Project description:Hair follicle (HF) regeneration begins when communication between quiescent epithelial stem cells (SCs) and underlying mesenchymal dermal papillae (DP) generates sufficient activating cues to overcome repressive BMP signals from surrounding niche cells. We uncovered a hitherto unrecognized DP transmitter, TGFβ2, which activates Smad2/3 transiently in HFSCs concomitant with entry into tissue regeneration. We used microarrays to detect the genes specifically affected by TGFß receptor II-deficient mice upon HFSC activation. Hair follicle stem cells (HFSCs) of hair gem (HG) and bulge, and total skin keratinocytes were FACS-purified from the mouse back skin at 2nd telogen-to-anagen transition stages.

Project description:During development, dermal papilla precursor cells (DPPCs) initiate embryonic hair follicle (HF) formation with epidermal placode cells. Obtaining DPPCs with trichogenic ability is critical for human HF regeneration because dermal papilla cells (DPCs) rapidly loseDuring development, dermal papilla precursor cells (DPPCs) initiate embryonic hair follicle (HF) formation with epidermal placode cells. Obtaining DPPCs with trichogenic ability is critical for human HF regeneration because dermal papilla cells (DPCs) rapidly lose their trichogenic ability in culture. Here, we generated trichogenic DPPCs from human induced pluripotent stem cells (iPSCs) via neural crest stem cells (NCSCs), based on the developmental evidence at the hair placode stage. SDC1+CD133− cells showed signature DP gene expression, spontaneous sphere formation and represented intermediate population in the differentiation way from NCSCs to DPCs. hiPSC-derived DPPCs generated HF equivalents in vitro and reconstituted de novo human HFs in vivo combined with hiPSC-derived epithelial stem cells. Remarkably, trichogenic ability of DPPC was only proven in the specific time window, providing insights into the loss of trichogenicity in cultured DPC. Thus, this study provides an in vitro model for studying DPC development and biology.

Project description:In this dataset, we include the expression data obtained from primary dermal papilla cell cultures and human hair follicle organ culture from occipital scalp

Project description:Hair follicle (HF) regeneration begins when communication between quiescent epithelial stem cells (SCs) and underlying mesenchymal dermal papillae (DP) generates sufficient activating cues to overcome repressive BMP signals from surrounding niche cells. We uncovered a hitherto unrecognized DP transmitter, TGFβ2, which activates Smad2/3 transiently in HFSCs concomitant with entry into tissue regeneration. We used microarrays to detect the genes specifically affected by TGFß receptor II-deficient mice upon HFSC activation.

Project description:The feather follicle is a “professional” regenerative organ that undergoes natural cycling and, regeneration after wound plucking. Similar to mammalian hair follicle, dermal papilla (DP) controls feather regeneration, shape, size, and axis. Here we report gene expression profiling for feather DP at different growth stages. For growth phase, we compared gene expression of DP, the ramogenic zone of feather branching epithelium (Erz) and the mesenchymal pulp (Pp). We also compared gene expression of DP at resting phase. To characterize the feather regeneration process, we further profiled gene expression at Day-2 and Day-4 post wound. Our results provide a resource for investigating feather growth and regeneration. Examination of gene expression in dermal papilla (DP) at growth phase and resting phase feather follicle, and during feather regeneration.

Project description:Dermal papilla cells isolated from the human hair follicle are capable of inducing hair growth in recipient epithelia. However, demonstrating disparity from rodent dermal papilla, human cells lose this inductive competance immediately upon growth in culture under normal growth conditions. We grew dermal papilla cells in hanging drop cultures that are morphologically akin to intact dermal papilla, and found that by enhancing the environment for aggregation, we could restore the inductive capacity of human dermal papilla cells in culture. The underlying genes that regulate the inductive potential of dermal papilla cells is not well understood, and we sought to use global profiling to identify key genes and pathways related to inductive competance within dermal papilla cells. We used Affymetrix microarrays to profile human dermal papilla cells in both hair inducing, and non-hair inducing states. Affymetrix microarrays were used to to perform profiling of human dermal papilla cells, both as intact tissues (freshly isolated from scalp), and at several stages in subsequent two dimensional culture; cell explant outgrowths (p0), cells at passage 1 (p1), passage 3 (p3) and passage 5 (p5). RNA was isolated from cultured cells 72 hours after feeding. Cells at passage 3 were also grown in hanging drops to form dermal spheroids, that were used for RNA collection 48 hours after establishment. All experiments were performed using tissue from three biological replicates (#D5, D6, D7),

Project description:Dermal sheath (DS) shows potent hair inducing capability and high plasticity without leading to immuno rejection. A recent study showed a subset of DS cells, identified as hair follicle (HF) dermal stem cells, can be mobilized to regenerate DS, maintain/supply the cell number of dermal papilla (DP) and modulate hair type. However, it is unclear how Wnt/β-catenin signaling regulates DS cells behaviors. Here we report that activation of β-catenin in DS, to some extent, endows it with hair inducing ability, reprogramming HF epidermal cells to generate new outgrowth. The new formed dermal condensates (DC)/DP lying adjacent the outgrowth derives from DS and/or its progeny, and homeostasis of pre-existing HFs is disturbed. Additionally, progressive skin fibrosis is prominent in hypodermis, where the excessive activated fibroblasts at least partially originate from DS and/or its progeny. Gene expression analysis of purified DS cells revealed that 44% DC signature genes are regulated, most of which are up-regulated. We found elevated expression of several growth factors, including Noggin, Fgf7 and Fgf10, which were previously implicated in HF induction. In summary, we confirm the high plasticity of DS cells by in vivo assays and report a mechanism by which Wnt/β-catenin signaling controls DS cells behaviors. We prospectively isolated control and cΔex3 DS cells (YFP+ve CD34-ve ALP-ve ITGα8-ve cells) from P15 dorsal skins by FACS.

Project description:Advanced age drives the progressive degeneration of mammalian hair follicles (HF) and termination of its regeneration cycle. The role of hair follicle dermal stem cell (hfDSC) in this age-associated HF dysfunction remains largely unexplored. Here, we first characterize a novel function of hfDSCs in regenerating the full dermal papilla (DP) after laser ablation. Next, we performed long-term fate mapping, age-dependant in vivo clonal analysis and in vitro proliferation assay on hfDSCs to describe the age-related defects in mesenchymal stem cell self-renewal and differentiation capabilities. Moreover, single-cell RNA-sequencing of the HF mesenchymal population mapped the intrinsic transcriptional changes that may drive their age-related dysfunction. We highlight the requirement of hfDSCs for normal HF regeneration. Our findings characterize a novel function of mesenchymal stem cells, and how this crucial cell becomes dysfunctional with age to drive age-related hair loss.

Project description:Mouse hair follicles undergo synchronized cycles. Cyclical regeneration and hair growth is fueled by hair follicle stem cells (HFSCs). We used RNA-seq to identify SOX9-dependent transcriptional changes and ChIP-seq to identify SOX9-bound genes in HF-SCs. Telogen quiescent hair follicle stem cells (HFSCs) and intefollicular epidermal cells (IFE) were FACS-purified for ChIP-sequcencing and HFSCs for RNA-Sequencing

Project description:Dermal sheath (DS) shows potent hair inducing capability and high plasticity without leading to immuno rejection. A recent study showed a subset of DS cells, identified as hair follicle (HF) dermal stem cells, can be mobilized to regenerate DS, maintain/supply the cell number of dermal papilla (DP) and modulate hair type. However, it is unclear how Wnt/β-catenin signaling regulates DS cells behaviors. Here we report that activation of β-catenin in DS, to some extent, endows it with hair inducing ability, reprogramming HF epidermal cells to generate new outgrowth. The new formed dermal condensates (DC)/DP lying adjacent the outgrowth derives from DS and/or its progeny, and homeostasis of pre-existing HFs is disturbed. Additionally, progressive skin fibrosis is prominent in hypodermis, where the excessive activated fibroblasts at least partially originate from DS and/or its progeny. Gene expression analysis of purified DS cells revealed that 44% DC signature genes are regulated, most of which are up-regulated. We found elevated expression of several growth factors, including Noggin, Fgf7 and Fgf10, which were previously implicated in HF induction. In summary, we confirm the high plasticity of DS cells by in vivo assays and report a mechanism by which Wnt/β-catenin signaling controls DS cells behaviors.