Abstract
BackgroundPeriodically regenerated hair follicles provide an excellent research model for studying tissue regeneration and stem cell homeostasis. Periodic activation and differentiation of hair follicle stem cells (HFSCs) fuel cyclical bouts of hair regeneration. HFSCs represent an excellent paradigm for studying tissue regeneration and somatic stem cell homeostasis. However, these crucial studies are hampered by the lack of a culture system able to stably expand human HFSCs and regulate their fate.ResultsHere, we use layer-by-layer (LbL) self-assembly with gelatin/alginate to construct a nanoscale biomimetic extracellular matrix (ECM) for an HFSC population. The LbL coating provides ECM and mechanical support for individual cells, which helps to maintain the CD200+α6+ HFSC population to a certain extent. Addition of key signal molecules (FGF-7 and VEGF-A) simulates the minimum essential components of the stem cell microenvironment, thereby effectively and stably expanding HFSCs and maintaining the CD200+α6+ HFSC population. Subsequently, BMP2 loaded to the nanocoated layer, as a slow-release signal molecule, activates BMP signaling to regulate HFSCs’ fate in order to obtain a purified CD200+α6+ HFSC population.ConclusionThis system can minimize the microenvironment of HFSCs; thus, stably amplifying HFSCs and revealing their plasticity. Our study thus provides a new tool for studies of hair follicle reconstruction and stem cell homeostasis.
Highlights
Regenerated hair follicles provide an excellent research model for studying tissue regeneration and stem cell homeostasis
The isolated outer root sheath cells (ORSCs) suspension was cultured in standard 2D culture condition with keratinocyte growth medium (KGM) on the fibroblast feeder layer, which is widely used in keratinocyte culture [10, 27]
Studies on good culture models that can steadily augment human hair follicle stem cells (HFSCs) on a large scale with control remain of growing interest in tissue hair follicle engineering and Stem cells (SCs) homeostasis
Summary
Regenerated hair follicles provide an excellent research model for studying tissue regeneration and stem cell homeostasis. Periodic activation and differentiation of hair follicle stem cells (HFSCs) fuel cyclical bouts of hair regeneration. HFSCs represent an excellent paradigm for studying tissue regeneration and somatic stem cell homeostasis. These crucial studies are hampered by the lack of a culture system able to stably expand human HFSCs and regulate their fate. Human adult stem cells (SCs) are critical for tissue homeostasis, repair, and regeneration [1, 2]. HFSCs are the key seed cells for tissue hair follicle reconstruction and provide an excellent paradigm for the study of somatic adult SC lineage [1]. Whereas various culture systems are dedicated to culturing HFSCs in vitro [5,6,7], there are no methods to maintain and expand true pluripotent human HFSCs in culture without fibroblast feeder cells, as well as in vitro methods for regulating the fate of human HFSCs and their progeny
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