Liao Yu-Jing, Chen Yi-Shiou, Lin Yu-Ching, Yang Jenn-Rong
Genetics and Physiology Division, Taiwan Livestock Research Institute, Ministry of Agriculture, Tainan, Taiwan,
Genetics and Physiology Division, Taiwan Livestock Research Institute, Ministry of Agriculture, Tainan, Taiwan.
Cells Tissues Organs. 2025;214(1):26-35. doi: 10.1159/000539320. Epub 2024 Jul 16.
Endothelial cells (EC) can be generated from porcine-induced pluripotent stem cells (piPSC), but poor efficiency in driving EC differentiation hampers their application and efficacy. Additionally, the culture of piPSC-derived EC (piPSC-EC) on three-dimensional (3D) scaffolds has not been fully reported yet. Here, we report a method to improve the generation of EC differentiation from piPSC and to facilitate their culture on 3D scaffolds, providing a potential resource for in vitro drug testing and the generation of tissue-engineered vascular grafts.
We initiated the differentiation of piPSC into EC by seeding them on laminin 411 and employing a three-stage protocol, which involved the use of distinct EC differentiation media supplemented with CHIR99021, BMP4, VEGF, and bFGF.
piPSC-EC not only expressed EC markers such as CD31, VE-cadherin, and von Willebrand factor (vWF) but also exhibited an upregulation of EC marker genes, including CD31, CD34, VEGFR2, VE-cadherin, and vWF. They exhibited functional characteristics similar to those of porcine coronary artery endothelial cells (PCAEC), such as tube formation and Dil-Ac-LDL uptake. Furthermore, when cultured on 3D scaffolds, piPSC-EC developed a 3D morphology and were capable of forming an endothelial layer and engineering capillary-like networks, though these lacked lumen structures.
Our study not only advances the generation of EC from piPSC through an inhibitor and growth factor cocktail but also provides a promising approach for constructing vascular network-like structures. Importantly, these findings open new avenues for drug discovery in vitro and tissue engineering in vivo.
猪诱导多能干细胞(piPSC)可分化生成内皮细胞(EC),但内皮细胞分化效率低下限制了其应用和效果。此外,关于三维(3D)支架上piPSC来源的内皮细胞(piPSC-EC)培养的报道尚不完善。在此,我们报告一种提高piPSC向内皮细胞分化生成效率并促进其在3D支架上培养的方法,为体外药物测试和组织工程血管移植物的构建提供了潜在资源。
我们将piPSC接种在层粘连蛋白411上,并采用三阶段方案启动其向内皮细胞的分化,该方案涉及使用添加CHIR99021、BMP4、VEGF和bFGF的不同内皮细胞分化培养基。
piPSC-EC不仅表达内皮细胞标志物,如CD31、血管内皮钙黏蛋白和血管性血友病因子(vWF),还表现出内皮细胞标志物基因的上调,包括CD31、CD34、血管内皮生长因子受体2(VEGFR2)、血管内皮钙黏蛋白和vWF。它们表现出与猪冠状动脉内皮细胞(PCAEC)相似的功能特征,如形成管腔和摄取Dil-Ac-LDL。此外,当在3D支架上培养时,piPSC-EC呈现出三维形态,能够形成内皮层并构建类似毛细血管的网络,尽管这些网络缺乏管腔结构。
我们的研究不仅通过抑制剂和生长因子组合促进了piPSC向内皮细胞的生成,还为构建类似血管网络的结构提供了一种有前景的方法。重要的是,这些发现为体外药物发现和体内组织工程开辟了新途径。
