Sox10 Functions as an Inducer of the Direct Conversion of Keratinocytes Into Neural Crest Cells.

Neural crest cells (NCCs) are highly migratory multipotent cells that play critical roles in embryogenesis. The generation of NCCs is controlled by various transcription factors (TFs) that are regulated by each other and combine to form a regulatory network. We previously reported that the conversion of mouse fibroblasts into NCCs was achieved by the overexpression of only one TF, Sox10; therefore, Sox10 may be a powerful inducer of the conversion of NCCs.

Early Development of Resident Macrophages in the Mouse Cochlea Depends on Yolk Sac Hematopoiesis.

Resident macrophages reside in all tissues throughout the body and play a central role in both tissue homeostasis and inflammation. Although the inner ear was once believed to be "immune-privileged," recent studies have shown that macrophages are distributed in the cochlea and may play important roles in the immune system thereof. Resident macrophages have heterogeneous origins among tissues and throughout developmental stages.

Melanoblasts as Multipotent Cells in Murine Skin.

Melanoblasts (MBs) are melanocyte precursors that are derived from neural crest cells (NCCs). We recently demonstrated the multipotency of MBs; they differentiate not only into pigmented melanocytes but also other NCC derivatives. We herein describe methods for the isolation of MBs from mouse skin by flow cytometry.

Direct Conversion of Mouse Embryonic Fibroblasts into Neural Crest Cells.

Neural crest cells (NCCs) are multipotent cells that emerge from the edges of the neural folds and extensively migrate throughout developing embryos. Dorsolaterally migrating NCCs colonize skin, differentiate into skin melanocytes, and lose their multipotency. Multipotent NCCs or NCCs derived multipotent stem cells (MSCs) were recently detected in their migrated locations, including skin, despite restrictions in cell fate acquisition following migration.

Galectin-1 enhances the generation of neural crest cells.

Neural crest (NC) cells are multipotent cells that emerge from the dorsal region of the neural tube. After delaminating from the neural tube, NC cells migrate throughout the developing embryo and differentiate into various cells: neurons and glial cells of the peripheral nervous system, melanocytes of skin, and skeletal elements of the face and head. We previously analyzed the gene expression profile of a NC subpopulation isolated from Sox10-IRES-Venus mice and found that the carbohydrate-binding protein, Galectin-1 (Gal-1) was strongly expressed in generating NC cells.

Gene array analysis of neural crest cells identifies transcription factors necessary for direct conversion of embryonic fibroblasts into neural crest cells.

Neural crest cells (NC cells) are multipotent cells that emerge from the edge of the neural folds and migrate throughout the developing embryo. Although the gene regulatory network for generation of NC cells has been elucidated in detail, it has not been revealed which of the factors in the network are pivotal to directing NC identity. In this study we analyzed the gene expression profile of a pure NC subpopulation isolated from Sox10-IRES-Venus mice and investigated whether these genes played a key role in the direct conversion of Sox10-IRES-Venus mouse embryonic fibroblasts (MEFs) into NC cells.

Multipotency of melanoblasts isolated from murine skin depends on the Notch signal.

Background: Melanoblasts (MBs), derived from neural crest cells, only differentiate into melanocytes (Ms) in vivo. We previously showed that MBs isolated from mouse skin were multipotent, generating neurons (Ns) and glial cells (Gs) together with Ms. Using Sox10-IRES-Venus mice and mouse embryonic stem cells, we investigated how MBs expressed their multipotency.

Extended multipotency of neural crest cells and neural crest-derived cells.

Neural crest cells (NCC) are migratory multipotent cells that give rise to diverse derivatives. They generate various cell types during embryonic development, including neurons and glial cells of the peripheral sensory and autonomic ganglia, Schwann cells, melanocytes, endocrine cells, smooth muscle, and skeletal and connective tissue cells of the craniofacial complex. The multipotency of NCC is thought to be transient at the early stage of NCC generation; once NCC emerge from the neural tube, they change into lineage-restricted precursors.

The stemness of neural crest cells and their derivatives.

Neural crest cells (NCCs) are unique to vertebrates and emerge from the border of the neural plate and subsequently migrate extensively throughout the embryo after which they differentiate into many types of cells. This multipotency is the main reason why NCCs are regarded as a versatile tool for stem cell biology and have been gathering attention for their potential use in stem cell based therapy. Multiple sets of networks comprised of signaling molecules and transcription factors regulate every developmental phase of NCCs, including maintenance of their multipotency.

Preferential gene transcription of T helper 2 cytokines in peripheral CCR4(+) CD4(+) lymphocytes in dogs.

Background: Previous studies reported the involvement of CC chemokine receptor 4 (CCR4)-positive CD4(+) cells in the pathogenesis of canine atopic dermatitis. In humans, CCR4 is selectively expressed on type 2 helper T (Th2) cells; however, a subset of canine CCR4(+) helper T cells has not been determined.

Hypothesis/objectives: To characterize the transcription profile of CCR4(+) CD4(+) lymphocytes isolated from the peripheral blood of healthy dogs.

Neural crest-derived cells sustain their multipotency even after entry into their target tissues.

Background: Neural crest cells (NC cells) are highly migratory multipotent cells. Their multipotency is transient at the early stage of their generation; soon after emerging from the neural tube, these cells turn into lineage-restricted precursors. However, recent studies have disputed this conventionally believed paradigm.

Tracing Sox10-expressing cells elucidates the dynamic development of the mouse inner ear.

The inner ear is constituted by complicated cochlear and vestibular compartments, which are derived from the otic vesicle, an embryonic structure of ectodermal origin. Although the inner ear development has been analyzed using various techniques, the developmental events have not been fully elucidated because of the intricate structure. We previously developed a Sox10-IRES-Venus mouse designed to express green fluorescent protein under the control of the Sox10 promoter.

Keratinocyte stem cells but not melanocyte stem cells are the primary target for radiation-induced hair graying.

Ionizing radiation (IR)-induced hair graying is caused by the ectopic differentiation of melanocyte stem cells (MSCs) in their niche located at the bulge region of the hair follicle. Keratinocyte stem cells (KSCs) in the bulge region are an important component of that niche. However, little is known about the relationship between MSC differentiation and the KSC niche during IR-induced hair graying.

Melanoblasts as multipotent cells in murine skin.

Melanoblasts are melanocyte precursors that are derived from neural crest cells (NCCs). Recently we showed that melanoblasts differentiate into not only pigmented melanocytes but also into other NCCs derivatives. Here, we describe methods for the isolation of melanoblasts from mouse skin by flow-cytometry.

Dual origin of melanocytes defined by Sox1 expression and their region-specific distribution in mammalian skin.

Melanocytes are pigment-producing cells generated from neural crest cells (NCCs) that delaminate from the dorsal neural tube. The widely accepted premise that NCCs migrating along the dorsolateral pathway are the main source of melanocytes in the skin was recently challenged by the finding that Schwann cell precursors are the major cellular source of melanocytes in the skin. Still, in a wide variety of vertebrate embryos, melanocytes are exclusively derived from NCCs.

Protective effect of Kit signaling for melanocyte stem cells against radiation-induced genotoxic stress.

Radiation-induced hair graying is caused by irreversible defects in the self-renewal and/or development of follicular melanocyte stem cells in the hair follicles. Kit signaling is an essential growth and differentiation signaling pathway for various cell lineages including melanocytes, and its radioprotective effects have been shown in hematopoietic cells. However, it is uncertain whether Kit signaling exerts a radioprotective effect for melanocytes.

Neural crest cells retain their capability for multipotential differentiation even after lineage-restricted stages.

Multipotency of neural crest cells (NC cells) is thought to be a transient phase at the early stage of their generation; after NC cells emerge from the neural tube, they are specified into the lineage-restricted precursors. We analyzed the differentiation of early-stage NC-like cells derived from Sox10-IRES-Venus ES cells, where the expression of Sox10 can be visualized with a fluorescent protein. Unexpectedly, both the Sox10+/Kit- cells and the Sox10+/Kit+ cells, which were restricted in vivo to the neuron (N)-glial cell (G) lineage and melanocyte (M) lineage, respectively, generated N, G, and M, showing that they retain multipotency.

Functionally distinct melanocyte populations revealed by reconstitution of hair follicles in mice.

Hair follicle reconstitution analysis was used to test the contribution of melanocytes or their precursors to regenerated hair follicles. In this study, we first confirmed the process of chimeric hair follicle regeneration by both hair keratinocytes and follicular melanocytes. Then, as first suggested from the differential growth requirements of epidermal skin melanocytes and non-cutaneous or dermal melanocytes, we confirmed the inability of the latter to be involved as follicular melanocytes to regenerate hair follicles during the hair reconstitution assay.

Unexpected multipotency of melanoblasts isolated from murine skin.

Melanoblasts, precursor of melanocytes, are generated from the neural crest and differentiate into melanocytes during their migration throughout the entire body. The melanoblasts are thought to be progenitor cells that differentiate only into melanocyte. Here, we show that melanoblasts, even after they have already migrated throughout the skin, are multipotent, being able to generate neurons, glial cells, and smooth muscle cells in addition to melanocytes.

Differentiation of mouse hepatic progenitor cells induced by hepatocyte nuclear factor-4 and cell transplantation in mice with liver fibrosis.

Background: Hepatocyte nuclear factor-4 (HNF-4) plays a central role in the differentiation process of hepatic cells. We investigated the effects of an overexpression of HNF-4 on hepatic progenitor cells isolated from a fetal mouse liver and transplantation of the cells in a mouse model of liver fibrosis.

Methods: Hepatic progenitor cells were isolated from the embryonic day 14.

Iris as a recipient tissue for pigment cells: organized in vivo differentiation of melanocytes and pigmented epithelium derived from embryonic stem cells in vitro.

Regenerative transplantation of embryonic stem (ES) cell-derived melanocytes into adult tissues, especially skin that includes hair follicles or the hair follicle itself, generally not possible, whereas that of ES cell-derived pigmented epithelium was reported previously. We investigated the in vivo differentiation of these two pigment cell types derived from ES cells after their transfer into the iris. Melanocytes derived from ES cells efficiently integrated into the iris and expanded to fill the stromal layer of the iris, like those prepared from neonatal skin.

Maintenance of undifferentiated mouse embryonic stem cells in suspension by the serum- and feeder-free defined culture condition.

The proven pluripotency of ES cells is expected to allow their therapeutic use for regenerative medicine. We present here a novel suspension culture method that facilitates the proliferation of pluripotent ES cells without feeder cells. The culture medium contains polyvinyl alcohol (PVA), free of either animal-derived or synthetic serum, and contains very low amounts of peptidic or proteinaceous materials, which are favorable for therapeutic use.

Isolation and characterization of Kit-independent melanocyte precursors induced in the skin of Steel factor transgenic mice.

Steel factor (SLF, also called KIT-ligand, mast cell growth factor, or stem cell factor) acting through the tyrosine kinase receptor KIT is thought to be indispensable for the early phase of melanocyte development both in vivo and in vitro. In the present study, Kit-independent precursor cells were generated in mice expressing exogenous SLF in their skin keratinocytes and were detected as pigmented spots after administration of Kit function-blocking antibody. We successfully purified these precursor or stem cells as Kit+CD45- cells by flow cytometry.

Transplantation of cells from eye-like structures differentiated from embryonic stem cells in vitro and in vivo regeneration of retinal ganglion-like cells.

Background: An embryonic stem (ES) cell-derived eye-like structure, made up of neural retinal lineage cells, retinal pigment epithelial (RPE) cells, and lens cells was constructed in our laboratory. We have shown that cells from these eye-like structures can be integrated into the developing optic vesicle of chicks. The purpose of this study was to determine whether the cells from these eye-like structures can differentiate into retinal ganglion cells (RGCs) when transplanted into the vitreous of an injured adult mouse retina.