Heart Institute (InCor), University of São Paulo Medical School, São Paulo, SP, Brazil.
School of Cardiovascular Medicine and Sciences, BHF Research Excellence Centre, King's College London, UK; Randall Centre for Cell and Molecular Biophysics (School of Basic and Medical Biosciences, King's College London), UK.
Biochem Biophys Res Commun. 2020 Dec 10;533(3):376-382. doi: 10.1016/j.bbrc.2020.09.021. Epub 2020 Sep 19.
Human induced pluripotent stem cell derived cardiomyocytes (hiPSC-CMs) resemble fetal cardiomyocytes and electrical stimulation (ES) has been explored to mature the differentiated cells. Here, we hypothesize that ES applied at the beginning of the differentiation process, triggers both differentiation of the hiPSC-CMs into a specialized conduction system (CS) phenotype and cell maturation. We applied ES for 15 days starting on day 0 of the differentiation process and found an increased expression of transcription factors and proteins associated with the development and function of CS including Irx3, Nkx2.5 and contactin 2, Hcn4 and Scn5a, respectively. We also found activation of intercalated disc proteins (Nrap and β-catenin). We detected ES-induced CM maturation as indicated by increased Tnni1 and Tnni3 expression. Confocal micrographs showed a shift towards expression of the gap junction protein connexin 40 in ES hiPSC-CM compared to the more dominant expression of connexin 43 in controls. Finally, analysis of functional parameters revealed that ES hiPSC-CMs exhibited faster action potential (AP) depolarization, longer intracellular Ca transients, and slower AP duration at 90% of repolarization, resembling fast conducting fibers. Altogether, we provided evidence that ES during the differentiation of hiPSC to cardiomyocytes lead to development of cardiac conduction-like cells with more mature cytoarchitecture. Thus, hiPSC-CMs exposed to ES during differentiation can be instrumental to develop CS cells for cardiac disease modelling, screening individual drugs on a precison medicine type platform and support the development of novel therapeutics for arrhythmias.
人诱导多能干细胞衍生的心肌细胞(hiPSC-CMs)类似于胎儿心肌细胞,已经探索了电刺激(ES)来使分化的细胞成熟。在这里,我们假设在分化过程开始时施加 ES,可触发 hiPSC-CMs 分化为专门的传导系统(CS)表型和细胞成熟。我们在分化过程的第 0 天开始施加 15 天的 ES,并发现转录因子和与 CS 的发育和功能相关的蛋白质的表达增加,包括 Irx3、Nkx2.5 和 contactin 2、Hcn4 和 Scn5a。我们还发现了连接蛋白 2(Nrap 和 β-连环蛋白)的连接蛋白 2(Nrap 和 β-连环蛋白)的激活。我们检测到 ES 诱导的 CM 成熟,表现为 Tnni1 和 Tnni3 表达增加。共聚焦显微镜图像显示,与对照相比,ES hiPSC-CM 中缝隙连接蛋白 connexin 40 的表达向表达转移,而 connexin 43 的表达更为占优势。最后,功能参数分析表明,ES hiPSC-CMs 表现出更快的动作电位(AP)去极化、更长的细胞内 Ca 瞬变和更慢的 90%复极化时的 AP 持续时间,类似于快速传导纤维。总之,我们提供的证据表明,在 hiPSC 分化为心肌细胞的过程中施加 ES 可导致具有更成熟细胞结构的心脏传导样细胞的发育。因此,在分化过程中暴露于 ES 的 hiPSC-CMs 可用于开发用于心脏疾病建模的 CS 细胞、在精准医学类型平台上对个体药物进行筛选以及支持心律失常的新型治疗方法的开发。
