RT Journal Article SR Electronic T1 Reprogramming of three-dimensional microenvironments for in vitro hair follicle induction JF bioRxiv FD Cold Spring Harbor Laboratory SP 2022.06.13.495917 DO 10.1101/2022.06.13.495917 A1 Tatsuto Kageyama A1 Akihiro Shimizu A1 Riki Anakama A1 Rikuma Nakajima A1 Kohei Suzuki A1 Yusuke Okubo A1 Junji Fukuda YR 2022 UL http://biorxiv.org/content/early/2022/06/16/2022.06.13.495917.abstract AB During embryonic development, reciprocal interactions between epidermal and mesenchymal layers trigger hair follicle morphogenesis. This study revealed that microenvironmental reprogramming via control over these interactions enabled hair follicle induction in vitro. A key approach is to modulate spatial distributions of epithelial and mesenchymal cells in their spontaneous organization. The de novo hair follicles with typical morphological features emerged in aggregates of the two cell types, termed hair follicloids, and hair shafts sprouted with near 100% efficiency in vitro. The hair shaft length reached ∼3 mm in culture. Typical trichogenic signaling pathways were upregulated in hair follicloids. Owing to replication of hair follicle morphogenesis in vitro, production and transportation of melanosomes were also monitored in the hair bulb region. This in vitro hair follicle model might be valuable for better understanding hair follicle induction, for evaluating hair growth as well as the inhibition of hair growth by drugs, and modeling gray hairs in a well-defined environment.Teaser In tissue morphogenesis, different types of cells harmonize in a pre-programmed manner using messenger systems such as epithelial-mesenchymal interactions. Organoids are a promising tool to elucidate such mechanisms on a molecular level. This work describes a strategy for reprograming three-dimensional microenvironments to trigger the initiation of in vitro regeneration of hair follicle organoids. Hair follicle organoids generated fully matured hair follicles, enabling the monitoring of hair follicle morphogenesis in vitro and determination of signaling pathways involved in early hair follicle morphogenesis. The principles uncovered herein may be relevant to other organ systems and will contribute to our understanding of developmental phenomena in physiological and pathological processes, eventually opening up new research avenues for the development of new treatment strategies.Competing Interest StatementThe authors have declared no competing interest.