Project description:Compared to skin wounds, oral mucosal wounds heal more rapidly with less inflammation, faster re-epithelialization, and minimal scarring. One cell type that may be a differentiating factor is keratinocytes. Using immortalized skin and oral keratinocytes, HaCaT and TIGK, respectively, we found that oral keratinocytes have an enhanced migratory and proliferative capacity. To examine the transcriptomic differences that underlie the improved healing abilities of oral keratinocytes, we generated an RNA-sequencing (RNA-seq) gene expression dataset utilizing HaCaT and TIGK. Differentially expressed genes (DEGs) were identified between HaCaT and TIGK at baseline and throughout the injury response. Gene Ontology (GO) or Reactome enrichment analysis was performed to understand the biological significance of DEGs. Processes related to inflammation and migration were uniquely enriched in TIGK. Additionally, TIGK retained its enhanced migratory capacity when grown on various basement membrane (BM) and extracellular matrix (ECM) substrates. This may be due to the differential expression of matrix metalloproteinases (MMPs) and integrins between HaCaT and TIGK. We also identified genes differentially over or under-expressed in HaCaT and TIGK following injury when compared to each respective cell type’s unwounded gene expression levels. Lastly, we showed that the post-injury secretome of TIGK promotes keratinocyte migration. Our comparative analyses suggest specific transcriptomic differences between oral and skin keratinocytes at unwounded baseline and in response to injury may underlie the distinct wound healing phenotypes seen in these two tissues. This work also provides a source of HaCaT and TIGK gene expression data over healing that can be used for future analyses.

Project description:The morphology and the behavior of skin and oral tissue keratinocytes are different. One significant dissimilarity between the two sites is the response to injury. Oral and skin keratinocytes have intrinsic differences in the response to injury and such differences are reflected in gene expression profiles. We used microarrays to investigate differences in global gene expression patterns between baseline skin and oral epithelium sheets without their underlying connective tissue.

Project description:The morphology and the behavior of skin and oral tissue keratinocytes are different. One significant dissimilarity between the two sites is the response to injury. Oral and skin keratinocytes have intrinsic differences in the response to injury and such differences are reflected in gene expression profiles. We used microarrays to investigate differences in global gene expression patterns between baseline skin and oral epithelium sheets without their underlying connective tissue. Paired skin and oral epithelium was separated from the dermis for RNA extraction and hybridization on Affymetrix microarrays. Skin epidermal tissues were obtained from the tail of mice and oral epidermal tissues were obtained from the hard palate. Enzymatically isolated epithelium was used for analysis.

Project description:To delineate the role of microRNAs in the site-specific injury response, we compared the microRNAome of skin and oral mucosa both at baseline and throughout the time course of wound healing.

Project description:Global warming and rising temperature significantly increase the incidence of heat stress, which is known to affect the process of inflammation and aging. However, the effect of heat stress on skin melanogenesis is not fully known. We found that healthy foreskin tissues underwent significant pigmentation when exposed to 41℃. Furthermore, heat stress promoted melanogenesis in pigment cells by increasing the paracrine effects of keratinocytes. High-throughput RNA sequencing showed that heat stress activates the Hedgehog (Hh) signaling pathway in keratinocytes. The agonists of Hh signaling promote the paracrine effect of keratinocytes on melanogenesis. In addition, TRPV3 agonists activate the Hh signaling in keratinocytes and augment its paracrine effect on melanogenesis. The heat-induced activation of Hh signaling is dependent on TRPV3-mediated Ca2+ influx. Heat exposure promotes melanogenesis by increasing the paracrine effects in keratinocytes via the TRPV3/Ca2+/Hh signaling pathway. Our findings provide insights into the mechanisms of heat-induced skin pigmentation.

Project description:SWATH-MS data for human keratinocytes (HaCaT cell line), sample 001-004 indicates HaCaT cells with no treatment, sample 005-008 indicates HaCaT cells induced by erastin, sample 009-012 indicates HaCaT cells induced by erastin plus MGO (methyglyoxal), and sample 013-016 indicates HaCaT cells induced by erastin plus GO (glyoxal). For more detailed information, please contact Dr.Chang Liu (hichang813@uri.edu)

Project description:Continuous exposure to ultraviolet (UV) is one of the main factors contributing to skin carcinogenesis. Sulforaphane (SFN) is a potent antioxidative agent which has potential to prevent the UV-induced skin cell transformation. We characterized the transcriptome and CpG methylation profile of human keratinocytes (HaCaT cells) treated with UVB and/or SFN using RNA sequencing.

Project description:Continuous exposure to ultraviolet (UV) is one of the main factors contributing to skin carcinogenesis. Sulforaphane (SFN) is a potent antioxidative agent which has potential to prevent the UV-induced skin cell transformation. We characterized the transcriptome and CpG methylation profile of human keratinocytes (HaCaT cells) treated with UVB and/or SFN using RNA sequencing.

Project description:We identified the transcription factor NRF3 as an important tumor-suppressing protein in the skin. To gain insight into the mechanisms of action of NRF3 in keratinocytes, we searched for NRF3 interactors in the SCC13 skin cancer and the immortalized non-tumorigenic HaCaT cell line using BioID interaction screening.

Project description:Disrupted skin barrier due to altered keratinocyte differentiation is common in pathologic conditions such as atopic dermatitis, ichthyosis and psoriasis. However, the molecular cascades governing keratinocyte terminal differentiation are still poorly understood. We have previously demostrated that a dominante mutation in ZNF750 leads to a clinical phenotype that reminiscent of psoriasis and seborrehic dermatitis. We defined ZNF750 as a nuclear effector that is atrongly activated in and essiential for keratinocyte terminal differentiation. ZNF750 knockdown in HaCaT keratinocytes markedly reduced the expression of epidermal late differentiation markers, including gene subsets of epidermal differentiation complex and skin barrier formation such as FLG, LOR, SPINK5, ALOX12B and DSG1, known to be mutated in various human skin diseases. Furthermore, ZNF750 over-expression in undifferentiated cells induced terminal differentiation genes. Thus, ZNF750 is a regulator of keratinocyte terminal differnetiation, and with its downstream targets can serve in future elucidation of therapeutics for common disease of skin barrier Gene expression analysis: To determine the differentaition signature for HaCaT keratinocytes, with ZNF750 gene silencing, total RNA was isolated in biologic triplicates from cells induced to differentiate for twelve days and hybridized to Affymerix Human Gene 1.0 ST arrays.