Air pollution-induced tanning of human skin.

BACKGROUND: Melanism is more frequent in animals living in polluted areas on urban-industrial sites. Given that an increasing number of people are exposed to elevated air pollution levels, it is possible that environmental pollutants affect melanogenesis in human skin. Epidemiological studies have shown that exposure to traffic-related air pollutants such as diesel exhaust particles (DEP) is associated with more clinical signs of hyperpigmentation. However, mechanistic evidence linking DEP exposure to pigmentation has been elusive. OBJECTIVES: To develop an ex␣vivo skin model to allow for repetitive topical application of relevant ambient DEP, and to provide proof of concept in humans. METHODS: We measured skin pigmentation, melanin and pigmentation-associated gene expression, and evaluated oxidative stress. RESULTS: Repetitive exposure of ex␣vivo skin to DEP at nontoxic concentrations increased skin pigmentation. This increase was visible to the naked eye, time dependent, and associated with an increase in melanin content and the transcription of genes involved in de novo melanin synthesis. Similarly, in healthy participants (n = 76), repetitive topical application of DEP at nontoxic concentrations increased skin pigmentation. DEP-induced pigmentation was mediated by an oxidative stress response. After the application of DEP, epidermal antioxidants were depleted, lipid peroxidation and oxidative DNA damage were enhanced, and in a vehicle-controlled, double-blind clinical study DEP-induced pigmentation was prevented by the topical application of an antioxidant mixture. CONCLUSIONS: Similar to solar radiation, air pollutants cause skin tanning. As eumelanin is an antioxidant, it is proposed that this response serves to protect human skin against air pollution-induced oxidative stress.

Ceramide and raft signaling are linked with each other in UVA radiation-induced gene expression.

Solar ultraviolet A (UVA) (320-400 nm) radiation-induced gene expression in keratinocytes is initiated at the level of the cell membrane via generation of singlet oxygen and subsequent formation of ceramide from sphingomyelin. We now report that the UVA response also involves raft signaling and that ceramide and raft signaling are linked with each other. Upon UVA irradiation, the lipid composition of rafts decreased 40% in sphingomyelin and 60% in cholesterol (Chol). Also, decrease of Chol increased the susceptibility towards UVA-induced gene expression, whereas increase of Chol completely abolished their capacity to generate signaling ceramides and to mount the subsequent UVA response. This inhibition was not associated with UVA-induced Chol oxidation and was also seen after treatment of cells with plant sterols. The UVA responsiveness depended on the ratio of Chol versus ceramide in rafts. A ratio smaller than 1 permitted initiation and transduction of the signaling response, whereas a ratio greater than 1, for example, upon sterol pretreatment, abolished this response, indicating that UVA radiation-induced ceramide signaling is controlled by the lipid composition of rafts.

Non-enzymatic triggering of the ceramide signalling cascade by solar UVA radiation.

Ceramide is a key component of intracellular stress responses. Evidence is provided for a novel mechanism of ceramide formation that mediates solar ultraviolet (UV) A radiation-induced expression of the intercellular adhesion molecule (ICAM)-1. Similarly to UVA radiation, ceramide stimulation of human keratinocytes induced ICAM-1 mRNA expression and activated the ICAM-1 promoter through transcription factor AP-2. Ceramide-activated AP-2 and ceramide-induced ICAM-1 reporter gene activation were abrogated through deletion of the AP-2 binding site. UVA radiation increased the level of ceramide in keratinocytes and inhibition of sphingomyelin synthesis prevented UVA radiation-induced ICAM-1 expression. Hitherto, two pathways have been identified for ceramide accumulation: hydrolysis from sphingomyelin through neutral and acid sphingomyelinases, and de novo synthesis by ceramide synthase. UVA radiation did not activate any of these enzymes. Ceramide generation in UVA-irradiated cells, however, was inhibited by singlet oxygen quenchers and mimicked in unirradiated cells by a singlet oxygen-generating system. In addition, UVA radiation and singlet oxygen both generated ceramide in protein-free, sphingomyelin-containing liposomes. This study indicates that singlet oxygen triggers a third, non-enzymatic mechanism of ceramide formation.