SKPs Derive from Hair Follicle Precursors and Exhibit Properties of Adult Dermal Stem Cells
SUMMARY Despite the remarkable regenerative capacity of mammalian skin, an adult dermal stem cell has not yet been identified. Here, we investigated whether skin-derived precursors (SKPs) might fulfill such a role. We show that SKPs derive from Sox2+ hair follicle dermal cells, and that these two cell populations are similar with regard to their transcriptome and functional properties. Both clonal SKPs and endogenous Sox2+ cells induce hair morphogenesis, differentiate into dermal cell types, and home to a hair follicle niche upon transplantation. Moreover, hair follicle-derived SKPs self-renew, maintain their multipotency, and serially reconstitute hair follicles. Finally, grafting experiments show that follicle-associated dermal cells move out of their niche to contribute cells for dermal maintenance and wound-healing. Thus, SKPs derive from Sox2+ follicle-associated dermal precursors and display functional properties predicted of a dermal stem cell, contributing to dermal maintenance, wound-healing, and hair follicle morphogenesis.
SUMMARY The cellular mechanisms that regulate the maintenance of adult tissue stem cells are still largely unknown. We show here that the p53 family member, TAp63, is essential for maintenance of epidermal and dermal precursors and that, in its absence, these precursors senesce and skin ages prematurely. Specifically, we have developed a TAp63 conditional knockout mouse and used it to ablate TAp63 in the germline (TAp63−/−) or in K14-expressing cells in the basal layer of the epidermis (TAp63fl/fl;K14cre+). TAp63−/− mice age prematurely and develop blisters, skin ulcerations, senescence of hair follicle-associated dermal and epidermal cells, and decreased hair morphogenesis. These phenotypes are likely due to loss of TAp63 in dermal and epidermal precursors since both cell types show defective proliferation, early senescence, and genomic instability. These data indicate that TAp63 serves to maintain adult skin stem cells by regulating cellular senescence and genomic stability, thereby preventing premature tissue aging.
We investigated the specific and associated effects of insulin and glucose on beta-cell growth and function in adult rats. By combining simultaneous infusion either of glucose and/or insulin or glucose and diazoxide, three groups of rats were constituted: hyperglycemic-hyperinsulinemic rats (high glucose-high insulin), hyperglycemic-euinsulinemic rats (high glucose), and euglycemic-hyperinsulinemic rats (high insulin). All the infusions lasted 48 h. Control rats were infused with 0.9% NaCl (saline controls). In all groups, beta-cell mass was significantly increased, compared with controls (by 70% in high glucose-high insulin rats, 65% in high glucose rats, and 50% in high insulin rats). The stimulation of neogenesis was suggested by the high number of islets budding from pancreatic ducts in high glucose-high insulin and high glucose rats and by the presence of numerous clusters of few beta-cells within the exocrine pancreas in high insulin rats. beta-Cell hypertrophy was observed only in high glucose-high insulin rats. The rate of beta-cell proliferation was similar to that of controls in high glucose-high insulin rats after a 48-h glucose infusion, dropped dramatically in high insulin rats, and dropped to a lesser extent in high glucose rats. In high glucose-high insulin and high glucose rats, beta-cell mass increase was related to a higher beta-cell responsiveness to glucose in vitro as measured by islet perifusion studies, whereas in high insulin rats, no significant enhancement of glucose induced insulin secretion could be noticed. The data show that glucose and insulin may have specific stimulating effects on beta-cell growth and function in vivo in adult rats independently of the influence they exert each other on their respective plasma concentration.
Skin-derived precursors (SKPs) are multipotent dermal stem cells that reside within a hair follicle niche and that share properties with embryonic neural crest precursors. Here, we have asked whether SKPs and their endogenous dermal precursors originate from the neural crest or whether, like the dermis itself, they originate from multiple developmental origins. To do this, we used two different mouse Cre lines that allow us to perform lineage tracing: Wnt1-cre, which targets cells deriving from the neural crest, and Myf5-cre, which targets cells of a somite origin. By crossing these Cre lines to reporter mice, we show that the endogenous follicle-associated dermal precursors in the face derive from the neural crest, and those in the dorsal trunk derive from the somites, as do the SKPs they generate. Despite these different developmental origins, SKPs from these two locations are functionally similar, even with regard to their ability to differentiate into Schwann cells, a cell type only thought to be generated from the neural crest. Analysis of global gene expression using microarrays confirmed that facial and dorsal SKPs exhibit a very high degree of similarity, and that they are also very similar to SKPs derived from ventral dermis, which has a lateral plate origin. However, these developmentally distinct SKPs also retain differential expression of a small number of genes that reflect their developmental origins. Thus, an adult neural crest-like dermal precursor can be generated from a non-neural crest origin, a finding with broad implications for the many neuroendocrine cells in the body.
SummaryRecent reports of directed reprogramming have raised questions about the stability of cell lineages. Here, we have addressed this issue, focusing upon skin-derived precursors (SKPs), a dermally derived precursor cell. We show by lineage tracing that murine SKPs from dorsal skin originate from mesenchymal and not neural crest-derived cells. These mesenchymally derived SKPs can, without genetic manipulation, generate functional Schwann cells, a neural crest cell type, and are highly similar at the transcriptional level to Schwann cells isolated from the peripheral nerve. This is not a mouse-specific phenomenon, since human SKPs that are highly similar at the transcriptome level can be made from neural crest-derived facial and mesodermally derived foreskin dermis and the foreskin SKPs can make myelinating Schwann cells. Thus, nonneural crest-derived mesenchymal precursors can differentiate into bona fide peripheral glia in the absence of genetic manipulation, suggesting that developmentally defined lineage boundaries are more flexible than widely thought.
Pluripotent neural crest (NC) cells differentiate to diverse lineages, including the neuronal, sympathoadrenal lineage. In primary NC cultures, bone morphogenetic protein 2 (BMP2) requires moderate activation of cAMP signaling for induction of the sympathoadrenal lineage. However, the mechanism by which cAMP signaling synergizes with BMP2 to induce the sympathodrenal lineage is unknown. Herein, we demonstrate that moderate activation of cAMP signaling induces both transcription and activity of proneural transcription factor Phox2a. In NC cultures inhibition of cAMPresponse element-binding protein (CREB)-mediated transcription by expression of dominant-negative CREB suppresses Phox2a transcription and sympathoadrenal lineage development. Interestingly, the constitutively active CREB DIEDML , despite inducing Phox2a transcription, is insufficient for sympathoadrenal lineage development, requiring activation of the cAMP pathway. Because CREB-DIEDML mediates cAMP-dependent transcription without requiring activation by the cAMP-dependent protein kinase A (PKA), these results identify PKA activation as necessary in sympathoadrenal lineage development. Treatment of NC cultures with the PKA inhibitor H89 or 1-10 nM okadaic acid (OA), a serine/threonine PP2A-like phosphatase inhibitor, suppresses sympathoadrenal lineage development. Likewise, OA treatment of the CNS-derived catecholaminergic CAD cell line inhibits cAMP-mediated neuronal differentiation. Specifically, OA inhibits cAMP-mediated Phox2a dephosphorylation, cAMP-dependent Phox2a DNA binding in vitro, and cAMP-and Phox2a-dependent dopamine--hydroxylase-luciferase reporter expression. Together, these results support cAMP-dependent Phox2a dephosphorylation is required for its activation. We conclude that moderate activation of cAMP signaling has dual inputs in catecholaminergic, sympathoadrenal lineage development; that is, regulation of both Phox2a transcription and activity. These results provide the first mechanistic understanding of how moderate activation of the cAMP pathway in synergy with BMP2 promotes sympathoadrenal lineage development. The neural crest (NC)3 is a pluripotent cell population derived from the lateral ridges of the neuroepithelium during closure of the neural tube (1). NC cells migrate along defined paths in the developing embryo, generating diverse cell types (2). The sympathoadrenal (SA) lineage originating from the trunk region of the neural tube (1) in response to instructive, microenvironmental signals develops to sympathetic neurons and chromaffin cells of the adrenal medulla (3). Cells committed to the SA lineage are characterized by expression of tyrosine hydroxylase (TH), the rate-limiting enzyme in catecholamine biosynthesis, and dopamine--hydroxylase (DBH), catalyzing the conversion of dopamine to norepinephrine (3).Bone morphogenetic proteins (BMPs) produced by the developing aorta (4 -9) and unidentified signals originating from the notochord and ventral neural tube (10 -14) are required for SA cell development. However, in ...
Since the discovery of the TP63 gene in 1998, many studies have demonstrated that DNp63, a p63 isoform of the p53 gene family, is involved in multiple functions during skin development and in adult stem/progenitor cell regulation. In contrast, TAp63 studies have been mostly restricted to its apoptotic function and more recently as the guardian of oocyte integrity. TAp63 endogenous expression is barely detectable in embryos and adult (except in oocytes), presumably because of its rapid degradation and the lack of antibodies able to detect weak expression. Nevertheless, two recent independent studies have demonstrated novel functions for TAp63 that could have potential implications to human pathologies. The first discovery is related to the protective role of TAp63 on premature aging. TAp63 controls skin homeostasis by maintaining dermal and epidermal progenitor/stem cell pool and protecting them from senescence, DNA damage and genomic instability. The second study is related to the role of TAp63, expressed by the primitive endoderm, on heart development. This unexpected role for TAp63 has been discovered by manipulation of embryonic stem cells in vitro and confirmed by the severe cardiomyopathy observed in brdm2 p63-null embryonic hearts. Interestingly, in both cases, TAp63 acts in a cell-nonautonomous manner on adjacent cells. Here, we discuss these findings and their potential connection during development.
β-cell neogenesis triggers the generation of new β-cells from precursor cells. Neogenesis from duct epithelium is the most currently described and the best documented process of differentiation of precursor cells into β-cells. It is contributes not only to β-cell mass expansion during fetal and nonatal life but it is also involved in the maintenance of the β-cell mass in adults. It is also required for the increase in β-cell mass in situations of increase insulin demand (obesity, pregnancy). A large number of factors controlling the differentiation of β-cells has been identified. They are classified into the following main categories: growth factors, cytokine and inflamatory factors, and hormones such as PTHrP and GLP-1. The fact that intestinal incretin hormone GLP-1 exerts a major trophic role on pancreatic β-cells provides insights into the possibility to pharmacologically stimulate β-cell neogenesis. This could have important implications for the of treatment of type 1 and type 2 diabetes. Transdifferentiation, that is, the differentiation of already differentiated cells into β-cells, remains controversial.However, more and more studies support this concept. The cells, which can potentially “transdifferentiate” into β-cells, can belong to the pancreas (acinar cells) and even islets, or originate from extra-pancreatic tissues such as the liver. Neogenesis from intra-islet precursors also have been proposed and subpopulations of cell precursors inside islets have been described by some authors. Nestin positive cells, which have been considered as the main candidates, appear rather as progenitors of endothelial cells rather than β-cells and contribute to angiogenesis rather than neogenesis. To take advantage of the different differentiation processes may be a direction for future cellular therapies. Ultimately, a better understanding of the molecular mechanisms involved in β-cell neogenesis will allow us to use any type of differentiated and/or undifferentiated cells as a source of potential cell precursors.
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