Project description:Bile acid (BA) homeostasis is maintained through a feedback loop operated by the nuclear hormone receptors FXR and SHP. Here we show that contrary to the current models placing FXR upstream of SHP in a linear regulatory pathway, the phenotypic consequence of the combined loss of both receptors is much more severe than the relatively modest impact of the loss of either Fxr or Shp alone. This is highlighted by the dramatic elevation of hepatic and serum BA levels in the double knockout (DKO) mice as early as three weeks of age coupled with a commensurate increase in Cyp7A1 expression and alterations in BA homeostatic genes. In addition, we find several genes necessary for C21 steroid biosynthetic pathway as novel targets for FXR and SHP. The elevated BAs result in severe hepato-pathology but the DKO mice surprisingly do not develop complete liver failure and live for over a year. Their survival is accompanied by an adaptive proliferation of the resident liver progenitor cell population, known as oval cells. Overall, these data demonstrate that FXR and SHP function coordinately to maintain BA homeostasis, and identify DKO mice as a novel genetic model for juvenile cholestatic disorders and for oval cell activation.

Project description:The small heterodimer partner (SHP) regulates fatty acid oxidation and lipogenesis in the liver by regulating peroxisome proliferator-activated receptor (PPAR) γ expression. SHP is also abundantly expressed in the myocardium. Therefore, we investigated the myocardial gene expression in a SHP deletion animal model.

Project description:We performed high-throughput RNA-sequencing on livers from hepatocyte specific Fxr-/- Shp-/- double knockout mice, and identified upregulation of N-glycan protein modification machinery. This correlated positively with Golgi structural defects and alterations in the hepatic secretome. This study identifies a new role for hepatic FXR-SHP axis in Golgi dynamics and N-glycosylation, apart from its traditional function in nutrient metabolism.

Project description:Background: Fibroblast growth factor-19 (FGF19) is an intestinal hormone that mediates postprandial metabolic responses in the liver. The unusual orphan nuclear receptor, Small Heterodimer Partner (SHP), acts as a co-repressor for many transcriptional factors and has been implicated in diverse biological pathways including FGF19-mediated repression of bile acid synthesis. To explore global functions of SHP in mediating FGF19 action, we identify genome-wide SHP binding sites in hepatic chromatin in mice treated with vehicle or FGF19 by ChIP-seq analysis. Results: The overall pattern of SHP binding sites between these two groups is similar, but SHP binding is enhanced at the sites by addition of FGF19. SHP binding is detected preferentially in promoter regions that are enriched in motifs for unexpected non-nuclear receptors. We observe global co-localization of SHP sites with published sites for SREBP-2, a master transcriptional activator of cholesterol biosynthesis. FGF19 increases functional interaction between endogenous SHP and SREBP-2 and inhibits SREBP-2 target genes, and these effects were blunted in SHP-knockout mice. Furthermore, FGF19-induced phosphorylation of SHP at Thr-55 is shown to be important for its functional interaction with SREBP-2 and reduction of liver/serum cholesterol levels. Conclusion: This study reveals SHP as a global transcriptional partner of SREBP-2 in regulation of sterol biosynthetic gene networks and provides a potential mechanism for cholesterol-lowering action of FGF19. Genome-wide SHP binding profiles in hepatic chromatin in mice under treatment of FGF19 or vehicle were generated using high throughput sequencing followed by chromatin immunoprecipitation.

Project description:To clarify the effect of SHP in LXRs-mediated signaling pathway, we performed global gene expression analysis of SHP siRNA transfected- or control siRNA transfected- astrocytes after IFN-γ and LXRs agonist. Microarray analysis revealed that expression of several genes encoding inflammatory mediators were reversed in SHP siRNA transfected-astrocytes, when compared with control siRNA transfected-astrocytes. Primary astrocytes were cultured from the cerebral cortices of 1 day-old Sprague-Dawley rats. The astrocytes were transfected with control siRNA or SHP siRNA and treated with IFN-γ in the presence or absence of GW for 3 h.

Project description:Farnesoid-X-Receptor (FXR) plays a central role in maintaining bile acid (BA) homeostasis by transcriptional control of numerous enterohepatic genes, including intestinal FGF19, a hormone that strongly represses hepatic BA synthesis. How activation of the FGF19 receptor at the membrane is transmitted to the nucleus for transcriptional regulation of BA levels and whether FGF19 signaling posttranslationally modulates function of FXR remain largely unknown. Here we show that FXR is phosphorylated at Y67 by non-receptor tyrosine kinase, Src, in response to postprandial FGF19, which is critical for its nuclear localization and transcriptional regulation of BA levels. Liver-specific expression of phospho-defective Y67F-FXR or Src-downregulation in mice result in impaired homeostatic responses to acute BA feeding, and exacerbate cholestatic pathologies upon drug-induced hepatobiliary insults. Also, the hepatic FGF19-Src-FXR pathway is defective in primary biliary cirrhosis patients. This study identifies Src-mediated FXR phosphorylation as a potential therapeutic target and biomarker for BA-related enterohepatic diseases.

Project description:To understand the influence of phosphorylation on the protein-protein interactions, we performed an AP-MS of SHP-1(FLAG) in HEK293T/17 cells co-transfected with TAOK3 and/or SRC kinase. Whilst TAOK3 phosphorylates Thr-394, SRC phosphorylates Tyr536 and Tyr564.

Project description:X-box binding protein 1 (XBP1) is a key component of the unfolded protein response that is activated in response to ER stress. Farnesoid X receptor (FXR) null (Fxr-/-) mice have elevated bile acid levels and progressive liver injury. Hepatic XBP1 pathway is activated in older Fxr-/- mice. This project is to investigate the role of liver XBP1 in Fxr-/- mice.

Project description:Cirrhosis is a late stage of fibrosis impairing liver function. Genetic animal models for cirrhosis are lacking, and molecular mechanisms remain unknown. We report the first murine genetic model recapitulating human cirrhosis induced by hepatocyte-specific elimination of MCRS1, a member of NSL and INO80 chromatin-modifier complexes. MCRS1 loss in hepatocytes modulates the expression of bile acid (BA) transporters, with a pronounced NTCP downregulation, concentrating BAs in liver sinusoids, thereby activating hepatic stellate cell (HSC) via FXR. Consistently, genetic FXR ablation in HSCs suppresses fibrotic marks in mice and in vitro cell culture. Mechanistically, deletion of a putative SANT domain from MCRS1 evicts HDAC1 from its H3 anchoring sites, increasing histone acetylation of BA transporter genes, modulating their expression and perturbing BA flow. Accordingly, human cirrhosis displays loss of nuclear MCRS1 and decreased NTCP expression. Thus, histone acetylation-mediated dysregulation of BA transporters, and consequently FXR activation by BAs in HSCs represent a central and universal signaling event in cirrhosis. The data is from single-nuclei RNA-seq of whole-liver collected during autopsy of 4 individuals with COVID-19 and PMI < 4.5 hours

Project description:Farnesoid X receptor (FXR) is a ligand activated nuclear receptor belonging to the nuclear receptor superfamily. Bile acids (BAs) are the endogenous ligand for FXR. FXR is a master regulator of BA homestasis, including BA synthesis, metabolism, transport, and enterohepatic circulation of BAs. Besides, FXR is involved in regulating diverse physioligical function in both humans and mice. GW4064 is a synthetic FXR agonist which selectively activates FXR and induce the transcription of FXR target genes. In this study, we treated wild type C57BL/6J mice with GW4064 at 100mg per kg body weight or vehicle control. Mice were treated three times, first dose at 8 am, second dose at 6 pm, third dose at 8 am the second day. Mice were sacrificed 2 hours after the last dose, and liver tissues were harvested for analysis. Animal protocols and procedures were approved by the Institutional Animal Care and Use Committee (IACUC) at the University of Kansas Medical Center. Total RNA from livers was prepared with TRIzol Reagent (Invitrogen, CA), and the whole transcription expression levels were determined using Mouse Gene 1.0 ST Array system manufactured by Affymetrix, Inc..