Project description:Despite widespread use of sunscreens that minimize erythema by blocking ultraviolet B (UVB) radiation, incidence rates of melanoma continue to rise. In considering this disparity between intervention and disease prevalence, we investigated the in vivo transcriptome of human skin treated with sunscreen and solar-simulated radiation (ssR). A focal skin area of healthy participants was exposed to ssR at 1 minimal erythema dose (MED), 0.1 MED or 100 J/m2 with or without prior application of sunscreen, or to non-UVB-spectrum of ssR (solar-simulated UVA/visible/infrared radiation: ssA). Skin biopsies were analyzed using expression microarrays.

Project description:Despite widespread use of sunscreens that minimize erythema by blocking ultraviolet B (UVB) radiation, incidence rates of melanoma continue to rise. In considering this disparity between intervention and disease prevalence, we investigated the in vivo transcriptome of human skin treated with sunscreen and solar-simulated radiation (ssR). A focal skin area of healthy participants was exposed to ssR at 1 minimal erythema dose (MED), 0.1 MED or 100 J/m2 with or without prior application of sunscreen, or to non-UVB-spectrum of ssR (solar-simulated UVA/visible/infrared radiation: ssA). Skin biopsies were analyzed using expression microarrays. Ninety-eight microarrays from 14 healthy human volunteers were analyzed. Focal skin areas of all 14 volunteers were exposed to 0 J/m2, 100 J/m2, 1 minimal erythema dose (MED), and 0.1 MED of solar-simulated radiation (ssR). Eight of the 14 volunteers (Group 1) were also exposed to ssA (ssR minus UVB) that were generated by removing UVB from 0 J/m2, 100 J/m2, 1 minimal erythema dose (MED), and 0.1 MED of ssR. Additionally, 6 of the 14 volunteers (Group 2) were treated with sunscreen of sun protection factor (SPF) 15, and exposed to 0 J/m2, 100 J/m2, 1 minimal erythema dose (MED), and 0.1 MED of ssR. Biopsy was taken 24 hours after exposure from each focal skin area for RNA extraction.

Project description:Kertinocyte cultures grown in 60 mm petri dishes were placed 186 mm from the solar simulator source (Solar-simulated ultraviolet radiation 1600W Xenon short arc lamp with an Oriel Air Mass 1 Direct Filter, (AM1:D:B; model 81074) and KG2 Short Pass Filter. irradiance 9.84 mW/cm² for UVA (98.3%), 0.174 mW/cm² for UVB (1.7%) and 10 mW/cm² (0.017 mW/cm² erythemally-weighted) for the total UVR irradiance) and received a dose of either 0, 10, 20 and 150 kJ/m2 of unweighted ultraviolet radiation and 0, 10 and 150 kJ/m2 of unweighted ultraviolet radiation with SPF 15 sunscreen filtration (Homosalate 3%, Octisalate 4%, Avobenzone 2%, Titanium dioxide 0.66%) (2 mg/cm2 sandwiched between two 5x5 inch quartz plates) and were temperature controlled at 37oC using a customized water-bath. Six and Twenty-four hours post-exposure cells were harvested and RNA was extracted and subjected to microarray analysis.

Project description:Solar urticaria (SU) is clinically characterised by rapid onset sunlight-induced urticaria, but its cutaneous pathophysiology is not well understood. The aim of this study was to investigate cutaneous cellular and molecular events in the evolution of SU responses following solar simulated ultraviolet radiation (SSR) exposure, and compare with responses in healthy controls (HC). Cutaneous biopsies were taken from unexposed skin and from skin exposed to a single low (physiological) dose of SSR, at 30 minutes, 3 hours and 24 hours post-exposure, in n=6 SU patients and n=6 HC. Biopsies were assessed by immunohistochemistry (n=6 SU, n=6 HC) and RNA-sequencing analysis (n=4 SU, n=4 HC). This dataset contains RNAseq data from the SU patients.

Project description:The aim of this study was to investigate cutaneous cellular and molecular events in the photodermatoses (including solar urticaria and photoaggravated atopic dermatitis) following solar simulated ultraviolet radiation (SSR) exposure, and this dataset comprised the healthy controls (HC). Cutaneous biopsies were taken from unexposed skin and from skin exposed to a single low (physiological) dose of SSR, at 30 minutes, 3 hours, 24 hours and 72 hours post-exposure, in n=6 HC. Biopsies were assessed by immunohistochemistry (n=6 HC) and RNA-sequencing analysis (n=4 HC).

Project description:BackgroundTerrestrial ultraviolet (UV) radiation causes erythema, oxidative stress, DNA mutations and skin cancer. Skin can adapt to these adverse effects by DNA repair, apoptosis, keratinization and tanning.ObjectivesTo investigate the transcriptional response to fluorescent solar-simulated radiation (FSSR) in sun-sensitive human skin in vivo.MethodsSeven healthy male volunteers were exposed to 0, 3 and 6 standard erythemal doses (SED). Skin biopsies were taken at 6 h and 24 h after exposure. Gene and microRNA expression were quantified with next generation sequencing. A set of candidate genes was validated by quantitative polymerase chain reaction (qPCR); and wavelength dependence was examined in other volunteers through microarrays.ResultsThe number of differentially expressed genes increased with FSSR dose and decreased between 6 and 24 h. Six hours after 6 SED, 4071 genes were differentially expressed, but only 16 genes were affected at 24 h after 3 SED. Genes for apoptosis and keratinization were prominent at 6 h, whereas inflammation and immunoregulation genes were predominant at 24 h. Validation by qPCR confirmed the altered expression of nine genes detected under all conditions; genes related to DNA repair and apoptosis; immunity and inflammation; pigmentation; and vitamin D synthesis. In general, candidate genes also responded to UVA1 (340-400 nm) and/or UVB (300 nm), but with variations in wavelength dependence and peak expression time. Only four microRNAs were differentially expressed by FSSR.ConclusionsThe UV radiation doses of this acute study are readily achieved daily during holidays in the sun, suggesting that the skin transcriptional profile of 'typical' holiday makers is markedly deregulated. What's already known about this topic? The skin's transcriptional profile underpins its adverse (i.e. inflammation) and adaptive molecular, cellular and clinical responses (i.e. tanning, hyperkeratosis) to solar ultraviolet radiation. Few studies have assessed microRNA and gene expression in vivo in humans, and there is a lack of information on dose, time and waveband effects. What does this study add? Acute doses of fluorescent solar-simulated radiation (FSSR), of similar magnitude to those received daily in holiday situations, markedly altered the skin's transcriptional profiles. The number of differentially expressed genes was FSSR-dose-dependent, reached a peak at 6 h and returned to baseline at 24 h. The initial transcriptional response involved apoptosis and keratinization, followed by inflammation and immune modulation. In these conditions, microRNA expression was less affected than gene expression.

Project description:The ubiquitous presence of solar UV radiation in human life is essential for vitamin D production but also leads to skin photoaging, damage, and malignancies. Photoaging and skin cancer have been extensively studied, but the effects of UV on the critical mechanical barrier function of the outermost layer of the epidermis, the stratum corneum (SC), are not understood. The SC is the first line of defense against environmental exposures like solar UV radiation, and its effects on UV targets within the SC and subsequent alterations in the mechanical properties and related barrier function are unclear. Alteration of the SC's mechanical properties can lead to severe macroscopic skin damage such as chapping and cracking and associated inflammation, infection, scarring, and abnormal desquamation. Here, we show that UV exposure has dramatic effects on cell cohesion and mechanical integrity that are related to its effects on the SC's intercellular components, including intercellular lipids and corneodesmosomes. We found that, although the keratin-controlled stiffness remained surprisingly constant with UV exposure, the intercellular strength, strain, and cohesion decreased markedly. We further show that solar UV radiation poses a double threat to skin by both increasing the biomechanical driving force for damage while simultaneously decreasing the skin's natural ability to resist, compromising the critical barrier function of the skin.

Project description:Solar ultraviolet (SUV) exposure is a major risk factor in the etiology of cutaneous squamous cell carcinoma (cSCC). People commonly use sunscreens to prevent SUV-induced skin damage and cancer. Nonetheless, the prevalence of cSCC continues to increase every year, suggesting that commercially available sunscreens might not be used appropriately or are not completely effective. In the current study, a solar simulated light (SSL)-induced cSCC mouse model was used to investigate the efficacy of eight commonly used FDA-approved sunscreen components against skin carcinogenesis. First, we tested FDA-approved sunscreen components for their ability to block UVA or UVB irradiation by using VITRO-SKIN (a model that mimics human skin properties), and then the efficacy of FDA-approved sunscreen components was investigated in an SSL-induced cSCC mouse model. Our results identified which FDA-approved sunscreen components or combinations are effective in preventing cSCC development. Not surprisingly, the results indicated that sunscreen combinations that block both UVA and UVB significantly suppressed the formation of cutaneous papillomas and cSCC development and decreased the activation of oncoproteins and the expression of COX-2, keratin 17, and EGFR in SSL-exposed SKH-1 (Crl:SKH1-Hrhr) hairless mouse skin. Notably, several sunscreen components that were individually purported to block both UVA and UVB were ineffective alone. At least one component had toxic effects that led to a high mortality rate in mice exposed to SSL. Our findings provide new insights into the development of the best sunscreen to prevent chronic SUV-induced cSCC development.

Project description:Multiple unique environmental factors such as space radiation and microgravity (?G) pose a serious threat to human gene stability during space travel. Recently, we reported that simultaneous exposure of human fibroblasts to simulated ?G and radiation results in more chromosomal aberrations than in cells exposed to radiation alone. However, the mechanisms behind this remain unknown. The purpose of this study was thus to obtain comprehensive data on gene expression using a three-dimensional clinostat synchronized to a carbon (C)-ion or X-ray irradiation system. Human fibroblasts (1BR-hTERT) were maintained under standing or rotating conditions for 3 or 24 h after synchronized C-ion or X-ray irradiation at 1 Gy as part of a total culture time of 2 days. Among 57,773 genes analyzed with RNA sequencing, we focused particularly on the expression of 82 cell cycle-related genes after exposure to the radiation and simulated ?G. The expression of cell cycle-suppressing genes (ABL1 and CDKN1A) decreased and that of cell cycle-promoting genes (CCNB1, CCND1, KPNA2, MCM4, MKI67, and STMN1) increased after C-ion irradiation under ?G. The cell may pass through the G1/S and G2 checkpoints with DNA damage due to the combined effects of C-ions and ?G, suggesting that increased genomic instability might occur in space.

Project description:The CCN family of proteins is involved in diverse biological functions such as cell growth, adhesion, migration, angiogenesis, and regulation of extracellular matrix. We have investigated expression of CCN family genes and alternations induced by solar-simulated ultraviolet irradiation in human skin in vivo. Transcripts of all six CCN genes were expressed in human skin in vivo. CCN5 was most abundantly expressed followed by CCN2>CCN3>CCN1>CCN4>CCN6. Solar-simulated ultraviolet irradiation increased mRNA expression of CCN1 and CCN2. In contrast, mRNA levels of CCN3, CCN4, CCN5, and CCN6, were reduced. Knowledge gained from this study provides the foundation to explore the functional roles of CCN gene products in cutaneous biology and responses to solar ultraviolet irradiation.