Induction of hair follicle neogenesis with cultured mouse dermal papilla cells in de novo regenerated skin tissues

De novo skin regeneration with human keratinocytes amplified in culture is a life‐saving procedure for patients with extensive skin loss and chronic wounds. It also provides a valuable platform for gene function and therapeutic assessments. Nevertheless, tissues generated in this manner lack hair follicles that are important for skin homeostasis, barrier function, and repair. In this study, we generated skin tissues with human keratinocytes combined with dermal papilla (DP) cells isolated from mouse whisker hair. For this, cultured keratinocytes and mouse DP (mDP) cells were mixed at 10:1 ratio and seeded onto devitalized human dermal matrix derived from surgically discarded human abdominoplasty skin. After 1 week in submerged culture, the cell/matrix composites were grafted onto the skin wound beds of immunocompromised NSG.SCID mice. Histological analysis of 6‐week‐old skin grafts showed that tissues generated with the addition of mDP cells contained Sox2‐positive dermal condensates and well‐differentiated folliculoid structures that express human keratinocyte markers. These results indicate that cultured mDP cells can induce hair follicle neogenesis in the de novo regenerated skin tissues. Our method offers a new experimental system for mechanistic studies of hair follicle morphogenesis and tissue regeneration and provides insights to solving an important clinical challenge in generation of fully functional skin with a limited source of donor cells.     

Neonatal murine skin‐derived cells transplanted using a mini‐chamber model produce robust and normal hair

Hair follicle reconstitution models are useful tools for investigating signalling and cytokines during hair follicle morphogenesis and cycling. The chamber model is one of the most established methods available for the study of hair follicle reconstitution and appears to be the most reproducible. However, the chamber model has several deficiencies: infection of skin wounds and subsequent animal death commonly occur, a large number of cells are required and only one chamber can be transplanted onto each animal. We modified these deficiencies by using a mini‐chamber method, which has the advantages of having a high graft take rate, requiring fewer cells and allowing several mini‐chambers to be transplanted onto each animal. In our study, cultured dermal cells at different passages (0 to high) lost the ability to reconstruct hair follicles, but dermal cells cultured overnight (12 h) retained this ability. Using the assay, newborn mice dermal cells that were freshly isolated and cultured overnight (12 h), as well as cultured dermal papilla cells from mice vibrissa follicles, all reconstructed hair follicles. However, cultured dermal papilla cells from human scalp follicles could not reconstruct hair follicles. Copyright © 2013 John Wiley & Sons, Ltd.     

Reconstitution of full‐thickness skin by microcolumn grafting

In addition to providing a physical barrier, skin also serves a diverse range of physiological functions through different specialized resident cell types/structures, including melanocytes (pigmentation and protection against ultraviolet radiation), Langerhans cells (adaptive immunity), fibroblasts (maintaining extracellular matrix, paracrine regulation of keratinocytes), sweat glands (thermoregulation) and hair follicles (hair growth, sensation and a stem cell reservoir). Restoration of these functional elements has been a long‐standing challenge in efforts to engineer skin tissue, while autologous skin grafting is limited by the scarcity of donor site skin and morbidity caused by skin harvesting. We demonstrate an alternative approach of harvesting and then implanting μm‐scale, full‐thickness columns of human skin tissue, which can be removed from a donor site with minimal morbidity and no scarring. Fresh human skin microcolumns were used to reconstitute skin in wounds on immunodeficient mice. The restored skin recapitulated many key features of normal human skin tissue, including epidermal architecture, diverse skin cell populations, adnexal structures and sweat production in response to cholinergic stimulation. These promising preclinical results suggest that harvesting and grafting of microcolumns may be useful for reconstituting fully functional skin in human wounds, without donor site morbidity. © 2016 The Authors Journal of Tissue Engineering and Regenerative Medicine Published by John Wiley & Sons Ltd.     

毛乳头细胞诱导毛囊形成的可能性研究

背景毛囊在伤口愈合,肿瘤发生等过程中起主导作用,由于其在活体内影响因素较多,故难以研究其生物学作用机制.目的利用培养的毛乳头细胞观察体内外条件下诱导毛囊形成的可能.设计非随机非对照的实验研究.地点和对象实验在第三军医大学大坪医院野战外科研究所完成.对象为正常人头皮中获取毛乳头细胞、真皮鞘细胞、毛囊上、下段及球部细胞.干预将毛乳头细胞、真皮鞘细胞分别与毛囊上、下段上皮细胞进行体外三维培养重建,用游离细胞混合移植于裸鼠,组织学观察毛囊形成情况.主要观察指标毛囊毛乳头细胞、真皮鞘细胞对分段毛囊上皮细胞的诱导分化作用.结果毛囊间表皮细胞、毛囊上段上皮细胞、下段上皮细胞和球部细胞在间质细胞凝胶上均可形成双层结构的组织工程皮肤,在真皮鞘细胞胶原凝胶上毛囊的上、下段上皮细胞形成了毛囊结构,移植于裸鼠后毛乳头细胞胶原凝胶诱导毛囊上、下段细胞形成了毛囊.低代毛乳头细胞与毛囊上皮细胞混合移植形成了数量较多、结构典型的毛囊,并有肉眼可见的毛发纤维产生.结论毛囊的真皮成分细胞即毛乳头细胞、真皮鞘细胞在体内、外均具有诱导毛囊形成的能力,通过与毛囊上皮细胞之间的相互作用,诱导毛囊形成.     

Force generation and protease gene expression in organotypic co‐cultures of fibroblasts and keratinocytes

Fibroblast–epithelium interactions are crucial for successful tissue engineering of skin and oral mucosal equivalents. In this study, we assessed early force generation in organotypic fibroblast–epithelium co‐cultures, using normal human keratinocytes (NHK) and HPV16‐transformed (UP) cells. During the initial 2 h period, organotypic co‐cultures containing both epithelial cell types produced significantly more force than fibroblasts alone (p < 0.05). After 2 h, the epithelial contribution became diminished and did not significantly contribute to intrinsic force generation by fibroblasts, and no differences were observed when using UP vs. NHK. We then measured protease gene expression at the end of the experimental period. Distinct differences were evident in protease expression both between NHK–human skin fibroblast (HSF) vs. UP–HSF co‐cultures and compared to fibroblasts alone. We conclude that whilst the very early contractile response of fibroblasts is enhanced by the overlying epithelium, this becomes diminished as the fibroblast response becomes predominant and it does contribute to tissue remodelling via regulation of protease expression. Copyright © 2009 John Wiley & Sons, Ltd.     

Reconstructed human skin shows epidermal invagination towards integrated neopapillae indicating early hair follicle formation in vitro

Application of reconstructed human Skin (RhS) is a promising approach for the treatment of extensive wounds and for drug efficacy and safety testing. However, incorporating appendages, such as hair follicles, into RhS still remains a challenge. The hair follicle plays a critical role in thermal regulation, dispersion of sweat and sebum, sensory and tactile functions, skin regeneration, and repigmentation. The aim of this study was to determine whether human neopapilla could be incorporated into RhS (differentiated epidermis on fibroblast and endothelial cell populated dermis) and whether the neopapillae maintain their inductive follicular properties in vitro. Neopapillae spheroids, constructed from expanded and self‐aggregating dermal papilla cells, synthesized extracellular matrix typically found in follicular papillae. Compared with dermal fibroblasts, neopapillae showed increased expression of multiple genes (Wnt5a, Wnt10b, and LEF1) known to regulate hair development and also increased secretion of CXCL1, which is a strong keratinocyte chemoattractant. When neopapillae were incorporated into the dermis of RhS, they stimulated epidermal down‐growth resulting in engulfment of the neopapillae sphere. Similar to the native hair follicle, the differentiated invaginating epidermis inner side was keratin 10 positive and the undifferentiated outer side keratin 10 negative. The outer side was keratin 15 positive confirming the undifferentiated nature of these keratinocytes aligning a newly formed collagen IV, laminin V positive basement membrane within the hydrogel. In conclusion, we describe a RhS model containing neopapillae with hair follicle‐inductive properties. Importantly, epidermal invagination occurred to engulf the neopapillae, thus demonstrating in vitro the first steps towards hair follicle morphogenesis in RhS.     

IDR‐1018 induces cell proliferation,migration, and reparative gene expression in 2D culture and 3D human skin equivalents

Skin lesions are associated with functional/cosmetic problems for those afflicted. Scarless regeneration is a challenge, not limited to the skin, and focus of active investigation. Recently, the host defense peptide innate defense regulatory peptide 1018 (IDR‐1018) has shown exciting regenerative properties. Nevertheless, literature regarding IDR‐1018 regenerative potential is scarce and limited to animal models. Here, we evaluated the regenerative potential of IDR‐1018 using human 2D and 3D human skin equivalents. First, we investigated IDR‐1018 using human cells found in skin—primary fibroblasts, primary keratinocytes, and the MeWo melanocytes cell line. IDR‐1018 promoted cell proliferation and expression of marker of proliferation Ki‐67, matrix metalloproteinase 1, and hyaluronan synthase 2 by fibroblasts. In keratinocytes, a drastic increase in expression was observed for Ki‐67, matrix metalloproteinase 1, C‐X‐C motif chemokine receptor type 4, C‐X‐C motif chemokine receptor type 7, fibroblast growth factor 2, hyaluronan synthase 2, vascular endothelial growth factor, and elastin, reflecting an intense stimulation of these cells. In melanocytes, increased migration and proliferation were observed following IDR‐1018 treatment. The capacity of IDR‐1018 to promote dermal contraction was verified using a dermal model. Finally, using a 3D human skin equivalent lesion model, we revealed that the regenerative potential of IDR1018, previously tested in mice and pigs, is valid for human skin tissue. Lesions closed faster in IDR‐1018‐treated samples, and the gene expression signature observed in 2D was reproduced in the 3D human skin equivalents. Overall, the present data show the regenerative potential of IDR‐1018 in an experimental system comprising human cells, underscoring the potential application for clinical investigation.     

Cyclosporine A increases hair follicle growth by suppressing apoptosis‐inducing factor nuclear translocation: a new mechanism

Cyclosporine A (CsA) enhances hair growth through caspase‐dependent pathways by retarding anagen‐to‐catagen phase transition in the hair follicle growth cycle. Whether apoptosis‐inducing factor (AIF), a protein that induces caspase‐independent apoptosis, can regulate the hair follicle cycle in response to CsA is currently unclear. Here, we show that the pro‐hair growth properties of CsA are in part due to blockage of AIF nuclear translocation. We first isolate hair follicles from murine dorsal skin. We then used Western blot, immunohistochemistry and immunofluorescence to evaluate the expression and localization of AIF in hair follicles. We also determined whether modulation of AIF was responsible for the effects of CsA at the anagen‐to‐catagen transition. AIF was expressed in hair follicles during the anagen, catagen and telogen phases. There was significant nuclear translocation of AIF as hair follicles transitioned from anagen to late catagen phase; this was inhibited by CsA, likely due to reduced cyclophilin A expression and attenuated AIF release from mitochondria. However, we note that AIF translocation was not completely eliminated, which likely explains why the transition to catagen phase was severely retarded by CsA, rather than being completely inhibited. We speculate that blockade of the AIF signalling pathway is a critical event required for CsA‐dependent promotion of hair growth in mice. The study of AIF‐related signalling pathways may provide insight into hair diseases and suggest potential novel therapeutic strategies.     

Hair follicle stem cells combined with human allogeneic acellular amniotic membrane for repair of full thickness skin defects in nude mice

Repair of large skin defects caused by burns, trauma, or tumor operations is a clinical challenge. Hair follicle stem cells (HFSCs) are involved in epithelialization of wounds, formation of new hair follicles and promote vascularization in the newly formed skin, and human acellular amniotic membrane (hAAM) is a promising scaffold for skin substitute. Here, we investigated the ability of rat HFSCs (rHFSCs) combined with an hAAM to repair full thickness skin defects in nude mice. The effect of the rHFSC‐hAAM composite on the repair of skin defects in nude mice was assessed by hematoxylin and eosin staining, immunohistochemistry, and EdU‐labeled cell tracking. Isolated and cultured rHFSCs had strong cloning and proliferation potentials. Immunofluorescence staining and flow cytometry assays showed that rHFSCs expressed high levels of integrin α6, CK15, p63, and Sox9. Cells cultured in hAAM showed flaky and cluster‐like morphology and were able to adhere and grow effectively. After transplantation, the rHFSC‐hAAM composite promoted wound healing in nude mice. Moreover, cells in the rHFSC‐hAAM composite were directly involved in hair follicle formation and angiogenesis of tissue around the hair follicle. These results provide an experimental and theoretical basis for the clinical application of HFSCs in repair of human skin defects and a new approach for skin tissue engineering.     

Control of hair growth and follicle size by VEGF-mediated angiogenesis

The murine hair follicle undergoes pronounced cyclic expansion and regression, leading to rapidly changing demands for its vascular support. Our study aimed to quantify the cyclic changes of perifollicular vascularization and to characterize the biological role of VEGF for hair growth, angiogenesis, and follicle cycling. We found a significant increase in perifollicular vascularization during the growth phase (anagen) of the hair cycle, followed by regression of angiogenic blood vessels during the involution (catagen) and the resting (telogen) phase. Perifollicular angiogenesis was temporally and spatially correlated with upregulation of VEGF mRNA expression by follicular keratinocytes of the outer root sheath, but not by dermal papilla cells. Transgenic overexpression of VEGF in outer root sheath keratinocytes of hair follicles strongly induced perifollicular vascularization, resulting in accelerated hair regrowth after depilation and in increased size of hair follicles and hair shafts. Conversely, systemic treatment with a neutralizing anti-VEGF antibody led to hair growth retardation and reduced hair follicle size. No effects of VEGF treatment or VEGF blockade were observed in mouse vibrissa organ cultures, which lack a functional vascular system. These results identify VEGF as a major mediator of hair follicle growth and cycling and provide the first direct evidence that improved follicle vascularization promotes hair growth and increases hair follicle and hair size.     

Gene expression profiling gets to the root of human hair follicle stem cells

Hair follicle stem cells sustain growth and cycling of the hair follicle and are located in the permanent portion of the follicle known as the bulge. In this issue of the JCI, Ohyama et al. report the characterization of global gene expression patterns of human hair follicle stem cells after their isolation using sophisticated laser capture techniques to microdissect out bulge cells. They discovered a panel of cell surface markers useful for isolating living hair follicle stem cells, a finding with potential therapeutic implications since isolated stem cells in mice can generate new hair follicles when transplanted to other mice. The findings of Ohyama et al. validate the use of the mouse for studying hair follicle biology but also underscore critical differences between mouse and human stem cell markers. In particular, CD34, which delineates hair follicle stem cells in the mouse, is not expressed by human hair follicle stem cells, while CD200 is expressed by stem cells in both species. Ultimately, this information will assist efforts to develop cell-based and cell-targeted treatments for skin disease.     

Adipose-derived stem cells (ASCs) as a source of endothelial cells in the reconstruction of endothelialized skin equivalents

Tissue-engineered autologous skin is a potential alternative to autograft for burn coverage, but produces poor clinical responses such as unsatisfactory graft intake due to insufficient vascularization. Endothelialized skin equivalents comprising human umbilical vein endothelial cells (HUVECs) survive significantly longer due to inosculation with the capillaries of the host, but these cells are allogeneic by definition. The aim of this study was to reconstruct an autologous endothelialized skin equivalent by incorporating progenitor or pre-differentiated endothelial cells derived from adipose tissue, easily accessible source for autologous transplantation. Human adipose tissue-derived stem cells were isolated from lipoaspirates and amplified to obtain endothelial progenitor cells, which were subsequently differentiated into endothelial cells. These cells were then seeded along with human fibroblasts into a porous collagen-glycosaminoglycan-chitosan scaffold to obtain an endothelialized dermal equivalent. Then, human keratinocytes give rise to a endothelialized skin equivalent. Immunohistochemistry and transmission electron microscopy results demonstrate the presence of capillary-like tubular structures in skin equivalents comprising pre-differentiated endothelial cells, but not endothelial progenitor cells. The former expressed both EN4 and von Willebrand factor, and Weibel-Palade bodies were detected in their cytoplasm. This study demonstrates that adipose tissue is an excellent source of autologous endothelial cells to reconstruct endothelialized tissue equivalents, and that pre-differentiation of stem cells is necessary to obtain vasculature in such models.     

皮肤组织工程中毛囊外根鞘细胞增殖能力及细胞角蛋白表达的意义

目的:通过培养人毛囊外根鞘细胞群,观察其增殖活性及细胞角蛋白K19的表达。方法:利用人头皮拔出的毛发,以组织块法和酶消化法培养毛囊外根鞘细胞,用四氮噻唑蓝(MTT)法比较其与表皮角质形成细胞的增殖能力,用免疫组化检测培养外根鞘细胞中细胞角蛋白K19的表达。结果:外根鞘细胞具有较表皮角质形成细胞更强的增殖能力,而且在培养的外根鞘细胞中有大量细胞角蛋白K19阳性的细胞。结论:由于外根鞘细胞具有较表皮角质形成细胞更强的增殖能力,同时含有大量K19阳性细胞,可以作为皮肤组织工程种子细胞来源。     

Matrix‐directed differentiation of human adipose‐derived mesenchymal stem cells to dermal‐like fibroblasts that produce extracellular matrix

Commercially available skin substitutes lack essential non‐immune cells for adequate tissue regeneration of non‐healing wounds. A tissue‐engineered, patient‐specific, dermal substitute could be an attractive option for regenerating chronic wounds, for which adipose‐derived mesenchymal stem cells (ADMSCs) could become an autologous source. However, ADMSCs are multipotent in nature and may differentiate into adipocytes, osteocytes and chondrocytes in vitro, and may develop into undesirable tissues upon transplantation. Therefore, ADMSCs committed to the fibroblast lineage could be a better option for in vitro or in vivo skin tissue engineering. The objective of this study was to standardize in vitro culture conditions for ADMSCs differentiation into dermal‐like fibroblasts which can synthesize extracellular matrix (ECM) proteins. Biomimetic matrix composite, deposited on tissue culture polystyrene (TCPS), and differentiation medium (DM), supplemented with fibroblast‐conditioned medium and growth factors, were used as a fibroblast‐specific niche (FSN) for cell culture. For controls, ADMSCs were cultured on bare TCPS with either DM or basal medium (BM). Culture of ADMSCs on FSN upregulated the expression of differentiation markers such as fibroblast‐specific protein‐1 (FSP‐1) and a panel of ECM molecules specific to the dermis, such as fibrillin‐1, collagen I, collagen IV and elastin. Immunostaining showed the deposition of dermal‐specific ECM, which was significantly higher in FSN compared to control. Fibroblasts derived from ADMSCs can synthesize elastin, which is an added advantage for successful skin tissue engineering as compared to fibroblasts from skin biopsy. To obtain rapid differentiation of ADMSCs to dermal‐like fibroblasts for regenerative medicine, a matrix‐directed differentiation strategy may be employed. Copyright © 2014 John Wiley & Sons, Ltd.     

Epidermal‐like architecture obtained from equine keratinocytes in three‐dimensional cultures

Despite the high prevalence of skin conditions in the horse, there is a dearth of literature on the culture and biology of equine skin cells, and this is partially attributable to the lack of suitable in vitro skin models. The objective of this study was to develop a three‐dimensional (3D) culture system that would support the proliferation and differentiation of equine keratinocytes, similar to that observed in natural epidermis. Cell monolayers were obtained from explants of equine skin and serially passaged as highly pure keratinocyte populations (> 95% of cells), based on their expression of cytokeratins, including CK‐5 and CK‐14, which are associated in vivo with proliferating keratinocyte populations. Explant‐derived keratinocytes were seeded into Alvetex? 3D tissue scaffolds for 30 days under conditions that promote cell differentiation. Ultrastructural, immunohistochemical and biochemical analyses revealed that keratinocytes within scaffolds were able to proliferate and attain tissue polarity, including differentiation into basal and suprabasal layers. The basal layer contained distinct cuboidal cells with large nuclei and stained for proliferative markers such as CK‐5 and CK‐14. In contrast, the suprabasal layers consisted of cells with distinct polyhedral morphology, abundant cytoplasmic processes and desmosomes indicative of stratum spinosum and distinct flattened cornified cells that expressed involucrin, a marker of terminal differentiation. Thus, keratinocytes derived from primary equine skin explants were able to attain epidermal‐like architecture in culture. This novel system could provide a very useful tool for modelling skin diseases, drug testing/toxicity studies and, potentially, equine regenerative medicine. Copyright © 2016 John Wiley & Sons, Ltd.     

Analysis of epidermal entry in experimental cutaneous Bacillus anthracis infections in mice

Cutaneous infection is the most common form of human anthrax, but little is known of Bacillus anthracis-epidermal interactions. To study the latter, we used experimental inoculations of B. anthracis Sterne spores onto mouse flank skin. In DBA/2 mice (a sensitive strain) 10(7) spores injected intradermally or applied under occlusive dressings to abraded skin produced ipsilateral inguinal edema and rapid death. Epicutaneous application to shaved-only skin produced edema and death in most animals, but at longer times. Mortality after inoculation onto abraded skin was less in C57BL/6 mice (a relatively resistant strain). Inoculations onto shaved-only skin immunized C57BL/6 mice, and they survived later intradermal spore injections. Histology revealed massive organism proliferation in remaining epidermis and hair follicles of inoculated abraded skin, but less growth in the dermis itself. Conversely, no foci could be located by microscopic examination after inoculation onto shaved-only skin. High-dose nonocclusive dressing inoculations onto unshaved skin in DBA/2 mice revealed small numbers of infective foci, all in hair follicles. These results suggest that epidermal damage may increase infection susceptibility to B. anthracis of hair follicle contents and remaining epidermal remnants; the findings also indicate that access may occur through hair follicles and the denuded dermis.     

Bald scalp in men with androgenetic alopecia retains hair follicle stem cells but lacks CD200-rich and CD34-positive hair follicle progenitor cells

Androgenetic alopecia (AGA), also known as common baldness, is characterized by a marked decrease in hair follicle size, which could be related to the loss of hair follicle stem or progenitor cells. To test this hypothesis, we analyzed bald and non-bald scalp from AGA individuals for the presence of hair follicle stem and progenitor cells. Cells expressing cytokeratin15 (KRT15), CD200, CD34, and integrin, α6 (ITGA6) were quantitated via flow cytometry. High levels of KRT15 expression correlated with stem cell properties of small cell size and quiescence. These KRT15(hi) stem cells were maintained in bald scalp samples. However, CD200(hi)ITGA6(hi) and CD34(hi) cell populations--which both possessed a progenitor phenotype, in that they localized closely to the stem cell-rich bulge area but were larger and more proliferative than the KRT15(hi) stem cells--were markedly diminished. In functional assays, analogous CD200(hi)Itga6(hi) cells from murine hair follicles were multipotent and generated new hair follicles in skin reconstitution assays. These findings support the notion that a defect in conversion of hair follicle stem cells to progenitor cells plays a role in the pathogenesis of AGA.     

Production of human tissue‐engineered skin trilayer on a plasma‐based hypodermis

Full thickness wounds require a dermal component to achieve functional permanent skin restoration. Currently available tissue‐engineered skin substitutes lack a subcutaneous fat layer that would functionally contribute some of the mechanical and thermoregulatory properties of normal skin. To generate a trilayer engineered skin equivalent, we included bone marrow mesenchymal (BM‐MSC) or adipose tissue‐derived (ASC) stromal cells in a human plasma hydrogel exposed to adipogenic clues for three weeks. Approximately half of the cells differentiated under these conditions into mature adipocytes that survived for two years in culture with minimal medium change. In vitro generation of bona fide fully differentiated adipocytes was assessed by leptin secretion and ultrastructurally demonstrated through semithin to ultrathin sectioning and lipid staining with osmium tetroxide. Furthermore, presence of BM‐MSCs or ASCs within the subcutaneous layer contributed to the epidermal differentiation program, with more proliferating basal cells depositing basal membrane proteins and differentiating into mature keratinocytes that were able to generate a pluristratified epithelium. In conclusion, we engineered a fully differentiated human skin trilayer that could present multiple applications such as use for in vitro drug absorption tests and regenerative therapies. Copyright © 2012 John Wiley & Sons, Ltd.