Project description:Here we used a pan-cytokeratin antibody to differentiate the epidermal from dermal compartment and assayed over 18,000 RNA probes from multiple regions of interest (ROI) comparing sun protected skin, and two regions (edge and center) from AK/sun damaged skin. This allows for a trajectory from sun protected to sun damaged within an individual. Traditionally, cancer biology focusses on change within the tumor compartment for diagnosis and staging and current genetic profiling of actinic keratosis (the precursor lesion for cutaneous squamous cell carcinoma) has focused on analysis limited to whole skin or the epidermal compartment alone. Here we use spatial transcriptomics to compare and contrast the epidermal and stromal compartments from different regions of actinic keratosis and matched sun protected skin from six individuals. Our data show that the major changes in AK at the transcriptional level are evident in the dermal compartment. Sun protected skin (n=5-6 from 6 individuals for a total of 34 ROI), the center of an AK lesion (n=3 for a total of 18 ROI) and edge of the AK lesion (n=2-3 for a total of 17 ROI) representing sun-damaged skin, from six unrelated individuals, the center of an AK lesion (n=3 for a total of 18 ROI) and edge of the AK lesion (n=2-3 for a total of 17 ROI) representing sun-damaged skin, from six unrelated individuals.

Project description:We studied the transcriptomic profile of actinic keratosis (AK) skin compared to matched samples from uninvolved skin (US) before and after treatment with ingenol mebutate gel. We found that AK has a distinct mRNA profile that separates it from uninvolved skin. In particular, numerous genes associated with epidermal development and keratinocyte differentiation, such as LCE3D, SPRR1A, PI3 and several genes in the keratin family were highly expressed in AK0 skin, but not in US0, in line with the hyperkeratosis characteristic for AK. Topical application of ingenol mebutate had a profound effect on the gene expression profile, and interestingly, many more genes were affected in US than in AK. Enrichment analysis revealed that the main responses to ingenol mebutate treatment of both US and AK were inflammatory response, response to wounding, and wound healing. 30 skin biopsies were analysed; 5 from each of 6 AK patients. Before initiation of treatment, baseline biopsies were taken from one AK lesion (AK0) and from uninvolved skin (US0). A third biopsy was taken after day 1 application of ingenol mebutate from one AK lesion (AK1). The fourth and fifth biopsies were obtained one day after the second topical application with ingenol mebutate from an AK lesion (AK2) and from uninvolved skin (US2), respectively.

Project description:Gene expression profiling of epidermal samples obtained from sun-exposed and sun-protected body sites from younger (<35 years old) and older (>60 years old) individuals. The Affymetrix U133A plus 2.0 array was used to obtain gene expression data. Samples included 4 younger sun exposed epidermal samples, 4 older sun exposed epidermal samples, 3 younger sun protected epidermal samples, 5 older sun protected epidermal samples.

Project description:Genome wide DNA methylation profiling of epidermal and dermal samples obtained from sun-exposed and sun-protected body sites from younger (<35 years old) and older (>60 years old) individuals. The Illumina Infinium 450k Human DNA methylation Beadchip was used to obtain DNA methylation profiles across approximately 450,000 CpGs in dermal and epidermal samples. Samples included 10 younger sun protected dermal samples, 10 younger sun exposed dermal samples, 10 older sun protected dermal samples, 10 older sun exposed dermal samples, 9 younger sun protected epidermal samples, 9 younger sun exposed epidermal samples, 10 older sun protected epidermal sample, 10 older sun exposed epidermal samples.

Project description:In this study we explored the effects of chronological and photoageing on the miRNome of human skin. To this end, miRNA expression was analysed in biopsies collected from sun-exposed (outer arm) and sun-protected (inner arm) skin from fair-skinned (phototype II/III) healthy female volunteers of two age groups: young, 18-25 years and aged, >70 years. Strict inclusion criteria were used for photoageing scoring and for chronological ageing. Microarray analysis revealed that chronological ageing had minor effect on the human skin miRNome. In contrast, photoageing had a robust impact on miRNAs, and a set of miRNAs differentially expressed between sun-protected and sun-exposed skin of the young and aged groups was identified. We have performed miRNome analysis (using microarray) on RNA isolated from sun-exposed and sun-protected skin of young and old females

Project description:Genome wide DNA methylation profiling of epidermal and dermal samples obtained from sun-exposed and sun-protected body sites from younger (<35 years old) and older (>60 years old) individuals. The Illumina Infinium 450k Human DNA methylation Beadchip was used to obtain DNA methylation profiles across approximately 450,000 CpGs in dermal and epidermal samples. Samples included 10 younger sun protected dermal samples, 10 younger sun exposed dermal samples, 10 older sun protected dermal samples, 10 older sun exposed dermal samples, 9 younger sun protected epidermal samples, 9 younger sun exposed epidermal samples, 10 older sun protected epidermal sample, 10 older sun exposed epidermal samples. Bisulphite converted DNA from the 78 samples were hybridized to the Illumina Infinium 450k Human Methylation Beadchip.

Project description:The project aims to look at mutational signatures in a rare inherited skin tumour syndrome called CYLD cutaneous syndrome. These patients develop multiple skin tumours that are seen at sun exposed and sun protected sites. We plan to carry out WGS on carefully curated tumours from such patients. We then plan to analyse this data for mutational signatures, comparing this between sun exposed and sun protected sites.

Project description:Although most cutaneous squamous cell carcinomas (cSCC) develop from actinic keratoses (AK), the key events for this evolution remain unclear. We have combined the results of different genomic and expression array platforms on matched samples of sun-exposed skin, AK and cSCC from ten immunocompetent patients, with the objective of better understanding the mechanisms involved in this progression. Gene expression analysis and copy number alterations were assessed using GeneChip Human Gene 2.0 ST Array® (Affymetrix ) and CytoScan HD Cytogenetics Solution® (Affymetrix) platforms, respectively. Integration of genome and transcriptome results was evaluated using the DR-Integrator tool. Additional studies (qPCR, immunohistochemistry and Western blot) were performed for selected genes. Twenty-two genes showed a progressive expression spectrum from clinically normal sun-exposed skin samples to cSCC. FOSL1 and BNC1 encode transcription factors whose expression was increased in cSCC in the expression array and the qPCR. By immunohistochemistry, FOSL1 showed an intense staining at the invasive front of cSCC samples and BNC1 expression varied from a nuclear location (sun-exposed skin) to a cytoplasmic location (cSCC). Western blot analyses confirmed the enhancement of FOSL1 and BNC1 expression. Additionally, the smallest overlapping regions of genomic imbalance (SORIs) involving at least 3 of the samples of each group (sun-exposed skin, AK or cSCC) were selected. One of the SORIs was a deletion in the p24.1 band of chromosome 3, shared by 7 of the cSCC. A strong correlation in the integration analysis was found for NEK10, a gene contained in the previously mentioned SORI. Loss of NEK10 expression in cSCC was confirmed by immunohistochemistry and western blot analyses. In conclusion, our findings suggest that FOSL1 may play a role in promoting the cSCC invasion ability. We have also identified two additional genes, NEK10 and BNC1, which could also act as tumor drivers.

Project description:Although most cutaneous squamous cell carcinomas (cSCC) develop from actinic keratoses (AK), the key events for this evolution remain unclear. We have combined the results of different genomic and expression array platforms on matched samples of sun-exposed skin, AK and cSCC from ten immunocompetent patients, with the objective of better understanding the mechanisms involved in this progression. Gene expression analysis and copy number alterations were assessed using GeneChip Human Gene 2.0 ST Array® (Affymetrix ) and CytoScan HD Cytogenetics Solution® (Affymetrix) platforms, respectively. Integration of genome and transcriptome results was evaluated using the DR-Integrator tool. Additional studies (qPCR, immunohistochemistry and Western blot) were performed for selected genes. Twenty-two genes showed a progressive expression spectrum from clinically normal sun-exposed skin samples to cSCC. FOSL1 and BNC1 encode transcription factors whose expression was increased in cSCC in the expression array and the qPCR. By immunohistochemistry, FOSL1 showed an intense staining at the invasive front of cSCC samples and BNC1 expression varied from a nuclear location (sun-exposed skin) to a cytoplasmic location (cSCC). Western blot analyses confirmed the enhancement of FOSL1 and BNC1 expression. Additionally, the smallest overlapping regions of genomic imbalance (SORIs) involving at least 3 of the samples of each group (sun-exposed skin, AK or cSCC) were selected. One of the SORIs was a deletion in the p24.1 band of chromosome 3, shared by 7 of the cSCC. A strong correlation in the integration analysis was found for NEK10, a gene contained in the previously mentioned SORI. Loss of NEK10 expression in cSCC was confirmed by immunohistochemistry and western blot analyses. In conclusion, our findings suggest that FOSL1 may play a role in promoting the cSCC invasion ability. We have also identified two additional genes, NEK10 and BNC1, which could also act as tumor drivers.

Project description:Photoaging is cumulative damage that is caused by chronic, repeated solar radiation exposure to skin. Its molecular mechanisms are poorly understood at the level of global gene expression.This study set out to uncover genes and functional modules involved in photoaging at the level of transcription, with the use of skin samples from Chinese women.Using the Illumina microarray platform, we compared the genome-wide expression profiles of 21 pairs of sun-exposed pre-auricular and sun-protected post-auricular skin samples from northern Chinese women.In total, 1,621 significantly regulated genes were identified from skin due to photoaging by microarray analysis. These genes were subjected to functional enrichment analyses with both the Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) annotation databases. As revealed by the functional analyses, the up-regulated functional modules in sun-exposed pre-auricular skin were related to various cellular activities in regulation of the skin homeostasis (e.g., the KEGG pathways TGF-beta signaling pathway and ECM-receptor interaction ), whereas the down-regulated functional modules were mostly metabolic-related. Additionally, five selected genes (HOXA5, LEPR, CLDN5, LAMC3, and CGA) identified as differentially-expressed were further confirmed on their expression by quantitative real-time PCR (Q-RT-PCR). Our findings suggest that damage from skin homeostasis and down-regulation of skin metabolism may play important roles in the process of photoaging. We compared the genome-wide expression profiles of 21 pairs of sun-exposed pre-auricular and sun-protected post-auricular skin samples from northern Chinese women by using the Illumina microarray platform.