Project description:While aneuploidy is found in more than 90% of solid tumors, it is unclear whether aneuploidy is the cause or the consequence of tumorigenesis. Different mouse models deficient in centrosomal or spindle checkpoint proteins that induce aneuploidy show either a promotion or a decrease in tumorigenesis depending on the tissues and the types of oncogenic stimuli. To investigate the effects of aneuploidy in skin development and tumorigenesis, we used Plk4 over-expression (Plk4OE) during epidermal development to assess centrosome amplification and aneuploidy. We found that PLK4OE in the developing epidermis induced centrosome amplification and multipolar divisions, consequently led to p53 stabilization and apoptosis of epidermal progenitors. This delayed epidermal stratification and induced lethal skin barrier defect in 50% of the mice. Plk4 transgene expression was shutdown postnatally in the surviving mice and PLK4OE mice never developed spontaneous skin tumors. Concomitant Plk4OE and P53 deletion (PLK4OE/p53cKO) rescued the defects in differentiation and stratification. Unexpectedly, p53 deletion did not rescue the apoptosis or eventual elimination of the cells overexpressing PLK4 and presenting multiple centrosomes. Remarkably, the short term presence of cells with supernumerary centrosomes postnatally was sufficient to generate aneuploidy and triggered spontaneous skin cancers with complete penetrance. These results reveal for the first time that aneuploidy induced by centrosome amplification, even if transient, can trigger tumorigenesis.

Project description:Hutchinson-Gilford progeria syndrome (HGPS) is the result of a defective form of the lamin A protein called progerin. While progerin is known to disrupt the properties of the nuclear lamina, the underlying mechanisms responsible for the pathophysiology of HGPS remain less clear. Previous studies in our laboratory have shown that progerin expression in murine epidermal basal cells results in impaired stratification and halted development of the skin. Stratification and differentiation of the epidermis is regulated by asymmetric stem cell division. In this dataset, we include the expression data using Affymetrix array. The samples were obtained from basal and suprabasal keratinocyes from 4-day old wild-type and bitransgenic (BT) mice.

Project description:Atopic Dermatitis (AD) is the most common inflammatory skin disease and characterized by a deficient epidermal barrier and cutaneous inflammation. Genetic studies suggest a key role of keratinocytes in AD pathogenesis, but the alterations in the proteome that occur in the entire epidermis have not been defined. Employing a pressure-cycling technology-data-independent acquisition (PCT-DIA) approach, we performed quantitative proteomics of epidermis from healthy volunteers and lesional and non-lesional skin of AD patients. Results were validated by targeted proteomics using parallel reaction monitoring mass spectrometry or by immunofluorescence staining. The identified proteins reflect the strong inflammation in lesional skin and the defect in keratinocyte differentiation and epidermal stratification. Most importantly, they reveal impaired activation of the NRF2-antioxidant pathway and reduced abundance of mitochondrial proteins involved in key metabolic pathways in the epidermis. These results provide insight into the molecular alterations in the epidermis of AD patients and identify novel targets for pharmaceutical intervention.

Project description:Sorting transmembrane cargo is essential for tissue development and homeostasis. However, mechanisms of intracellular trafficking in stratified epidermis are poorly understood. Here we identify an interaction between the retromer endosomal trafficking component, VPS35, and the desmosomal cadherin, Desmoglein-1 (Dsg1). Dsg1 is specifically expressed in stratified epidermis and when properly localized on the plasma membrane of basal keratinocytes, promotes stratification. We show that the retromer drives Dsg1 recycling from the endo-lysosomal system to the plasma membrane to support stratification. The retromer-enhancing chaperone, R55, promotes the membrane localization of Dsg1 and a trafficking-deficient mutant associated with a severe inflammatory skin disorder, enhancing its ability to promote stratification. In the absence of Dsg1, retromer association with and expression of the glucose transporter GLUT1 increases, exposing a potential link between Dsg1 deficiency and epidermal metabolism. Our work provides the first evidence for retromer function in epidermal regeneration, identifying it as a potential therapeutic target.

Project description:Expression of enzymatically inactive caspase-8, or deletion of caspase-8 from basal epidermal keratinocytes, triggers chronic skin inflammation in mice. Unlike similar inflammation resulting from arrest of NF-kB activation in the epidermal cells, the effect induced by caspase-8 deficiency did not depend on TNF, IL1, dermal macrophage function, or expression of the Toll-like receptor adapter proteins MyD88 or TRIF. Both interferon regulatory factor (IRF)3 and TANK-binding kinase were constitutively phosphorylated in the caspase-8-deficient epidermis, and knockdown of IRF3 in the epidermis-derived cells from these mice abolished the expression of upregulated genes. Temporal and spatial analyses of the alterations in gene expression that result from caspase-8 deficiency reveal that the changes are initiated before birth, around the time that cornification develops, and occur mainly in the suprabasal layer. Finally, we found that caspase-8-deficient keratinocytes display an enhanced response to gene activation by transfected DNA. Our findings suggest that an enhanced response to endogenous activators of IRF3 in the epidermis, presumably generated in association with keratinocyte differentiation, contributes to the skin inflammatory process triggered by caspase-8 deficiency. Epidermal keratinocytes were isolated from the skin of Casp-8F/M-bM-^@M-^SK5-Cre or Casp-8F/+K5-Cre mice. Keratinocyte samples from two mice of each genotype were isolated and subsequently cultured. Total RNA was extracted at the first and the third passage of cultivation (8 RNA samples originated in total). The appropriate pairs of RNA samples suited for a direct comparison of the two different genotypes under examination were differently labeled and subsequently co-hybridized onto one microarray (dual color design).

Project description:To characterize the global transcriptome of human keratinocyte stem cells (KSC) and keratinocyte progenitors (KP), primary basal keratinocyte subpopulations enriched in quiescent stem cells [Itg-α6bright / Trf-Rdim] or in cycling progenitors [Itg-α6bright / Trf-Rbright] were purified by flow cytometry from human skin samples. Sorted keratinocytes were then seeded in culture plates and maintained in culture medium overnight (15 hours), and genome-wide transcriptome analysis of these two subpopulations was directly performed, in order to globally maintain the initial phenotypes. After RNA preparation, gene profiling was performed using oligonucleotide microarrays (26068 probes). LOWESS normalisation was applied. Keywords: epidermis, keratinocyte stem cells, progenitors, transcriptome, stemness

Project description:Epidermal keratinocytes are key for maintenance of the integrity of the epidermis. One of the main drivers of keratinocyte differentiation is the calcium gradient; calcium concentration gradually increases towards the outer layers of the epidermis. Atopic dermatitis (AD) is a disorder associated with a chronic inflammatory state and a compromised epidermal barrier. Keratinocytes secrete lipid-rich small extracellular vesicles (sEVs) that acts as mediators of both local and long-distance signaling.

Project description:Skin homeostasis is guided by spatiotemporal regulation of gene expression, establishing each stage of keratinocyte differentiation. The current study presents transcriptomic and chromatin profiling for the proliferating (basal) and differentiated (suprabasal) cell populations derived from neonate mice (p0-p2) skin epidermis. This multi-omic approach will enable idenitification of cell specific epidermal cross-talk central to the equlibirum.

Project description:Skin homeostasis is guided by spatiotemporal regulation of gene expression, establishing each stage of keratinocyte differentiation. The current study presents transcriptomic and chromatin profiling for the proliferating (basal) and differentiated (suprabasal) cell populations derived from neonate mice (p0-p2) skin epidermis. This multi-omic approach will enable idenitification of cell specific epidermal cross-talk central to the equlibirum.

Project description:Skin homeostasis is guided by spatiotemporal regulation of gene expression, establishing each stage of keratinocyte differentiation. The current study presents transcriptomic and chromatin profiling for the proliferating (basal) and differentiated (suprabasal) cell populations derived from neonate mice (p0-p2) skin epidermis. This multi-omic approach will enable idenitification of cell specific epidermal cross-talk central to the equlibirum.