Project description:SHP (small heterodimer partner; NR0B2) belongs to the nuclear hormone receptor superfamily, which regulates numerous developmental and metabolic cellular functions. To study physiological function of SHP, we generated congenic SHP-/- mice on C57Bl/6 background. When the congenic SHP-/- mice were challenged with a western diet (harlan, TD.88137) for 22 weeks, they were resistant to diet induced obesity and hepatic steatosis compared to WT controls. However, their hepatic insulin sensitivity was compromised when assessed with phospho-Akt levels after insulin injection. Therefore, we investigated hepatic gene expression using illumina beadchip array to explore mechanisms underneath the unique liver physiology in SHP-/- mice. Livers were collected from C57Bl/6 wild type and C57Bl/6 SHP-/- mice fed chow or western diet. The 1 microgram of total RNA obtained from individual mouse (n=4 per group) and subjected to illumina beadchip gene expression profiling.

Project description:Bile acids are not only physiological detergents facilitating nutrient absorption, but also signaling molecules regulating metabolic homeostasis. We reported recently that transgenic expression of CYP7A1 in mice stimulated bile acid synthesis and prevented Western diet-induced obesity, insulin resistance and hepatic steatosis. The aim of this experiment is to determine the impact of induction of hepatic bile acid synthesis on liver metabolism by determining hepatic gene expression profile in CYP7A1 transgenic mice. CYP7A1 transgenic mice and wild type control mice were fed either standard chow diet or high fat high cholesterol Western diet for 4 month. Hepatic gene expressions were measured by microarray analysis. Our results indicate that hepatic bile acid synthesis is closely linked to cholesterogenesis and lipogenesis, and maintaining bile acid homeostasis is improtant in hepatic metabolic homeostasis. Male aged matched (~ 12-14 weeks) CYP7A1 transgenic mice and their wild type control littermates were fed a standard chow diet or a high fat (42%) high cholesterol (0.2%) diet (Harlan Teklad #88137) for 4 month Four groups (4 mice/group) are included in the experiments: Group 1: WT _ Chow Group 2: CYP7A1-tg + chow Group 3: WT + Western diet Group 4: CYP7A1-tg _ Western diet Total liver mRNA was isolated with a RNeasy kit (Qiagen) and used for microarray analysis.

Project description:SHP (small heterodimer partner; NR0B2) belongs to the nuclear hormone receptor superfamily, which regulates numerous developmental and metabolic cellular functions. To study physiological function of SHP, we generated congenic SHP-/- mice on C57Bl/6 background. When the congenic SHP-/- mice were challenged with a western diet (harlan, TD.88137) for 22 weeks, they were resistant to diet induced obesity and hepatic steatosis compared to WT controls. However, their hepatic insulin sensitivity was compromised when assessed with phospho-Akt levels after insulin injection. Therefore, we investigated hepatic gene expression using illumina beadchip array to explore mechanisms underneath the unique liver physiology in SHP-/- mice.

Project description:To investigate the role of Per2 in glucose metabolism in-vivo we used mice bearing a targeted gene mutation in the Per2 gene (Per2brdm) and thus unable to express a functional Per2 protein. Mice were hosted in our standard mouse facility in a 12-hour light and 12-hour dark cycle. Wt and Per2brdm mice were fed with either standard chow diet or high-fat diet for 24 weeks and analyzed for glucose homeostasis. Glucose tolerance test (GTT) and insulin tolerance test (ITT) were performed on mice food deprived for 7 hours. For pyruvate tolerance test (PTT) mice were fasted for 14 hours. Glucose levels were measured over 12 hours starvation time-courses during the light and the dark phase. Fed and fasting blood glucose and hepatic glycogen content were measured over different circadian time-points. To investigate the role of Per2 in the control of liver gene expression we performed DNA-microarray analysis of RNA preparations from liver of Per2brdm and WT mice.

Project description:Skeletal muscle insulin resistance is a prominent early feature in the pathogenesis of type 2 diabetes (T2D). In attempt to overcome this defect, we generated mice overexpressing insulin receptors (IR) specifically in skeletal muscle (IRMOE). On normal chow, IRMOE mice have similar body weight as controls, but an increase in lean mass and glycolytic muscle fibers and reduced fat mass. IRMOE mice also show higher basal phosphorylation of IR, IRS-1 and Akt in muscle and improved glucose tolerance compared to controls. When challenged with high fat diet (HFD), IRMOE mice are protected from diet-induced obesity. This is associated with reduced inflammation in fat and liver, improved glucose tolerance and improved systemic insulin sensitivity. Surprisingly, however, in both chow and HFD-fed mice, insulin stimulated Akt phosphorylation is significantly reduced in muscle of IRMOE mice, indicating post-receptor insulin resistance. RNA sequencing reveals downregulation of several post-receptor signaling proteins that contribute to this resistance. Thus, enhancing early insulin signaling in muscle by overexpression of the insulin receptor protects mice from diet-induced obesity and its effects on glucose metabolism. However, chronic overstimulation of this pathway leads to post-receptor desensitization, indicating the critical balance between normal signaling and hyperstimulation of the insulin signaling pathway.

Project description:Individuals with hepatic steatosis often display several metabolic abnormalities including insulin resistance and muscle atrophy. Previously, we found that hepatic steatosis results in an altered hepatokine secretion profile, thereby inducing skeletal muscle insulin resistance via inter-organ crosstalk. In this study, we aimed to investigate whether the altered secretion profile in the state of hepatic steatosis also induces skeletal muscle atrophy via effects on muscle protein turnover. To investigate this, eight-week-old male C57BL/6J mice were fed a chow (4.5% fat) or a high-fat diet (HFD; 45% fat) for 12 weeks to induce hepatic steatosis, after which the livers were excised and cut into ~200 µm slices. Slices were cultured to collect secretion products (conditioned medium; CM). Differentiated L6-GLUT4myc myotubes were incubated with chow or HFD CM to measure glucose uptake. Differentiated C2C12 myotubes were incubated with chow or HFD CM to measure protein synthesis and breakdown, and gene expression via RNA sequencing. Furthermore, proteomics analysis was performed in chow and HFD CM. It was found that HFD CM caused insulin resistance in L6-GLUT4myc myotubes compared with chow CM, as indicated by a blunted insulin-stimulated increase in glucose uptake. Furthermore, protein breakdown was increased in C2C12 cells incubated with HFD CM, while there was no effect on protein synthesis. RNA profiling of C2C12 cells indicated that 197 genes were differentially expressed after incubation with HFD CM, compared with chow CM, and pathway analysis showed that pathways related to anatomical structure and function were enriched. Proteomic analysis of the CM showed that 32 proteins were differentially expressed in HFD CM compared with chow CM. Pathway enrichment analysis indicated that these proteins had important functions with respect to insulin-like Growth Factor transport and uptake, and affect post-translational processes, including protein folding, protein secretion and protein phosphorylation. In conclusion, the results of this study support the hypothesis that secretion products from the liver contribute to the development of muscle atrophy in individuals with hepatic steatosis.

Project description:To investigate the role of Per2 in glucose metabolism in-vivo we used mice bearing a targeted gene mutation in the Per2 gene (Per2brdm) and thus unable to express a functional Per2 protein. Mice were hosted in our standard mouse facility in a 12-hour light and 12-hour dark cycle. Wt and Per2brdm mice were fed with either standard chow diet or high-fat diet for 24 weeks and analyzed for glucose homeostasis. Glucose tolerance test (GTT) and insulin tolerance test (ITT) were performed on mice food deprived for 7 hours. For pyruvate tolerance test (PTT) mice were fasted for 14 hours. Glucose levels were measured over 12 hours starvation time-courses during the light and the dark phase. Fed and fasting blood glucose and hepatic glycogen content were measured over different circadian time-points. To investigate the role of Per2 in the control of liver gene expression we performed DNA-microarray analysis of RNA preparations from liver of Per2brdm and WT mice. We extracted total RNA from liver of four different Per2brdm and WT mice. Mice from the same cohort were sacrificed after 8 hours of starvation. After normalization we performed a fold change comparison selecting probes with a p value < 0.05.

Project description:We profiled the transcriptomes of chow diet-fed and high-fat diet-fed mice across insulin stimulation time points. We also profiled the effects of metformin treatment on mouse liver transcritomes. Our temporal analyses of chow-diet and 16 week high-fat diet transcriptomics following insulin stimulation uncovered several regulator of G-protein signaling genes, particularly Rgs4, that are specifically regulated transcriptionally in HFD livers following insulin stimulation. We validated these findings with additional assays of RGS4 mRNA and protein levels and characterized this molecule's role in regulating hepatic insulin responses in mice.

Project description:Non-alcoholic fatty liver disease (NAFLD) is a chronic disease caused by hepatic steatosis. Adenosine deaminases acting on RNA (ADARs) catalyze adenosine to inosine RNA editing. However, the functional role of ADAR2 in NAFLD is unclear. ADAR2+/+/GluR-BR/R mice (wild type, WT) and ADAR2−/−/GluR-BR/R mice (ADAR2 KO) mice were fed with standard chow or high-fat diet (HFD) for 12 weeks. ADAR2 KO mice exhibited protection against HFD–induced glucose intolerance, insulin resistance, and dyslipidemia. Moreover, ADAR2 KO mice displayed reduced liver lipid droplets in concert with decreased hepatic TG content, improved hepatic insulin signaling, better pyruvate tolerance, and increased glycogen synthesis. Mechanistically, ADAR2 KO effectively mitigated excessive lipid production via AMPK/Sirt1 pathway. ADAR2 KO inhibited hepatic gluconeogenesis via the AMPK/CREB pathway and promoted glycogen synthesis by activating the AMPK/GSK3β pathway. These results provided novel evidence that ADAR2 KO protected against NAFLD progression through activation of AMPK signaling pathways.

Project description:Among vertebrate animals, mammals have retained a unique molecular change that allows an intracellular arrestin domain-containing protein to bind covalently to thioredoxin. This interaction of Thioredoxin-Interacting Protein (TXNIP) with thioredoxin can only occur when thioredoxin is in the reduced state, allowing TXNIP to "sense" the cellular oxidized environment1. Here we show that a single cysteine in TXNIP mediates the development of hepatic insulin resistance in the setting of a high fat diet (HFD). Mice with exchange of TXNIP Cysteine 247 for Serine (C247S) showed improved whole-body and hepatic insulin sensitivities compared to wildtype (WT) controls following an 8-week HFD. The inhibition of the TXNIP-thioredoxin interaction under chow and HFD also regulated plasma and liver lipids and reduced free fatty acid accumulation in the livers following HFD. We also show molecularly that in HFD-fed TXNIP C247S mice livers, Toll-like Receptor 4 (TLR4)-mediated Nuclear factor kappa B (NFkB) activation and TLR4-mediating WD repeat and FYVE domain containing 1 (wdfy1) mRNA expressions were decreased, as well as PKC activity as a potential molecular mechanism to improve insulin/Akt signaling. These data show that mammals have a single amino acid enabling interaction of redox state with TXNIP that mediates insulin resistance in the setting of a high-fat diet. This reveals a potential evolutionarily-conserved mechanism for hepatic insulin resistance in metabolic syndromes.