To determine the roles of FGF15 in liver regeneration, liver regrowth in FGF15 knockout (KO)mice after 2/3 partial hepatectomy (PHx) was studied. Data demonstrated that mouse genetic background greatly impacted the outcome of liver regeneration in FGF15 KO mice after PHx. FGF15 KOmice on a pure C57BL/6J
genetic background were embryonic lethal. Under 75% C57BL/6J and 25% 129SvJ genetic background, KO mice exhibited higher rates of liver learn more necrosis and death within 48 hrs following PHx compared to WT or KO mice with 25% C57BL/6J and 75% 129SvJ genetic background. Furthermore, FGF15 KO mice with 75% C57BL/6J and 25% 129SvJ genetic background showed increased bile acid and bilirubin levels and impaired expression of markers of DNA synthesis and cell cycle progression. Specifically, the cell signaling pathways critical for liver regeneration priming andmouse survival, including signal transducer and activator of transcription 3 (STAT3), nuclear factor kB (NFkB), mitogen-activated protein kinase (MAPK), protein kinase B (PKB/AKT) and mammalian
target of rapamycin (mTOR), were either interrupted or deactivated at 30 mins and/or 3 hrs following PHx. Additionally, 10 and 30 mins after PHx, there was a delayed and reduced induction of immediate-early GSK1120212 genes, including growth-control transcription factors that are critical for regenerative response in the post-hepatectomized MCE公司 liver. In summary, the results suggest that FGF15 is critical for liver regeneration after PHx, likely by maintaining bile acid homeostasis and/or being involved in the initiation of liver regeneration, and its effects are modified by genetic background. Disclosures:
The following people have nothing to disclose: Bo Kong, Jiansheng Huang, Yan Zhu, Guodong Li, Jessica A. Williams, Steven H. Shen, Lauren M. Aleksunes, Jason R. Richardson, Udayan Apte, David A. Rudnick, Grace L. Guo Purpose: The pathogenic link between gut microbiota and chronic liver disease requires elucidation. In the present study, we hypothesized that small bowel bacterial overgrowth and translocation induces changes in bile composition through reduction in hepatobiliary transporter expression, which eventually lead to liver injury. Methods: In order to study this hypothesis, a 3 cm jejunal self-filling blind loop (SFBL) was surgically created in C57BL/6 mice, 5 cm distal to the ligament of Treitz. Control mice underwent laparotomy (sham). Mice were sacrificed three weeks after surgery. Aerobic and anaerobic bacterial cultures of SFBL luminal content, peritoneal cavity, mesenteric lymph node, liver and blood were performed to evaluate bacterial overgrowth and translocation. Histology scoring was performed on H&E-stained slides by a pathologist blinded to experimental design to evaluate intestinal and liver inflammation and injury.