Hair follicle stem cell marker nestin expression in regenerating hair follicles of patients with alopecia areata

Cells that are nestin positive and keratin 15 (K15) negative are located in the hair follicle pluripotent stem cell (hfPS) area (hfPSA). The hfPSA is located within the root of the sebaceous glands, in a region just above the hair follicle bulge area. In the current study, we investigated the expression pattern of the stem cell marker nestin in the hair follicle cycling of patients with alopecia areata. In the normal human scalp, the majority of hair follicles are in the anagen phase of development. While it is often difficult to identify nestin expression in late anagen phases, nestin-expressing cells are easily identified in proliferating cells located in the hfPSA of the growing early and middle anagen phase hair follicles. In patients exhibiting alopecia areata, the middle anagen hair follicles with growing cells were found to be nestin positive and K15 negative. In contrast, the hair follicles undergoing degradation in alopecia areata patients demonstrated lymphocytic infiltration within the nestin- and K15-negative dermal papilla cells. Both the nestin-positive hfPSA and K15-positive hair follicle bulge areas were not damaged in all phases. In addition, the regenerating early anagen hair follicles demonstrated nestin-positive and K15-negative cells within the dermal papilla and in the area surrounding the hair bulb. These results suggest that the nestin-positive cells play an important role not only in the hfPSA, but also in the dermal papilla in the regenerating hair follicle.     

Proteoglycan expression patterns in human hair follicle

BACKGROUND: Proteoglycans (PGs) are known to play key roles in many cellular signalling pathways involved in hair follicle biology. Although some PG core proteins have previously been described in adult human hair follicles, their glycosaminoglycan (GAG) moieties have been less studied. OBJECTIVES: To add knowledge about PG core protein and GAG distributions in human anagen hair follicle and, for selected follicles, during catagen. METHODS: We used immunohistochemistry and immunohistofluorescence to revisit the expression pattern of GAG chains and core proteins in human hair follicle. The studied epitopes included CD44v3, syndecan-1, perlecan, versican, aggrecan, biglycan, heparan sulphate (HS), chondroitin sulphate (CS), dermatan sulphate (DS) and keratan sulphate (KS). RESULTS: The membrane PGs syndecan-1 and CD44v3 were respectively detected in the epithelial part of whole hair and in the outer root sheath basal layer. The dermal part of the hair follicle contained high amounts of extracellular PGs such as perlecan, versican, aggrecan, biglycan and their saccharidic moieties, namely HS, CS, DS and KS. We also observed a variable distribution of these components along the hair follicle. Especially, we noted a PG impoverishment at the very bottom of the anagen bulb. Moreover, while type D chondroitin expression remained unaffected, 4C3-CS and PG4-CS/DS epitopes respectively decreased in the dermal papilla and the connective tissue sheath, at the onset of catagen. CONCLUSIONS: GAG and PG expression along the human anagen hair follicle was characterized by (i) discontinuities mainly affecting the basement membrane and (ii) disappearance of some epitopes at catagen onset. These results are discussed in term of functionalities in nutrient diffusion, cell proliferation and differentiation, and hair protection.     

Functional anatomy of the hair follicle: The Secondary Hair Germ

The secondary hair germ (SHG)—a transitory structure in the lower portion of the mouse telogen hair follicle (HF)—is directly involved in anagen induction and eventual HF regrowth. Some crucial aspects of SHG functioning and ontogenetic relations with other HF parts, however, remain undefined. According to recent evidence (in contrast to previous bulge‐centric views), the SHG is the primary target of anagen‐inducing signalling and a source of both the outer root sheath (ORS) and ascending HF layers during the initial (morphogenetic) anagen subphase. The SHG is comprised of two functionally distinct cell populations. Its lower portion (originating from lower HF cells that survived catagen) forms all ascending HF layers, while the upper SHG (formed by bulge‐derived cells) builds up the ORS. The predetermination of SHG cells to a specific morphogenetic fate contradicts their attribution to the “stem cell” category and supports SHG designation as a “germinative” or a “founder” cell population. The mechanisms of this predetermination driving transition of the SHG from “refractory” to the “competent” state during the telogen remain unknown. Functionally, the SHG serves as a barrier, protecting the quiescent bulge stem cell niche from the extensive follicular papilla/SHG signalling milieu. The formation of the SHG is a prerequisite for efficient “precommitment” of these cells and provides for easier sensing and a faster response to anagen‐inducing signals. In general, the formation of the SHG is an evolutionary adaptation, which allowed the ancestors of modern Muridae to acquire a specific, highly synchronized pattern of hair cycling.     

Hair cycle-dependent changes in adrenergic skin innervation, and hair growth modulation by adrenergic drugs

Skin nerves may exert "trophic" functions during hair follicle development, growth, and/or cycling. Here, we demonstrate hair cycle-related plasticity in the sympathetic innervation of skin and hair follicle in C57BL/6 mice. Compared with telogen skin, the number of nerve fibers containing norepinephrine or immunoreactive for tyrosine hydroxylase increased during the early growth phase of the hair cycle (anagen) in dermis and subcutis. The number of these fibers declined again during late anagen. beta2-adrenoreceptor-positive keratinocytes were transiently detectable in the noncycling hair follicle epithelium, especially in the isthmus and bulge region, but only during early anagen. In early anagen skin organ culture, the beta2-adrenoreceptor agonist isoproterenol promoted hair cycle progression from anagen III to anagen IV. The observed hair cycle-dependent changes in adrenergic skin innervation on the one hand, and hair growth modulation by isoproterenol, accompanied by changes in beta2-adrenoreceptor expression of selected regions of the hair follicle epithelium on the other, further support the concept that bi-directional interactions between the hair follicle and its innervation play a part in hair growth control. This invites one to systematically explore the neuropharmacologic manipulation of follicular neuroepithelial interactions as a novel therapeutic strategy for managing hair growth disorders.     

Hair cycle-specific expression of versican in human hair follicles

BACKGROUND: Versican, a large chondroitin sulfate proteoglycan molecule, is implicated in the induction of hair morphogenesis, the initiation of hair regeneration, and the maintenance of hair growth in mouse species. In contrast, in human hair follicles, the distribution and the roles of versican remains obscure. OBJECTIVES: To elucidate the implication of versican in normal human hair growth. METHODS: Versican expression was examined by in situ hybridization (mRNA) and immunohistochemistry (protein). RESULTS: The results clearly showed specific versican gene expression in the dermal papilla of anagen, which apparently decreased in the dermal papilla of catagen hair follicles. No specific signal was detectable in telogen hair follicles. Consistent with ISH results, versican immunoreactivity was extended over the dermal papilla of anagen hair follicles, and again, this staining diminished in the catagen phase of human hair follicles. Interestingly, versican proteins were deposited outside K15-positive epithelial cells in the bulge throughout the hair cycle. Versican immunoreactivity in the dermal papilla was almost lost in vellus-like hair follicles affected by male pattern baldness. CONCLUSION: Specific expression of versican in the anagen hair follicles suggests its importance to maintain the normal growing phase of human as well as mouse.     

Hair follicle expression of 1,25-dihydroxyvitamin D3 receptors during the murine hair cycle

Because the hair follicle is a highly hormone-sensitive miniorgan, the role of hormones produced locally in the skin in the control of hair growth deserves systematic analysis. It has been shown previously that the potent steroid hormone 1,25-dihydroxyvitamin D₃ (1,25-D₃) modulates growth and differentiation of keratinocytes via binding to a high-affinity nuclear vitamin D receptor (VDR). In this study, we have examined the in situ expression of VDR during the murine hair cycle. VDR expression was detected immunohistochemically. To obtain defined stages of the murine hair cycle, hair growth was induced by depilation in C57 BL-6 mice. In addition to the recognized VDR expression of outer root sheath keratinocytes, we detected VDR immunoreactive cells in the dermal papilla, the mesenchymal key structure of the hair follicle. Furthermore, VDR immunoreactivity in the nuclei of outer root sheath keratinocytes and in dermal papilla cells was stronger during anagen IV-VI and catagen than during telogen and anagen I-III. This suggests hair cycle-associated changes in the expression of VDR, and points to a potential role for 1,25-D₃ in hair follicle biology. Selected follicular cell populations may display hair cycle-dependent sensitivity to 1,25-D₃ stimulation.     

Epimorphin expression during human foetal hair follicle development

Epimorphin is a mesenchymal protein expressed in several organs and known to have an essential role in epithelial tissue organization, including hair follicle morphogenesis, in mice. Although about 90% homology has been reported between human and mouse epimorphin exon sequences, there is no information about expression and function of epimorphin in hair follicle development in humans. In order to elucidate the expression pattern of epimorphin in human hair follicle morphogenesis and to compare it with the distribution of tenascin and neural cell adhesion molecule (NCAM), skin samples from human foetuses of a series of estimated gestational ages (EGAs) (46-168 days EGA) were studied using monoclonal anti-epimorphin antibody MC-1, anti-tenascin antibody and anti-human NCAM antibody. Epimorphin was detected in the mesenchymal cell condensation at the pregerm stage (< 75 days EGA), and there was strong expression of epimorphin in the perifollicular mesenchymal cells around the hair germ (75-84 days EGA). At the hair peg stage (85-104 days EGA), epimorphin was around the hair peg with the strongest staining in the neck portion. This sequence of staining patterns was similar to that of tenascin. In the bulbous hair peg (105-134 days EGA), the perifollicular dermal mesenchymal cells were evenly positive for epimorphin. Mesenchymal cells underneath the follicle bulb prior to formation of the dermal papilla were also positive for epimorphin. In the lanugo hair follicle (> 134 days EGA), dermal papilla cells expressed epimorphin as well as tenascin and NCAM. These results indicate that epimorphin expression is closely linked to developing hair follicles in human foetuses. This suggests that epimorphin may have an important part in induction of morphogenesis during human foetal hair follicle development.     

大疱性类天疱疮抗原2在毛发周期不同阶段的表达情况

目的：研究大疱性类天疱疮抗原2(BPAG2)在毛发周期不同阶段的表达情况及其对毛发生长和毛发周期的影响。方法：间接免疫荧光、免疫组化、透射电镜和原位杂交。结果：BPAG2和其它基底膜相关分子如层粘连蛋白一样，在整个毛发周期中持续表达，不随毛发周期的不同阶段发生周期性变化。透射电镜研究发现在人头发毛囊的玻璃膜位置存在半桥粒结构。结论：BPAG2的持续表达说明它对于毛囊的作用主要是参与半桥粒的组成，维持结构稳定，而不是直接参与毛发周期的调节。     

Hair follicle kinetics in psoriasis

The rate of epidermal cell production has been measured in the various parts of scalp hair follicles in patients with psoriasis of the scalp, and in controls with normal scalp skin. An in vitro technique was used in which thin tissue slices were exposed to tritiated thymidine enabling cells about to divide to become autoradiographically labelled. Biopsies from thirteen patients with psoriasis and nine controls were examined in this way. The labelling indices of the interfollicular epidermis was 27-5% in the psoriatics and 9-5% in the controls. The upper part of the external root sheath had a labelling index of 28% in the psoriatic group compared to 13-9% for the controls. The labelling indices of the sebaceous glands, matrices and external root sheaths were very similar in the two groups. The findings support the hypothesis for a dermal stimulating influence causing the increased epidermopoiesis seen in psoriasis.     

Integral hair lipid in human hair follicle

Integral hair lipid (IHL) is bound to the keratinized cell surface to make an environmentally resistant lipid envelope. It is mainly positioned on the hair cuticle and inner root sheath. IHL in the hair follicle may regard as hair barrier to be similar to the epidermal lipid layer functioning as skin barrier. Major constituents of IHL are fatty acid, phytosphingosine, ceramide in decreasing order. Minor constituents of IHL are cholesterol, cholesterol sulfate and cholesterol oleate. Cuticle or cortical cell surface in hair are abundant in fatty acids unlike the keratinized area of epidermis or sebaceous gland, and about 30-40% of such fatty acids are composed of 18-methyl-eicosanoic acid which is known to be bound to proteins by ester or thioester bond. Various factors including moisture, solvent, oxidative damage during bleaching or permanent waving affect IHL. Photochemical changes also can occur in IHL as well as in hair protein and hair pigment. Lipid metabolism is thought to play an essential role in lipid envelope of hair, but also involvement in hair development and function.     

Bone morphogenetic proteins and their antagonists in skin and hair follicle biology

Bone morphogenetic proteins (BMP) are members of the transforming growth factor-beta superfamily regulating a large variety of biologic responses in many different cells and tissues during embryonic development and postnatal life. BMP exert their biologic effects via binding to two types of serine/threonine kinase BMP receptors, activation of which leads to phosphorylation and translocation into the nucleus of intracellular signaling molecules, including Smad1, Smad5, and Smad8 ("canonical" BMP signaling pathway). BMP effects are also mediated by activation of the mitogen-activated protein (MAP) kinase pathway ("noncanonical" BMP Signaling pathway). BMP activity is regulated by diffusible BMP antagonists that prevent BMP interactions with BMP receptors thus modulating BMP effects in tissues. During skin development, BMPs its receptors and antagonists show stringent spatiotemporal expressions patterns to achieve proper regulation of cell proliferation and differentiation in the epidermis and in the hair follicle. In normal postnatal skin, BMP are involved in the control of epidermal homeostasis, hair follicle growth, and melanogenesis. Furthermore, BMP are implicated in a variety of pathobiologic processes in skin, including wound healing, psoriasis, and carcinogenesis. Therefore, BMPs represent new important players in the molecular network regulating homeostasis in normal and diseased skin. Pharmacologic modulation of BMP signaling may be used as a new approach for managing skin and hair disorders.     

Neuron-specific PGP9.5 expression in rat hair follicle development and cycle

Protein gene product PGP9.5 is a neuron-specific ubiquitin C-terminal hydrolase. We found that it also has immunoreactivity in the hair follicle of the Wistar rat dorsal skin and its expression patterns change with the development and cycle. During the morphogenesis, the PGP9.5 was expressed in the hair germ and hair peg elongated from the epidermis, and became restricted in the outer root sheath as the development progressed. In catagen, however, the PGP9.5 was detected in the tailing epithelial strand of the regressing proximal follicle epithelium, and in the keratinocytes directly contacted with the club hair, but rarely in the outer root sheath. With the beginning of the anagen of the second hair follicle, the PGP9.5 was again expressed in the second hair germ, and in the keratinocytes surrounding the remaining club hair and of distal follicle of the first hair. These findings showed that PGP9.5 is not specific to the neuron but is also involved in the hair follicle, and should provide new insight into the development and regression of the hair follicle.     

Apoptosis in the hair follicle

Apoptosis plays an important role in many physiological processes, ranging from morphogenetic events to adult tissue homeostasis, and defects in its regulation contribute to many disorders. Here we review molecular mechanisms of apoptosis in the hair follicle (HF), whose cyclical growth pattern is repeatedly interrupted by apoptosis-driven involution (catagen). We review the common mechanisms underlying apoptosis in the HF during catagen, as well as differences in the regulation of apoptosis between distinct HF cell populations. An overview is provided on the expression and function of molecules involved in the control of various phases of the apoptotic process during catagen.     

Oligonucleotide treatment increases eumelanogenesis, hair pigmentation and melanocortin-1 receptor expression in the hair follicle

It was previously reported that telomere homologue oligonucleotides (T-oligos) can induce a variety of cellular responses in skin including increased melanogenesis. To assess the effects of T-oligos on hair pigmentation, we administered thymidine dinucleotide (pTT), one-third of the TTAGGG telomere repeat sequence, intradermally at distinct time points of the depilation-induced hair cycle in C3H/HeJ mice. Penetration of T-oligos into the hair follicle (HF) was monitored by using FITC-labelled pTT and confocal microscopy. pTT treatment on days 1-5 after depilation, during early anagen, did not significantly alter the number and proliferation of melanocytes (Trp-2-positive cells), compared with vehicle-treated controls. However, pTT treatment on days 5-12 after depilation, during mid- to late anagen, resulted in the formation of darker hairs, that showed a significantly increased eumelanin/total melanin ratio in their sub-apical agouti band region, compared with vehicle-treated controls (P < 0.05). By RT-PCR and western blot, full thickness skin of pTT-treated mice showed increases in Trp-1, Trp-2 and tyrosinase mRNA and protein levels, compared with control mice. Western blot analyses of two receptors that positively regulate eumelanogenesis, melanocortin type 1 receptor (MC-1R) and kit, showed increased expression of MC-1R protein in pTT-treated versus control skin, while the levels of c-kit receptor remained unchanged. These data demonstrate that pTT treatment increases eumelanogenesis in HFs, associated with increased tyrosinase, TRP-1 and MC-1R expression. These data also raise the possibility of using T-oligos to modulate hair pigmentation.