The restoration of hair-inductive potential in human dermal papilla cells (hDPCs) is a tremendous challenge for hair regeneration. Much of the research thus far has indicated that three-dimensional (3-D) culture shows improved efficacy in hair follicle (HF) neogenesis. However, mature HF cannot regenerate in an incomplete microenvironment. This study developed an optimized 3-D co-culture system to restore the hair-inductive characteristics of hDPCs by mimicking the in-vivo microenvironment. As a result, Matrigel-encapsulated hDPCs spontaneously formed into hDPC aggregates (hDPAs), which exhibited better activity, higher proliferation rates, and less apoptosis and hypoxia than the ultra-low attachment culture. Interestingly, the co-culture with the hair matrix cells and dermal sheath cup cells further enhanced the expression of hair regeneration-related genes of hDPAs compared to conditioned medium and improved mature HF induction. In addition, these hDPAs with higher hair inductivity could be produced on a large scale and easily separated for gene expression detection. Finally, the mRNA sequencing, PCR, and WB results showed that the co-culture biomimetic microenvironment stimulated the canonical Wnt signaling pathway and inhibited the BMP signaling pathway. Thus, this co-culture system will provide a reliable platform that allows high-throughput culture, testing, and harvesting of hDPAs for HF tissue engineering. STATEMENT OF SIGNIFICANCE: Extensive hair loss continues to be difficult to treat and causes significant patient morbidity. Hair follicle (HF) tissue engineering may seem to be a way out. However, the absence of the in-vivo microenvironment fails to regenerate mature hairs. This study systematically described a biomimetic co-culture approach to generate better quality human dermal papilla cell aggregates (hDPAs) with improved hair inductive properties, which can be further used for HF tissue engineering. The hDPC microenvironment was reprogrammed through the controllable formation of self-assembled organoids in Matrigel and the tri-culture with hair matrix cells and dermal sheath cup cells. This work indicates that the production of hDPAs could be readily scaled, in theory for large-scale assays, analyses, or therapeutic applications.
Keywords: 3-D co-culture; Biomimetic microenvironment; Dermal papilla cell; Hair follicle regeneration; Tissue engineering.
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