Long-Term Fate of Human Fetal Liver Progenitor Cells Transplanted in Injured Mouse Livers.

Liver progenitor cells have the potential to repair and regenerate a diseased liver. The success of any translational efforts, however, hinges on thorough understanding of the fate of these cells after transplant, especially in terms of long-term safety and efficacy. Here, we report transplantation of a liver progenitor population isolated from human fetal livers into immune-permissive mice with follow-up up to 36 weeks after transplant. We found that human progenitor cells engraft and differentiate into functional human hepatocytes in the mouse, producing albumin, alpha-1-antitrypsin, and glycogen. They create tight junctions with mouse hepatocytes, with no evidence of cell fusion. Interestingly, they also differentiate into functional endothelial cell and bile duct cells. Transplantation of progenitor cells abrogated carbon tetrachloride-induced fibrosis in recipient mice, with downregulation of procollagen and anti-smooth muscle actin. Paradoxically, the degree of engraftment of human hepatocytes correlated negatively with the anti-fibrotic effect. Progenitor cell expansion was most prominent in cirrhotic animals, and correlated with transcript levels of pro-fibrotic genes. Animals that had resolution of fibrosis had quiescent native progenitor cells in their livers. No evidence of neoplasia was observed, even up to 9 months after transplantation. Human fetal liver progenitor cells successfully attenuate liver fibrosis in mice. They are activated in the setting of liver injury, but become quiescent when injury resolves, mimicking the behavior of de novo progenitor cells. Our data suggest that liver progenitor cells transplanted into injured livers maintain a functional role in the repair and regeneration of the liver. Stem Cells 2018;36:103-113.

Hepatic differentiation of human amniotic epithelial cells and in vivo therapeutic effect on animal model of cirrhosis.

BACKGROUND AND AIM: Human amniotic epithelial cells (hAECs) have been touted as an ideal stem cell candidate, being ethically neutral, immunologically naïve, plentiful in origin, and retaining plasticity in its fetal stage. We hypothesized that by applying natural physiological signals of the developing liver, hAECs can be coaxed into becoming functional immunopermissive hepatocyte-like cells. These cells would have tremendous potential for allogenic cellular transplantation in the treatment of chronic liver insufficiency. METHODS: hAECs were obtained from term placentas and subjected to hepatic trans-differentiation. Hepatic differentiated cells were analyzed with immunophenotyping, electron microscopy, reverse transcription-polymerase chain reaction as well as characterized for hepatic metabolic function. In vivo efficacy was tested using intrasplenic transplantation into non-obese diabetic (NOD) Scid Gamma mice with thioacetamide-induced chronic liver failure and analyzed for engraftment and improvement in liver indices. RESULTS: With hepatic differentiation, hAECs assumed a hepatocytic polygonal morphology with upregulation of transcription factors responsible for liver specification. These hepatic differentiated-hAECs (HD-AECs) demonstrated bile canaliculi formation, secreted albumin, eliminated indo-cyanine green, uptook low-density lipoprotein, and inducible CYP3A4 and CYP2C9 enzymatic activities. Transplantation of HD-AECs and de novo hAECs in mice model of cirrhosis showed successful in vivo engraftment and differentiation into functional hepatocytes positive for human-specific albumin. HD-AEC cells that had undergone hepatic differentiation showed the greatest improvement in albumin function while preserving human leukocyte antigen-G expression postdifferentiation. CONCLUSION: hAECs were able to differentiate into functional hepatocyte-like cells both in vivo and in vitro. They showed therapeutic efficacy after transplantation in mice model of cirrhosis, offering an exciting source of cells for generation of functionally useful hepatocytes.