&lt;b&gt;&lt;i&gt;Staphylococcus epidermidis&lt;/i&gt;&lt;/b&gt; Activates Aryl Hydrocarbon Receptor Signaling in Human Keratinocytes: Implications for Cutaneous Defense

Rademacher, Franziska; Simanski, Maren; Hesse, Bettina; Dombrowsky, Gregor; Vent, Nikolas; Gläser, Regine; Harder, Jürgen

doi:10.1159/000492162

Cited by 31 publications

(37 citation statements)

References 44 publications

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“…The effects observed in our colonised models are less acute and rather in line with what is seen for commensal communities in vivo. For example, similar to what is seen in host–microbiome animal studies both organisms lead to increased gene expression of β-defensins DEFB3A and DEFB4A (Lai et al 2010 ; Rademacher et al 2019 ). These β-defensins are critical but not exclusive for host defence, with induction of DEFB3A relying, amongst other things, on activation of TLR2 (Shin and Choi 2010 ).…”

Section: Discussionmentioning

confidence: 72%

Microbially competent 3D skin: a test system that reveals insight into host–microbe interactions and their potential toxicological impact

et al. 2020

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The skin`s microbiome is predominantly commensalic, harbouring a metabolic potential far exceeding that of its host. While there is clear evidence that bacteria-dependent metabolism of pollutants modulates the toxicity for the host there is still a lack of models for investigating causality of microbiome-associated pathophysiology or toxicity. We now report on a biologically characterised microbial–skin tissue co-culture that allows studying microbe–host interactions for extended periods of time in situ. The system is based on a commercially available 3D skin model. In a proof-of-concept, this model was colonised with single and mixed cultures of two selected skin commensals. Two different methods were used to quantify the bacteria on the surface of the skin models. While Micrococcus luteus established a stable microbial–skin tissue co-culture, Pseudomonas oleovorans maintained slow continuous growth over the 8-day cultivation period. A detailed skin transcriptome analysis showed bacterial colonisation leading to up to 3318 significant changes. Additionally, FACS, ELISA and Western blot analyses were carried out to analyse secretion of cytokines and growth factors. Changes found in colonised skin varied depending on the bacterial species used and comprised immunomodulatory functions, such as secretion of IL-1α/β, Il-6, antimicrobial peptides and increased gene transcription of IL-10 and TLR2. The colonisation also influenced the secretion of growth factors such as VFGFA and FGF2. Notably, many of these changes have already previously been associated with the presence of skin commensals. Concomitantly, the model gained first insights on the microbiome’s influence on skin xenobiotic metabolism (i.e., CYP1A1, CYP1B1 and CYP2D6) and olfactory receptor expression. The system provides urgently needed experimental access for assessing the toxicological impact of microbiome-associated xenobiotic metabolism in situ.

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Section: Discussionmentioning

confidence: 72%

Microbially competent 3D skin: a test system that reveals insight into host–microbe interactions and their potential toxicological impact

et al. 2020

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“… higher yeast counts have been found to correlate with SD symptom and/or severity; M furfur (formerly known as Pityrosporum orbiculare , P ovale , P furfur ) has been implicated as the most common source of dandruff; Malassezia was shown to activate the NLRP3 inflammasome via the dectin‐1 and Syk signalling cascade, causing the release of the proinflammatory cytokine IL‐1β, and altered host cytokine expression profile; of the diverse chemical entities that are effective in treating SD and dandruff—such as azoles, hydroxypyridones, allylamines, selenium and zinc pyrithione—the main shared mechanism of action is their antifungal activity; Malassezia utilizes human sebum triglycerides as food, and the metabolites such as oleic acid and arachidonic acid cause aberrant epidermal differentiation, barrier defects, and inflammatory response; Malassezia infection has also been reported in domestic animals such as goats, cats and dogs as well as monkeys, associated with seborrhoea (dry or greasy) and dermatitis, suggesting that mammalian skin shares an evolutionarily conserved hyperresponsiveness to this yeast; Malassezia can produce metabolites such as indirubin and indolo[3,2‐b]carbazole that stimulate the aryl hydrocarbon receptor and can thereby modulate antigen presenting cell functions, at least in vitro . Given that aryl hydrocarbon receptor‐mediated signalling is increasingly appreciated as a major player in human skin physiology and pathology that modulates, for example skin responses to environmental toxins and bacterial stimuli, this potential pathway through which the yeast might impact on skin inflammation deserves more systemic dissection. …”

Section: Sd Aetiology: Malassezia Yeast—cause or Associated Factor?mentioning

confidence: 99%

Seborrheic dermatitis—Looking beyond Malassezia

Wikramanayake

Borda

Miteva

et al. 2019

Experimental Dermatology

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Seborrhoeic Dermatitis (SD) is a very common chronic and/or relapsing inflammatory skin disorder whose pathophysiology remains poorly understood. Yeast of the genus Malassezia has long been regarded as a main predisposing factor, even though causal relationship has not been firmly established. Additional predisposing factors have been described, including sebaceous activity, host immunity (especially HIV infection), epidermal barrier integrity, skin microbiota, endocrine and neurologic factors, and environmental influences. Genetic studies in humans and mouse models—with particularly interesting insights from examining the Mpzl3 knockout mice and their SD‐like skin phenotype, and patients carrying a ZNF750 mutation—highlight defects in host immunity, epidermal barrier and sebaceous activity. After synthesizing key evidence from the literature, we propose that intrinsic host factors, such as changes in the amount or composition of sebum and/or defective epidermal barrier, rather than Malassezia, may form the basis of SD pathobiology. We argue that these intrinsic changes provide favourable conditions for the commensal Malassezia to over‐colonize and elicit host inflammatory response. Aberrant host immune activity or failure to clear skin microbes may bypass the initial epidermal or sebaceous abnormalities. We delineate specific future clinical investigations, complemented by studies in suitable SD animal models, that dissect the roles of different epidermal compartments and immune components as well as their crosstalk and interactions with the skin microbiota during the process of SD. This research perspective beyond the conventional Malassezia‐centric view of SD pathogenesis is expected to enable the development of better therapeutic interventions for the management of recurrent SD.

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“…Moreover, overexpression of constitutively activated AHR in basal epidermal KCs in mice led to AD-like inflammation [116,117]. Recently, it was shown that Staphylococcus epidermidis is able to trigger IL-1β and IL-1α in an AHR-dependent manner in HSEs, suggesting a pro-inflammatory role of AHR [118]. This proves the complexity of the mechanism of action of such transcription factors.…”

Section: 3d Cultures Helped Unravel New Pathogenic Pathways In Atomentioning

confidence: 99%

3D-Organotypic Cultures to Unravel Molecular and Cellular Abnormalities in Atopic Dermatitis and Ichthyosis Vulgaris

Leman

Moosbrugger‐Martinz

Blunder

et al. 2019

Cells

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Atopic dermatitis (AD) is characterized by dry and itchy skin evolving into disseminated skin lesions. AD is believed to result from a primary acquired or a genetically-induced epidermal barrier defect leading to immune hyper-responsiveness. Filaggrin (FLG) is a protein found in the cornified envelope of fully differentiated keratinocytes, referred to as corneocytes. Although FLG null mutations are strongly associated with AD, they are not sufficient to induce the disease. Moreover, most patients with ichthyosis vulgaris (IV), a monogenetic skin disease characterized by FLG homozygous, heterozygous, or compound heterozygous null mutations, display non-inflamed dry and scaly skin. Thus, all causes of epidermal barrier impairment in AD have not yet been identified, including those leading to the Th2-predominant inflammation observed in AD. Three dimensional organotypic cultures have emerged as valuable tools in skin research, replacing animal experimentation in many cases and precluding the need for repeated patient biopsies. Here, we review the results on IV and AD obtained with epidermal or skin equivalents and consider these findings in the context of human in vivo data. Further research utilizing complex models including immune cells and cutaneous innervation will enable finer dissection of the pathogenesis of AD and deepen our knowledge of epidermal biology.

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<b><i>Staphylococcus epidermidis</i></b> Activates Aryl Hydrocarbon Receptor Signaling in Human Keratinocytes: Implications for Cutaneous Defense

Cited by 31 publications

References 44 publications

Microbially competent 3D skin: a test system that reveals insight into host–microbe interactions and their potential toxicological impact

Microbially competent 3D skin: a test system that reveals insight into host–microbe interactions and their potential toxicological impact

Seborrheic dermatitis—Looking beyond Malassezia

3D-Organotypic Cultures to Unravel Molecular and Cellular Abnormalities in Atopic Dermatitis and Ichthyosis Vulgaris

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