Human keratinocyte radiosensitivity is linked to redox modulation

Background: Ionising radiation-induced reactive oxygen species (ROS) overproduction induces keratinocyte alterations and constitutes one of the most common effects after therapeutic γ-irradiation. ROS production is controlled by a complex enzymatic system. Objective: The aim of our study is to analyse the role of radiation-induced oxidative stress in keratinocytes death by apoptosis. We hypothesized that keratinocyte capacity to hamper radiation-induced ROS generation may control their radiosensitivity. Methods: For this purpose, an original human skin explant model was developed and two types of human epidermal cells were used: primary keratinocytes NHEK and spontaneous non-tumourigenic cell line HaCaT. Results: cDNA-arrays analysis was performed 24 h after a 20 Gy γ-radiation and revealed down-regulation of genes involved in oxidative stress control and the apoptosis process. This was confirmed by alterations in catalase, GPx and SOD enzymatic activities. This redox modulation was concomitant to the down-regulation of anti-apoptotic genes and up-regulation of some pro-apoptotic genes (caspase 10, ubiquitin C). Interestingly TUNEL labelling revealed an increase in the number of apoptotic cells. We also demonstrated a differential inducibility of the cell antioxidant network in two keratinocyte lines, which results in a differential cellular level of ROS, explaining their different radiosensitivities. Conclusion: Keratinocytes apoptosis is partly dependent on ROS production after exposure to γ-rays. In addition, the differential radiosensitivity of keratinocytes is linked to different oxidative stress responses. © 2005 Japanese Society for Investigative Dermatology. Published by Elsevier Ireland Ltd. All rights reserved

Collapse of skin antioxidant status during the subacute period of cutaneous radiation syndrome: A case report

This case report describes a patient suffering from accidental cutaneous radiation syndrome. Clinical symptoms were characterized by the presence of moist epidermal denudation over approximately 8% of the body surface without signs of necrosis 88 days after radiation exposure. The skin transcriptional profile was obtained and provides a comprehensive overview of the changes in gene expression associated with skin wound healing after irradiation. In particular, our data show a specific set of genes, i.e. SOD1, GPX1, TDX1, TDX2 and HSP60, implicated in the redox control of normal skin repair after radiation exposure, whereas HOX1 and HOX2 were involved in the pathological skin repair. A reduction in the antioxidant capacity of the irradiated tissue concomitant with a progressive establishment of an uncontrolled inflammatory response was noted. Our data corroborate the hypothesis that ROS modulation is a key element of the healing response after cutaneous exposure to radiation and that the collapse of skin antioxidant status interferes directly with wound healing in skin after radiation exposure. Thus a better understanding of the molecular events through which oxidative stress modulates the healing response could result in a more rational therapeutic approach to the pathological process induced after exposure of skin to radiation. © 2007 by Radiation Research Society

Protective effect of geranylgeranylacetone against radiation-induced delayed effects on human keratinocytes

International audienceSkin exposure to ionizing radiation affects the normal wound healing process. We investigated the beneficial effects of a pharmacological treatment with geranylgeranylacetone (GGA) on keratinocytes using in vitro scratch wound injury assay in nonirradiated and irradiated conditions. Irradiation affected the wound closure of keratinocytes 24 h after scratch injury, whereas re-epithelialization was markedly accelerated after GGA treatment when compared to nontreated keratinocytes. We demonstrated that GGA treatment increased migration of human epidermal keratinocytes and this migratory property was not related to RhoA signaling. Interestingly, Western blot analysis revealed that GGA treatment down-regulated caspase 3 active form expression and up-regulated the activated phenotype by inducing both keratin 6 (K6) expression and interleukin-1β (IL-1β) release without modification of the differentiate phenotype. Finally, the proteomic profiling was performed on keratinocytes, showing that global protein changes occurred after irradiation of keratinocytes treated or untreated with GGA