Project description:Millions suffer from skin diseases. Functional epidermal stem cells are needed in skin therapy or drug screening in vitro. We obtained functional epidermal stem cells with intact stemness and cell junctions by treating them with wnt3a. Moreover, epidermal stem cell-derived exosomes were useful in epidermal development. Finally, functional epidermal 3D organoids with polarity were cultured using wnt3a and the supernatant derived from epidermal stem cells and fresh medium in a 1:1 ratio. These results provide novel directions for the improvement of skin organoids and their potential in clinical application.

Project description:Despite the strong need for the large-scale generation of human epidermal cells for cell therapy of extensive and severe skin injury, tissue-engineered skin construction and dermatological investigation, the effectiveness of current culture methods is limited and have yet to meet the huge demands sufficiently. Here, we report the establishment of a simple and robust 3D culture system using chemical defined, serum-free medium supplemented with small molecules and growth factors, tailored for human epidermal organoids generation and expansion. The conditions allowed 10,000-fold expansion of the primary epidermal cells within 6 weeks, with the cell architecture and gene expression preserved. We further noticed that only Integrin α6-positive basal stem cells freshly isolated from human epidermis could form expandable epidermal organoids. The epidermal cells inside of the organoids also have the potential to reconstruct multi-layered human epidermis equivalents under classical air-liquid interface condition. Remarkably, the epidermal organoids enable to model the anthropophilic and epidermis-restricted Trichophyton Rubrum infection. This model faithfully mimics and reflects the clinical pathological reactions of reinforced physical barrier by promoting keratinocytes differentiation and accelerated formation of the stratum corneum for adaptation and resistance to infection. Furthermore, the infection model also suggested that constraining host IL-1 signaling may underline the high degree of adaptation of Trichophyton Rubrum to human skin, and the tendency to be chronic and recurrent infection. Thus, human epidermal organoids present a powerful platform for modeling human dermatology, skin tissue engineering and cell therapy.

Project description:In the project “A Dual-Acting Nitric Oxide Donor and Phosphodiesterase 5 Inhibitor Activates Autophagy in Primary Skin Fibroblasts» by Esther Martínez-Martínez and Joern Dengjel, we performed expression proteomics analyzing the response of normal human fibroblasts (NHF) isolated from healthy skin to the drug TOP-N53.

Project description:There is increasing evidence that autophagy contributes to the epidermal differentiation; however, the role of autophagy in epidermal tight junction (TJ) barrier remains unclear. To evaluate the role of autophagy in the maintenance of skin TJ barrier, we knocked out autophagy in human primary keratinocytes by infecting cells with autophagy-related gene 3 (Atg3) C264S mutant adenovirus.

Project description:The formation of tissue patterns is critical for organ functions in development and regeneration. To advance the use of organoids for organ regeneration, we learn principles that govern the skin organoids to regenerate hairs. We show the formation of epidermal-dermal coupled cysts function as competent morphogenetic units (CMU) which harbor the ability of skin organoids to regenerate. ScRNA-sequencing shows the emergence of cell types and new cell interactions during CMU formation. In newborn skin organoids, epidermal cells undergo apical-basal polarization via the IFNr-PKR-PKC signaling module. Dermal-Tgfb regulates Gsk3 to establish basement membranes between the epidermal cyst and dermal cells. Meanwhile, VEGF signaling mediates dermal cell attachment to the cyst. Adult cells cannot form organoids but can be induced to generate CMUs and regenerate hairs by adding IFNr or VEGF. We compare the similar principles and different paths used to establish morphogenetic competency in developing skin, wound-induced hair neogenesis, and organoids.

Project description:Extracellular vesicle(EV) secretion and capture is an important method of communication between cells. Melanocytes and their surrounding keratinocytes form epidermal melanin units in the thin, outermost layer of the skin to protect the skin from ultraviolet radiation damage. It is important to understand the mechanisms by which changes in melanocyte EV signal transduction influence pigmentation. EVs from melanocytes were extracted and used to investigate changes in the miRNA profile of EVs, and the effect of exosomal miR-28-3p on keratinocyte with transcriptomics was analyzed by RNA-seq analysis.Our results indicate that the content of miR-28 in EVs may be reduced to induce keratinocytes to prevent carcinogenesis, resist infection and prevent premature apoptosis.

Project description:Hair follicle formation depends on reciprocal epidermal-dermal interactions and occurs during skin development, but not in adult life. This suggests that the properties of dermal fibroblasts change during postnatal development. To examine this, we used a PdgfraEGFP mouse line to isolate GFP-positive fibroblasts from neonatal skin, adult telogen and anagen skin and adult skin in which ectopic hair follicles had been induced (EF skin) by transgenic epidermal activation of beta-catenin. We also isolated epidermal cells from each mouse. The gene expression profile of EF epidermis was most similar to that of anagen epidermis, consistent with activation of beta-catenin signalling. In contrast, adult dermis with ectopic hair follicles more closely resembled neonatal dermis than adult telogen or anagen dermis. In particular, genes associated with mitosis were upregulated and extracellular matrix-associated genes were downregulated in neonatal and EF fibroblasts. We confirmed that sustained epidermal beta-catenin activation stimulated fibroblasts to proliferate to reach the high cell density of neonatal skin. In addition, the extracellular matrix was comprehensively remodelled, with mature collagen being replaced by collagen subtypes normally present only in developing skin. The changes in proliferation and extracellular matrix composition originated from a specific subpopulation of fibroblasts located beneath the sebaceous gland. Our results show that adult dermis is an unexpectedly plastic tissue that can be reprogrammed to acquire the molecular, cellular and structural characteristics of neonatal dermis in response to cues from the overlying epidermis. We have isolated the following populations of cells from mouse back skin by flow cytometry: 1A) GFP+ WT neonatal dermal fibroblasts, 1B) ItgA6+ WT neonatal epidermal keratinocytes, 2A) GFP+ WT telogen dermal fibroblasts, 2B) ItgA6+ WT telogen epidermal keratinocytes, 3A) GFP+ D2 transient activation (anagen) dermal fibroblasts, 3B) ItgA6+ D2 transient activation (anagen) epidermal keratinocytes, 4A) GFP+ D2 sustained activation (ectopic follicles) dermal fibroblasts, 4B) ItgA6+ D2 sustained activation (ectopic follicles) epidermal keratinocytes

Project description:We analyze the effect of magnetic 3D bioprinting using NanoShuttle-PL on the proteome of primary human skin fibroblasts and epidermal squamous cell carcinoma cells. NanoStuttle-PL employs magnetic nanoparticles that interact electrostatically with cells rendering them magnetic and allowing manipulation of their 3D assembly using external magnetic forces.

Project description:Hair follicle formation depends on reciprocal epidermal-dermal interactions and occurs during skin development, but not in adult life. This suggests that the properties of dermal fibroblasts change during postnatal development. To examine this, we used a PdgfraEGFP mouse line to isolate GFP-positive fibroblasts from neonatal skin, adult telogen and anagen skin and adult skin in which ectopic hair follicles had been induced (EF skin) by transgenic epidermal activation of beta-catenin. We also isolated epidermal cells from each mouse. The gene expression profile of EF epidermis was most similar to that of anagen epidermis, consistent with activation of beta-catenin signalling. In contrast, adult dermis with ectopic hair follicles more closely resembled neonatal dermis than adult telogen or anagen dermis. In particular, genes associated with mitosis were upregulated and extracellular matrix-associated genes were downregulated in neonatal and EF fibroblasts. We confirmed that sustained epidermal beta-catenin activation stimulated fibroblasts to proliferate to reach the high cell density of neonatal skin. In addition, the extracellular matrix was comprehensively remodelled, with mature collagen being replaced by collagen subtypes normally present only in developing skin. The changes in proliferation and extracellular matrix composition originated from a specific subpopulation of fibroblasts located beneath the sebaceous gland. Our results show that adult dermis is an unexpectedly plastic tissue that can be reprogrammed to acquire the molecular, cellular and structural characteristics of neonatal dermis in response to cues from the overlying epidermis.

Project description:Mammalian epidermal stem cells maintain homeostasis of skin epidermis and contribute to its regeneration throughout adult life. While two-dimensional mouse epidermal stem cell cultures have been established decades ago, a long-term, feeder cell- and serum-free culture system recapitulating murine epidermal architecture has not been available. Here we describe an epidermal organoid culture system that allows long-term, genetically stable expansion of adult epidermal stem cells. Our epidermal expansion media combines atypically high calcium concentrations, activation of cyclic AMP, FGF and R-spondin signaling with inhibition of BMP signaling. Organoids are established robustly from adult mouse skin and expand over at least 6 months, while maintaining the basal-apical organization of the mouse interfollicular epidermis. The system represents a powerful tool to study epidermal homeostasis and disease in vitro.