Dermal Papilla Cell-Derived Extracellular Vesicles Increase Hair Inductive Gene Expression in Adipose Stem Cells via β-Catenin Activation

Recently, extracellular vesicle (EV)-mediated cell differentiation has gained attention in developmental biology due to genetic exchange between donor cells and recipient cells via transfer of mRNA and miRNA. EVs, also known as exosomes, play a role in maintaining paracrine cell communication and can induce cell proliferation and differentiation. However, it remains unclear whether adipose-derived stem cells (ASCs) can adopt dermal papilla (DP)-like properties with dermal papilla cell-derived extracellular vesicles (DPC-EVs). To understand the effect of DPC-EVs on cell differentiation, DPC-EVs were characterized and incubated with ASCs, of monolayer and spheroid cell cultures, in combination with the CAO1/2FP medium specialized for dermal papilla cells (DPCs). DPC-like properties in ASCs were initially evaluated by comparing several genes and proteins with those of DPCs via real-time PCR analysis and immunostaining, respectively. We also evaluated the presence of hair growth-related microRNAs (miRNAs), specifically mir-214-5P, mir-218-5p, and mir-195-5P. Here, we found that miRNA expression patterns varied in DPC-EVs from passage 4 (P4) or P5. In addition, DPC-EVs in combination with CAP1/2FP accelerated ASC proliferation at low concentrations and propagated hair inductive gene expression for versican (vcan), alpha-smooth muscle actin (α-sma), osteopontin (opn), and N-Cam (ncam). Comparison between the expression of hair inductive genes (vcan, α-sma, ctnb, and others), the protein VCAN, α-SMA and β-Catenin (CTNB), and hair inductive miRNAs (mir-214-5P, mir-218-5p, and mir-195-5p) of DPC-EVs revealed similarities between P4 DPC-EVs-treated ASCs and DPCs. We concluded that early passage DPC-EVs, in combination with CAP1/2FP, enabled ASCs to transdifferentiate into DPC-like cells.

Keratin is not only a Structural Protein in Hair: Keratin-mediated Hair Growth

Keratin is known to be a major protein in hair, but the biological function of keratin in hair growth is unknown, which led us to conduct a pilot study to elucidate biological function of keratin in hair growth via cellular interactions with hair forming cells. Here, we show hair growth is stimulated by intradermal injection of keratin into mice, and show that outer root sheath cells undergo transforming growth factor-β2-induced apoptosis, resulting in keratin exposure. Keratin exposure appears to be critical for dermal papilla cell condensation and hair germ formation as immunodepletion and silencing keratin prevent dermal papilla cell condensation and hair germ formation. Furthermore, silencing keratin in mice resulted in a marked suppression of anagen follicle formation and hair growth. Our study imply a new finding of how to initiate hair regeneration and suggests the potent application of keratin biomaterial for the treatment of hair loss.