In vivo regulation of murine hair growth: insights from grafting defined cell populations onto nude mice

A graft model for hair development

Follicular cell implantation (FCI) is an experimental cell therapy for the treatment of hair loss that uses cultured hair follicle cells to induce new hair formation. This treatment is based on the demonstration that adult dermal papilla cells (DPC) retain the hair inductive capacity they acquired during hair morphogenesis in the embryo. For FCI, hair inductive cells are isolated from scalp biopsies and then propagated in culture in order to provide enough cells to generate many new follicles from a few donor follicles. Following expansion in culture, the cells are implanted into the scalp where they induce the formation of new follicles. Because the process relies on the ability to retain the potential for hair induction during the expansion of DPC in culture, we sought a consistent, reliable and easily performed in vivo assay in which to test hair induction. In this study, we describe a simple graft model that supports hair morphogenesis. The assay combines dermal cells with embryonic mouse epidermis that provides the keratinocyte component of induced follicles. The grafts are placed under a protective skin flap in the host athymic mouse where the cells will form a skin graft with hair if the dermal cells are hair inductive DPC. Using the assay, freshly isolated and cultured mouse embryo dermal cells as well as cultured dermal papilla cells from other species all induced hair formation. The induced hairs were aesthetically indistinguishable from those of the epidermal donor in length, thickness, and pigmentation, and they were histologically normal.

Distinct epidermal stem cell compartments are maintained by independent niche microenvironments

The mammalian epidermis is a stratified, multilayered epithelium, consisting of the interfollicular epidermis and associated appendages, which extend into the dermis and include hair follicles, sebaceous glands, and sweat glands. Stem cells are essential for the maintenance of this tissue and are also potential sources of multipotent adult precursor cells. Stem cell populations occupying specific locations or niches have been identified in the interfollicular epidermis, the hair follicle and the sebaceous gland. Recent research has focused on how the stem cell niches provide specific sites where stem cells can reside indefinitely and undergo self-renewal or differentiation into specific cell lineages, as required for epidermal replenishment or hair follicle growth.

In vitro expansion of immature melanoblasts and their ability to repopulate melanocyte stem cells in the hair follicle

Elucidation of the molecular mechanisms underlying stem cell regulation is of great importance both for basic biology and for clinical applications. Melanocyte stem cells (MSCs) are an excellent model in which to study the molecular basis of stem cell regulation, as the genetic alterations involved in the maintenance of the stem cells are readily identifiable by a premature hair graying phenotype. Research on MSCs has been hampered by the lack of a reliable system to assay their function. Here, by co-culturing highly purified melanoblasts (MBs) with XB2 keratinocytes, we describe an efficient culture method that allows the expansion of immature MBs in vitro. These MBs are also capable of undergoing terminal differentiation into mature melanocytes (MCs) when differentiation is induced. Furthermore, by performing a hair-follicle reconstitution assay in which expanded MBs in a mixture of epidermal and dermal cells were grafted to reconstitute a hair follicle, we demonstrate that the expanded MBs retain their capacity to become incorporated into newly developed hair follicles and repopulate the MC stem cell population there. Thus, by integrating genetic manipulations in cultured MBs in vitro, this method provides a powerful tool with which to study the molecular basis of stem cell regulation.

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.

Isolation of a mesenchymal cell population from murine dermis that contains progenitors of multiple cell lineages

The skin contains two known subpopulations of stem cells/epidermal progenitors: a basal keratinocyte population found in the interfollicular epithelium and cells residing in the bulge region of the hair follicle. The major role of the interfollicular basal keratinocyte population may be epidermal renewal, whereas the bulge population may only be activated and recruited to form a cutaneous epithelium in case of trauma. Using 3-dimensional cultures of murine skin under stress conditions in which only reserve epithelial cells would be expected to survive and expand, we demonstrate that a mesenchymal population resident in neonatal murine dermis has the unique potential to develop an epidermis in vitro. In monolayer culture, this dermal subpopulation has long-term survival capabilities in restricted serum and an inducible capacity to evolve into multiple cell lineages, both epithelial and mesenchymal, depending on culture conditions. When grafted subcutaneously, this dermal subpopulation gave rise to fusiform structures, reminiscent of disorganized muscle, that stained positive for smooth muscle actin and desmin; on typical epidermal grafts, abundant melanocytes appeared throughout the dermis that were not associated with hair follicles. The multipotential cells can be repeatedly isolated from neonatal murine dermis by a sequence of differential centrifugation and selective culture conditions. These results suggest that progenitors capable of epidermal differentiation exist in the mesenchymal compartment of an abundant tissue source and may have a function in mesenchymal-epithelial transition upon insult. Moreover, these cells could be available in sufficient quantities for lineage determination or tissue engineering applications.

Intrinsic differences among spatially distinct neural crest stem cells in terms of migratory properties, fate determination, and ability to colonize the enteric nervous system

We have systematically examined the developmental potential of neural crest stem cells from the enteric nervous system (gut NCSCs) in vivo to evaluate their potential use in cellular therapy for Hirschsprung disease and to assess differences in the properties of postmigratory NCSCs from different regions of the developing peripheral nervous system (PNS). When transplanted into developing chicks, flow-cytometrically purified gut NCSCs and sciatic nerve NCSCs exhibited intrinsic differences in migratory potential and neurogenic capacity throughout the developing PNS. Most strikingly, gut NCSCs migrated into the developing gut and formed enteric neurons, while sciatic nerve NCSCs failed to migrate into the gut or to make enteric neurons, even when transplanted into the gut wall. Enteric potential is therefore not a general property of NCSCs. Gut NCSCs also formed cholinergic neurons in parasympathetic ganglia, but rarely formed noradrenergic sympathetic neurons or sensory neurons. Supporting the potential for autologous transplants in Hirschsprung disease, we observed that Endothelin receptor B (Ednrb)-deficient gut NCSCs engrafted and formed neurons as efficiently in the Ednrb-deficient hindgut as did wild-type NCSCs. These results demonstrate intrinsic differences in the migratory properties and developmental potentials of regionally distinct NCSCs, indicating that it is critical to match the physiological properties of neural stem cells to the goals of proposed cell therapies.

Epithelial skin stem cells

Major progress in understanding epithelial skin stem cells has been accomplished. This has been possible by developing new methods for labeling, tracking, isolating, and characterizing enriched populations of stem cells. This chapter summarizes in vivo and in vitro assays that are currently employed to analyze skin epithelial stem cells. Despite progress, the definition of a stem cell is currently a functional one. Unambiguous identification of a stem cell in intact tissue is still not possible. These limitations hamper molecular studies aimed at unraveling the cellular mechanisms operating in the stem cell compartment. This chapter emphasizes current methods for analyzing hair follicle stem cells, as opposed to other epithelial compartments, because the hair follicle has been most intensively studied up to date.

Host immune responses in ex vivo approaches to cutaneous gene therapy targeted to keratinocytes

Epidermal gene therapy may benefit a variety of inherited skin disorders and certain systemic diseases. Both in vivo and ex vivo approaches of gene transfer have been used to target human epidermal stem cells and achieve long-term transgene expression in immunodeficient mouse/human chimera models. Immunological responses however, especially in situations where a neoantigen is expressed, are likely to curtail expression and thereby limit the therapy. In vivo gene transfer to skin has been shown to induce transgene-specific immune responses. Ex vivo gene transfer approaches, where keratinocytes are transduced in culture and transplanted back to patient, however, may avoid signals provided to the immune system by in vivo administration of vectors. In the current study, we have developed a stable epidermal graft platform in immunocompetent mice to analyze host responses in ex vivo epidermal gene therapy. Using green fluorescent protein (GFP) as a neoantigen and an ex vivo retrovirus-mediated gene transfer to mouse primary epidermal cultures depleted of antigen-presenting cells (APCs), we show induction of GFP-specific immune responses leading to the clearance of transduced cells. Similar approach in immunocompetent mice tolerant to GFP resulted in permanent engraftment of transduced cells and continued GFP expression. Activation of transgene-specific immune responses in ex vivo gene transfer targeted to keratinocytes require cross-presentation of transgene product to APCs, a process that is most amenable to immune modulation. This model may be used to explore strategies to divert transgene-specific immune responses to less destructive or tolerogenic ones.

Molecular dissection of mesenchymal-epithelial interactions in the hair follicle

De novo hair follicle formation in embryonic skin and new hair growth in adult skin are initiated when specialized mesenchymal dermal papilla (DP) cells send cues to multipotent epithelial stem cells. Subsequently, DP cells are enveloped by epithelial stem cell progeny and other cell types to form a niche orchestrating hair growth. Understanding the general biological principles that govern the mesenchymal–epithelial interactions within the DP niche, however, has been hampered so far by the lack of systematic approaches to dissect the complete molecular make-up of this complex tissue. Here, we take a novel multicolor labeling approach, using cell type–specific transgenic expression of red and green fluorescent proteins in combination with immunolabeling of specific antigens, to isolate pure populations of DP and four of its surrounding cell types: dermal fibroblasts, melanocytes, and two different populations of epithelial progenitors (matrix and outer root sheath cells). By defining their transcriptional profiles, we develop molecular signatures characteristic for the DP and its niche. Validating the functional importance of these signatures is a group of genes linked to hair disorders that have been largely unexplored. Additionally, the DP signature reveals novel signaling and transcription regulators that distinguish them from other cell types. The mesenchymal–epithelial signatures include key factors previously implicated in ectodermal-neural fate determination, as well as a myriad of regulators of bone morphogenetic protein signaling. These findings establish a foundation for future functional analyses of the roles of these genes in hair development. Overall, our strategy illustrates how knowledge of the genes uniquely expressed by each cell type residing in a complex niche can reveal important new insights into the biology of the tissue and its associated disease states.

Determining the molecular signature of the cells that orchestrate hair follicle growth generates new insights that will aid in understanding the normal biology and disease states of this tissue.

An In Vivo Mouse Model of Human Skin Substitute Containing Spontaneously Sorted Melanocytes Demonstrates Physiological Changes after UVB Irradiation

Human skin substitutes (HSS) have been developed for repairing burns and other acute or chronic wounds. But although the clinical utility of HSS is well known, scant attention has been paid to their cosmetic properties, especially with regard to color compatibility with the patient's complexion. In this study, we generated an HSS from mixed cell slurries containing keratinocytes and fibroblasts with and without melanocytes on the back of severe combined immunodeficient mice by means of a spontaneous cell-sorting technique. At 16 wk after grafting, Caucasian donor-derived HSS with melanocytes were macroscopically clearly darker than those without melanocytes, and a more darkly pigmented HSS was produced when cells from donors of African descent were seeded. Immunohistochemistry of c-kit, S-100, and HMB45, as well as Fontana-Masson staining and transmission electron microscopy (TEM) demonstrated that melanocytes spontaneously localized to the basal layer. Melanosome transfer to keratinocytes was correctly reorganized, and melanin was evenly dispersed in the basal and suprabasal layers. Colorimetric analysis showed a significantly lower L-value by day 14 following irradiation with 120 mJ per cm2 ultraviolet-B (UVB) (p<0.01), whereas epidermal thickness increased by 50% 1 d after exposure (p<0.01), indicating a normal physiological response to UVB irradiation. These findings suggest that HSS with spontaneously sorted melanocytes offer a means of treating both the structural and cosmetic aspects of skin conditions and trauma, such as pigmentary disorders and skin wounds, by allowing manipulation of the color and population of donor melanocytes.

Organogenesis from dissociated cells: generation of mature cycling hair follicles from skin-derived cells

Hair follicle formation and cycling involve extensive and continuous interactions between epithelial and mesenchymal components. A system for rapidly and reproducibly generating hair follicles from dissociated epithelial and mesenchymal cells is described here. The system serves both as a tool for measuring the trichogenic property of cells and as a tool for studying the mechanisms that dissociated cells use to assemble an organ. In this system, hair follicles develop when dissociated cells, isolated from newborn mouse skin, are injected into adult mouse truncal skin. This morphogenetic process involves the aggregation of epithelial cells to form clusters that are sculpted by apoptosis to generate "infundibular cysts". From the "infundibular cysts", hair germs form centrifugally followed by follicular buds and then pegs that grow asymmetrically to differentiate into cycling mature pilosebaceous structures. Marker studies correlate the molecular differentiation of these follicles with in situ systems. This study suggests that the earliest phase of a developing epithelial-mesenchymal system--even from dissociated cell preparations--requires an epithelial platform.

Sustained Hedgehog signaling is required for basal cell carcinoma proliferation and survival: conditional skin tumorigenesis recapitulates the hair growth cycle

Temporally and spatially constrained Hedgehog (Hh) signaling regulates cyclic growth of hair follicle epithelium while constitutive Hh signaling drives the development of basal cell carcinomas (BCCs), the most common cancers in humans. Using mice engineered to conditionally express the Hh effector Gli2, we show that continued Hh signaling is required for growth of established BCCs. Transgene inactivation led to BCC regression accompanied by reduced tumor cell proliferation and increased apoptosis, leaving behind a small subset of nonproliferative cells that could form tumors upon transgene reactivation. Nearly all BCCs arose from hair follicles, which harbor cutaneous epithelial stem cells, and reconstitution of regressing tumor cells with an inductive mesenchyme led to multilineage differentiation and hair follicle formation. Our data reveal that continued Hh signaling is required for proliferation and survival of established BCCs, provide compelling support for the concept that these tumors represent an aberrant form of follicle organogenesis, and uncover potential limitations to treating BCCs using Hh pathway inhibitors.

Self-renewal, multipotency, and the existence of two cell populations within an epithelial stem cell niche

In adult skin, each hair follicle contains a reservoir of stem cells (the bulge), which can be mobilized to regenerate the new follicle with each hair cycle and to reepithelialize epidermis during wound repair. Here we report new methods that permit their clonal analyses and engraftment and demonstrate the two defining features of stem cells, namely self-renewal and multipotency. We also show that, within the bulge, there are two distinct populations, one of which maintains basal lamina contact and temporally precedes the other, which is suprabasal and arises only after the start of the first postnatal hair cycle. This spatial distinction endows them with discrete transcriptional programs, but surprisingly, both populations are growth inhibited in the niche but can self-renew in vitro and make epidermis and hair when grafted. These findings suggest that the niche microenvironment imposes intrinsic "stemness" features without restricting the establishment of epithelial polarity and changes in gene expression.

Characterization of hair follicles induced in implanted, cultured rat keratinocyte sheets

Cultured rat keratinocyte sheets form hair follicles in combination with rat vibrissa dermal papillae when they are transplanted subcutaneously in syngeneic rats and athymic mice. In the present study, the histologic details of these induced follicles were analyzed by preparing cultured sheets mixed with normal rat keratinocytes and green fluorescent protein (GFP)-transgenic rat keratinocytes. Histologic examination demonstrated that some induced follicles maintained their size and morphology for at least 18 weeks, whereas others decreased in size and others totally differentiated into cornified structures between 3 and 6 weeks. The percentage of the grafts with GFP-positive cells decreased during the same period. This finding suggests that some GFP-positive cells were transient-amplifying cells that turned into terminally differentiated cells and were lost during this period. Some large follicles and some small follicles maintained their hair-producing ability and the proliferative activity in their hair matrix for 18 weeks. In addition, one 6-week-old follicle contained label-retaining cells in the outer root sheath. Seven of 25 follicles induced from chimera epithelium contained both GFP-positive cells and GFP-negative cells. These results suggest that stem cells are present in the induced follicle and the induced follicle consists of polyclonally derived cells. The presence of early anagen-like large follicles at week 6 and 9 and a telogen-like small follicle at week 18 also suggests that hair-growth cycle phases proceeded in the induced follicles. In conclusion, the follicles induced in the cultured keratinocyte sheets maintained hair-producing ability and proliferative activity for at least 18 weeks. This and the presence of label-retaining cells suggest that there are stem cells in the induced follicles, which seem to have a hair-growth cycle.

Novel Collagen Sponge Reinforced with Polyglycolic Acid Fiber Produces Robust, Normal Hair in Murine Hair Reconstitution Model

The hair reconstitution assay is a useful system for studying cell-cell and epithelial-mesenchymal interaction. The current method consists of transplantation of both epidermal and dermal cells, using a silicone chamber placed on an athymic nude mouse. However, because of leakage and tilting of the grafted cells, the rate and area of hair growth vary depending on the chamber. We modified this method by using a collagen sponge as a scaffold and compared two types of collagen sponges, each having different tensile strengths. A conventional collagen sponge disturbed normal hair follicle formation; in contrast, a collagen sponge containing polyglycolic acid (PGA) fiber supported proper restructuring of skin and hair follicles. These data suggested the usefulness of PGA fiber-containing collagen sponges for hair reconstitution in research and clinical applications.

Participation of adult mouse bone marrow cells in reconstitution of skin

Results of recent studies have indicated that bone marrow cells can differentiate into various cells of ectodermal, mesodermal, and endodermal origins when transplanted into the body. However, the problems associated with those experiments such as the long latent period, rareness of the event, and difficulty in controlling the processes have hampered detailed mechanistic studies. In the present study, we examined the potency of mouse bone marrow cells to differentiate into cells comprising skin tissues using a skin reconstitution assay. Bone marrow cells from adult green fluorescent protein (GFP)-transgenic mice were transplanted in a mixture of embryonic mouse skin cells (17.5 days post-coitus) onto skin defects made on the backs of nude mice. Within 3 weeks, fully differentiated skin with hair was reconstituted. GFP-positive cells were found in the epidermis, hair follicles, sebaceous glands, and dermis. The localization and morphology of the cells, results of immunohistochemistry, and results of specific staining confirmed that the bone marrow cells had differentiated into epidermal keratinocytes, sebaceous gland cells, follicular epithelial cells, dendritic cells, and endothelial cells under the present conditions. These results indicate that this system is suitable for molecular and cellular mechanistic studies on differentiation of stem cells to various epidermal and dermal cells.

Animal and in vitro models for the study of hair follicles

Since the way in which the hair follicle functions is not well understood, many hair disorders are poorly controlled. A range of in vitro and in vivo models have therefore been developed to investigate the cell biological and biochemical mechanisms involved in the organization of this complex tissue. These range from cultures of a single cell type, such as those of the regulatory, mesenchyme-derived dermal papilla, through organ culture of isolated follicles to natural or genetically manipulated animal models. Each system has advantages and disadvantages for studying particular aspects of follicular function and some are potentially useful for the development of novel treatments for hair disorders.

Molecular insights into the hair follicle and its pathology: a review of recent developments

In the last few years by means of the elucidation of the human genome and the acquisition of powerful investigative tools we have begun to understand the molecular basis of hair follicle growth control. In this article I will describe some of the salient recent contributions to the field and review the implications these findings have had on our understanding of mechanisms in dermatology and dermatopathology.

Mice lacking Smad3 are protected against cutaneous injury induced by ionizing radiation

Transforming growth factor-beta (TGF-beta) plays a central role in the pathogenesis of inflammatory and fibrotic diseases, including radiation-induced fibrosis. We previously reported that mice null for Smad3, a key downstream mediator of TGF-beta, show accelerated healing of cutaneous incisional wounds with reduced inflammation and accumulation of matrix. To determine if loss of Smad3 decreases radiation-induced injury, skin of Smad3+/+ [wild-type (WT)] and -/- [knockout (KO)] mice was exposed to a single dose of 30 to 50 Gy of gamma-irradiation. Six weeks later, skin from KO mice showed significantly less epidermal acanthosis and dermal influx of mast cells, macrophages, and neutrophils than skin from WT littermates. Skin from irradiated KO mice exhibited less immunoreactive TGF-beta and fewer myofibroblasts, suggesting that these mice will have a significantly reduced fibrotic response. Although irradiation induced no change in the immunohistochemical expression of the TGF-beta type I receptor, the epidermal expression of the type II receptor was lost after irradiation whereas its dermal expression remained high. Primary keratinocytes and dermal fibroblasts prepared from WT and KO mice showed similar survival when irradiated, as did mice exposed to whole-body irradiation. These results suggest that inhibition of Smad3 might decrease tissue damage and reduce fibrosis after exposure to ionizing irradiation.

Controls of hair follicle cycling

Nearly 50 years ago, Chase published a review of hair cycling in which he detailed hair growth in the mouse and integrated hair biology with the biology of his day. In this review we have used Chase as our model and tried to put the adult hair follicle growth cycle in perspective. We have tried to sketch the adult hair follicle cycle, as we know it today and what needs to be known. Above all, we hope that this work will serve as an introduction to basic biologists who are looking for a defined biological system that illustrates many of the challenges of modern biology: cell differentiation, epithelial-mesenchymal interactions, stem cell biology, pattern formation, apoptosis, cell and organ growth cycles, and pigmentation. The most important theme in studying the cycling hair follicle is that the follicle is a regenerating system. By traversing the phases of the cycle (growth, regression, resting, shedding, then growth again), the follicle demonstrates the unusual ability to completely regenerate itself. The basis for this regeneration rests in the unique follicular epithelial and mesenchymal components and their interactions. Recently, some of the molecular signals making up these interactions have been defined. They involve gene families also found in other regenerating systems such as fibroblast growth factor, transforming growth factor-beta, Wnt pathway, Sonic hedgehog, neurotrophins, and homeobox. For the immediate future, our challenge is to define the molecular basis for hair follicle growth control, to regenerate a mature hair follicle in vitro from defined populations, and to offer real solutions to our patients' problems.

p21(WAF1/Cip1) functions as a suppressor of malignant skin tumor formation and a determinant of keratinocyte stem-cell potential

p21(WAF1/Cip1) is one of the best characterized downstream targets of p53, and the growth suppressing function of this cyclin-dependent kinase inhibitor is well established. However, whether p21 exerts a tumor-suppressing function of its own remains to be established. We report here that, similarly to loss of p53, disruption of the p21(WAF1/Cip1) gene results in a markedly increased susceptibility to chemically induced skin carcinoma formation, whereas the number of papillomas is reduced. Previous evidence indicates that malignant versus benign keratinocyte tumor formation is likely to involve distinct target-cell populations with a different commitment to differentiation. In parallel with the increased susceptibility to carcinoma formation, loss of p21(WAF1/Cip1) was found to promote keratinocyte subpopulations with increased growth/differentiation potential, including clonal growth capability, reversible commitment to differentiation, and capability to generate all types of terminally differentiated keratinocytes present in vivo, not only in the interfollicular epidermis but also in hair follicles. Thus, these findings have revealed a function of p21 as a suppressor of malignant but not benign skin-tumor formation and a determinant of the growth/differentiation potential of keratinocyte subpopulations.

Establishment of rat dermal papilla cell lines that sustain the potency to induce hair follicles from afollicular skin

Dermal papilla cells in culture show a lower proliferative capacity compared with dermal fibroblasts, and lose their in situ potency to induce hair follicles in the epidermis at more than 10 passage numbers. This study overcomes these limitations of cultured papilla cells and for the first time demonstrates that papilla cells can be serially cultured for a long period without losing their hair-inductive potency. Outgrowth and the ensuing proliferation of papilla cells were markedly stimulated when explants of rat vibrissa papillae were cultured with rat sole-derived keratinocytes. Such feeder effects of the keratinocytes could be replaced to some extent with conditioned medium of the cells. Serial cultivation of papilla cells was established by maintaining them in the conditioned medium in which they were subcultured for more than 90 passages with an approximate population doubling time of 30 h, a value similar to that of rat dermal fibroblasts. During the subculture, they showed morphologic characteristics and phenotypic expressions of original papilla cells. Even after at least 70 passages, papilla cells sustained the innate hair follicle inductive ability at a level comparable with that of intact dermal papillae. The established cell lines did not show tumorigenicity when they were subcutaneously implanted into nude mice. The culture method developed in this study should facilitate the search for a biochemical entity of dermal papilla cells.

Proliferation and differentiation of organoid hair follicle cells co-cultured with fat cells in collagen gel matrix culture

Using rat skin, we studied the influence of fat cells on the proliferation and differentiation of organoid hair follicle cells in a three-dimensional collagen gel matrix culture system. We cultured organoid hair follicles embedded in collagen gel under each of the following three conditions: cell-free collagen gel for control experiments (condition 1); co-culture with fat cells in close apposition (condition 2); and co-culture with fat cells in spatial separation (condition 3). Outgrowths of epithelial cells from the organoid hair follicles associated with perifollicular proliferation of fibroblasts were observed under conditions 1 and 3. Under condition 2, proliferation of both organoid hair follicle cells and fibroblasts was inhibited, but differentiation of the hair follicle cells appeared to be accelerated. Fat cells are considered to have an inhibitory effect on the proliferation of perifollicular fibroblasts, which might have resulted in the inhibition of hair follicle cell proliferation and also in the better maintenance of normal follicular structure and integrity, allowing for hair-type differentiation to proceed. A direct accelerating effect of fat cells on hair follicle differentiation may also have been responsible. In a physiological state (co-culture with keratinocytes on the collagen gel), similar results were observed under conditions 1 and 2. The different findings under conditions 2 and 3 may be due to either of two possibilities: either the concentration gradient of the soluble factors released from fat cells, acting on either the hair follicle cells or the perifollicular fibroblasts as an inhibitor of proliferation, caused the difference in the results, or direct contact between the organoid hair follicle cells and fat cells may have influenced the accelerating effect of fat cells on the differentiation of hair follicle cells.

Expression of two Ig family adhesion molecules in the murine hair cycle: DCC in the bulge epithelia and NCAM in the follicular papilla

The hair cycle involves remodeling of cells and of cell groups into a complex follicular structure. During skin appendage development, adhesion molecules such as neural cell adhesion molecule (NCAM) and deleted in colon carcinoma (DC) participate in the formation of cell groups. NCAM has been found to be expressed in the mesenchyme during mouse hair follicle induction. DCC expression has been observed in the epithelial cells of the developing feather. We postulate that these two molecules may also define cell groups in the cycling hair follicle. Here we report their spatio-temporal expression patterns during the depilation-induced murine hair cycle. NCAM expression was also examined in positive and negative hair-inductive follicular papilla cell lines. Throughout the hair cycle, DCC expression was confined to the basal keratinocytes of the epidermis and the epithelial portion of the hair follicle. During mid-anagen, two types of deleted in colon carcinoma staining were observed. One was a cell surface pattern seen in the epithelial cells in the bulge region where the follicular stem cells reside. The other was a diffuse cytoplasmic staining pattern in the transient hair follicle epithelia located below the bulge region. Prominent NCAM staining was observed in the follicular papilla throughout the hair cycle and was accompanied by weak staining of the matrix epithelia. NCAM expression correlated with hair induction by a follicular papilla cell line. The results suggest that DCC and NCAM define the permanent cell groups of the hair follicle and that NCAM is important for hair induction.

Primary mouse keratinocyte cultures contain hair follicle progenitor cells with multiple differentiation potential

The interfollicular epidermis contains a single type of terminally differentiated keratinocytes, whereas hair follicles are composed of a minimum of six or seven distinct types. Whether or not these various populations of terminally differentiated keratinocytes originate from one or more progenitor cells has not been established. A related and important question is whether keratinocyte progenitor cells with a pluripotent potential, able to form not only epidermis but also hair follicles, can be maintained in vitro for any period of time. We have addressed these questions using skin reconstitution assays with admixed populations of genetically labeled, cultured keratinocytes. Examination of reconstituted epidermis and hair follicles showed that neither was composed of a random mixture of differently labeled keratinocytes, as would be predicted if they originated from a random reassociation of cells. Instead, the reconstituted interfollicular epidermis contained distinct columnar units, comprising all the overlying layers and most likely derived from a single progenitor cell. In contrast, hair follicles were found to be composed of cells of multiple origin, with each population showing a striking localization to a separate concentric region. The vast majority of reconstituted follicles appeared to derive from a minimum of two or, in a significant fraction of cases, three progenitor cells, one for the generation of the shaft (cuticle, cortex, and medulla), one for the inner root sheath, and the third for the outer root sheath. The general implications of these findings for epidermis and hair follicle formation and for keratinocyte stem cell cultivation are discussed.

Human hair follicle regeneration following amputation and grafting into the nude mouse

In this study we investigated the capacity of the human hair follicle to regenerate a fiber-forming bulb after its amputation. We removed the bases from terminal follicles from a variety of sites and transplanted the follicles onto athymic mice, either still attached to a skin graft or as subcutaneous implants of individual follicles. External hair growth was observed on the skin grafts, and histology of the follicles revealed restoration of dermal papillae and follicle bulb structures. This result suggests that the capacity of hair follicles to regenerate their lower structures after removal, which was first demonstrated on whisker follicles, may be a general phenomenon. It emphasizes the importance of specific cellular subpopulations within the follicle and the role of dermal-epidermal interactions in adult follicle activities.

FGF induces new feather buds from developing avian skin

Induction of skin appendages involves a cascade of molecular events. The fibroblast growth factor (FGF) family of peptide growth factors is involved in cell proliferation and morphogenesis. We explored the role of the FGFs during skin appendage induction using developing chicken feather buds as a model. FGF-1, FGF-2, or FGF-4 was added directly to the culture medium or was released from pre-soaked Affigel blue beads. Near the midline, FGFs led to fusion of developing feather buds, representing FGFs' ability to expand feather bud domains in developing skin. In lateral regions of the explant where feather placodes have not formed, FGF treatment produces a zone of condensation and a region with an increased number of feather buds. In ventral epidermis that is normally apteric (without feathers), FGFs can also induce new feather buds. Like normal feather buds, the newly induced buds express Shh. The expression of Grb, Ras, Raf, and Erk, intracellular signaling molecules known to be downstream to tyrosine kinase receptors such as the FGF receptor, was enriched in feather bud domains. Genistein, an inhibitor of tyrosine kinase, suppressed feather bud formation and the effect of FGF. These results indicate that there are varied responses to FGFs depending on epithelial competence. All the phenotypic responses, however, show that FGFs facilitate the formation of skin appendage domains.

Hair follicle growth controls

Research in hair biology has embarked in the pursuit for molecules that control hair growth. Many molecules already have been associated with the controls of hair patterning, hair maturation, and hair cycling and differentiation. Knowing how these molecules work gives us the tools for understanding and treating patients with hair disorders.

The use of dermal papilla cells in studies of normal and abnormal hair follicle biology

The mesenchyme-derived dermal papilla plays a major regulatory role in the complex cell biology of the hair follicle. The ability to culture dermal papilla cells from a range of species and particularly a range of normal and disordered human hair follicles has enabled the development of a powerful new model system for investigating hair follicle biology. Already these studies have reinforced the importance of dermal papilla cells in initiating new follicle growth and in androgen action in human hair follicles. The retention of hair growth inducing capabilities and characteristics that reflect their in vivo responsiveness to androgens in culture means that they offer a potentially useful approach despite significant drawbacks in working with the cells themselves. Further studies using dermal papilla cells may well elucidate key molecules involved in hair biology in health and disease and, thereby, lead to better therapeutic regimens.

The product of the mouse nude locus, Whn, regulates the balance between epithelial cell growth and differentiation

Mutations in the winged-helix nude (whn) gene result in the nude mouse and rat phenotypes. The pleiotropic nude phenotype which affects the hair, skin, and thymus suggests that whn plays a pivotal role in the development and/or maintenance of these organs. However, little is known about whn function in these organs. We show here that in skin whn is specifically expressed in epithelial cells and not the mesenchymal cells, and using a hair reconstitution assay, we demonstrate that the abnormal nude mouse hair development is attributable to a functional defect of the epithelial cells. Examination of nude mouse primary keratinocytes in culture revealed that these cells have an increased propensity to differentiate in an abnormal fashion, even under conditions that promote proliferation. Furthermore, nude mouse keratinocytes displayed a 100-fold increased sensitivity to the growth-inhibitory/differentiation effects of the phorbol ester TPA. In parallel with these findings, we directly show that whn functions as a transcription factor that can specifically suppress expression of differentiation/TPA-responsive genes. The region of Whn responsible for these effects was mapped to the carboxy-terminal transactivating domain. These results establish whn as a key regulatory factor involved in maintaining the balance between keratinocyte growth and differentiation. The general implications of these findings for an epithelial self-renewal model will be discussed.

Immortalized rat whisker dermal papilla cells cooperate with mouse immature hair follicle buds to activate type IV procollagenases in collagen matrix coculture: correlation with ability to promote hair follicle development in nude mouse grafts

An in vivo nude mouse graft model and an in vitro collagen matrix culture system were used to study interactions of immature hair follicle buds from newborn mice with clonally derived AdE1A-12S-immortalized rat whisker dermal papilla cell lines. Of the 19 available dermal papilla cell lines, four consistently supported good hair follicle development and hair growth in grafts. Seven cell lines were clearly negative in this assay, and the remaining eight cell lines yielded poor to moderate hair growth. As a correlate to in vivo extracellular matrix remodeling accompanying hair follicle development, type IV collagenase activity in the medium from cocultures of dermal papilla cells and hair follicle buds was analyzed by gelatin zymography. Hair follicle buds cultured alone secrete primarily the 92-kDa type IV procollagenase. Cocultivation of hair follicle buds with eight of the dermal papilla cell lines resulted in activation of this proenzyme and activation of the 72-kDa and 92-kDa type IV procollagenases produced by the dermal papilla cells. Seven of these eight dermal papilla cell lines support hair growth in the graft system. In the absence of dermal papilla cells, several growth factors induced activation of the 92-kDa procollagenase secreted by hair follicle buds cultured in serum-free medium: epidermal growth factor, transforming growth factor alpha, acidic fibroblast growth factor, and keratinocyte growth factor. The current working hypothesis is that a) hair follicle epithelial cells interact with dermal papilla cells in coculture by mutual induction of growth factors and cytokines that stimulate the release and activation of matrix remodeling proteases; and b) the ability of dermal papilla cells to interact with hair follicle epithelial cells in this way may be crucial for controlled dermal matrix remodelling during HF development.

The pharmacology of immunosuppressant drugs in skin transplant rejection in mice and other rodents

1. Skin transplantation in rodents is a convenient, widely used method, particularly in mice. It is used as much as an indicator of immune responsiveness as for pharmacological studies. 2. Many differences exist in experimental protocols, both for transplantation and drug administration and in this review, the increase in graft survival time with respect to control times is used to indicate drug effects, in an attempt to account for these differences. 3. The mechanisms underlying skin graft rejection in rodents are described, emphasising the crucial role of both helper and effector T cells. 4. The pharmacology of clinically-used immunosuppressants, including CsA, FK506, rapamycin and purine or pyrimidine synthesis inhibitors, in rodent models of skin transplantation is reviewed. 5. The effects of other potential immunosuppressants and compounds modulating immune responses are described, including the effects of UV light and involvement of platelet-derived factors, prostaglandins and thromboxanes.