Project description:It has long been known that excessive mitotic activity due to H-Ras can block keratinocyte differentiation and cause skin cancer. It is not clear, however, whether there are any innate surveillants that ensure keratinocytes undergoing terminal differentiation, preventing the disease. IKKα induces keratinocyte terminal differentiation and its reduction promotes skin tumor development. However, its nature function in skin cancer is unknown. Here we found that mice with IKKα deletion in keratinocytes or in hair follicle keratinocytes developed a thickened epidermis and spontaneous squamous cell-like carcinomas. Inactivation of epidermal growth factor receptor (EGFR) or reintroduction of IKKα inhibited excessive mitosis, induced terminal differentiation, and prevented skin cancer through an EGFR-driven autocrine loop in mice. Thus, IKKα serves as an innate surveillant.

Project description:Progenitor cells at the basal layer of skin epidermis play an essential role in maintaining tissue homeostasis and enhancing wound repair in skin. The proliferation, differentiation, and cell death of epidermal progenitor cells have to be delicately regulated, as deregulation of this process can lead to many skin diseases, including skin cancers. However, the underlying molecular mechanisms involved in skin homeostasis remain poorly defined. In this study, with quantitative proteomics approach, we identified an important interaction between KDF1 (Keratinocyte Differentiation Factor 1) and IKKα (IκB kinase α) in differentiating skin keratinocytes. Ablation of either KDF1 or IKKα in mice leads to similar but striking abnormalities in skin development, particularly in skin epidermal differentiation. With biochemical and mouse genetics approach, we further demonstrate that the interaction of IKKα and KDF1 is essential for epidermal differentiation. To probe deeper into the mechanisms, we find that KDF1 associates with a deubiquitinating protease, USP7 (Ubiquitin Specific Peptidase 7), and KDF1 can regulate skin differentiation through deubiquitination and stabilization of IKKα. Taken together, our study unravels an important molecular mechanism underlying skin tissue homeostasis and epidermal differentiation.

Project description:We generated Ikkα-KA/KA knock-in mice (KA/KA), in which an ATP binding site of Ikkα Lys 44 was replaced by alanine. The knock-in mice develop severe skin lesions and begin to die after 6 to 10 months. We also found lung SCCs in some of the mice. To study lung SCC development, we stabilize the skin condition by crossing KA/KA with Lori.Ikkα transgenic mice to generate KA/KA-Lori.Ikkα mice, which 100% spontaneously developed lethal lung SCC at 4 to 6 months of age. Clodronate-liposomes obtained from Dr. N. van Rooijen (Vrije Universiteit, Amsterdam, Netherlands) were intravenously injected into mice twice every week, started in 4 weeks old mice, and continued for 3 months. The dose of clodronate-liposomes was 100µl during the first month and elevated to 150 100µl after that. The depletion efficacy was confirmed by detecting pulmonary macrophages with Flow Cytometry. Depletion of macrophages in these KA/KA-Lori.Ikkα mice could significantly reduce inflammation and prevent lung SCC developmrnt. This aim of this microarray assay is to identify differentially expressed genes among Wild type, KA/KA-Lori.Ikkα, and macophage-depleted KA/KA-Lori.Ikkα mice, which may highlight the important genes or parthways involved in inflammation-associated lung SCC carcinogenesis. Three samples were analyzed: 1. WT (lung tissue from wild type mouse); 2. KA2 (mixture tissue of lung SCC and tumor neighbor from KA/KA-Lori-Ikkα mouse ); 3. KAT (lung tissue from KA/KA-Lori-Ikkα mouse with macrophage depletion treatment)

Project description:Expression analyses comparing c-Fos expressing keratinocytes vs non-expressing controls. Skin squamous cell carcinomas (SCCs) are the second most prevalent skin cancers. Chronic skin inflammation has been associated with the development of SCCs, but the contribution of skin inflammation to SCC development remains largely unknown. In this study we demonstrate that inducible expression of c-fos in the epidermis of adult mice is sufficient to promote inflammation-mediated epidermal hyperplasia leading to the development of pre-neoplastic lesions. Interestingly, c-Fos transcriptionally controls mmp10 and s100a7a15 expression in keratinocytes subsequently leading to CD4 T cell recruitment to the skin, thereby promoting epidermal hyperplasia. Combining inducible c-fos expression in the epidermis with a single dose of the carcinogen 7,12-Dimethylbenz(a)anthracene (DMBA) leads to the development of highly invasive SCCs, which are prevented by using the anti-inflammatory drug Sulindac. Moreover, human SCCs display a correlation between c-FOS expression and elevated levels of MMP10 and S100A15 proteins as well as CD4 T cell infiltration. Our studies demonstrate a bidirectional crosstalk between pre-malignant keratinocytes and infiltrating CD4 T cells in SCC development. Therefore, targeting inflammation along with the newly identified targets, such as MMP10 and S100A15, represent promising therapeutic strategies to treat SCCs. 5 different time points measured in triplicate comparing Dox-treated vs untreated c-FostetON keratinocytes

Project description:We generated Ikkα-KA/KA knock-in mice (KA/KA), in which an ATP binding site of Ikkα Lys 44 was replaced by alanine. The knock-in mice develop severe skin lesions and begin to die after 6 to 10 months. We also found lung SCCs in some of the mice. To study lung SCC development, we stabilize the skin condition by crossing KA/KA with Lori.Ikkα transgenic mice to generate KA/KA-Lori.Ikkα mice, which 100% spontaneously developed lethal lung SCC at 4 to 6 months of age. Clodronate-liposomes obtained from Dr. N. van Rooijen (Vrije Universiteit, Amsterdam, Netherlands) were intravenously injected into mice twice every week, started in 4 weeks old mice, and continued for 3 months. The dose of clodronate-liposomes was 100µl during the first month and elevated to 150 100µl after that. The depletion efficacy was confirmed by detecting pulmonary macrophages with Flow Cytometry. Depletion of macrophages in these KA/KA-Lori.Ikkα mice could significantly reduce inflammation and prevent lung SCC developmrnt. This aim of this microarray assay is to identify differentially expressed genes among Wild type, KA/KA-Lori.Ikkα, and macophage-depleted KA/KA-Lori.Ikkα mice, which may highlight the important genes or parthways involved in inflammation-associated lung SCC carcinogenesis.

Project description:Depending on the tumor type IκB kinase α (IKKα) can act as tumor promoter or tumor suppressor in various malignancies. Here we demonstrate a key function of IKKα in the suppression of a tumoricidal microenvironment during intestinal carcinogenesis. Mice deficient in IKKα kinase activity are largely protected from intestinal tumor development that is dependent on the enhanced recruitment of IFNγ expressing M1-like myeloid cells. In IKKα mutant mice M1-like polarization is not controlled in a cell autonomous manner but depends rather on the interplay of both IKKα mutant tumor epithelia and immune cells. Tamoxifen-inducible β-catc.a. mice comprise an excellent model to study Wnt-dependent tumor initiation. These mice are characterized by IEC-restricted stabilization of β-catenin causing rapid expansion of intestinal crypts and loss of differentiated IEC. To further explore the underlying IKKα controlled pro-proliferative mechanism, we performed a microarray analysis comparing RNA isolated from wildtype, IkkαAA/AA, β-catc.a. or β-catc.a./IkkαAA/AA IEC 15 days after the first tamoxifen administration. and within 4 weeks β-catc.a. mice succumb to this marked crypt hyperproliferation

Project description:Expression analyses comparing c-Fos expressing keratinocytes vs non-expressing controls. Skin squamous cell carcinomas (SCCs) are the second most prevalent skin cancers. Chronic skin inflammation has been associated with the development of SCCs, but the contribution of skin inflammation to SCC development remains largely unknown. In this study we demonstrate that inducible expression of c-fos in the epidermis of adult mice is sufficient to promote inflammation-mediated epidermal hyperplasia leading to the development of pre-neoplastic lesions. Interestingly, c-Fos transcriptionally controls mmp10 and s100a7a15 expression in keratinocytes subsequently leading to CD4 T cell recruitment to the skin, thereby promoting epidermal hyperplasia. Combining inducible c-fos expression in the epidermis with a single dose of the carcinogen 7,12-Dimethylbenz(a)anthracene (DMBA) leads to the development of highly invasive SCCs, which are prevented by using the anti-inflammatory drug Sulindac. Moreover, human SCCs display a correlation between c-FOS expression and elevated levels of MMP10 and S100A15 proteins as well as CD4 T cell infiltration. Our studies demonstrate a bidirectional crosstalk between pre-malignant keratinocytes and infiltrating CD4 T cells in SCC development. Therefore, targeting inflammation along with the newly identified targets, such as MMP10 and S100A15, represent promising therapeutic strategies to treat SCCs.

Project description:Depending on the tumor type IκB kinase α (IKKα) can act as tumor promoter or tumor suppressor in various malignancies. Here we demonstrate a key function of IKKα in the suppression of a tumoricidal microenvironment during intestinal carcinogenesis. Mice deficient in IKKα kinase activity are largely protected from intestinal tumor development that is dependent on the enhanced recruitment of IFNγ expressing M1-like myeloid cells. In IKKα mutant mice M1-like polarization is not controlled in a cell autonomous manner but depends rather on the interplay of both IKKα mutant tumor epithelia and immune cells.

Project description:In this study, we found that kinase-dead IKKα knockin (KAL) mice. develop spontaneous lung squamous cell carcinomas (SCCs) associated with IKKα downregulation and marked pulmonary inflammation.KKα downregulation dysregulates the expression of multiple oncogenes and tumor suppressors in K5+ lung epithelial cells. The mutant macrophages increase inflammatory responses and oxidative stress to promote DNA damage in IKKα-mutant K5+ lung epithelial cells, which further dysregulate the levels of multiple oncogenes, tumor suppressors, and stem cell genes, thereby promoting the IKKαlowK5+p63hi cell transition to tumor cells in L-IkkαKA/KA lungs. To further investigate the underlying mechanisms by which the lung SCC development, we generated two cell lines, named as S1 and S2 individually, which were derived from KAL lung SCC. The S1 cells express high level of Sca1 and exhibit tumorigenic phenotype, while the S2 cells express low level of Sca1 and exhibit less tumorigenic phenotype. The aim of this microarray assay is to identify differentially expressed genes between S1 and S2 cells, which may highlight the important genes or pathways involved in inflammation-associated lung SCC carcinogenesis.

Project description:Cursons2015 - Regulation of ERK-MAPK signaling in human epidermis Model comparing the abundance of phosphorylated MAPK signalling proteins and calcium signalling in the epidermis. This model is described in the article: Regulation of ERK-MAPK signaling in human epidermis. Cursons J, Gao J, Hurley DG, Print CG, Dunbar PR, Jacobs MD, Crampin EJ. BMC Syst Biol 2015; 9: 41 Abstract: The skin is largely comprised of keratinocytes within the interfollicular epidermis. Over approximately two weeks these cells differentiate and traverse the thickness of the skin. The stage of differentiation is therefore reflected in the positions of cells within the tissue, providing a convenient axis along which to study the signaling events that occur in situ during keratinocyte terminal differentiation, over this extended two-week timescale. The canonical ERK-MAPK signaling cascade (Raf-1, MEK-1/2 and ERK-1/2) has been implicated in controlling diverse cellular behaviors, including proliferation and differentiation. While the molecular interactions involved in signal transduction through this cascade have been well characterized in cell culture experiments, our understanding of how this sequence of events unfolds to determine cell fate within a homeostatic tissue environment has not been fully characterized.We measured the abundance of total and phosphorylated ERK-MAPK signaling proteins within interfollicular keratinocytes in transverse cross-sections of human epidermis using immunofluorescence microscopy. To investigate these data we developed a mathematical model of the signaling cascade using a normalized-Hill differential equation formalism.These data show coordinated variation in the abundance of phosphorylated ERK-MAPK components across the epidermis. Statistical analysis of these data shows that associations between phosphorylated ERK-MAPK components which correspond to canonical molecular interactions are dependent upon spatial position within the epidermis. The model demonstrates that the spatial profile of activation for ERK-MAPK signaling components across the epidermis may be maintained in a cell-autonomous fashion by an underlying spatial gradient in calcium signaling.Our data demonstrate an extended phospho-protein profile of ERK-MAPK signaling cascade components across the epidermis in situ, and statistical associations in these data indicate canonical ERK-MAPK interactions underlie this spatial profile of ERK-MAPK activation. Using mathematical modelling we have demonstrated that spatially varying calcium signaling components across the epidermis may be sufficient to maintain the spatial profile of ERK-MAPK signaling cascade components in a cell-autonomous manner. These findings may have significant implications for the wide range of cancer drugs which therapeutically target ERK-MAPK signaling components. This model is hosted on BioModels Database and identified by: BIOMD0000000659. To cite BioModels Database, please use: Chelliah V et al. BioModels: ten-year anniversary. Nucl. Acids Res. 2015, 43(Database issue):D542-8. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.