Perivascular hair follicle stem cells associate with a venule annulus.

The perivascular microenvironment helps in maintaining stem cells in many tissues. We sought to determine whether there is a perivascular niche for hair follicle stem cells. The association of vessels and follicle progenitor cells began by embryonic day 14.5, when nascent hair placodes had blood vessels approaching them. By birth, a vascular annulus stereotypically surrounded the keratin 15 negative (K15-) stem cells in the upper bulge and remained associated with the K15- upper bulge throughout the hair cycle. The angiogenic factor Egfl6 was expressed by the K15- bulge and was localized adjacent to the vascular annulus, which comprised post-capillary venules. Although denervation altered the phenotype of upper bulge stem cells, the vascular annulus persisted in surgically denervated mouse skin. The importance of the perivascular niche was further suggested by the fact that vascular annuli formed around the upper bulge of de novo-reconstituted hair follicles before their innervation. Together, these findings demonstrate that the upper bulge is associated with a perivascular niche during the establishment and maintenance of this specialized region of hair follicle stem cells.

CD200-expressing human basal cell carcinoma cells initiate tumor growth.

Smoothened antagonists directly target the genetic basis of human basal cell carcinoma (BCC), the most common of all cancers. These drugs inhibit BCC growth, but they are not curative. Although BCC cells are monomorphic, immunofluorescence microscopy reveals a complex hierarchical pattern of growth with inward differentiation along hair follicle lineages. Most BCC cells express the transcription factor KLF4 and are committed to terminal differentiation. A small CD200(+) CD45(-) BCC subpopulation that represents 1.63 ± 1.11% of all BCC cells resides in small clusters at the tumor periphery. By using reproducible in vivo xenograft growth assays, we determined that tumor initiating cell frequencies approximate one per 1.5 million unsorted BCC cells. The CD200(+) CD45(-) BCC subpopulation recreated BCC tumor growth in vivo with typical histological architecture and expression of sonic hedgehog-regulated genes. Reproducible in vivo BCC growth was achieved with as few as 10,000 CD200(+) CD45(-) cells, representing ~1,500-fold enrichment. CD200(-) CD45(-) BCC cells were unable to form tumors. These findings establish a platform to study the effects of Smoothened antagonists on BCC tumor initiating cell and also suggest that currently available anti-CD200 therapy be considered, either as monotherapy or an adjunct to Smoothened antagonists, in the treatment of inoperable BCC.

A humanized stromal bed is required for engraftment of isolated human primary squamous cell carcinoma cells in immunocompromised mice.

Epithelial cancers are the most common malignancies and the greatest cause of cancer mortality worldwide. The incidence of keratinocyte-derived (non-melanoma) skin cancers is increasing rapidly. Despite access to abundant tumor tissue and ease of observation, acceptance of non-melanoma skin cancers as model carcinomas has been hindered by the lack of a reliable xenograft model. Herein we describe conditions that allow routine xeno-engraftment of primary human squamous cell carcinoma (SCCa) cells. Tumor development required creation of an appropriate stromal bed before xenografting tumor tissue onto the backs of athymic nude mice. We also demonstrate that the stromal bed must be "humanized" if primary human SCCa is to be propagated from cell suspensions. SCCa xenografts recapitulated the histological grade and phenotype of the original tumors with considerable fidelity, even after serial passage, irrespective of the histological grade of the primary human SCCa. This model, which to our knowledge is previously unreported, can be used for drug testing, as well as for studies that are relevant to the biology of primary human SCCa and other epithelial cancers.

Identification and characterization of tumor-initiating cells in human primary cutaneous squamous cell carcinoma.

Primary human squamous cell carcinomas (SCCas) are heterogeneous invasive tumors with proliferating outer layers and inner differentiating cell masses. To determine if tumor-initiating cells (TICs) are present in SCCas, we utilized newly developed reliable in vitro and in vivo xenograft assays that propagate human SCCas, and demonstrated that a small subset of SCCa cells (∼1%) expressing Prominin-1 (CD133) in the outer layers of SCCas were highly enriched for TICs (∼1/400) compared with unsorted SCCa cells (TICs ∼1/10(6)). Xenografts of CD133+ SCCas recreated the original SCCa tumor histology and organizational hierarchy, whereas CD133- cells did not, and only CD133+ cells demonstrated the capacity for self-renewal in serial transplantation studies. We present a model of human SCCas in which tumor projections expand with outer leading edges that contain CD133+ TICs. Successful cancer treatment will likely require that the TICs identified in cancers be targeted therapeutically. The demonstration that TICs are present in SCCas and are enriched in a CD133- expressing subpopulation has not been, to our knowledge, previously reported.

A gene therapy approach for long-term normalization of blood pressure in hypertensive mice by ANP-secreting human skin grafts.

The use of bioengineered human skin as a bioreactor to deliver therapeutic factors has a number of advantages including accessibility that allows manipulation and monitoring of genetically modified cells. We demonstrate a skin gene therapy approach that can regulate blood pressure and treat systemic hypertension by expressing atrial natriuretic peptide (ANP), a hormone able to decrease blood pressure, in bioengineered human skin equivalents (HSE). Additionally, the expression of a selectable marker gene, multidrug resistance (MDR) type 1, is linked to ANP expression on a bicistronic vector and was coexpressed in the human keratinocytes and fibroblasts of the HSE that were grafted onto immunocompromised mice. Topical treatments of grafted HSE with the antimitotic agent colchicine select for keratinocyte progenitors that express both MDR and ANP. Significant plasma levels of human ANP were detected in mice grafted with HSE expressing ANP from either keratinocytes or fibroblasts, and topical selection of grafted HSE resulted in persistent high levels of ANP expression in vivo. Mice with elevated plasma levels of human ANP showed lower renin levels and, correspondingly, had lower systemic blood pressure than controls. Furthermore, mice with HSE grafts expressing human ANP did not develop elevated blood pressure when fed a high-salt diet. These findings illustrate the potential of this human skin gene therapy approach to deliver therapeutic molecules systemically for long-term treatment of diverse diseases.

Efficient procurement of epithelial stem cells from human tissue specimens using a Rho-associated protein kinase inhibitor Y-27632.

The efficient culture of stem cells from epithelial tissues such as skin and corneas is important for both experimental studies and clinical applications of tissue engineering. We now demonstrate that treatment of human-skin-derived keratinocytes with a Rho-associated protein kinase inhibitor Y-27632 for the initial 6 days of primary culture can increase the number of keratinocytes that possess stem cell properties to form colonies during in vitro culture of freshly isolated cells and subsequent passage (50-fold). Further, we show that Y-27632 treatment can increase the total number of prostate epithelial cells derived from human prostate specimens. Therefore, the use of Y-27632 during primary cultures offers a simple and effective way to prepare a large number of epithelial stem cells from various human epithelial tissues.

An approach to achieve long-term expression in skin gene therapy.

For gene therapy purposes, the skin is an attractive organ to target for systemic delivery of therapeutic proteins to treat systemic diseases, skin diseases, or skin cancer. To achieve long-term stable expression of a therapeutic gene in keratinocytes (KC), we have developed an approach using a bicistronic retroviral vector expressing the desired therapeutic gene linked to a selectable marker (multidrug resistant gene, MDR) that is then introduced into KC and fibroblasts (FB) to create genetically modified human skin equivalent (HSE). After grafting the HSE onto immunocompromised mice, topical colchicine treatment is used to select and enrich for genetically modified keratinocyte stem cells (KSC) that express MDR and are resistant to colchicine's antimitotic effects. Both the apparatus for topical colchicine delivery and the colchicine doses have been optimized for application to human skin. This approach can be validated by systemic delivery of therapeutic factors such as erythropoietin and the antihypertensive atrial natriuretic peptide.

Telomerase-immortalized non-malignant human prostate epithelial cells retain the properties of multipotent stem cells.

Understanding prostate stem cells may provide insight into the origin of prostate cancer. Primary cells have been cultured from human prostate tissue but they usually survive only 15-20 population doublings before undergoing senescence. We report here that RC-170N/h/clone 7 cells, a clonal cell line from hTERT-immortalized primary non-malignant tissue-derived human prostate epithelial cell line (RC170N/h), retain multipotent stem cell properties. The RC-170N/h/clone 7 cells expressed a human embryonic stem cell marker, Oct-4, and potential prostate epithelial stem cell markers, CD133, integrin alpha2beta1(hi) and CD44. The RC-170N/h/clone 7 cells proliferated in KGM and Dulbecco's Modified Eagle Medium with 10% fetal bovine serum and 5 microg/ml insulin (DMEM+10% FBS+Ins.) medium, and differentiated into epithelial stem cells that expressed epithelial cell markers, including CK5/14, CD44, p63 and cytokeratin 18 (CK18); as well as the mesenchymal cell markers, vimentin, desmin; the neuron and neuroendocrine cell marker, chromogranin A. Furthermore the RC170 N/h/clone 7 cells differentiated into multi tissues when transplanted into the sub-renal capsule and subcutaneously of NOD-SCID mice. The results indicate that RC170N/h/clone 7 cells retain the properties of multipotent stem cells and will be useful as a novel cell model for studying the mechanisms of human prostate stem cell differentiation and transformation.

Human bullous pemphigoid antigen 2 transgenic skin elicits specific IgG in wild-type mice.

Bullous pemphigoid antigen 2 (BPAG2) is targeted by autoantibodies in patients with bullous pemphigoid (BP), and absent in patients with one type of epidermolysis bullosa (OMIM #226650). A keratin 14 promoter construct was used to produce transgenic (Tg) mice appropriately expressing human BPAG2 (hBPAG2) in murine epidermal basement membrane (BM). Grafts of Tg skin placed on gender-matched, syngeneic wild type (Wt) or major histocompatibility complex I (MHC I)-/- mice elicited IgG that bound human epidermal BM and BPAG2. Production of such IgG in grafted mice was prompt (detectable within 16+/-2 days), robust (titer > or = 1,280), durable (present > or = 380 days), and correlated with the involution and loss of Tg skin grafts. MHC II-/- mice grafted with Tg skin did not develop anti-hBPAG2 IgG or graft loss indicating that MHC II:CD4+ T cell interactions were crucial for these responses. Tg skin grafts on Wt mice developed neutrophil-rich infiltrates, dermal edema, subepidermal blisters, and deposits of immunoreactants in epidermal BM. This model shows fidelity to alterations seen in patients with BP, has relevance to immune responses that may arise in patients with epidermolysis bullosa following BPAG2 gene replacement, and can be used to identify interventions that may block production of IgG against proteins in epidermal BM.

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.

Bone marrow-derived keratinocytes are not detected in normal skin and only rarely detected in wounded skin in two different murine models.

OBJECTIVE: Because the ability of bone marrow-derived cells (BMDCs) to repopulate tissues and the possible mechanisms of repopulation remain controversial, we used two distinct murine models to determine whether BMDCs can repopulate epidermal keratinocytes during either steady-state homeostasis or after tissue injury. METHODS: The accessibility of skin keratinocytes makes it an excellent tissue to assess BMDC repopulation. In the two murine models, BMDCs from either male homologous B6, 129S Rosa26 mice that constitutively express ss-galactosidase or male hemizygote C57 BL/6-Tg(ACTbEGFP)1Osb/J mice expressing enhanced green fluorescent protein were transplanted via tail vein injection into control lethally irradiated (9.5 Gy) congenic female recipients and the percentage of keratinocytes derived from the transplanted BMDCs, both with and without wounding, was carefully determined. RESULTS: Analysis of bone marrow, thymus, spleen, and lymph nodes confirmed complete engraftment of donor BMDCs 6 months post-bone marrow transplantation. However, during steady-state homeostasis, bone marrow-derived keratinocytes could not be detected in the epidermis. In a skin wound-healing model, the epidermis contained only rare bone marrow-derived keratinocytes (< 0.0001%) but did contain scattered bone marrow-derived Langerhans cells. CONCLUSIONS: These results suggest that BMDCs do not significantly contribute to steady-state epidermal homeostasis and are not required or responsible for providing keratinocyte stem cells and keratinocyte repopulation following skin injury.

A large preclinical animal model to assess ex vivo skin gene therapy applications.

Because of its easy accessibility, the skin is a very attractive target for gene therapy purposes. To study potential clinical applications in a preclinical setting, appropriate animal models are needed. Pig skin is very similar to human skin, and a variety of human diseases that are potentially amenable to gene therapy applications also occur in pigs. Only a few studies have analyzed the engraftment of transduced keratinocytes (KC) in pigs, however, with limited success. We describe a porcine model in which pig KC were transduced ex vivo with a retroviral vector encoding a marker gene and subsequently grafted onto the autologous host, utilizing a relatively simple grafting technique. Enhanced transduction efficiency was achieved by an optimized transduction protocol including centrifugation of the retroviral vector at a temperature of 32 degrees C. Transduced KC were then seeded onto acellular dermis, forming a stratified epidermis. Grafting was performed by creating full thickness wounds and placing the skin graft onto the muscle fascia, covered by a protective skin flap for several days. Successful engraftment of transduced KC was demonstrated by immunohistochemistry of biopsies taken at different time points, showing transgene expression in 40-50% of grafted KC. After 4 weeks, KC expressing a foreign marker gene was lost, suggesting a transgene-specific immune response in the immunocompetent pigs and highlighting the potential problems for clinical gene therapy studies when transferring new genetic material into a patient. The model presented here may be used to examine applications of skin gene therapy, where retroviral vectors encoding endogenous pig genes will be expressed in the skin.

Characterization and isolation of stem cell-enriched human hair follicle bulge cells.

The human hair follicle bulge is an important niche for keratinocyte stem cells (KSCs). Elucidation of human bulge cell biology could be facilitated by analysis of global gene expression profiles and identification of unique cell-surface markers. The lack of distinctive bulge morphology in human hair follicles has hampered studies of bulge cells and KSCs. In this study, we determined the distribution of label-retaining cells to define the human anagen bulge. Using navigated laser capture microdissection, bulge cells and outer root sheath cells from other follicle regions were obtained and analyzed with cDNA microarrays. Gene transcripts encoding inhibitors of WNT and activin/bone morphogenic protein signaling were overrepresented in the bulge, while genes responsible for cell proliferation were underrepresented, consistent with the existence of quiescent noncycling KSCs in anagen follicles. Positive markers for bulge cells included CD200, PHLDA1, follistatin, and frizzled homolog 1, while CD24, CD34, CD71, and CD146 were preferentially expressed by non-bulge keratinocytes. Importantly, CD200+ cells (CD200hiCD24loCD34loCD71loCD146lo) obtained from hair follicle suspensions demonstrated high colony-forming efficiency in clonogenic assays, indicating successful enrichment of living human bulge stem cells. The stem cell behavior of enriched bulge cells and their utility for gene therapy and hair regeneration will need to be assessed in in vivo assays.

A proteomic characterization of the plasma membrane of human epidermis by high-throughput mass spectrometry.

Membrane proteins are responsible for many critical cellular functions and identifying cell surface proteins on different keratinocyte populations by proteomic approaches would improve our understanding of their biological function. The ability to characterize membrane proteins, however, has lagged behind that of soluble proteins both in terms of throughput and protein coverage. In this study, a membrane proteomic investigation of keratinocytes using a two-dimensional liquid chromatography (LC) tandem-mass spectrometry (MS/MS) approach that relies on a buffered methanol-based solubilization, and tryptic digestion of purified plasma membrane is described. A highly enriched plasma membrane fraction was prepared from newborn foreskins using sucrose gradient centrifugation, followed by a single-tube solubilization and tryptic digestion of membrane proteins. This digestate was fractionated by strong cation-exchange chromatography and analyzed using microcapillary reversed-phase LC-MS/MS. In a set of 1306 identified proteins, 866 had a gene ontology (GO) annotation for cellular component, and 496 of these annotated proteins (57.3%) were assigned as known integral membrane proteins or membrane-associated proteins. Included in the identification of a large number of aqueous insoluble integral membrane proteins were many known intercellular adhesion proteins and gap junction proteins. Furthermore, 121 proteins from cholesterol-rich plasma membrane domains (caveolar and lipid rafts) were identified.

Topical colchicine selection of keratinocytes transduced with the multidrug resistance gene (MDR1) can sustain and enhance transgene expression in vivo.

In gene therapy, a clinically relevant therapeutic effect requires long-term expression of the desired gene at a level sufficient to correct or at least alleviate the underlying gene defect. One approach to achieve persistent as well as high-level transgene expression in a significant percentage of target cells would be to select cells expressing both the desired transgene and a linked selectable gene--such as the human multi-drug resistance (MDR1) gene--in a bicistronic vector. Because of its accessibility, the skin is a very attractive target tissue to select genetically modified cells, allowing topical application of a selecting agent, thus minimizing potential toxic side effects. Among the potential selecting drugs, agents that block cell division, such as colchicine, are of particular interest because the use of anti-mitotic drugs takes advantage of the rapid keratinocyte (KC) turnover in the epidermis and the need for continued proliferation to substitute the KC lost due to selection. Before assessing the therapeutic benefit of such an approach, several key questions need to be answered in preclinical models: (1) Does topical colchicine application achieve the desired in vivo effect by blocking KC mitosis without eliciting unwanted toxic side effects? (2) Are MDR-transduced (MDR+) human KC still able to proliferate and differentiate when treated with colchicine? (3) Can MDR+ KC be enriched by topical selection? (4) Does topical selection result in persistent transgene expression by selecting KC stem cells expressing MDR? To answer these questions and to test the feasibility of such an approach both an in vitro skin equivalent and an in vivo human skin graft model were developed in which MDR+ KC were treated with different dosages of colchicine. Quantitative and qualitative analyses of MDR expression in human KC showed that topical colchicine treatment selects high-level transgene expression in a high percentage of KC. Moreover, determination of transgene copy numbers demonstrated that MDR+ KC progenitor cells were enriched by topical selection resulting in long-term expression of the transgene in the skin. Thus, in summary, these models demonstrate that topical selection of MDR+ KC is a safe approach to efficiently enhance long-term gene expression in the skin and holds future promise for clinical gene therapy applications.

Induction of GVHD-like skin disease by passively transferred CD8(+) T-cell receptor transgenic T cells into keratin 14-ovalbumin transgenic mice.

To understand the mechanisms involved in immunological tolerance to skin-associated antigens, we have developed transgenic (Tg) mice that express a model self-antigen, membrane-bound chicken ovalbumin (OVA), under the control of a keratin 14 (K14) promoter. K14-mOVA Tg mice express OVA mRNA in the epidermis, and appear normal. K14-mOVA Tg mice failed to mount T cell and delayed type hypersensitivity reactions to OVA, suggesting that the Tg mice were tolerant to OVA. Skin dendritic cells, including Langerhans cells, may contribute to the tolerance induction because migratory skin DC derived from K14-mOVA efficiently activated CD8(+) T cells from OVA-specific T-cell receptor (Va2/Vb5) Tg (OT-I) mice. OT-I cells expanded and accumulated in skin-draining lymph nodes after intravenous injected into K14-mOVA mice and exhibited activation markers. Graft-versus-host disease-like skin lesions appeared in K14-mOVA mice by day 7 after injection of OT-I cells. These studies demonstrate that K14-mOVA Tg mice are susceptible to an autoimmunelike skin disease induced by passively transferred naïve CD8(+) OVA T-cell receptor Tg T cells, and serve as a good model for understanding self-tolerance and for the investigation of the pathogenesis, treatment and potential prevention of cell-mediated autoimmune reactions in skin.