Project description:Androgenetic alopecia (AGA) is characterized by a progressive and androgen-dependent loss of hair from the frontal and vertex regions of the scalp. Although large-scale genetic analyses have identified >300 genetic risk factors, the underlying causal genes and pathways, and their involvement in core pathophysiological mechanisms, remain unclear. In the present study, systematic profiling of differential mRNA and microRNA expression was performed in human hair follicle samples from frontal and occipital scalp regions. Taken together, the present data improve understanding of the genomic regions, genes, and pathways that are implicated in AGA pathobiology.
Project description:To identify differentially expressed genes in androgenetic alopecia specifically in the adipose, adipose tissue samples from affected male participants were collected through punch biopsy at two different sites: bald (frontal) and normal (occipital,as control) scalp. After removal of the epidermis, dermis and hair follicle, we isolated RNA from the remaining adipose layer of the bald and normal scalp then performed gene expression analysis on the RNA-seq data to compare the profiles of the bald and normal scalp.
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:Androgenetic alopecia (AGA) is a progressive dermatological disorder of scalp hair loss, while beard growth in AGA is normally unaffected. In an attempt to identify genes that contribute to the androgen-responsive phenotype, we performed a thorough transcriptome profiling of hair follicles (HFs) from frontal and occipital scalp, chin and armpit. Through this analysis, three specifiic different expressed genes(LGALS7B, FABP4, FOS) were identified using qPCR, immunofluorescence. The differences in the expression of these genes in cultured beard and frontal HF reflected less inflammation and immune response, more active keratinization and PPARs signaling in beard HFs compared to frontal HFs. This profiling results be used to understand the different molecular mechanism of hair growth between AGA beard and HF, and those provided a possibility for the enlarged beard phenotype and AGA treatment.
Project description:It is well accepted that elevated mechanical tension of the skin surrounding a healing wound stimulates a fibrotic cascade of events and contributes to an increased size of scars. A laxity paradox in the field of hair transplantation describes a phenomenon opposing this view. During Strip Follicular Unit Transplantation (Strip FUT), surgeons remove a strip of scalp skin (approximately 5 cm x 10 cm, depending on the number of hair follicles required) from the occipital scalp, which is then used to harvest hair follicles that will be transplanted into the balding frontal scalp. Most patients with normal scalp skin laxity heal with narrow normotrophic scars, while a small number of patients (14%) with very loose scalp skin, and so low residual skin tension, heal with post operating scar widening (4 - 12 mm). These scars, referred to as stretched scars in the hair transplantation field, often require revision surgery or secondary hair grafting into the scar. We hypothesise that stretched scars present a unique transcriptional signature different from other types of scars. To determine the gene expression profile of stretched scars, we used Affymetrix microarrays to perform profiling of fibrotic dermis and the surrounding patient-matched healthy dermis.
Project description:Scarring alopecia consists of a collection of disorders characterized by destruction of hair follicles, replacement with fibrous scar tissue, and irreversible hair loss. Alopecia affects men and women worldwide and can be a significant source of psychological stress and depression for affected individuals. The purpose of this study was to explore metabolic profiles in scalp tissue samples from normal control subjects (n=6) and in matched samples obtained from affected (n=12) and unaffected (n=12) areas of the scalp in patients with lymphocytic Frontal Fibrosing Alopecia (FFA). Frontal fibrosing alopecia results from destruction of hair follicles by an inflammatory lymphocytic infiltrate that is localized around the upper portion of the hair follicle.
Project description:The key pathophysiological changes in androgenetic alopecia (AGA) are limited to hair follicles (HFs) in frontal and vertex regions, except for the occipital region. To identify biological differences among HF subpopulations. Paired vertex and occipital HFs from 10 male AGA donors were collected for RNA-seq assay. Furthermore, hair follicle and cell experiments were conducted on the identified key genes to reveal their roles in AGA. Our study aimed to uncover potential lncRNA indicators for AGA and reveal the potential mechanism underlying the involvement of AL136131.3 in hair growth in AGA.
Project description:Transcriptome analysis of DP signature gene expression in hTERT-immortalized balding (BAB) and non-balding (BAN) dermal papilla cells derived from frontal and occipital scalp of male patients with androgenetic alopecia Hamilton grade IV.
Project description:The use of dermal papilla cells for hair follicle (HF) regeneration is long accepted much attention. However, cultured dermal papilla cells tend to lose the hair-inducible capability during passaging, which restricts its application. Increasing evidences indicate that dermal papilla cells exert their regulatory function of HF growth mainly through their unique paracrine properties, opening up a way to exosome therapies.This study aimed to explore the effects of exosomes from high and low-passaged human scalp follicle dermal papilla cells (DP-Exos) on hair follicle stem cells (HFSCs) activation and hair growth, and to investigate the underline mechanism. DP-Exos were isolated by ultracentrifugation and cultured with human scalp follicles and HFSCs. The hair elongation and cell proliferation was assessed. Quantitative real-time PCR (qRT-PCR) and Western-blot were performed to detect the expression levels of a class of miRNAs and proteins which have positive roles in regulating hair growth and HFSCs proliferation. High throughput miRNA sequencing of miRNAs in high (P8) and low-passaged (P3) DP-Exos was performed, and the utmost miRNA and its target gene was identified via bioinformatics analysis.