Department of Textile Technology, Regenerative Engineering Laboratory, Indian Institute of Technology, Delhi, India.
ITC Life Sciences and Technology Centre, ITC Ltd., Bangalore, India.
J Cell Physiol. 2018 Nov;233(11):9015-9030. doi: 10.1002/jcp.26853. Epub 2018 Jun 19.
Human hair dermal papilla (DP) cells are specialized mesenchymal cells that play a pivotal role in hair regeneration and hair cycle activation. The current study aimed to first develop three-dimensional (3D) DP spheroids (DPS) with or without a silk-gelatin (SG) microenvironment, which showed enhanced DP-specific gene expression, resulting in enhanced extracellular matrix (ECM) production compared with a monolayer culture. We tested the feasibility of using this DPS model for drug screening by using minoxidil, which is a standard drug for androgenic alopecia. Minoxidil-treated DPS showed enhanced expression of growth factors and ECM proteins. Further, an attempt has been made to establish an in vitro 3D organoid model consisting of DPS encapsulated by SG hydrogel and hair follicle (HF) keratinocytes and stem cells. This HF organoid model showed the importance of structural features, cell-cell interaction, and hypoxia akin to in vivo HF. The study helped to elucidate the molecular mechanisms to stimulate cell proliferation, cell viability, and elevated expression of HF markers as well as epithelial-mesenchymal crosstalks, demonstrating high relevance to human HF biology. This simple in vitro DP organoid model system has the potential to provide significant insights into the underlying mechanisms of HF morphogenesis, distinct molecular signals relevant to different stages of the hair cycle, and hence can be used for controlled evaluation of the efficacy of new drug molecules.
人类头皮毛囊真皮乳头(DP)细胞是一种特化的间充质细胞,在毛发再生和毛囊激活中起着关键作用。本研究旨在首先开发具有或不具有丝胶(SG)微环境的三维(3D)DP 球体(DPS),与单层培养相比,这显示出增强的 DP 特异性基因表达,从而导致细胞外基质(ECM)产生增强。我们通过使用米诺地尔(一种治疗雄性脱发的标准药物)测试了这种 DPS 模型用于药物筛选的可行性。米诺地尔处理的 DPS 表现出生长因子和 ECM 蛋白的表达增强。此外,还尝试建立了一种由 SG 水凝胶包封的 DPS 和毛囊(HF)角质形成细胞和干细胞组成的体外 3D 类器官模型。该 HF 类器官模型显示了结构特征、细胞-细胞相互作用和类似于体内 HF 的缺氧的重要性。该研究有助于阐明刺激细胞增殖、细胞活力和 HF 标志物以及上皮-间充质串扰的表达升高的分子机制,这与人类 HF 生物学高度相关。这种简单的体外 DP 类器官模型系统有可能为 HF 形态发生的潜在机制、与毛发周期不同阶段相关的不同分子信号提供重要的见解,因此可用于控制评估新药物分子的功效。
