[Characteristics of microsomal phase II metabolic enzymes in mouse embryonic stem cell-derived liver tissue].

OBJECTIVE: To investigate the characteristics of phase II metabolic enzymes in mouse embryonic stem (ES) cell-derived liver tissue. METHODS: Mature hepatocytes were differentiated from embryonic stem cells in cultured mouse embryoid bodies (EB) at d18. Western blot was used to detect the expression of uridine 5'-diphosphate glucronosyl transferase (UGT1a1,UGT1a6) and microsomal glutathione S-transferases 1(mGST1) during the differentiation course.The derived liver tissue was incubated with UDPGA and 7-HFC,the formation of 7-HFC glucuronide was detected by HPLC to examine the total activities of UGT1a1 and UGT1a6. Furthermore, the microsomes were incubated with CDNB and GSH,and the mGST1 activity was measured by spectrometry. RESULTS: An increase tendency of UGT1a1 expression was noticed during the differentiation course. UGT1a6 and mGST1 were not detected in the earlier stage until d18 of differentiation. The metabolic activity of mGST1 in the derived hepatocytes was 7.65 nmol/min/mg on d18. CONCLUSION: The ES cell-derived liver tissue possesses partial metabolic function of phase II enzymes on d18 of differentiation,which might be used as a model for in vitro research on hepatic pathophysiology and phase II drug metabolism.

PPAR-beta facilitating maturation of hepatic-like tissue derived from mouse embryonic stem cells accompanied by mitochondriogenesis and membrane potential retention.

Relatively little is known about mitochondria metabolism in differentiating embryonic stem (ES) cells. Present research focused on several elements of cellular energy metabolism in hepatic-like tissue derived from mouse ES cells. We demonstrated that mitochondrial location patterns and mitochondrial membrane potential (DeltaPsi(m)) existed in subsequent differentiation of the tissue. Mitochondriogenesis appeared at the early stage and kept a normal DeltaPsi(m) in differentiated mature hepatocytes. Peroxisome proliferator-activated receptor-alpha (PPAR-alpha) expression was transitorily increased at the beginning, and kept a relatively low level later, which accompanied by expression of PPAR-gamma coactivator (PGC)-1alpha, a master regulator of mitochondrial biogenesis. PPAR-beta expression showed robust up-regulation in the late differentiation course. Enhanced co-expressions of PPAR-beta and albumin with catalysis of UDP-glucuronosyltransferases (UGTs) were observed at mature stage. While PPAR-gamma expression changed little before and after differentiation. Mitochondriogenesis could be accelerated by PPAR-alpha specific agonist WY14643 and abolished by its antagonist GW6471 at the early stage. Neither of them affected mitochondrial DeltaPsi(m) and albumin generation in the differentiated hepatocytes. Furthermore, maturation of hepatic-like tissue and mitochondriogenesis in hepatocyte could be efficiently stimulated by PPAR-beta specific agonist L165041 and abolished by PPAR-beta specific antagonist GSK0660, but not affected by PPAR-gamma specific agonist GW1929. In conclusion, the derived hepatic tissue morphologically possessed cellular energy metabolism features. PPAR-alpha seemed only necessary for early mitochondriogenesis, while less important for DeltaPsi(m) retention in the mature tissue derived. The stimulation of PPAR-beta but not -gamma enhanced hepatogenesis, hepatocytes maturation, and mitochondriogenesis. PPAR-beta took an important role in cellular energy metabolism of hepatogenesis.

[Gene expressions of phase II enzymes in mouse embryonic stem cell-derived hepatocytes].

OBJECTIVE: To elucidate gene expressions of phase II enzymes in the mouse embryonic stem (ES) cell-derived hepatocytes. METHODS: Embryoid body (EB) formation cultures were applied in directed differentiation of ES to hepatic-like cells. The expressions of hepatic-specific genes, including AFP, ALB, Cyp7a1, were detected by RT-PCR during the differentiation course. Albumin was detected by immunocyto- chemistry. The gene expressions of mGST1 and UGTs family, including UGT1a1, UGT1a6, UGT1a9 and UGT2b5, were investigated using RT-PCR. RESULTS: A notable gene expression of AFP and ALB was observed on d 8. On d 18, AFP gene failed to express, while ALB and Cyp7a1 genes were detected.Albumin-positive staining was detected in hepatic-like cells. Phase II enzyme genes expressed in variance during the differentiation course, UGT1a1 and UGT1a9 were expressed stably, UGT1a6 expression increased gradually, and UGT2b5 failed to express. Little mGST1 gene expression could been detected in the early course until d 18. In addition, all the enzymes gene expressions in the derived hepatocytes on d 18 were similar to those from mature mouse hepatocytes. CONCLUSIONS: Mouse ES cell-derived mature hepatocytes express phase II enzyme UGTs and mGST1 genes similar to those in mature hepatocytes. The system may offer an alternative animal testing model related to phase enzymes in further research.

MAPEG expression in mouse embryonic stem cell-derived hepatic tissue system.

The expressions of membrane-associated proteins in eicosanoid and glutathione metabolism (MAPEG), a superfamily involved in both inflammation and cell protection, were investigated in an in vitro system of mouse embryonic stem (ES) cell-derived hepatic tissue. Gene expressions of all MAPEG members were demonstrated in a developmental-dependent manner in the derived hepatic tissue. The protein expression of microsomal glutathione S-transferase 1 (MGST1) was not detected until differentiating day 14. It gradually increased by maturation of hepatic tissue. The microsomes of ES cell-derived hepatic tissue possessed the MGST1-like catalytic activity. However, MGST1 from the microsome preparation could not form dimers as usual when exposed to reactive nitrogen species ONOO. Among the other members in MAPEG, weak expressions of leukotriene C(4) synthase (LTC(4)S) and microsomal prostaglandin E synthase 1 (mPGES-1) were observed. A stable expression of 5-Lipoxygenase activating protein (FLAP) appeared during the entire course of differentiation. MGST2 and MGST3 failed to express in the derived hepatic tissue, although mRNA of them do existed. In conclusion, ES cell-derived hepatic tissue possess MAPEG gene expression features, but not all protein expression could be detected, which helps to understand not only the nature of the tissue derived, but also the fate of bioartificial liver system, and may as well provide a valuable in vitro model for research in both inflammation process and toxic events in hepatological fields.