Effects UV-A and visible light on skin cells and hair

Sunlight presents electromagnetic radiation over a wide spectral range, including the regions of ultraviolet (UV-C, UV-B, UV-A), visible and infrared. Each region interacts with skin dependending on the photophysics and photochemistry of the respective absorbing compounds. UV-A light causes the generation of reactive oxygen and nitrogen species (ROS and RNS) by photosensitization of endogenous molecules (flavin coenzymes, porphyrins, melanins). When photosensitizers produce amounts of ROS and RNS larger than the cell capacity to suppress these species, a set of redox imbalance, which damages biomolecules such as nucleic acids, lipids and proteins. This damage cause cell death and to other phenotypic and genotypic changes and also stimulates the release of proinflammatory cytokines. In order to better understand the dynamics of the mechanisms of cellular responses after exposure to UV-A and visible light, we initially characterized the photophysical properties of melanin and detected the production of singlet oxygen (1O2) by photosensitization in the visible, as well as the suppression of these excited species by reaction of singlet oxygen with the double bonds of the reactive groups presented in the melanin indols. These processes were also observed in hair and led us to propose a model that explains the effects of visible light on the structure and color of hair. We also demonstrated that pheomelanin produces more (30%) 1O2 than eumelanin, which undergoes a quick change on its structure by photodegradation. The effect of these processes in the skin was studied at the cellular level. We demonstrated that epithelial cells with larger melanin content have stronger generation of 1O2, which causes DNA damage and necro-apoptotic death after irradiation with visible light. The photo-oxidation of melanin by visible light has motivated us to study a pigment that was not only able to protect against UV-B but also against visible. Pigmentation with Acetyl-Tyrosine proved nontoxic and protective against UV-B and visible light instead of pigmentation with Tyrosine, which shielded against UV-B but showed toxicity in the visible. This effect was associated with the polymer, cell location and not with its structure. UV-A light, in turn, promotes the accumulation of lipofuscin, within autophagic vacuoles of keratinocytes also enabling phototoxicity in the visible light. The lipofuscin within the autophagic vacuoles is fotooxidized by visible light, causing DNA damage and programmed cell death type II. Linear dose of UV-A that trigger the release of cytokines were also characterized. (AU)