UVB radiation-induced signaling in mammalian cells involves two major pathways: one that is initiated through the generation of DNA photoproducts in the nucleus and a second one that occurs independently of DNA damage and is characterized by cell surface receptor activation. The chromophore for the latter one has been unknown. Here, we report that the UVB response involves tryptophan as a chromophore. We show that through the intracellular generation of photoproducts, such as the arylhydrocarbon receptor (
Human skin is exposed to infrared radiation (IR) from natural and artificial sources. In previous studies, near IR radiation (IRA; 760-1,440 nm) was shown to elicit a retrograde mitochondrial signaling response leading to induction of matrix metalloproteinase-1 (MMP-1) expression. These studies, however, have exclusively employed cultured human skin fibroblasts ex vivo. Here, we have assessed the in vivo relevance of these observations by exposing healthy human skin in vivo to physiologically relevant doses of IRA. Eighty percent of the tested individuals responded to IRA radiation by upregulating of MMP-1 expression. Specifically, IRA irradiation caused increased expression of MMP-1 in the dermis, but not in the epidermis. Raman spectroscopy revealed that IRA radiation also caused a significant decrease in the antioxidant content of human skin. In vitro studies had previously shown that IRA-induced MMP-1 expression was mediated through an oxidative stress response, which originates from the mitochondrial electron transport chain. We now report that incubation of cultured human dermal fibroblasts or treatment of human skin with specific antioxidants prevented IRA radiation-induced MMP-1 expression in vitro and in vivo. Thus, IRA irradiation most likely promotes premature skin aging and topical application of appropriate antioxidants represents an effective photoprotective strategy.
Human skin is exposed to infrared (IR) radiation (760 nm–1 mm) from natural as well as artificial sources that are increasingly used for cosmetic or medical purposes. Epidemiological data and clinical observations, however, indicate that IR radiation cannot be considered as totally innocuous to human skin. In particular, IR radiation, similar to ultraviolet radiation, seems to be involved in photoaging and potentially also in photocarcinogenesis. The molecular consequences resulting from IR exposure are virtually unknown. Recent studies, however, have begun to shed light on the basic molecular processes such as cellular signal transduction and gene expression triggered by exposure to IR radiation. In response to IR irradiation, mitogen‐activated protein kinase signaling pathways were activated mediating the upregulation of matrix metalloproteinase‐1 expression. This previously unrecognized molecular ‘IR response’ shows that IR radiation is capable of specifically interfering with cellular functions and provides a molecular basis for biological effects of IR on human skin.
Oxidative damage accumulation in macromolecules has been considered as a cause of cellular damage and pathology. Rarely, the oxidative stress parameters in healthy humans related to the individual age have been reported. The purpose of this study was to examine the redox status in plasma and erythrocytes of healthy individuals and determine correlations between these parameters and the aging process. The following parameters were used: malondialdehyde (MDA), protein carbonyls (PCO), 4-hydroxy-2,3-trans-nonenal (HNE), reduced glutathione (GSH), glutathione disulfide (GSSG) and uric acid (UA) in blood and plasma samples of 194 healthy women and men of ages ranging from 18 to 84 years. The results indicate that the balance of oxidant and antioxidant systems in plasma shifts in favor of accelerated oxidation during ageing. That is demonstrated by increases of MDA, HNE, GSSG and by the slight decrease of erythrocytic GSH with age. As the content of UA is more determined by metabolic and nutritional influences than by the balance between prooxidants and antioxidants there was no significant age-related change observed. For plasma concentrations of HNE the first time age-dependent reference values for healthy humans are presented.
The exact pathogenesis of photoaging of the skin is not yet known. Earlier, a number of molecular pathways explaining one or more characteristics of photoaged skin have been described, but a unifying mechanistic concept is still missing. Here we propose the "Defective Powerhouse Model of Premature Skin Aging", which reconciles most of the earlier conducted research as one concept. In this model, the persistence of UV radiation-induced mtDNA deletions or the infrared radiation-induced disturbance of the electron flow of the mitochondrial electron transport chain leads to inadequate energy production in dermal fibroblasts. As a consequence of this defective powerhouse, retrograde mitochondrial signaling pathways are triggered that then they transduce functional and structural alterations in the skin. This model, which is supported by a growing number of recent studies, is of direct clinical importance in preventing and treating photoaging in human skin.Journal of Investigative Dermatology Symposium Proceedings (2009) 14, 44-49; doi:10.1038/jidsymp.2009.1.
Mutations of mitochondrial (mt) DNA play a role in neurodegeneration, normal aging, premature aging of the skin (photoaging), and tumors. We and others could demonstrate that mtDNA mutations can be induced in skin cells in vitro and in normal human skin in vivo by repetitive, sublethal ultraviolet (UV)-A-irradiation. These mutations are mediated by singlet oxygen and persist in human skin as long-term biomarkers of UV exposure. Although mtDNA exclusively encodes for the respiratory chain, involvement of the energy metabolism in mtDNA mutagenesis and a protective role of the energy precursor creatine have thus far not been shown. We assessed the amount of a marker mutation of mtDNA, the so-called common deletion, by real-time PCR. Induction of the common deletion was paralleled by a measurable decrease of oxygen consumption, mitochondrial membrane potential, and ATP content, as well as an increase of matrix metalloproteinase-1. Mitochondrial mutagenesis as well as functional consequences could be normalized by increasing intracellular creatine levels. These data indicate that increase of the energy precursor creatine protects from functionally relevant, aging-associated mutations of mitochondrial DNA.
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