Three-dimensional cardiac organoid formation accelerates the functional maturation of human induced pluripotent stem cell-derived cardiomyocytes

Hanbyeol Lee, Jeong Suk Im, Daejin Choi, Jieun An, Subin Kim, Seunghee Yeon, Seulgi Yoon, Dong-Hun Woo
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引用次数: 1

Abstract

Human induced pluripotent stem cell (hiPSC)-derived cardiomyocytes (CMs) offer a promising source for heart regeneration, disease modeling, and drug screening. Recent developments in organoid technology have made it possible to study how hiPSC-derived CMs interact together, and this culture system mimics the tissue environment and behavior of the cardiac cells in our body. However, the similarities and differences between conventional 2-dimensional (2D) culture and 3-dimensional (3D) organoid culture systems for CM differentiation have been incompletely elucidated. To study how the individual microenvironment formed by each culture system affects the properties of CMs differentiated from hiPSCs, we conducted a comparative study between 2D monolayer and direct 3D cardiac organoid (hiCO) differentiation from hiPSCs throughout the sequential differentiation stages. Although identical differentiation cues were applied to hiPSCs, the 3D differentiation system strongly exhibited higher mesoderm commitment and cardiac induction than 2D monolayer differentiation. In the late stage of differentiation, the 3D hiCOs showed a higher frequency of a mature myofibrillar isoform switching in sarcomere structure of differentiated CMs than was observed in monolayer culture, although over 94% of cardiac troponin T-positive cells resulted at the end point of differentiation in both systems. Furthermore, the accelerated structural maturation in 3D hiCOs resulted in increased expression of cardiac-specific ion channel genes and Ca2+ transient properties, with a high signal amplitude and rapid contractility. The present study provides details surrounding the 2D and 3D culture methods for CM differentiation from iPSCs, and focuses on 3D cell culture as an improved strategy for approaching and applying cardiac maturation.
三维心脏类器官的形成加速了人诱导多能干细胞衍生的心肌细胞的功能成熟
人类诱导多能干细胞(hiPSC)衍生的心肌细胞(CMs)为心脏再生、疾病建模和药物筛选提供了一个有希望的来源。类器官技术的最新发展使得研究hipsc来源的CMs如何相互作用成为可能,并且这种培养系统模拟了我们体内心脏细胞的组织环境和行为。然而,传统的2维(2D)培养和3维(3D)类器官培养系统在CM分化中的异同尚未完全阐明。为了研究每种培养体系形成的个体微环境如何影响从hipsc分化的CMs的特性,我们在整个顺序分化阶段对hipsc的2D单层和直接3D心脏类器官(hiCO)分化进行比较研究。尽管对hiPSCs应用了相同的分化线索,但3D分化系统比2D单层分化表现出更高的中胚层承诺和心脏诱导。在分化后期,与单层培养相比,3D hiCOs在分化的CMs的肌瘤结构中显示出更高频率的成熟肌原纤维异构体转换,尽管在两种系统中,超过94%的心肌肌钙蛋白t阳性细胞在分化终点出现。此外,三维hiCOs结构成熟的加速导致心脏特异性离子通道基因表达和Ca2+瞬态特性增加,具有高信号幅度和快速收缩性。本研究提供了关于从iPSCs分化CM的2D和3D培养方法的详细信息,并重点介绍了3D细胞培养作为接近和应用心脏成熟的改进策略。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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