Eli and Edythe Broad Center of Regeneration Medicine and Stem Cell Research, University of California San Francisco, San Francisco, California, USA.
Department of Pediatrics, University Children's Hospital, Bern, Switzerland.
Hepatology. 2022 Sep;76(3):646-659. doi: 10.1002/hep.32247. Epub 2021 Dec 18.
Patient-derived human-induced pluripotent stem cells (hiPSCs) differentiated into hepatocytes (hiPSC-Heps) have facilitated the study of rare genetic liver diseases. Here, we aimed to establish an in vitro liver disease model of the urea cycle disorder ornithine transcarbamylase deficiency (OTCD) using patient-derived hiPSC-Heps.
Before modeling OTCD, we addressed the question of why hiPSC-Heps generally secrete less urea than adult primary human hepatocytes (PHHs). Because hiPSC-Heps are not completely differentiated and maintain some characteristics of fetal PHHs, we compared gene-expression levels in human fetal and adult liver tissue to identify genes responsible for reduced urea secretion in hiPSC-Heps. We found lack of aquaporin 9 (AQP9) expression in fetal liver tissue as well as in hiPSC-Heps, and showed that forced expression of AQP9 in hiPSC-Heps restores urea secretion and normalizes the response to ammonia challenge by increasing ureagenesis. Furthermore, we proved functional ureagenesis by challenging AQP9-expressing hiPSC-Heps with ammonium chloride labeled with the stable isotope [ N] ( NH Cl) and by assessing enrichment of [ N]-labeled urea. Finally, using hiPSC-Heps derived from patients with OTCD, we generated a liver disease model that recapitulates the hepatic manifestation of the human disease. Restoring OTC expression-together with AQP9-was effective in fully correcting OTC activity and normalizing ureagenesis as assessed by NH Cl stable-isotope challenge.
Our results identify a critical role for AQP9 in functional urea metabolism and establish the feasibility of in vitro modeling of OTCD with hiPSC-Heps. By facilitating studies of OTCD genotype/phenotype correlation and drug screens, our model has potential for improving the therapy of OTCD.
患者来源的人诱导多能干细胞(hiPSCs)分化为肝细胞(hiPSC-Heps)促进了对罕见遗传肝脏疾病的研究。在这里,我们旨在使用患者来源的 hiPSC-Heps 建立尿素循环障碍鸟氨酸转氨甲酰酶缺乏症(OTCD)的体外肝脏疾病模型。
在对 OTCD 进行建模之前,我们首先解决了 hiPSC-Heps 一般比成人原代人肝细胞(PHHs)分泌更少尿素的原因。由于 hiPSC-Heps 尚未完全分化并保留了一些胎儿 PHHs 的特征,我们比较了人胎儿和成人肝组织中的基因表达水平,以确定导致 hiPSC-Heps 中尿素分泌减少的基因。我们发现胎儿肝脏组织以及 hiPSC-Heps 中缺乏水通道蛋白 9(AQP9)的表达,并表明在 hiPSC-Heps 中强制表达 AQP9 可通过增加尿素生成来恢复尿素分泌并使对氨的反应正常化。此外,我们通过用稳定同位素标记的氯化铵( NH Cl)对表达 AQP9 的 hiPSC-Heps 进行[ N]挑战,并通过评估[ N]标记的尿素的富集来证明功能性尿素生成。最后,使用源自 OTCD 患者的 hiPSC-Heps,我们生成了一种肝脏疾病模型,该模型再现了人类疾病的肝表现。与 AQP9 一起恢复 OTC 表达可有效完全纠正 OTC 活性,并通过 NH Cl 稳定同位素挑战来正常化尿素生成。
我们的结果确定了 AQP9 在功能性尿素代谢中的关键作用,并建立了使用 hiPSC-Heps 对 OTCD 进行体外建模的可行性。通过促进 OTCD 基因型/表型相关性和药物筛选的研究,我们的模型有可能改善 OTCD 的治疗方法。
