Isolation and clonal analysis of human epidermal keratinocyte stem cells in long-term culture

We developed a procedure for growing normal epidermal keratinocyte stem cells isolated from a single punch biopsy of adult human skin in long-term culture. Primary skin epithelial cells were maintained in collagen-coated plates with irradiated human neonatal foreskin fibroblasts (line HPI.1) as a feeder for more than 120 days, approximately 115 population doublings, without signs of replicative senescence. Clonal analysis revealed the presence of holoclones, meroclones, and paraclones. Only emerging colonies with high proliferative potentials and extensive capacities for division (holoclones and meroclones) were subcultured, favoring the expansion of stem cells and progenitors capable of prolonged self-maintenance when subcloned, thus accounting for the prevailing long-term proliferation of the original culture. We found that meroclones included bipotent progenitors capable of generating both keratinocytes and mucin-producing cells. The numbers of these cells were greater after confluence, suggesting that commitment for their differentiation occurred late in the life of a single clone. On a three-dimensional gelatin matrix and on a collagen layer containing the fibroblast feeder, cells isolated from the expansion of holoclones and meroclones formed stratified cohesive layers of keratinocytes that were able to further differentiate, as in normal skin. These results indicate that our procedure will serve as a valuable tool to study expansion of epidermal stem cells as well as the growth mechanisms and cell products associated with their growth and differentiation.     

Transient expression of keratin 19 is induced in originally negative interfollicular epidermal cells by adhesion of suspended cells

Keratin 19 and nuclear reactivity to an endogenous lectin, galectin-1, represent a potential marker of epidermal stem cells. We detected expression of keratin 19 and nuclear binding sites for galectin-1 in adult cells migrating from the hair follicle, where cells expressing keratin 19 are located in the bulge region. The results were compared with the expression of both markers in cells adhering from suspension prepared from the interfollicular epidermis without keratin-19-positive cells and with nuclear binding sites for galectin-1. The results were compared with data from basal cell carcinomas. All cells were analyzed concerning size, as it is known that cell diameter influences the clonogenic potential of keratinocytes. The major result of this study is the observation of transient expression of keratin 19 and nuclear galectin-1 binding sites in originally negative interfollicular epidermal cells induced by adhesion. These cells were very small in size, similar to basal cells of the interfollicular epidermis or the bulge region of the hair follicle. The influence of the suspension regimen on beta1-integrin expression, cell diameter and growth was also monitored. A population of cells highly positive for beta1 integrin of the same diameter as keratin-19-positive cells insensitive to induction of terminal differentiation by lack of anchorage was characterized. Cells of the same size were also observed in the keratin-19-positive cells of basal cell carcinomas. In conclusion, the expression of poor levels of differentiation induced by cell adhesion is transient. Also, keratin 19 expression should not be exclusively regarded as a marker of stem cell activity.     

Embryonic development of hair follicle pluripotent stem (hfPS) cells

Our laboratory discovered nestin-expressing hair follicle stem cells and demonstrated their pluripotency. We have shown that nestin-positive and K15-negative multipotent hair follicle stem cells are located above the hair follicle bulge, and we termed these cells hair follicle pluripotent stem (hfPS) cells. We have previously shown that hair follicle stem cells can regenerate peripheral nerve and spinal cord. In the present study, we describe the embryonic development of the hair follicle stem cell area (hfPSCA), which is located above the bulge and below the sebaceous glands in the adult mouse. At embryonic day 16.5 (E16.5) of nestindriven GFP (ND-GFP) transgenic mice, which express nestin in hfPS cells, the ND-GFP hair follicle stem cells are located in mesenchymal condensates. At postnatal day 0 (P0), the ND-GFP-expressing cells are migrating to the upper part of the hair follicle from the dermal papilla. At P3, keratin 15 (K15)-positive cells, derived from ND-GFP dermal papilla cells, are located in the outer-root sheath and basal layer of the epidermis. By P10, the ND-GFP have formed the K15-positive outer-root sheath as well as the ND-GFP hfPSA. These results suggest that ND-GFP hfPS cells in the dermal papilla form nestin-expressing hair follicle stem cells in the first hair cycle. These observations provide new insight into the origins of hfPS cells and the hfPSCA.     

Tcf3 and Lef1 regulate lineage differentiation of multipotent stem cells in skin

In skin, multipotent stem cells generate the keratinocytes of the epidermis, sebaceous gland, and hair follicles. In this paper, we show that Tcf3 and Lef1 control these differentiation lineages. In contrast to Lef1, which requires Wnt signaling and stabilized beta-catenin to express the hair-specific keratin genes and control hair differentiation, Tcf3 can act independently of its beta-catenin interacting domain to suppress features of epidermal terminal differentiation, in which Tcf3 is normally shut off, and promote features of the follicle outer root sheath (ORS) and multipotent stem cells (bulge), the compartments which naturally express Tcf3. These aspects of Tcf3's action are dependent on its DNA binding and Groucho repressor-binding domains. In the absence of its beta-catenin interacting domain, Lef1's behavior (Delta NLef1) seems to be markedly distinct from that of Delta NTcf3. Delta NLef1 does not suppress epidermal differentiation and promote ORS/bulge differentiation, but rather suppresses hair differentiation and gives rise to sebocyte differentiation. Taken together, these findings provide powerful evidence that the status of Tcf3/Lef complexes has a key role in controlling cell fate lineages in multipotent skin stem cells.     

Adult hair follicle stem cells do not retain the older DNA strands in vivo during normal tissue homeostasis

Tissue stem cells have been proposed to segregate the chromosomes asymmetrically (in a non-random manner), thereby retaining preferentially the older “immortal” DNA strands bearing the stemness characteristics into one daughter cell, whereas the newly synthesized strands are segregated to the other daughter cell that will commit to differentiation. Moreover, this non-random segregation would protect the stem cell genome from accumulating multiple mutations during repeated DNA replication. This long-standing hypothesis remains an active subject of study due to conflicting results for some systems and lack of consistency among different tissue stem cell populations. In this review, we will focus on work done in the hair follicle, which is one of the best-understood vertebrate tissue stem cell system to date. In cell culture analysis of paired cultured keratinocytes derived from hair follicle, stem cells suggested a non-random segregation of chromosome with respect to the older DNA strand. In vivo, the hair follicle stem cells appear to self-renew and differentiate at different phases of their homeostatic cycle. The fate decisions occur in quiescence when some stem cells migrate out of their niche and commit to differentiation without self-renewal. The stem cells left behind in the niche self-renew symmetrically and randomly segregate the chromosomes at each division, making more stem cells. This model seems to apply to at least a few other vertebrate tissue stem cells in vivo.     

角质细胞无血清培养基促进大鼠毛囊干细胞的增殖

背景：以往研究培养毛囊干细胞多使用DMEM/F12+体积分数10%胎牛血清培养基,而进年来开发出的角质细胞无血清培养基也可应用于毛囊干细胞的培养。 目的：观察3种不同培养基对大鼠毛囊干细胞增殖情况及干细胞纯度的影响。 方法：取大鼠触须部皮肤组织,体式显微镜下分离出毛囊组织,中性蛋白酶Ⅱ与胰蛋白酶和乙二胺四乙酸混合液“两步酶法”消化。所得细胞悬液按细胞数平均分为3份,分别使用角质细胞无血清培养基、DMEM/F12+体积分数10%胎牛血清及角质细胞无血清培养基+体积分数10%胎牛血清共3种培养基培养,Ⅳ型胶原差速贴壁法筛选毛囊干细胞,进行传代培养。 结果与结论：培养毛囊干细胞传至第3代,锥虫蓝染色计数法检测结果显示,此3组间细胞活率差异无显著性意义(P > 0.05)。CCK8比色法检测细胞生长曲线显示,培养前2 d,此3组细胞生长均较缓慢;培养4 d,细胞生长进入对数生长期,3种培养基培养的细胞增殖活性：角质细胞无血清培养基+10%胎牛血清组>DMEM/F12+10%胎牛血清>角质细胞无血清培养基(P < 0.05)。流式细胞仪检测显示,角质细胞无血清培养基组CD34的表达高于角质细胞无血清培养基+10%胎牛血清组(P < 0.05)。DMEM/F12+10%胎牛血清组中CD34、β1-整合素(CD29)及CK15标记物的表达低于其他2组(P < 0.05)。结果表明,角质细胞无血清培养基较DMEM/F12+体积分数10%胎牛血清能培养出纯度更高的毛囊干细胞,并且在此培养基培养的基础上加入血清,能够促进毛囊干细胞的增殖。     

The Skin: A Home to Multiple Classes of Epithelial Progenitor Cells

To maintain homeostasis in the adult skin, epithelial keratinocyte stem cells are thought to divide infrequently giving rise to short-lived (transit amplifying) cells that undergo a limited number of cell divisions and ultimately terminal differentiation. This model for the epidermal stem cell niche has increased in complexity by the multiple putative progenitor keratinocyte populations that have recently been identified in distinct regions of the interfollicular epidermis and hair follicle appendages. Under normal conditions, these progenitor populations are long-lived and able to sustain the cellular input to certain epidermal structures including the interfollicular epidermis and sebaceous gland. Other putative epithelial progenitors derived from the hair follicle possess high in vitro proliferative capacity and are able to regenerate skin, hair and sebaceous lineages in transplantation studies. These new findings present the cutaneous epithelium as a highly compartmentalized structure potentially maintained by multiple classes of progenitor cells. In this review, we will discuss the implications of these new putative epithelial progenitor populations and their potential to be influenced by external stimuli for skin homeostasis and carcinogenesis.     

Stem cell activity of human side population and alpha6 integrin-bright keratinocytes defined by a quantitative in vivo assay

The isolation and characterization of living human epithelial stem cells is difficult because distinguishing cell surface markers have not been identified with certainty. Side population keratinocytes (SP-KCs) that efflux Hoechst 33342 fluorescent dye, analogous to bone marrow-derived side population (SP) hematopoietic stem cells, have been identified in human skin, but their potential to function as keratinocyte stem cells (KSCs) in vivo is not known. On the other hand, human keratinocyte populations that express elevated levels of beta1 and alpha6 integrins and are distinct from SP-KCs, which express low levels of integrins, may be enriched for KSCs based on reported results of in vitro cell culture assays. When in vitro assays were used to measure total cell output of human SP-KCs and integrin-bright keratinocytes, we could not document their superior long-term proliferative activity versus unfractionated keratinocytes. To further assess the KSC characteristics in SP-KCs and integrin-bright keratinocytes, we used an in vivo competitive repopulation assay in which bioengineered human epidermis containing competing keratinocyte populations with different human major histocompatibility (MHC) class I antigens were grafted onto immunocompromised mice, and the intrinsic MHC class I antigens are used to quantify expansion of competing populations. In these in vivo studies, human SP-KCs showed little competitive expansion in vivo and were not enriched for KSCs. In contrast, keratinocytes expressing elevated levels of alpha6 integrin and low levels of CD71 (alpha6-bright/CD71-dim) expanded over 200-fold during the 33-week in vivo study. These results definitively demonstrate that human alpha6-bright/CD71-dim keratinocytes are enriched with KSCs, whereas SP-KCs are not.     

Characterization and localization of side population cells in mouse skin

Recently, the detection of side population (SP) cells, which have the ability to strongly efflux Hoechst 33342 fluorescence dye, has attracted attention as a method of stem cell isolation. We identified SP cells from mouse skin using the same method as from bone marrow. This population almost completely disappeared after treatment with the calcium channel blocker verapamil. SP cells were mainly localized in the epidermis, with a few in the dermis. The ratio of SP cells decreased as the mouse became older. Surface marker analysis revealed that the sorted SP cells expressed alpha6-integrin, beta1-integrin, Sca-1, keratin 14, and keratin 19, which are proliferating and progenitor cell markers, at levels higher than in non-SP cells, while they expressed E-cadherin, CD34, and CD71 at lower levels. The expression of breast cancer resistance protein 1 (BCRP1), which participates in dye efflux, was expressed at high levels at both the protein and mRNA level in sorted SP cells. Immunohistochemical analysis showed that BCRP1 was expressed in the basal layers and hair bulge regions of mouse skin. BCRP1 mRNA was found in basal layers and hair follicles of newborn skin by in situ hybridization. These results indicate that the localization of BCRP1-positive cells is compatible with that of keratinocyte stem cells. Based on the close relationship between BCRP1 and the SP cell phenotype, we conclude that keratinocyte stem cells are closely related to the SP- or BCRP1-positive cells.     

Differential expression of cyclin D1 in the human hair follicle

The proliferation of keratinocytes in the hair follicle varies from slowly cycling, intermittently proliferating stem cells in the bulge to rapidly proliferating, transient cells in the bulb. To better understand the biological differences between these two compartments, we sought to identify differentially expressed genes using cDNA macroarray analysis. Cyclin D1 was one of 13 genes increased in the bulge compared to the bulb, and its differential expression was corroborated by quantitative real-time polymerase chain reaction (PCR) on the original samples. Using immunohistochemical staining, laser-capture microdissection (LCM) and quantitative real-time PCR, we localized cyclin D1 to the suprabasal cells of the telogen bulge and anagen outer root sheath (ORS). Surprisingly, cyclin D1, D2, and D3 were not detectable by immunohistochemistry in the rapidly proliferating hair-producing cells of the anagen bulb (matrix cells), while these cells were strongly positive for Ki-67 and retinoblastoma protein. In contrast, pilomatricoma, a tumor thought to be derived from matrix cells, was positive for cyclin D1, D2, and D3. Our results suggest that cyclin D1 may mediate the proliferation of stem cells in the bulge to more differentiated transient amplifying cells in the suprabasal ORS. In contrast, non-cyclin D1-proteins appear to control cell division of the highly proliferative bulb matrix cells. This non-cyclin D1-mediated proliferation may provide a protective mechanism against tumorigenesis, which is overridden in pilomatricomas. Our data also demonstrate that the combination of DNA macroarray, LCM and quantitative real-time PCR is a powerful approach for the study of gene expression in defined cell populations with limited starting material.     

Epidermal stem cells

The clinical implications of understanding epidermal stem cell biology abound. Thousands of burns victims across the world have benefited from early research into the proliferation of epidermal keratinocytes in vitro. Advances now indicate there are a number of stem cell repositories within the epidermis, two of which, the interfollicular epidermis and the bulge region of the hair follicle, may supply each other when damaged. This review details the progress made in the identification and characterisation of stem cells within the epidermis and discusses the molecules involved in the epidermal stem cell's choice of fate. Finally, the skin, like bone marrow, could be a readily accessible source of stem cells for therapeutic intervention and evidence of skin stem cell plasticity is highlighted.     

Bone marrow cells engraft within the epidermis and proliferate in vivo with no evidence of cell fusion

In adults, bone marrow-derived cells (BMDC) can contribute to the structure of various non-haematopoietic tissues, including skin. However, the physiological importance of these cells is unclear. This study establishes that bone marrow-derived epidermal cells are proliferative and, moreover, demonstrates for the first time that BMDC can localize to a known stem cell niche: the CD34-positive bulge region of mouse hair follicles. In addition, engraftment of bone marrow cells into the epidermis is significantly increased in wounded skin, bone marrow-derived keratinocytes can form colonies in the regenerating epidermis in vivo, and the colony-forming capacity of these cells can be recapitulated in vitro. In some tissues this apparent plasticity is attributed to differentiation, and in others to cell fusion. Evidence is also provided that bone marrow cells form epidermal keratinocytes without undergoing cell fusion. These data suggest a functional role for bone marrow cells in epidermal regeneration, entering known epidermal stem cell niches without heterokaryon formation.     

Overexpression of Bcl-2 protects from ultraviolet B-induced apoptosis but promotes hair follicle regression and chemotherapy-induced alopecia

Hair follicle (HF) growth and regression is an exquisitely regulated process of cell proliferation followed by massive cell death and is accompanied by cyclical expression of the apoptosis regulatory gene pair, Bcl-2 and Bax. To further investigate the role of Bcl-2 expression in the control of hair growth and keratinocyte apoptosis, we have used transgenic mice that overexpress human Bcl-2 in basal epidermis and in the outer root sheath under the control of the human keratin-14 promoter (K14/Bcl-2). When irradiated with ultraviolet B (UVB) light, K14/Bcl-2 mice developed about 5-10-fold fewer sunburn cells (ie, apoptotic keratinocytes) in the basal layer of the epidermis, compared to wild-type mice, whereas cultures of primary keratinocytes from transgenic mice were completely resistant to UVB-induced histone formation, at doses that readily induced histone release from wild-type cells. K14/Bcl-2 mice show no alteration of neonatal hair follicle morphogenesis or of the onset of the first wave of HF regression (catagen). However, compared to wild-type controls, K14/Bcl-2 mice subsequently displayed a significant acceleration of spontaneous catagen progression. During chemotherapy-induced alopecia, follicular dystrophy was promoted in K14/Bcl-2 mice. Thus, although K14-driven overexpression of Bcl-2 protected murine epidermal keratinocytes from UVB-induced apoptosis, it surprisingly promoted catagen- and chemotherapy-associated keratinocyte apoptosis.     

Extramammary Paget's disease—a proliferation of adnexal origin?

AIM: To investigate a possible follicular origin of extramammary Paget's disease (EPD). EPD is a predominantly intraepidermal tumour with extensive involvement of adnexal structures and high recurrence rates suggesting a follicular stem cell origin. Cytokeratin (CK) 15 and CK19 are considered markers for follicular stem cells located in the hair follicle bulge region. METHODS AND RESULTS: Formalin-fixed paraffin-embedded tissues of 12 cases of primary EPD (three anal, nine vulvar) were studied immunohistochemically with antibodies to CK15 and CK19. All cases of EPD showed polygonal Paget cells in the interfollicular epidermis, hair follicles, sebaceous and apocrine glands distributed individually, in nests and in gland-like areas. The polygonal Paget cells were intimately associated with small, flat, mitotically active, 'compressed' keratinocytes. The large Paget cells uniformly expressed CK19 in 12/12 EPD. The small 'compressed' keratinocytes showed strong cytoplasmic CK15 staining in 9/12 EPD with focal accentuation, while the polygonal Paget cells were negative. CONCLUSIONS: These histological and immunohistochemical observations allow the following conclusions: (i) the small, flat, 'compressed' keratinocytes are an integral part of EPD; (ii) the dual cell population is reminiscent of sebaceous glands with mature sebocytes and germinative keratinocytes; (iii) since both cell types express cytokeratins typical for follicular differentiation, EPD may be a proliferation of adnexal stem cells residing in the infundibulo-sebaceous unit of hair follicles and adnexal structures.     

毛囊干细胞的研究进展

【摘要】毛囊干细胞是毛囊组织维持自我更新的基础,它具有干细胞的一般特征,普遍认为定位于毛囊隆突部。毛囊干细胞的标记物是分离和鉴定细胞的重要依据,在多种信号通路调控下可以分化为毛囊、皮脂腺和表皮。至此,毛囊干细胞在组织工程皮肤中的作用引起人们的关注,就毛囊干细胞的研究进展作一阐述。     

The pathogenesis of primary cicatricial alopecias

Cicatricial (scarring) alopecia results from irreversible damage to epithelial stem cells located in the bulge region of the hair follicle, generally as a result of inflammatory mechanisms (eg, in the context of autoimmune disease). In primary cicactricial alopecia (PCA), the hair follicle itself is the key target of autoaggressive immunity. This group of permanent hair loss disorders can be classified into distinct subgroups, characterized by the predominant peri-follicular inflammatory cell type. In none of these PCA forms do we know exactly why hair follicles begin to attract such an infiltrate. Thus, it is not surprising that halting or even reversing this inflammation in PCA is often extremely difficult. However, increasing evidence suggests that healthy hair follicle epithelial stem cells enjoy relative protection from inflammatory assault by being located in an immunologically "privileged" niche. Because this protection may collapse in PCA, one key challenge in PCA research is to identify the specific signaling pathways that endanger, or restore, the relative immunoprotection of these stem cells. After a summary of pathobiological principles that underlie the development and clinical phenotype of PCA, we close by defining key open questions that need to be answered if more effective treatment modalities for this therapeutically very frustrating, but biologically fascinating, group of diseases are to be developed.