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.     

Derivation of keratinocyte progenitor cells and skin formation from embryonic stem cells

Despite numerous elegant transgenic mice experiments, the absence of an appropriate in vitro model system has hampered the study of the early events responsible for epidermal and dermal commitments. Embryonic stem (ES) cells are derived from the pluripotent cells of the early mouse embryo. They can be expanded infinitely in vitro while maintaining their potential to spontaneously differentiate into any cell type of the three germ layers, including epidermal cells. We recently reported that ES cells have the potential to recapitulate the reciprocal instructive ectodermal-mesodermal commitments, which are characteristic of embryonic skin formation. Derivation of epidermal cells from murine ES cells has been successfully established by exposing the cells to precisely controlled instructive influences normally found in the body, including extracellular matrix and the morphogen BMP-4. These differentiated ES cells are able to form, in culture, a multilayered epidermis coupled with an underlying dermal compartment similar to native skin. This bioengineered skin provides a powerful tool for studying the molecular mechanisms controlling skin development and epidermal stem cell properties.     

Glycome profiling by lectin microarray reveals dynamic glycan alterations during epidermal stem cell aging

Aging in the epidermis is marked by a gradual decline in barrier function, impaired wound healing, hair loss, and an increased risk of cancer. This could be due to age‐related changes in the properties of epidermal stem cells and defective interactions with their microenvironment. Currently, no biochemical tools are available to detect and evaluate the aging of epidermal stem cells. The cellular glycosylation is involved in cell–cell communications and cell–matrix adhesions in various physiological and pathological conditions. Here, we explored the changes of glycans in epidermal stem cells as a potential biomarker of aging. Using lectin microarray, we performed a comprehensive glycan profiling of freshly isolated epidermal stem cells from young and old mouse skin. Epidermal stem cells exhibited a significant difference in glycan profiles between young and old mice. In particular, the binding of a mannose‐binder rHeltuba was decreased in old epidermal stem cells, whereas that of an α2‐3Sia‐binder rGal8N increased. These glycan changes were accompanied by upregulation of sialyltransferase, St3gal2 and St6gal1 and mannosidase Man1a genes in old epidermal stem cells. The modification of cell surface glycans by overexpressing these glycogenes leads to a defect in the regenerative ability of epidermal stem cells in culture. Hence, our study suggests the age‐related global alterations in cellular glycosylation patterns and its potential contribution to the stem cell function. These glycan modifications detected by lectins may serve as molecular markers for aging, and further functional studies will lead us to a better understanding of the process of skin aging.     

Extracellular matrix from normal but not Steel mutant mice enhances melanogenesis in cultured mouse neural crest cells

The Steel mutation is a non-cell-autonomous defect in mice that affects the development of several stem cell populations, including germ cells, hematopoietic cells, and neural crest-derived pigment cells. To characterize the environmental lesion caused by the Steel mutation, we have compared the ability of normal and mutant extracellular matrix material to support the differentiation of normal mouse neural crest cells in vitro. Extracellular matrix deposited by cultured skin cells isolated from normal fetuses enhanced melanogenesis by crest cells over that observed on plastic substrata. In contrast, matrix material produced by Steel-Dickie (Sld) fetal skin cells failed to enhance melanogenesis. Adrenergic differentiation by neural crest-derived cells was promoted equally by both normal and mutant extracellular matrix compared to control substrata. We conclude that the environmental defect in mutant embryos selectively affects a melanogenic subpopulation of neural crest cells and resides, at least in part, in the extracellular matrix.     

Dedifferentiation derived cells exhibit phenotypic and functional characteristics of epidermal stem cells

Differentiated epidermal cells can dedifferentiate into stem cells or stem cell‐like cells in vivo. In this study, we report the isolation and characterization of dedifferentiation‐derived cells. Epidermal sheets eliminated of basal stem cells were transplanted onto the skin wounds in 47 nude athymic (BALB/c‐nu/nu) mice. After 5 days, cells negative for CK10 but positive for CK19 and β₁‐integrin emerged at the wound‐neighbouring side of the epidermal sheets. Furthermore, the percentages of CK19 and β₁‐integrin⁺ cells detected by flow cytometric analysis were increased after grafting (P < 0.01) and CK10⁺ cells in grafted sheets decreased (P < 0.01). Then we isolated these cells on the basis of rapid adhesion to type IV collagen and found that there were 4.56% adhering cells (dedifferentiation‐derived cells) in the grafting group within 10 min. The in vitro phenotypic assays showed that the expressions of CK19, β₁‐integrin, Oct4 and Nanog in dedifferentiation‐derived cells were remarkably higher than those in the control group (differentiated epidermal cells) (P < 0.01). In addition, the results of the functional investigation of dedifferentiation‐derived cells demonstrated: (1) the numbers of colonies consisting of 5–10 cells and greater than 10 cells were increased 5.9‐fold and 6.7‐fold, respectively, as compared with that in the control (P < 0.01); (2) more cells were in S phase and G2/M phase of the cell cycle (proliferation index values were 21.02% in control group, 45.08% in group of dedifferentiation); (3) the total days of culture (28 days versus 130 days), the passage number of cells (3 passages versus 20 passages) and assumptive total cell output (1 × 10⁵ cells versus 1 × 10¹² cells) were all significantly increased and (4) dedifferentiation‐derived cells, as well as epidermal stem cells, were capable of regenerating a skin equivalent, but differentiated epidermal cells could not. These results suggested that the characteristics of dedifferentiation‐derived cells cultured in vitro were similar to epidermal stem cells. This study may also offer a new approach to yield epidermal stem cells for wound repair and regeneration.     

Putative epidermal stem cell convert into corneal epithelium-like cell under corneal tissue <Emphasis Type="Italic">in vitro</Emphasis>

Rhesus putative epidermal stem cells are being investigated for their potential use in regenerative corneal epithelium-like cells, which may provide a practical source of autologous seed cells for the construction of bioengineered corneas. The goal of this study was to investigate the potential of epidermal stem cells for trans-differentiation into corneal epithelium-like cells. Rhesus putative epidermal stem cells were isolated by type IV collagen attachment method. Flow cytometry analysis, immunohistology and RT-PCR were conducted to identify the expression of specific markers (β1m α6 integrin, K15, K1/K10, K3/K12 and CD71) on the isolated rapid attaching cells. The isolated cells were cocultured with human corneal limbal stroma and corneal epithelial cells. After coculture, the expression of the same specific markers was evaluated in order to identify expression difference caused by the coculture conditions. K3/K12 expression was analyzed in coculture cells on day 2, 4, 6, 8 and 10. Putative epidermal stem cells in conditioned culture media were used as control. Putative epidermal stem cells were predominant in rapid attaching cells by type IV collagen attachment isolation. Before being cocultured, the rhesus putative epidermal stem cells expressed K15, α6 and β1 integrin, but no CD71, K1/K10 and K3/K12. After coculture, these cells expressed K3/K12 (a marker of corneal epithelial cells), K15 and β1 integrin, but no K1/K10. Cells being not coculture converted into terminally differentiated cells expressing K1/K10. These results indicate that rhesus putative epidermal stem cells can trans-differentiate into corneal epithelium-like cells and, therefore, may have potential therapeutic application as autologous seed cells for the construction of bioengineered corneas.     

Enrichment of epidermal stem cells by rapid adherence and analysis of the reciprocal interaction of epidermal stem cells with neighboring cells using an organotypic system

Keratinocytes have the ability to adhere to extracellular matrix rapidly. With this in mind, in this study we isolated keratinocytes known as rapidly adhering (RA) cells. To compare epidermal regenerative abilities, skin substitutes were reconstructed by adding keratinocytes or RA cells to two groups of bioengineered dermis made by fibroblasts and hair follicle dermal cells respectively. After transplantation, the results illustrated that the skin substitutes including RA cells were integrated into the host tissue. Furthermore, with hair follicle dermal cells' influences, the RA cells could form structures very similar to normal hair follicles. These results indicate that RA cells are predominately comprised of epidermal stem cells. The results also demonstrated that besides the reciprocal interaction of epidermal stem cells with dermal cells, the interaction of epidermal stem cells with keratinocytes were critical in epidermis morphogenesis and self-renewal, and application of RA cells could optimize engineering of skin substitutes.     

Ultrastructural and immunocytochemical detection of keratins and extracellular matrix proteins in lizard skin cultured in vitro

The present study shows the localization of epidermal and dermal proteins produced in lizard skin cultivated in vitro. Cells from the skin have been cultured for up to one month to detect the expression of keratins, actin, vimentin and extracellular matrix proteins (fibronectin, chondroitin sulphate proteoglycan, elastin and collagen I). Keratinocytes and dermal cells weakly immunoreact for Pan-Cytokeratin but not with the K17-antibody at the beginning of the cell culture when numerous keratin bundles are present in keratinocyte cytoplasm. The dense keratin network disappears after 7-12 days in culture, and K17 becomes detectable in both keratinocytes and mesenchymal cells isolated from the dermis. While most epidermal cells are lost after 2 weeks of in vitro cultivation dermal cells proliferate and form a pellicle of variable thickness made of 3-8 cell layers. The fibroblasts of this dermal equivalent produces an extracellular matrix containing chondroitin sulphate proteoglycan, collagen I, elastic fibers and fibronectin, explaining the attachment of the pellicle to the substratum. The study indicates that after improving keratinocyte survival a skin equivalent for lizard epidermis would be feasible as a useful tool to analyze the influence of the dermis on the process of epidermal differentiation and the control of the shedding cycle in squamates.     

NASA-approved rotary bioreactor enhances proliferation of human epidermal stem cells and supports formation of 3D epidermis-like structure

The skin is susceptible to different injuries and diseases. One major obstacle in skin tissue engineering is how to develop functional three-dimensional (3D) substitute for damaged skin. Previous studies have proved a 3D dynamic simulated microgravity (SMG) culture system as a "stimulatory" environment for the proliferation and differentiation of stem cells. Here, we employed the NASA-approved rotary bioreactor to investigate the proliferation and differentiation of human epidermal stem cells (hEpSCs). hEpSCs were isolated from children foreskins and enriched by collecting epidermal stem cell colonies. Cytodex-3 micro-carriers and hEpSCs were co-cultured in the rotary bioreactor and 6-well dish for 15 days. The result showed that hEpSCs cultured in rotary bioreactor exhibited enhanced proliferation and viability surpassing those cultured in static conditions. Additionally, immunostaining analysis confirmed higher percentage of ki67 positive cells in rotary bioreactor compared with the static culture. In contrast, comparing with static culture, cells in the rotary bioreactor displayed a low expression of involucrin at day 10. Histological analysis revealed that cells cultured in rotary bioreactor aggregated on the micro-carriers and formed multilayer 3D epidermis structures. In conclusion, our research suggests that NASA-approved rotary bioreactor can support the proliferation of hEpSCs and provide a strategy to form multilayer epidermis structure.     

Putative epidermal stem cell convert into corneal epithelium-like cell under corneal tissue in vitro

Rhesus putative epidermal stem cells are being investigated for their potential use in regenerative corneal epithelium-like cells, which may provide a practical source of autologous seed cells for the construction of bioengineered corneas. The goal of this study was to investigate the potential of epidermal stem cells for trans-differentiation into corneal epithelium-like cells. Rhesus putative epidermal stem cells were isolated by type IV collagen attachment method. Flow cytometry analysis, immunohistology and RT-PCR were conducted to identify the expression of specific markers (β1m α6 integrin, K15, K1/K10, K3/K12 and CD71) on the isolated rapid attaching cells. The isolated cells were cocultured with human corneal limbal stroma and corneal epithelial cells. After coculture, the expression of the same specific markers was evaluated in order to identify expression difference caused by the coculture conditions. K3/K12 expression was analyzed in coculture cells on day 2, 4, 6, 8 and 10. Putative epidermal stem cells in conditioned culture media were used as control. Putative epidermal stem cells were predominant in rapid attaching cells by type IV collagen attachment isolation. Before being cocultured, the rhesus putative epidermal stem cells expressed K15, α6 and β1 integrin, but no CD71, K1/K10 and K3/K12. After coculture, these cells expressed K3/K12 (a marker of corneal epithelial cells), K15 and β1 integrin, but no K1/K10. Cells being not coculture converted into terminally differentiated cells expressing K1/K10. These results indicate that rhesus putative epidermal stem cells can trans-differentiate into corneal epithelium-like cells and, therefore, may have potential therapeutic application as autologous seed cells for the construction of bioengineered corneas. Supported in part by Hi-tech Research and Development Program of China (Grant No. 2003AA205005), the Specialized Research Fund for the Doctoral Program of Higher Education (SRFDP, No.20030558074), the Key Technologies Research and Development Programme of the Tenth Five-Year Plan (Grant No. 2004BA720A15), Scientific and Technological Program (Grant Nos. A3020101 and 2003A3020401) of Guangdong Province     

Extracellular products of Staphylococcus aureus reversibly inhibit the terminal differentiation of cultured mouse epidermal cells

The effect of extracellular products from Staphylococcus aureus on the differentiation of mouse epidermal cells was studied using an in vitro cell culture system. The extracellular products from a clinical strain of S. aureus isolated from human skin lesions reversibly inhibited the Ca++-induced terminal differentiation of epidermal cells, as determined by their morphology and the extent of cornified envelope formation. This suggests that a similar modification of cell differentiation is involved in the pathogenesis of S. aureus-induced skin disease.     

Isolation of human basal keratinocytes by selective adhesion to extracellular matrix proteins

Epidermal human cells (keratinocytes) differently interact with extracellular matrix proteins of the skin basal membrane depending on the stages of their differentiation. The pool of basal keratinocytes commonly includes stem cells and transient amplifying cells. They directly attach to the skin basal membrane. Keratinocytes change their adhesive properties during differentiation, lose direct interaction with the basal membrane and move to suprabasal epidermal strata. From this, it is suggested that basal and primarily stem cells can be isolated from a heterogenous keratinocyte population due to their selective adhesion to the extracellular matrix proteins. In the current study, we analysed the specificity of interaction between primary keratinocytes and extracellular matrix proteins (collagens of I and IV types, laminin-2/4, fibronectin and matrigel). We have demonstrated that the basal keratinocytes extracted from the skin have different adhesive abilities. The rapidly spreading cells usually interacted with collagen and fibronectin rather that with laminin-2/4 or matrigel. The majority of these cells being represented by basal keratinocytes. Our data demonstrate that the applied method of keratinocyte selection may be directed for precise isolation of skin stem from a common cell population.     

Culture of human pluripotent stem cells using completely defined conditions on a recombinant E-cadherin substratum

Background  

To maintain pluripotency of human embryonic stem (huES) cells in feeder-free culture it has been necessary to provide a Matrigel substratum, which is a complex of poorly defined extracellular matrices and growth factors derived from mouse Engelbreth-Holm-Swarm sarcoma cells. Culture of stem cells under ill-defined conditions can inhibit the effectiveness of maintaining cells in a pluripotent state and reduce reproducibility of differentiation protocols. Moreover recent batches of Matrigel have been found to be contaminated with the single stranded RNA virus, Lactate Dehydrogenase Elevating Virus (LDEV), raising concerns regarding the safety of using stem cells that have been cultured on Matrigel in a therapeutic setting. To circumvent such concerns, we attempted to identify a recombinant matrix that could be used as an alternative to Matrigel for the culture of human pluripotent stem cells. huES and human induced pluripotent stem (hiPS) cells were grown on plates coated with a fusion protein consisting of E-cadherin and the IgG Fc domain using mTeSR1 medium.     

Reprogramming adult dermis to a neonatal state through epidermal activation of β-catenin

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 by transgenic epidermal activation of β-catenin (EF skin). 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 β-catenin signalling. By 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 β-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.     

Extracellular matrix components direct porcine muscle stem cell behavior

In muscle tissue, extracellular matrix proteins, together with the vasculature system, muscle-residence cells and muscle fibers, create the niche for muscle stem cells. The niche is important in controlling proliferation and directing differentiation of muscle stem cells to sustain muscle tissue. Mimicking the extracellular muscle environment improves tools exploring the behavior of primary muscle cells. Optimizing cell culture conditions to maintain muscle commitment is important in stem cell-based studies concerning toxicology screening, ex vivo skeletal muscle tissue engineering and in the enhancement of clinical efficiency. We used the muscle extracellular matrix proteins collagen type I, fibronectin, laminin, and also gelatin and Matrigel as surface coatings of tissue culture plastic to resemble the muscle extracellular matrix. Several important factors that determine myogenic commitment of the primary muscle cells were characterized by quantitative real-time RT-PCR and immunofluorescence. Adhesion of high PAX7 expressing satellite cells was improved if the cells were cultured on fibronectin or laminin coatings. Cells cultured on Matrigel and laminin coatings showed dominant integrin expression levels and exhibited an activated Wnt pathway. Under these conditions both stem cell proliferation and myogenic differentiation capacity were superior if compared to cells cultured on collagen type I, fibronectin and gelatin. In conclusion, Matrigel and laminin are the preferred coatings to sustain the proliferation and myogenic differentiation capacity of the primary porcine muscle stem cells, when cells are removed from their natural environment for in vitro culture.     

Differential Calcium Requirements For Growth of Mouse Skin Epithelial and Fibroblast Cells

Concentrations of extracellular Ca⁺⁺ optimum for growth of cell types of mesodermal origin have been reported to be up to 100-fold higher than concentrations optimal for epidermal or other epithelial lining cells. In order to examine Ca⁺⁺ requirements of epithelial v. fibroblastic cells derived from a common tissue source, prior to prolonged culture, freshly isolated mouse epidermal keratinocytes, hair follicle cells and dermal fibroblasts were plated at high density or at clonal density in medium ranging from 0.014 to 1.4 mM Ca⁺⁺. Epithelial skin cells grew best at Ca⁺⁺ levels below 0.1 mM while dermal fibroblasts grew best at a Ca⁺⁺ concentration of 1.4 mM. the epithelial cell types exhibited marked morphologic changes in response to Ca⁺⁺, while the fibroblasts did not. These results suggest that the variations in Ca⁺⁺ response between lining epithelium and mesenchymal cells resulted from inherent differences in these cell types, but a mechanism for such differential effects has not yet been defined.     

Hypertrophic Gene Expression Induced by Chronic Stretch of Excised Mouse Heart Muscle

Altered mechanical stress and strain in cardiac myocytes induce modifications in gene expression that affects cardiac remodeling and myocyte contractile function. To study the mechanisms of mechanotransduction in cardiomyocytes, probing alterations in mechanics and gene expression has been an effective strategy. However, previous studies are self-limited due to the general use of isolated neonatal rodent myocytes or intact animals. The main goal of this study was to develop a novel tissue culture chamber system for mouse myocardium that facilitates loading of cardiac tissue, while measuring tissue stress and deformation within a physiological environment. Intact mouse right ventricular papillary muscles were cultured in controlled conditions with superfusate at 95% O₂/ 5% CO₂, and 34°C, such that cell to extracellular matrix adhesions as well as cell to cell adhesions were undisturbed and both passive and active mechanical properties were maintained without significant changes. The system was able to measure the induction of hypertrophic markers (BNP, ANP) in tissue after 2 hrs and 5 hrs of stretch. ANP induction was highly correlated with the diastolic load of the muscle but not with developed systolic load. Load induced ANP expression was blunted in muscles from muscle-LIM protein knockout mice, in which defective mechanotransduction pathways have been predicted.     

Collagen degradation in the rabbit skin during short-term tissue culture

Full thickness rabbit skin explants were cultured on plastic dish for 1 week and the sequential morphological changes were examined daily by light and electron microscopy. During the cultured period, bundles of dermal collagen fibres gradually loosened and were removed from the upper dermis and from the cut margin of the explant, which was covered by a sheet of migrating epidermal cells. In these areas, cells containing phagocytosed collagen fibrils were observed from the 3rd day to the end of the culture period. These cells containing phagocytosed collagen fibrils included dermal fibroblasts and macrophages, epidermal keratinocytes and endothelial cells lining blood vessels. The presence of acid phosphatase activity in vacuoles containing the collagen fibrils suggested that intracellular degradation of collagen was occurring. In addition, extracellular collagen degradation was recognized around fibroblasts and beneath the migrating epidermis by the high collagenolytic activity at these sites. These findings suggest that both intra- and extracellular collagen degradation may participate in collagen removal from dermal connective tissue in cultured skin explants.     

恒河猴皮肤干细胞的体外培养纯化与鉴定

探索恒河猴皮肤干细胞的体外培养及纯化条件,为进一步的研究奠定基础. 通过组织块培养法和消化培养法 在体外培养恒河猴表皮细胞,然后用Ⅳ型胶原吸附法吸附20 min,获得快吸附细胞. 对快吸附细胞进行克隆培养,并进行免疫细胞化学双标染色、RT PCR鉴定 β1 整合素和角蛋白15的表达,用流式细胞仪鉴定纯化前后的细胞中 β1 整合素和角蛋白15的阳性细胞比例,并通过透射电镜观察细胞的超微结构. 组织块培养法和消化培养法均可获得表皮细胞,Ⅳ型胶原纯化后的细胞胞体较小,饱满,核/浆比例大,细胞镶嵌状排列. 细胞克隆分析显示,细胞全克隆生长率高. 细胞免疫荧光显示,分选后的细胞显示 β1 整合素和角蛋白15阳性. RT PCR检查呈现 β1 整合素和角蛋白15的特异性片段. 流式细胞仪检查显示,纯化前的细胞中角蛋白15阳性细胞占总细胞中的比例为8％, β1 整合素阳性细胞的比例为10.7％;纯化后,角蛋白15阳性细胞的比例为89.4％, β1 整合素阳性细胞的比例为88.5％. 通过组织块培养法和消化培养法均可培养获得活性良好的表皮细胞,Ⅳ型胶原吸附法是一种简便、有效的皮肤干细胞分离方法,可以为进一步的眼表上皮替代重建眼表提供足量的高纯度的干细胞建立可靠的物质基础.