Adam Aziza A A, Jongejan Aldo, Moerland Perry D, van der Mark Vincent A, Oude Elferink Ronald P, Chamuleau Robert A F M, Hoekstra Ruurdtje
Tytgat Institute for Liver and Intestinal Research, AG&M, Amsterdam UMC, University of Amsterdam, Meibergdreef 69-71, 1105 BK, Amsterdam, The Netherlands.
Department of Clinical Epidemiology, Biostatistics and Bioinformatics, Amsterdam UMC, University of Amsterdam, Meibergdreef 9, 1105 AZ, Amsterdam, The Netherlands.
Cytotechnology. 2020 Jun;72(3):377-395. doi: 10.1007/s10616-020-00384-w. Epub 2020 Mar 4.
Human liver cell line HepaRG is a well-known source of human hepatocyte-like cells which, however, displays limited biotransformation and a tendency to transform after 20 passages. The new HepaRG-CAR cell line overexpressing constitutive androstane receptor (CAR, NR1I3), a regulator of detoxification and energy metabolism outperforms the parental HepaRG cell line in various liver functions. To further characterize this cell line and assess its stability we compared HepaRG-CAR with HepaRG cells at different passages for their expression profile, ammonia and lactate metabolism, bile acid and reactive oxygen species (ROS) production. Transcriptomic profiling of HepaRG-CAR vs. HepaRG early-passage revealed downregulation of hypoxia, glycolysis and proliferation and upregulation of oxidative phosphorylation genesets. In addition CAR overexpression downregulated the mTORC1 signaling pathway, which, as mediator of proliferation and metabolic reprogramming, may play an important role in the establishment of the HepaRG-CAR phenotype. The ammonia and lactate metabolism and bile acid production of HepaRG-CAR cells was stable for 10 additional passages compared to HepaRG cells. Interestingly, bile acid production was 4.5-fold higher in HepaRG-CAR vs. HepaRG cells, whereas lactate and ROS production were 2.7- and 2.0-fold lower, respectively. Principal component analysis showed clustering of HepaRG-CAR (early- and late-passage) and HepaRG early-passage and not with HepaRG late-passage indicating that passaging exerted larger effect on the transcriptional profile of HepaRG than HepaRG-CAR cells. In conclusion, overexpression of CAR in HepaRG cells improves their bile acid production, mitochondrial energy metabolism, and stability, with the latter possibly due to reduced ROS production, resulting in an optimized source of human hepatocytes.
人肝细胞系HepaRG是一种著名的人肝样细胞来源,然而,它的生物转化能力有限,并且在传代20次后有转化的倾向。新的过表达组成型雄甾烷受体(CAR,NR1I3)的HepaRG-CAR细胞系,CAR是一种解毒和能量代谢的调节因子,在各种肝功能方面优于亲代HepaRG细胞系。为了进一步表征该细胞系并评估其稳定性,我们比较了不同传代次数的HepaRG-CAR细胞和HepaRG细胞的表达谱、氨和乳酸代谢、胆汁酸和活性氧(ROS)生成。HepaRG-CAR与早期传代的HepaRG的转录组分析显示,缺氧、糖酵解和增殖相关基因下调,氧化磷酸化基因集上调。此外,CAR的过表达下调了mTORC1信号通路,mTORC1作为增殖和代谢重编程的介质,可能在HepaRG-CAR表型的建立中起重要作用。与HepaRG细胞相比,HepaRG-CAR细胞的氨和乳酸代谢以及胆汁酸生成在另外10次传代中保持稳定。有趣的是,HepaRG-CAR细胞的胆汁酸生成比HepaRG细胞高4.5倍,而乳酸和ROS生成分别低2.7倍和2.0倍。主成分分析显示,HepaRG-CAR(早期和晚期传代)和早期传代的HepaRG聚类在一起,而不与晚期传代的HepaRG聚类,这表明传代对HepaRG转录谱的影响大于对HepaRG-CAR细胞的影响。总之,在HepaRG细胞中过表达CAR可改善其胆汁酸生成、线粒体能量代谢和稳定性,后者可能是由于ROS生成减少,从而产生了优化的人肝细胞来源。
