Project description:Cutaneous squamous cell carcinoma (cSCC) is the second most common skin cancer type and arises from keratinocytes. Most cSCC progress from a UV-induced precancerous lesion termed actinic keratosis (AK). Despite various efforts to characterize these lesions molecularly, the etiology of AK and its progression to cSCC remain only partially understood. Here we have used Infinium MethylationEPIC BeadChips to interrogate the DNA methylation status of about 850.000 CpGs in epidermal preparations from healthy skin, AK and cSCC. Importantly, we found that the premalignant AK samples displayed classical features of cancer methylomes and were highly similar to cSCC methylomes. Further analysis identified typical features of stem cell methylomes, such as a reduced DNA methylation age, non-CpG methylation and stem cell-related keratin and enhancer methylation patterns. Interestingly, this signature was detected only in one half of the AK and cSCC samples, while the other half showed methylation patterns that were more closely related to the control epidermis. These findings suggest the existence of two distinct subclasses of AK and cSCC that originate from distinct keratinocyte differentiation stages.

Project description:Here, we performed scRNA-seq to compare the transcriptomes of individual cells from three groups: (1) healthy sun-exposed skin; (2) AK samples; (3) cSCC samples. A total of 81792 cells from 8 AK samples, 3 cSCC samples and 3 control skin tissue were characterized, which comprising representatives from each of the major dermal cell types. Our results demonstrate the heterogeneity within tissues/patients and corroborated the effect of the tumor environment during carcinogenesis, especially immune cell populations. Additionally, we identified a list of gene expression changes that affected several known cancerous pathways, with potential evolution trajectory from a subset of AK premalignant cells to cSCC cells. Our findings will improve current understanding about the mechanism of AK-cSCC progression, and are potentially valuable in providing novel precautionary/ therapeutic markers.

Project description:Keratinocyte cancers (KC) are the most prevalent malignancies in fair-skinned populations, posing a significant medical and economic burden to health systems. KC originate in the epidermis and mainly comprise basal cell carcinoma (BCC) and cutaneous squamous cell carcinoma (cSCC). Here, we combined single-cell transcriptomics, methylomics and multi-omics to investigate the epigenomic dynamics during epidermal differentiation. We identified ~4,000 differentially accessible regions between undifferentiated and differentiated keratinocytes, corresponding to regulatory regions associated with key transcription factors. DNA methylation at these regions defined AK/cSCC subtypes with epidermal stem cell- or keratinocyte-like features. Using cell type deconvolution tools and integration of bulk and single-cell methylomes, we demonstrate that these subclasses are consistent with distinct cells-of-origin. Further characterization of the subclasses with an epigenetic mitotic-like clock, and the study of other unstratified KC entities uncovered distinct phenotypic and clinical features for the subclasses, linking invasive and metastatic KC cases with undifferentiated cells-of-origin. Our study provides a thorough characterization of the epigenomic dynamics underlying human keratinocyte differentiation and uncovers novel links between KC cells-of-origin and their prognosis

Project description:In the present study, we aim to identify key genes or pathways in the progression from normal skin to actinic keratoses (AK), then to cutaneous squamous cell carcinoma (cSCC) by transcriptomics analysis. We firstly established a UVR-induced cSCC model using SKH-1 hairless mouse successfully. Then, the transcriptome profiles among normal skin, AK and cSCC were investigated. We also constructed pseudo trajectory and deconvoluted the cell compositions among these three different tissues. A series of bioinformatics and molecular experiments analyses were carried out and we found retinoic acid receptor-related receptor alpha (Rora) was involved in this progression. Our results demonstrated Rora can be a potential therapeutic target for cSCC, which facilitates the treatment of cSCC.

Project description:Cutaneous squamous cell carcinoma (cSCC) is the second most frequent of the keratinocyte-derived malignancies with actinic keratosis (AK) as a precancerous lesion. To comprehensively delineate the underlying mechanisms for the whole progression from normal skin to AK to invasive cSCC, we performed single-cell RNA-seq (scRNA-seq) to acquire the transcriptomes of 138,982 cells from 13 samples of six patients including AK, squamous cell carcinoma in situ (SCCIS), cSCC and their normal tissues, covering comprehensive clinical courses of cSCC. We identified diverse cell types, including important subtypes with different gene expression profiles and functions in major keratinocytes. In SCCIS, we discovered the malignant subtypes of basal cells with differential proliferative and migration potential. Differentially expressed genes (DEG) analysis screened out multiple key driver genes including transcription factors (TFs) along AK to cSCC progression. Immunohistochemistry (IHC) / immunofluorescence (IF) experiments and single-cell ATAC sequencing (scATAC-seq) data verified the expression changes of these genes. The functional experiments confirmed the important roles of these genes in regulating cell proliferation, apoptosis, migration and invasion in cSCC tumor. Furthermore, we comprehensively described the tumor microenvironment (TME) landscape and potential keratinocyte-TME crosstalk in cSCC providing theoretical basis for immunotherapy. Together, our findings provide a valuable resource for deciphering the progression from AK to cSCC and identifying potential targets for anticancer treatment of cSCC.

Project description:Cutaneous squamous cell carcinoma (cSCC) is one of the most common malignancies in fair skinned populations worldwide and its incidence is increasing. Despite previous observations of multiple genetic abnormalities in cSCC, the oncogenic process remains elusive. The purpose of this study was to investigate the transcriptomes of cSCC and actinic keratoses (AK), to elucidate key differences between precursor AK lesions and invasive carcinoma. This study identified 196 genes that are differentially expressed between AK and cSCC, with enrichment for processes including epidermal differentiation, cell migration, cell cycle regulation and metabolism. Gene set enrichment analysis highlighted a key role for the MAPK pathway in the transition from AK to cSCC. Furthermore, the differentiation status of the tumor influenced the gene expression profile, which may have implications for drug sensitivity and response in clinical trials. These data indicate that progression to cSCC is associated with a complex pattern of molecular changes. We have identified relevant pathways involved in this process, in particular that the MAPK pathway may be pivotal to the transition from AK and may represent a potential therapeutic target. RNA was extracted by laser capture microdissection from 10 AK and 30 cSCC, for analysis using the Affymetrix HG U133 Plus 2.0 microarrays. The cSCC samples included a range of histological diagnoses (well differentiated through to poorly differentiatied) from both immunocompetent and immunosuppressed patients.

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:Keratinocyte cancers (KC) are the most prevalent malignancies in fair-skinned populations, posing a significant medical and economic burden to health systems. KC originate in the epidermis and mainly comprise basal cell carcinoma (BCC) and cutaneous squamous cell carcinoma (cSCC). Here we combined single-cell multi-omics, transcriptomics and methylomics to investigate the epigenomic dynamics during epidermal differentiation. We identified ~4,000 differentially accessible regions between undifferentiated and differentiated keratinocytes, corresponding to regulatory regions associated with key transcription factors. DNA methylation at these regions defined AK/cSCC subtypes with epidermal stem cell- or keratinocyte-like features. Using cell type deconvolution tools and integration of bulk and single-cell methylomes, we demonstrate that these subclasses are consistent with distinct cells-of-origin. Further characterization of the phenotypic traits of the subclasses, and the study of additional unstratified KC entities uncovered distinct clinical features for the subclasses, linking invasive and metastatic KC cases with undifferentiated cells-of-origin. Our study provides a thorough characterization of the epigenomic dynamics underlying human keratinocyte differentiation and uncovers novel links between KC cells-of-origin and their prognosis.

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.