Isolation, culture and identification of epidermal stem cells from newborn mouse skin

In healthy individuals, skin integrity is maintained by epidermal stem cells which self-renew and generate daughter cells that undergo terminal differentiation. Epidermal stem cells represent a promising source of stem cells, and their culture has great potential in scientific research and clinical application. However, no single method has been universally adopted for identifying and isolating epidermal stem cells. Here, we reported the isolation and characterization of putative epidermal stem cells from newborn mouse skin. The keratinocytes were separated enzymatically. Putative epidermal stem cells were selected by rapid adherence on a composite matrix made of type I collagen and fibronectin. Unattached cells were discarded after 10 min, and the attached cells were cultured in a defined culture medium. The isolated cells showed the typical epidermal stem cell morphology. Immunofluorescence indicated that the cells were strongly stained for β₁ integrin family of extracellular matrix receptors. In conclusion, mouse putative epidermal stem cells were successfully isolated from newborn mouse epidermis on the basis of high rapid adhesion to extracellular matrix proteins and cultured in vitro.     

Role of melanoma chondroitin sulphate proteoglycan in patterning stem cells in human interfollicular epidermis

Human interfollicular epidermis is renewed by stem cells that are clustered in the basal layer in a patterned, non-random distribution. Stem cells can be distinguished from other keratinocytes by high expression of beta1 integrins and lack of expression of terminal differentiation markers; they divide infrequently in vivo but form actively growing colonies in culture. In a search for additional stem cell markers, we observed heterogeneous epidermal expression of melanoma chondroitin sulphate proteoglycan (MCSP). MCSP was expressed by those keratinocytes with the highest beta1 integrin levels. In interfollicular epidermis, expression was confined to non-cycling cells and, in culture, to self-renewing clones. However, fluorescence-activated cell sorting on the basis of MCSP and beta1 integrin expression gave no more enrichment for clonogenic keratinocytes than sorting for beta1 integrins alone. To interfere with endogenous MCSP, we retrovirally infected keratinocytes with a chimera of the CD8 extracellular domain and the MCSP cytoplasmic domain. CD8/MCSP did not affect keratinocyte proliferation or differentiation but the cohesiveness of keratinocytes in isolated clones or reconstituted epidermal sheets was greatly reduced. CD8/MCSP caused stem cell progeny to scatter without differentiating. CD8/MCSP did not alter keratinocyte motility but disturbed cadherin-mediated cell-cell adhesion and the cortical actin cytoskeleton, effects that could be mimicked by inhibiting Rho. We conclude that MCSP is a novel marker for epidermal stem cells that contributes to their patterned distribution by promoting stem cell clustering.     

The effect of low temperatures on the viability of human epidermal keratinocytes found at different stages of differentiation

The aim of this study was a comparative analysis to the degree of stability of human epidermal cells found at different stages of differentiation to low temperatures. The effect of different subzero temperatures of liquid nitrogen vapor on keratinocytes found both in human skin fragments and as isolated cells extracted from skin fragments has been studied. The degree of stability of epidermal cells low temperatures was evaluated by their ability to form a multilayer stratum in culture; hence this phenomenon explains the survival of a sufficient amount of proliferative cells after exposure to subzero temperatures. Quantitative analysis of the ratio of epidermal stem, transitory and differentiated cells in a population of viable cells before and after exposure to low temperatures were determined using antibodies corresponding to their different stages of differentiation. The results of this research show that the stability of human epidermal cells to low temperature differs depending on their stage of differentiation both in situ and in vitro. Epidermal stem cells and transitory cells are more stable than differentiated cells.     

Enrichment and characterization of mouse putative epidermal stem cells

Epidermis, a continuously renewing tissue, is maintained by stem cells that proliferate and replenish worn out or damaged cells in the tissue during life. Cultured epidermal stem cells have great potential in scientific research and clinical application. However, isolating a pure and viable population of epidermal stem cells and culturing them has been challenging. In this study, putative epidermal stem cells of mouse were isolated by combining Hoechst 33342 and propidium iodide staining with fluorescence-activated cell sorting. Molecular markers expression pattern analysis showed that cytokeratin 14, integrin beta1 and p63 are expressed in the sorted putative stem cells, but not active beta-catenin, nestin and involucrin. Our results provide further supporting data that mouse putative epidermal stem cells could be successfully isolated by combining Hoechst dye staining with fluorescence-activated cell sorting and cultured in vitro. The cultured mouse putative epidermal stem cells could be used as a potent tool for studying stem cell biology and testing stem cell therapy.     

Structure of Pumilio reveals similarity between RNA and peptide binding motifs

Translation regulation plays an essential role in the differentiation and development of animal cells. One well-studied case is the control of hunchback mRNA during early Drosophila embryogenesis by the trans-acting factors Pumilio, Nanos, and Brain Tumor. We report here a crystal structure of the critical region of Pumilio, the Puf domain, that organizes a multivalent repression complex on the 3' untranslated region of hunchback mRNA. The structure reveals an extended, rainbow shaped molecule, with tandem helical repeats that bear unexpected resemblance to the armadillo repeats in beta-catenin and the HEAT repeats in protein phosphatase 2A. Based on the structure and genetic experiments, we identify putative interaction surfaces for hunchback mRNA and the cofactors Nanos and Brain Tumor. This analysis suggests that similar features in helical repeat proteins are used to bind extended peptides and RNA.     

Smad7-induced beta-catenin degradation alters epidermal appendage development

To assess whether Smad signaling affects skin development, we generated transgenic mice in which a Smad antagonist, Smad7, was induced in keratinocytes, including epidermal stem cells. Smad7 transgene induction perturbed hair follicle morphogenesis and differentiation, but accelerated sebaceous gland morphogenesis. Further analysis revealed that independent of its role in anti-Smad signaling, Smad7 bound beta-catenin and induced beta-catenin degradation by recruiting an E3 ligase, Smurf2, to the Smad7/beta-catenin complex. Consequently, Wnt/beta-catenin signaling was suppressed in Smad7 transgenic hair follicles. Coexpression of the Smurf2 and Smad7 transgenes exacerbated Smad7-induced abnormalities in hair follicles and sebaceous glands. Conversely, when endogenous Smad7 was knocked down, keratinocytes exhibited increased beta-catenin protein and enhanced Wnt signaling. Our data reveal a mechanism for Smad7 in antagonizing Wnt/beta-catenin signaling, thereby shifting the skin differentiation program from forming hair follicles to sebaceous glands.     

Epidermal Stem Cells

Epidermis contains a compartment of stem cells but currently there is no common criterion to recognize individual stem cells with any confidence. Epidermis appears to contain stem cells of different levels of maturity and it is very likely that the main repository of epidermal stem cells is located in the hair follicle from which cells can emigrate into epidermis and also give rise to follicular and sebaceous keratinocytes. Epidermis consists of proliferative units containing stem and transit-amplifying cells, but the exact size of a proliferative unit cannot be measured accurately. The available data suggest that populations of stem and transit-amplifying cells are not discrete but represent a continuum from cells with a high self-renewal capacity and a low probability of differentiation to those with low self-renewal capacities and high commitments to differentiation. Stem cells occupy a special niche that provides a microenvironment, including an adhesion of stem cells to the basal membrane and their paracrine interactions with neighbor epidermal and mesenchymal cells. The fate of an epidermal stem cell depends on its prehistory and microenvironment.     

Stem cell-like properties of human umbilical cord lining epithelial cells and the potential for epidermal reconstitution

Background aimsStem cells are particularly attractive for many cell-based therapeutic interventions because of their ability to self-renew and their capacity to differentiate into site-specific differentiating cells. Restoration of the integrity of epithelial continuity is an essential aspect of wound repair and tissue regeneration. We are currently looking at the potential of human umbilical cord lining cells as a source of epithelial stem cells with appropriate differentiation capacity for potential epidermal reconstitution.MethodsWe isolated human umbilical cord lining epithelial cells (CLEC) and characterized their phenotype from the perspective of proliferative potential, telomere length, expression of epidermal differentiation markers, as well as stem cell-specific markers, and clonogenicity. Their potential for epidermal reconstitution was investigated in an organotypic culture model.ResultsThe results demonstrated that CLEC present a long telomere length and have a relatively high proliferative potential and passaging ability in culture. CLEC display some of the stem cell-specific markers for epithelial as well as pluripotent stem cells, including CK19, p63, OCT-4, SSEA-4, TRA-1–60, SOX2 and Nanog. CLEC are capable of generating a fully stratified epithelium in organotypic culture.ConclusionsThe potential of CLEC to be used in clinical applications for specialized epithelial reconstruction is still unexplored. The demonstration that CLEC have stem cell-like properties and are capable of generating fully stratified epithelium provides support for their potential clinical application in epidermal reconstitution.     

Stathmokinetic Analysis of Human Epidermal Cells in vitro

Proliferation kinetics of cultured human epidermal cells is characterized in quantitative terms. Three distinct subpopulations of keratinocytes, two of which are cycling have been discriminated by two parameter DNA/RNA flow cytometry. Based on mathematical modelling, the cell cycle parameters of the cycling subpopulations have been assessed from stathmokinetic data collected at different time points after initiation of cultures (7–15 days). the first subpopulation is composed of low-RNA cells which resemble basal keratinocytes of epidermis and which show some characteristics of stem cells; these cells have a mean generation time of approximately 100 hr. the second subpopulation consists of high-RNA cells, resembling stratum spinosum cells of epidermis, which have an average generation time of approximately 40 hr. the third subpopulation consists of non-cycling cells with G_o/G₁ DNA content, with cytochemical features similar to those of cells in granular layer of epidermis. The results based on modelling can reproduce with acceptable accuracy the actual growth curve of the cultured cell population. Analysis of kinetics and differentiation of human keratinocytes is of interest in view of the recent application of cultured epidermal cell sheets for transplantation onto burn wounds. the results of this study also reveal the existence of regulatory mechanisms associated with proliferation and differentiation in the cultured epidermal cell population.     

Location and clonal analysis of stem cells and their differentiated progeny in the human ocular surface.

We have analyzed the proliferative and differentiation potential of human ocular keratinocytes. Holoclones, meroclones, and paraclones, previously identified in skin, constitute also the proliferative compartment of the ocular epithelium. Ocular holoclones have the expected properties of stem cells, while transient amplifying cells have variable proliferative potential. Corneal stem cells are segregated in the limbus, while conjunctival stem cells are uniformly distributed in bulbar and forniceal conjunctiva. Conjunctival keratinocytes and goblet cells derive from a common bipotent progenitor. Goblet cells were found in cultures of transient amplifying cells, suggesting that commitment for goblet cell differentiation can occur late in the life of a single conjunctival clone. We found that conjunctival keratinocytes with high proliferative capacity give rise to goblet cells at least twice in their life and, more importantly, at rather precise times of their life history, namely at 45-50 cell doublings and at approximately 15 cell doublings before senescence. Thus, the decision of conjunctival keratinocytes to differentiate into goblet cells appears to be dependent upon an intrinsic "cell doubling clock. " These data open new perspectives in the surgical treatment of severe defects of the anterior ocular surface with autologous cultured conjunctival epithelium.     

Axin, a negative regulator of the Wnt signaling pathway, forms a complex with GSK-3beta and beta-catenin and promotes GSK-3beta-dependent phosphorylation of beta-catenin.

Glycogen synthase kinase-3 (GSK-3) mediates epidermal growth factor, insulin and Wnt signals to various downstream events such as glycogen metabolism, gene expression, proliferation and differentiation. We have isolated here a GSK-3beta-interacting protein from a rat brain cDNA library using a yeast two-hybrid method. This protein consists of 832 amino acids and possesses Regulators of G protein Signaling (RGS) and dishevelled (Dsh) homologous domains in its N- and C-terminal regions, respectively. The predicted amino acid sequence of this GSK-3beta-interacting protein shows 94% identity with mouse Axin, which recently has been identified as a negative regulator of the Wnt signaling pathway; therefore, we termed this protein rAxin (rat Axin). rAxin interacted directly with, and was phosphorylated by, GSK-3beta. rAxin also interacted directly with the armadillo repeats of beta-catenin. The binding site of rAxin for GSK-3beta was distinct from the beta-catenin-binding site, and these three proteins formed a ternary complex. Furthermore, rAxin promoted GSK-3beta-dependent phosphorylation of beta-catenin. These results suggest that rAxin negatively regulates the Wnt signaling pathway by interacting with GSK-3beta and beta-catenin and mediating the signal from GSK-3beta to beta-catenin.     

Low electromagnetic field (50 Hz) induces differentiation on primary human oral keratinocytes (HOK)

This work concerns the effect of low frequency electromagnetic fields (ELF) on biochemical properties of human oral keratinocytes (HOK). Cells exposed to a 2 mT, 50 Hz, magnetic field, showed by scanning electron microscopy (SEM) modification in shape and morphology; these modifications were also associated with different actin distribution, revealed by phalloidin fluorescence analysis. Moreover, exposed cells had a smaller clonogenic capacity, and decreased cellular growth. Indirect immunofluorescence with fluorescent antibodies against involucrin and beta-catenin, both differentiation and adhesion markers, revealed an increase in involucrin and beta-catenin expression. The advance in differentiation was confirmed by a decrease of expression of epidermal growth factor (EGF) receptor in exposed cells, supporting the idea that exposure to electromagnetic field carries keratinocytes to higher differentiation level. These observations support the hypothesis that 50 Hz electromagnetic fields may modify cell morphology and interfere in differentiation and cellular adhesion of normal keratinocytes.     

Effect of cooling to low temperatures on viability of human skin keratinocytes at different stages of differentiation

The goal of this study was to conduct a comparative analysis of the degree of resistance to low temperatures of human epidermal cells found at different stages of differentiation. The action of liquid-nitrogen vapors was analyzed in experiments in vitro at various temperature regimes on fragments of the human integral skin and on isolated from them and cultivated keratinocytes. The degree of resistance of keratinocytes to the action of cooling to low temperatures was evaluated by their ability to form a multilayer stratum in culture, which indicates the preservation of the viability of the cells treated with cold. This approach allowed one to reveal the diapason of optimal regimes of the action of low temperatures on cells in the composition of tissue and after their conversion into culture. The quantitative ratios of the epidermal stem, transitory, and differentiated cells in a population of viable cells before and after exposure to low temperatures were determined with antibodies that correspond to their different stages of differentiation. The degree of resistance of keratinocytes to action of cooling to low temperatures was evaluated by their ability to form a multilayer stratum in culture, which indicates preservation of viability of the cells treated with cold. The results of this study show that the resistance of human epidermal cells to low temperature differs depending on their stage of differentiation both in situ and in vitro. The epidermal stem and transitory cells are more stable than the differentiated cells.     

Wingless signaling regulates the maintenance of ovarian somatic stem cells in Drosophila

Identifying the signals involved in maintaining stem cells is critical to understanding stem cell biology and to using stem cells in future regenerative medicine. In the Drosophila ovary, Hedgehog is the only known signal for maintaining somatic stem cells (SSCs). Here we report that Wingless (Wg) signaling is also essential for SSC maintenance in the Drosophila ovary. Wg is expressed in terminal filament and cap cells, a few cells away from SSCs. Downregulation of Wg signaling in SSCs through removal of positive regulators of Wg signaling, dishevelled and armadillo, results in rapid SSC loss. Constitutive Wg signaling in SSCs through the removal of its negative regulators, Axin and shaggy, also causes SSC loss. Also, constitutive wg signaling causes over-proliferation and abnormal differentiation of somatic follicle cells. This work demonstrates that wg signaling regulates SSC maintenance and that its constitutive signaling influences follicle cell proliferation and differentiation. In mammals, constitutive beta-catenin causes over-proliferation and abnormal differentiation of skin cells, resulting in skin cancer formation. Possibly, mechanisms regulating proliferation and differentiation of epithelial cells, including epithelial stem cells, is conserved from Drosophila to man.