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 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.

Project description:The dermal sheath cup is the peribulbar component of the hair follicle dermal sheath, and has hair inductive potential similar to the dermal papilla. To characterize it in comparison with other mesenchymal follicle tissuesparts, we performed gene expression profiling of intact dermal sheath cups, which were separated from hair follicles by microdissection. Gene expression profiles of the dermal sheath cup, dermal papilla and upper dermal sheath were compared. We identified a dermal sheath cup signature composed of 32 upregulated genes, which included extracellular matrix components and BMP binding mollecules, while dermal papilla signature included a number of dermal papilla signature genes which had already reported. Analyses of upstream regulators showed that TGF- b1 is a putative regulator of these genes. These results suggest some of molecular mechanism that contributes to human dermal sheath cup properties, which could be useful for hair follicle bioengineering.

Project description:In our study, we found that low-passage dermal papilla cells (DPCs) and dermal sheath cells (DSCs) has higher homing rate than that of high-passage DPCs and DSCs. To uncover the molecular mechanisms underlying the difference of homing rate between low-passage DPCs/DSCs and high-passage DPCs/DSCs, we perform transcriptome analysis of mRNA expression profiles of low-passage and high-passage DPCs and DSCs.

Project description:To investigate new health functions by blackcurrant extract (BCE), we compare altered of the genes expression before and after BCE (1.0μg/ml) treatment in human follicle dermal papilla cells (HFDPC).

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:The libraries contained in this experiment come from hair follicle dermal papilla primary whole cells, HFDPC isolated from independent donors. They are stranded PE101 Illumina Hi-Seq RNA-Seq libraries from rRNA-depleted Total RNA > 200 nucleotides in size. For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODE_Data_Use_Policy_for_External_Users_03-07-14.pdf

Project description:Hair Follicle regeneration relies on both epithelial components (bulge and hair germ cells) and a mesenchymal one (dermal papilla cells). We used microarrays to detail the global programme of gene expression underlying organ regeneration at the transition between quiescent stages (early and middle telogen) and the initiation of a new growth (late telogen).

Project description:We investigated the role of AMPK activation in the progression of senescence in HFDPCs. The anti-senescence effects of adenine, a recently identified AMPK activator, were determined in a comparison with AICAR, a pharmacological AMPK activator, in HFDPCs. The results showed that either adenine or AICAR induced phosphorylation of Thr172 of AMPK in HFDPCs. As revealed by microarray analysis, significant changes of gene expression pattern were observed in the high-passage HFDPCs compared with that at lower passage level. A chip study using total RNA recovered from three separate wild-type cultures of Human follicle dermal papilla cells (HFDPCs) and three separate cultures of a triple adenine-treated cells.

Project description:Hair follicle matrix, outer root sheath, dermal papilla cells and melanocytes and a dermal fraction enriched in fibroblasts were FACS isolated from 4d backskins. Targets from two biological replicates of each were generated and the expression profiles were determined using Affymetrix Mouse Genechip 430A arrays. Comparisons between the sample groups allow the identification of cell-type specific genes. Experiment Overall Design: Mx, ORS, DF, DP and Mc were FACSorted from Lef1-RFP/K14-H2BGFP mice from 4 day old backskins