‐17F‐mediated expression of IκBζ during chemical inhibition of these two signalling pathways. In summary, we present IκBζ as a novel key regulator of IL‐17F‐driven effects in psoriasis. Thus, antagonists to IκBζ could potentially provide a more targeted approach for treating psoriasis as well as for treating the other inflammatory and immune‐mediated diseases for which IL‐17‐targeting drugs have recently been approved.     

IL‐36γ has proinflammatory effects on human endothelial cells

Interleukin‐36 cytokines are predominantly expressed by epithelial cells. Significant upregulation of epidermal IL‐36 is now a recognised characteristic of psoriatic skin inflammation. IL‐36 is known to induce inflammatory responses in dendritic cells, fibroblasts and epithelial cells. Although vascular alterations are a hallmark of psoriatic lesions and dermal endothelial cells are well known to play a critical role in skin inflammation, the effects of IL‐36 on endothelial cells are unexplored. We here show that endothelial cells including dermal microvascular cells express a functionally active IL‐36 receptor. Adhesion molecules VCAM‐1 and ICAM‐1 are upregulated by IL‐36γ stimulation, and this is reversed by the presence of the endogenous IL‐36 receptor antagonist. IL‐36γ‐stimulated endothelial cells secrete the proinflammatory chemokines IL‐8, CCL2 and CCL20. Chemotaxis assays showed increased migration of T‐cells following IL‐36γ stimulation of endothelial cells. These results suggest a role for IL‐36γ in the dermal vascular compartment, and it is likely to enhance psoriatic skin inflammation by activating endothelial cells and promoting leucocyte recruitment.     

Evidence for a regulatory loop between IFN‐γ and IL‐33 in skin inflammation

Interleukin‐33 has recently gained much attention due to its role in allergic responses. It has been shown to amplify Th2 responses and to act as a damage‐associated molecular pattern. IL‐33 acts on a broad range of cells and has been proposed to link innate and adaptive features of allergic responses. It was the aim of this study to investigate this property of IL‐33 in the inflammatory response characterising atopic dermatitis (AD). We have analysed the response of skin‐resident cells derived from patients with AD and healthy donors with regard to the expression of IL‐33 and its receptor ST2. The functional impact of IL‐33 on CD4+ T cells was investigated. Keratinocytes and dermal fibroblasts clearly differ in their regulation of IL‐33. In fibroblasts, the concerted action of TNF‐α and IL‐1β was the strongest inducer, whereas IFN‐γ is clearly the key molecule that upregulates IL‐33 in keratinocytes with a more pronounced response of cells derived from patients with AD. Keratinocytes from patients with AD showed a markedly higher constitutive expression level of surface ST2. CD4+ T cells respond to IL‐33. Unexpectedly, IL‐33 failed to induce a significant secretion of IL‐5 or IL‐13. By contrast, high amounts of IFN‐γ were detectable if IL‐33 was added to the T‐cell receptor‐stimulated cells or in combination with IL‐12. These results suggest that IL‐33 and IFN‐γ are closely interlinked in epidermal AD inflammation. IFN‐γ induces IL‐33 in keratinocytes and IL‐33 acts on activated T cells to further increase the release of IFN‐γ, therefore contributing to drive skin inflammation towards chronic responses.     

Primary human keratinocytes efficiently induce IL‐1‐dependent IL‐17 in CCR6+ T cells

Abstract: Keratinocytes and activated T cells interact in skin inflammation by virtue of chemokines and cytokines. T cell‐derived IL‐17 has been described to play an important role in the course of psoriatic inflammation. In this study, we addressed how keratinocytes influence the secretion of IL‐17 in autologous T cell subsets. We found that a co‐culture of autologous keratinocytes and T cell‐receptor‐stimulated T cells markedly enhanced the production of IL‐17. Besides the importance of direct cell contact, this effect was mainly mediated by IL‐1 and could be blocked by the IL‐1 antagonist anakinra. An additional increase in IL‐17 production by IL‐23 was only seen in the presence of IL‐1, which thus plays a permissive role for the action of IL‐23. Importantly, co‐culture of keratinocytes with CCR6+ CD4+ T cells that are enriched for Th17 cells resulted in significantly higher IL‐17 production compared to co‐culture with CD4+ T cells.