Stem cells and the skin

Stem cells live long lives, renew themselves, and differentiate into more mature, less potent, specialized cells, such as epidermal keratinocytes and dermal fibroblasts. Stem cells can be embryonic, if derived from an embryo, or adult/somatic if derived from postembryonic tissue. By producing new skin cells, stem cell division and differentiation can potentially rejuvenate skin and restore hair. To reproduce, stem cells can undergo symmetric nondifferentiative or differentiative divisions, or asymmetric differentiative divisions. Asymmetric divisions reproduce the stem cell and provide a more differentiated, but less potent transient amplifying cell. Divisions and differentiation of transient amplifying cells regenerate tissues by producing cells of a specific lineage, for example, keratinocytes. Epidermal stem cells lie in niches in the interfollicular epidermis, sebaceous gland, and in the bulge regions of hair follicles. These epidermal stem cells renew the epidermis, the sebaceous glands, and hair follicles after mature cells die. Dermal stem cells lie in the hair papillae, around pericytes, and elsewhere among other dermal cells. These form pericytes, myoblasts, fibroblasts, chondrocytes, and other specialized dermal cells. Along with other signaling pathways, the Wnt signaling pathway controls stem cell fate. Wnt signals enlist two functionally and chemically different gene coactivators to direct the time and type of replicative divisions. Stem cells may help to heal wounds, repair damaged tissues, regenerate aged skin, and reinvigorate growth of skin, hair, nails, and mucous membranes.     

中波紫外线诱导小鼠皮肤光损伤中miRNA141表达的研究

【摘要】 目的 探讨小室移植法重建小鼠毛囊,观察细胞成分对毛囊再生的影响。 方法 取0 ～ 2 d的C57BL/6乳鼠背部皮肤,胰酶消化后分离表真皮,再分离出毛囊上皮细胞。实验分表皮细胞混合毛囊胚芽组、真皮细胞组、表皮细胞混合毛囊胚芽 + 真皮细胞组、毛囊上皮细胞 + 真皮细胞组。用小室移植法接种于裸鼠背部,并于移植后1、2、4、8周观察变化,HE染色观察毛囊组织学形态。 结果 小鼠毛囊细胞移植1周时,背部小室开始脱落,伤口结痂;2周时除表皮细胞组外,另3组均长出了短小的毛发,镜下可见毛囊样结构;4周及8周时除表皮细胞组外,均长出了正常的毛发,表皮细胞与真皮细胞混合组及毛囊上皮细胞与真皮细胞混合组毛发生长情况良好,优于单独的真皮细胞组。 结论 毛囊细胞小室移植后可形成新的毛囊,上皮细胞及真皮细胞在毛囊重建中具有重要的作用。 【关键词】 毛囊; 毛囊重建; 鼠科     

Hair follicle regeneration using grafted rodent and human cells

Hair follicle regeneration involves epithelial-mesenchymal interactions (EMIs) of follicular epithelial and dermal papilla (DP) cells. Co-grafting of those cellular components from mice allows complete hair reconstitution. However, regeneration of human hair in a similar manner has not been reported. Here, we investigated the possibility of cell-based hair generation from human cells. We found that DP-enriched cells (DPE) are more critical than epidermal cells in murine hair reconstitution on a cell number basis, and that murine DPE are also competent for hair regeneration with rat epidermal cells. Co-grafting of human keratinocytes derived from neonatal foreskins with murine DPE produced hair follicle-like structures consisting of multiple epidermal cell layers with a well-keratinized innermost region. Those structures expressed hair follicle-specific markers including hair keratin, and markers expressed during developmental stages. However, the lack of regular hair structures indicates abnormal folliculogenesis. Similar hair follicle-like structures were also generated with cultured human keratinocytes after the first passage, or with keratinocytes derived from adult foreskins, demonstrating that epidermal cells even at a mature stage can differentiate in response to inductive signals from DP cells. This study emphasizes the importance of EMI in follicular generation and the differentiation potential of epidermal keratinocytes.     

A membrane protein preferentially expressed by a subpopulation of immature lymphoid cells, epidermal basal keratinocytes, and other epithelial cells

A murine monoclonal antibody, designated EL-1, was raised by immunization with a human malignant T cell line. It reacted specifically with a membrane antigen expressed on T and B lymphoblastoid cell lines, a subpopulation of normal thymocytes and bone marrow lymphocytes, lymphocytes from a subset of patients with non-B, non-T cell acute lymphoblastic leukemia or T cell acute lymphoblastic leukemia and epithelial stem cells. The latter reactivity was especially striking in the skin, where only basal epidermal keratinocytes and epidermal appendages, including eccrine sweat glands, sebaceous glands and hair follicles, stained positively. A human epidermoid carcinoma cell line was also stained by EL-1. Suprabasilar keratinocytes and acellular keratin did not stain. However, in vitro proliferating fetal lung fibroblasts stained positively. Membrane immunoprecipitation analysis demonstrated that the antigen recognized by antibody EL-1 is a single protein of molecular weight 105 kilodaltons which did not change with exhaustive chemical reduction. Metabolic radiolabeling studies demonstrated that this protein is synthesized by the cell and not merely taken up from the culture medium. This antibody can be useful in studying keratinocyte differentiation in epidermal malignancies and normal skin.     

Expression patterns of programmed cell death 4 protein in normal human skin and some representative skin lesions

Expression of a tumor suppressor gene, programmed cell death 4 (PDCD4), was investigated at the protein level in the human skin. Immunohistochemically, PDCD4 protein expressed mainly in suprabasal layers, while PDCD4-positive and -negative areas were observed discontinuously in the basal cell layer of the epidermis. In hair follicles, the suprabulbar area including the hair and inner root sheath was immunoreactive, while the bulbar area, containing germinative cells which were strongly proliferating cell nuclear antigen (PCNA)-positive, was not or less. PDCD4 therefore appears to be important in the differentiation of hair follicles. PDCD4-positive cells were localized in the inside layers while PCNA-positive cells were located in the basal layer in the outer root sheath of hair follicles. The cells of sebaceous glands and sweat glands also were PDCD4-positive. The PDCD4 protein was localized mostly in nuclei of cutaneous cells. PDCD4 expression was found to be suppressed in the epidermis overlying an adult T-cell lymphoma (ATL), possibly reflecting a paracrine effect of factors produced by ATL cells. PDCD4 expression was suppressed in the keratinocyte cell line HaCaT by exposure of cultures to epidermal growth factor, transforming growth factor-beta1 or hepatocyte growth factor. Immunohistochemically, various skin cancers tended to show less PDCD4 expression than normal skin. Promotion of expression might prove useful in preventing or treating certain skin cancers.     

Dissociated skin cells regenerate hair follicles in a microwound, “The Punch Assay”

The purpose of this study was to develop a new, easily executed hair follicle regeneration system and assay, which could be further developed for clinical or cosmetic applications. Dissociated epidermal and dermal progenitor cells, isolated either from neonatal C57BL/6 mice or human foetal scalp tissues, were suspended in (10 μL) F12 medium and pipetted into a 1 or 2 mm-diameter punch biopsy wounds on the back skin of immunodeficient mice. At 3 weeks after transplantation, although pigmented mouse hairs could efficiently form at the injection sites with delivery of mouse cells, none hair formed on the host mouse skin at 3 months after delivery of human cells. Under the same conditions, human follicles could be regenerated when the human skin cells were delivered onto a 2 mm size punch created on a reconstituted human skin (hRSK), which previously generated on the back of an immunodeficient mouse, but the efficiency of hair formation was low. We demonstrated that both mouse and human regenerated follicles showed normal histology and differentiation markers; moreover, the cell chasing experiment confirmed that the regenerated hair follicles were formed from transplanted cells. Compared to other current hair reconstituted assays, the Punch Assay is relatively simple and generates normal hair follicles within a smaller wound. We suggest that the punch assay is a better in vivo assay of cell trichogenicity.     

毛囊混合细胞在胶原/壳聚糖多孔支架上重建毛囊样结构

目的探讨利用毛囊混合细胞植入胶原／壳聚糖多孔支架内体外重建毛囊的可行性。方法用滴加法或注射法将体外培养的C57BL／6J近交系乳鼠背部皮肤毛囊混合细胞以不同传代数、不同细胞密度接种至胶原／壳聚糖多孔支架，倒置显微镜下观察支架表面或浅层的细胞生长或毛囊形成情况。将支架经10％甲醛固定后行组织学观察（H-E染色）。另用共聚焦激光扫描显微镜观察支架内活细胞的生长以及毛囊样结构的形成。结果在一定传代次数和细胞密度下，在支架内可形成具有毛干的毛囊样结构。激光共聚焦扫描显微镜发现团块内细胞排列呈同心圆状，整个三维结构似一长颈花瓶，且该结构仅见于注射法接种细胞的支架内。结论毛囊混合细胞植入胶原／壳聚糖多孔支架内体外可形成具有毛干的毛囊样结构。     

Sheep vibrissa dermal papillae induce hair follicle formation in heterotypic skin equivalents

Cultured skin equivalents were constructed by combining keratinocytes, outer root sheath cells or isolated epidermis, in vitro, with a matrix composed of collagen and cultured fibroblasts. When equivalents were grafted on to host animals, the epidermis thickened considerably, and tongues of cells penetrated the dermis, giving the dermal/epidermal junction a deeply sculptured profile. No cutaneous appendages were found in these grafts. We explored the possibility of inducing hair follicles by incorporating ovine hair follicle dermal papillae into constructs composed of an isolated epidermal sheet and a contracted dermal equivalent. In vitro, no morphogenetic changes associated with follicle formation were observed in the recombinants, but when grafted on to nude mice, follicle-like structures were identified. The follicles were large, and had developed adjacent to the epidermis, indicating that the matrix environment of the induced follicles may not have been compatible with the downgrowth of the epidermal plugs normally observed during follicle formation in living skin. Nevertheless, in histological sections, the induced structures displayed many of the morphological characteristics of follicles in vivo, including the production of keratinized hairs. These results indicate that skin equivalents provide a useful model for the study of the chemical and structural features of matrices that facilitate hair follicle development.     

表皮干细胞与表皮肿瘤

表皮干细胞具有无限增殖及多向分化的特性，其子代细胞可以形成角质形成细胞、毛囊、皮脂腺的分化细胞。肿瘤一般起源于单个发生癌性突变的细胞，表皮干细胞很可能是各种类型表皮肿瘤发生的主要靶细胞，分化细胞则能通过影响肿瘤干细胞的克隆扩增，对肿瘤的发生起重要作用。     

Role of bulge cells in wound healing: possible implications for hidradenitis suppurativa

The hair follicle bulge harbors a cluster of quiescent epithelial stem cells, which generate the new lower hair follicle during follicle cycling. The role of bulge cells for maintenance of the hair follicle and epidermis during normal homeostasis and after wounding remains controversial. To address these questions, we targeted the suicide gene, thymidine kinase (TK), or CrePR recombinase to hair follicle bulge cells using a K15 promoter. Administration of ganciclovir to K15‐TK mice caused their death due to gastrointestinal injury. We then treated immunodeficient mice carrying K15‐TK skin grafts with ganciclovir. This resulted in injury of bulge cells within several days. Loss of hair and permanent injury to hair follicles ensued. Dermal scarring was also present. The epidermis without follicles survived for several months. To further assess the contribution of bulge cells to epidermis, we used double transgenic K15‐crePR1, R26R mice. After 5 days of treatment with RU‐486 (time 0), bulge cells and a small fraction of epidermal cells expressed LacZ under control of the ROSA promoter. To determine whether bulge cells moved into the epidermis under normal homeostatic conditions, we counted labeled epidermal basal cells at times 0, 30 days, and 180 days. We found that the percentage of labeled epidermal basal cells (approximately 1%) remained constant, indicating an absence of cell movement from the bulge to the epidermis. After punch wounding, bulge progeny were detected in a radial pattern in the re‐epithelialized area. Radial streaks of bulge cell progeny emanated from the hair follicles at the wound edge. Bulge cell progeny proliferated and expressed normal epidermal differentiation markers such as keratin 10 and loricrin. Overall, these results indicate that follicular stem cells in the bulge are necessary for hair follicle survival and that these cells functionally contribute to epidermal regeneration in response to wounding; however, the epidermis self‐renews autonomously of the bulge under normal conditions. The role of bulge cells in hidradenitis suppurativa (HS) is not known; however, pathological studies suggest aberrant proliferation of the hair follicle may accompany HS and inappropriate stem cell activation and differentiation could be a component of this disorder. The K15‐crePR1 transgenic mouse will serve as a powerful tool for evaluating the role of hair follicle stem cells in mouse models of HS. Studying hair follicle stem cells with recently defined markers for these cells will be useful for evaluating stem cell behavior in HS lesions.     

Expression pattern and intensity of protoporphyrin IX induced by liposomal 5-aminolevulinic acid in rat pilosebaceous unit throughout hair cycle

We have developed liposomal formulation of 5-aminolevulinic acid (ALA) to enhance topical delivery and examined ALA-induced protoporpyrin (PpIX) expression in rat pilosebaceous unit throughout hair cycle. Two types of liposomes—glycerol dilaulate (GDL) and phosphatidylcholine (PC)—were formulated and both liposomal ALA increased PpIX expression in rat dorsal skin and pilosebaceous units when compared with free ALA. However, iontophoresis combined with liposomal ALA reduced the expression intensity of PpIX in hair bulbs although it achieved deeper and wider expression of PpIX through transfollicular pathway. After topical application in intact or depilated rat skin, liposomal ALA produced excellent PpIX expression in pilosebaceous units. The expression pattern and intensity of PpIX changed in hair cycle-dependent manner: specific expression only in sebaceous glands was observed at telogen; strong expression in whole pilosebaceous units was shown at anagen with intense expressions in hair bulbs and sebaceous glands; and a pattern similar to anagen but reduced intensity in the hair bulbs was seen at catagen. Throughout hair cycle, the expression pattern and intensity were dramatically changed in hair follicular epithelial cells depending on the cell density and proliferation activity of those cells, whereas those were consistent in sebaceous glands regardless of hair cycle. Little expression was shown in dermis. Photoactivation effect of 20% liposomal ALA-PDT using a red filtered-halogen lamp damaged sebaceous glands, hair follicles and epidermal layers. Formation of a thicker epidermal layer was observed, and hair induction after depilation was inhibited along with damage in sebaceous glands.     

毛囊间充质干细胞的研究进展

 毛囊间充质干细胞（HFMSCs）是一类具有自我再生能力、高度增殖潜能、可多向分化且来源丰富的慢周期标记滞留细胞,可促进表皮、毛囊和皮脂腺再生。得益于其来源丰富、易获得、可于体外扩增、无需基因操作、不会形成肿瘤和无伦理限制等特点,毛囊间充质干细胞在再生医学中具有重要优势。Wnt、Shh、Notch和BMP等信号通路之间的协同和拮抗作用在干细胞稳态调节、表皮发育和毛囊再生过程中发挥至关重要的作用,这些途径的失调可能导致毛发脱落或者肿瘤的发生。本文综述毛囊间充质干细胞的分类及其特异性生物标记物、毛囊间充质干细胞的活化以及影响毛发再生的生物分子途径,为毛发疾病的治疗提供新的线索和靶点。     

Expression of the small heat shock protein HSP 27 in developing human skin

The 27 kDa heat shock protein (HSP 27) is expressed in keratinocytes of the upper epidermal layers, and recent evidence suggests that this protein is involved in the regulation of epidermal differentiation. The expression of HSP 27 was investigated in developing human skin by immunohistochemistry utilizing a specific monoclonal antibody. We used formalin-fixed, paraffin-embedded tissue of abdominal skin obtained from 34 human fetuses ranging between 13 and 30 weeks estimated gestational age (EGA). We found that HSP 27 is not expressed in keratinocytes until week 14 EGA. At this stage staining is observed in the periderm and the upper intermediate cells but not in hair germs. During further development, HSP 27 expression correlates with increasing epidermal differentiation, i.e. shedding of the periderm and beginning of keratinization. HSP 27 expression is confined to the upper cell layers and sparse basal cells. In hair follicles, HSP 27 can be detected in the innermost cell layer of the outer root sheath and in keratinocytes of the bulge identical to what is observed in adult skin. The hair papilla, matrix cells and sebaceous glands are negative for HSP 27 and remain so during further development. In eccrine sweat glands of the 24th week EGA, HSP 27 is confined to the superficial cell layer of the sweat ducts. In the present report we demonstrate differentiation-related expression of HSP 27 in developing human skin. Further in vitro studies will address the molecular function of HSP 27 in epidermal differentiation and development.     

Stem cells and alopecia: a review of pathogenesis

Recent work has focused on the hair follicle as the main source of multipotent stem cells in the skin. The hair follicle bulge contains multipotent stem cells that can form the epidermis, hair follicles and sebaceous glands and help in repopulation of the epidermis after injury. The localization of these stem cells to the bulge area may explain why some types of inflammatory alopecia cause permanent loss of hair (cicatricial alopecia) (such as lichen planopilaris and discoid lupus erythematosus), while others (such as alopecia areata) are reversible (noncicatricial alopecia). The lack of distinctive bulge morphology in human hair follicles has hampered studies of bulge cells. To date, the best marker for bulge stem cells in human hair is cytokeratin (CK) 15; human bulge cells have been reported to express CK15 selectively throughout all stages of the hair cycle in different types of follicles. There is direct evidence in the mouse, and indirect evidence in the human, that compromising the integrity of the sebaceous gland and/or bulge is important in the development of alopecia. Several interesting studies have been done in the last few years to investigate the role of stem cells in alopecia, especially nonscarring types. This is a review about the role of stem cells in the pathogenesis of alopecia (scarring and nonscarring).     

Myo/Nog cells in normal, wounded and tumor-bearing skin

Murine and human skin were examined for the presence of Myo/Nog cells that were originally discovered in the chick embryo by their expression of MyoD mRNA, noggin and the G8 antigen. Myo/Nog cells are the primary source of noggin in telogen hair follicles. They are scarce within the interfollicular dermis and absent in the epidermis. Within 24 h following epidermal abrasion, Myo/Nog cells increase in number in the follicles and appear in the wound. Myo/Nog cells are also recruited to the stroma of tumors formed from v‐Ras‐transformed keratinocytes (Ker/Ras). Human squamous cell carcinomas and malignant melanomas contain significantly more Myo/Nog cells than basal cell carcinomas. Myo/Nog cells are distinct from macrophages, granulocytes and cells expressing alpha smooth muscle actin in the tumor stroma. Myo/Nog cells may be modulators of skin homoeostasis and wound healing, and potential diagnostic and therapeutic targets in skin cancer.     

Plasticity of hair follicle dermal cells in wound healing and induction

The capacity of adult hair follicle dermal cells to participate in new follicle induction and regeneration, and to elicit responses from diverse epithelial partners, demonstrates a level of developmental promiscuity and influence far exceeding that of interfollicular fibroblasts. We have recently suggested that adult follicle dermal cells have extensive stem or progenitor cell activities, including an important role in skin dermal wound healing. Given that up to now tissue engineered skin equivalents have several deficiencies, including the absence of hair follicles, we investigated the capacity of follicle dermal cells to be incorporated into skin wounds; to form hair follicles in wound environments; and to create a hair follicle-derived skin equivalent. In our study, we implanted rat follicle dermal cells labelled with a vital dye into ear and body skin wounds. We found that they were incorporated into the new dermis in a manner similar to skin fibroblasts, but that lower follicle dermal sheath also assimilated into hair follicles. Using different combinations of follicle dermal cells and outer root sheath epithelial cells in punch biopsy wounds, we showed that new hair follicles were formed only with the inclusion of intact dermal papillae. Finally by combining follicle dermal sheath and outer root sheath cells in organotypic chambers, we created a skin equivalent with characteristic dermal and epidermal architecture and a normal basement membrane - the first skin to be produced entirely from hair follicle cells. These data support the hypothesis that follicle dermal cells may be important in wound healing and demonstrate their potential usefulness in human skin equivalents and skin substitutes. While we have made progress towards producing skin equivalents that contain follicles, we suggest that the failure of cultured dermal papilla cells to induce follicle formation in wounds illustrates the complex role the follicle dermis may play in skin. We believe that it demonstrates a genuine dichotomy of activity for follicle cells within skin.     

A model system to analyse the ability of human keratinocytes to form hair follicles

Earlier studies showed that dermal cells lose trichogenic capacity with passage, but studies on the effect of keratinocyte passage on human hair follicle neogenesis and graft quality have been hampered by the lack of a suitable model system. We recently documented human hair follicle neogenesis in grafted dermal‐epidermal composites, and in the present study, we determined the effects of keratinocyte passage on hair follicle neogenesis. Dermal equivalents were made with cultured human dermal papilla cells and were overlaid with either primary or passaged human keratinocytes to form dermal‐epidermal composites; these were then grafted onto immunodeficient mice. Superior hair follicle neogenesis was observed using early keratinocyte cultures. Characteristics such as formation of hair shafts and sebaceous glands, presence of hair follicles with features of anagen or telogen follicles, and reproducible hair and skin function parameters make this model a tool to study human hair follicle neogenesis and development.     

Expression of macrophage migration inhibitory factor in rat skin during embryonic development

Abstract:  We have previously shown that human epidermal keratinocytes express macrophage migration inhibitory factor (MIF) mRNA, and immunohistochemical studies showed that MIF is expressed in human epidermis. To explore the possible pathophysiological roles of MIF in skin during rat fetal development, we examined the expression patterns of MIF during rat epidermal development using Northern blot analysis and in situ hybridization. Expression of MIF mRNA was first detected by in situ hybridization in the developing epidermis and hair germ cells from embryonic day (ED) 16. From ED 19, moderate levels of MIF expression were detected in the epidermis and epithelial sheath cells of growing hair follicles. In postnatal rat skin, higher MIF expression was detected in the epidermis and hair follicles on postnatal day 3. These observations were also confirmed by Northern blot analysis. Immunohistochemical analysis with an anti-MIF antibody showed a similar distribution to that of the mRNA. Our results suggest that MIF is associated with epidermal and hair follicle development.     

The advantages of hair follicle pluripotent stem cells over embryonic stem cells and induced pluripotent stem cells for regenerative medicine

Multipotent adult stem cells have many potential therapeutic applications. Our recent findings suggest that hair follicles are a promising source of easily accessible multipotent stem cells. Stem cells in the hair follicle area express the neural stem cell marker nestin, suggesting that hair-follicle stem cells and neural stem cells have common features. Nestin-expressing hair follicle stem cells can form neurons and other cell types, and thus adult hair follicle stem cells could have important therapeutic applications, particularly for neurologic diseases. Transplanted hair follicle stem cells promote the functional recovery of injured peripheral nerve and spinal cord. Recent findings suggest that direct transplantation of hair-follicle stem cells without culture can promote nerve repair, which makes them potentially clinically practical. Human hair follicle stem cells as well as mouse hair follicle stem cells promote nerve repair and can be applied to test the hypothesis that human hair follicle stem cells can provide a readily available source of neurologically therapeutic stem cells. The use of hair follicle stem cells for nerve regeneration overcomes critical problems of embryonic stem cells or induced pluripotent stem cells in that the hair follicle stem cells are multipotent, readily accessible, non-oncogenic, and are not associated with ethical issues.     

Immunohistochemical demonstration of peptidylarginine deiminase in human sweat glands.

Human skin is known to contain protein-bound citrulline. This is the product of enzymatic deimination of arginine residues catalyzed by peptidylarginine deiminase. We probed frozen sections of human skin with a rabbit antiserum raised to rat skeletal muscle peptidylarginine deiminase using the avidin-biotin-peroxidase complex technique. This led us to interesting findings. No staining was observed in epidermis, inner root sheaths of hair follicles, sebaceous glands, and hair erector muscle. However, we noticed specific staining of the cytoplasm of secretory and myoepithelial cells of both eccrine and apocrine sweat glands. The procedure also stained neoplastic cells present in specimens dissected from extramammary Paget's disease. The data mean that peptidylarginine deiminase may be used as a new marker in the classification of skin neoplasms showing sweat gland differentiation. Possible localization of multiple types of peptidylarginine deiminases in human skin is discussed.