Project description:Nonalcoholic fatty liver disease (NAFLD) is a major health problem and a leading cause of chronic liver disease in the United States and developed countries. In humans, genetic factors greatly influence individual susceptibility to NAFLD. The goals of this study were to compare the magnitude of interindividual differences in the severity of liver injury induced by methyl-donor deficiency among individual inbred strains of mice and to investigate the underlying mechanisms associated with the variability. Feeding mice a choline- and folate-deficient diet for 12 wk caused liver injury similar to NAFLD. The magnitude of liver injury varied among the strains, with the order of sensitivity being A/J M-bM-^IM-^H C57BL/6J M-bM-^IM-^H C3H/HeJ < 129S1/SvImJ M-bM-^IM-^H CAST/EiJ < PWK/PhJ < WSB/EiJ. The interstrain variability in severity of NAFLD liver damage was associated with dysregulation of genes involved in lipid metabolism, primarily with a down-regulation of the peroxisome proliferator receptor M-NM-1 (PPARM-NM-1)-regulated lipid catabolic pathway genes. Markers of oxidative stress and oxidative stress-induced DNA damage were also elevated in the livers but were not correlated with severity of liver damage. These findings suggest that the PPARM-NM-1-regulated metabolism network is one of the key mechanisms determining interstrain susceptibility and severity of NAFLD in mice. Male A/J, C3H/HeJ and WSB/EiJ inbred mice were maintained on either control or choline- and folate-deficient (CFD) diets for 12 weeks. Gene expression profiles in the livers from control mice and mice fed a CFD-diet were investigated.

Project description:Tamoxifen is a non-steroidal anti-estrogenic drug widely used for the treatment and prevention of breast cancer in women; however, there is evidence that tamoxifen is hepatocarcinogenic in rats, but not in mice. Additionally, it has been reported that tamoxifen may cause non-alcoholic fatty liver disease (NAFLD) in humans and experimental animals. The goals of the present study were to (i) investigate the mechanisms of the resistance of mice to tamoxifen-induced hepatocarcinogenesis, and (ii) clarify effects of tamoxifen on NAFLD-associated liver injury. Feeding female WSB/EiJ mice a 420 p.p.m. tamoxifen-containing diet for 12 weeks resulted in an accumulation of tamoxifen-DNA adducts, (E)-M-NM-1-(deoxyguanosin-N2-yl)-tamoxifen (dG-TAM) and (E)-M-NM-1-(deoxyguanosin-N2-yl)-N-desmethyltamoxifen (dG-DesMeTAM), in the livers. The levels of hepatic dG-TAM and dG-DesMeTAM DNA adducts in tamoxifen-treated mice were 578 and 340 adducts/108 nucleotides, respectively, while the extent of global DNA and repetitive elements methylation and histone modifications did not differ from the values in control mice. Additionally, there was no biochemical or histopathological evidence of NAFLD-associated liver injury in mice treated with tamoxifen. A transcriptomic analysis of differentially expressed genes demonstrated that tamoxifen caused predominantly down-regulation of hepatic lipid metabolism genes accompanied by a distinct over-expression of the lipocalin 13 (Lcn13) and peroxisome proliferator receptor gamma (PparM-NM-3), which may prevent the development of NAFLD. The results of the present study demonstrate that the resistance of mice to tamoxifen-induced liver carcinogenesis may be associated with its ability to induce genotoxic alterations only without affecting the cellular epigenome and an inability of tamoxifen to induce the development of NAFLD. Female and male WSB/EiJ mice were fed diet containing 420 p.p.m. tamoxifen for 12 weeks, and then tamoxifen-DNA adduct formation and gene expression profiles in the livers from four control and four tamoxifen-treated mice were investigated.

Project description:We demonstrate that conjugated linoleic acid (CLA), when given to mice as a dietary supplement, induced an enlarged liver and hepatic steatosis. The progression of NAFLD and insulin resistance was reversed by GW6471 a small-molecule antagonist of PPARα. Transcriptional profiling of livers unraveled that genes involved in lipid metabolism core gene programs controlled by PPARα in response to CLA and GW6471.Our findings reveal a novel role of PPARα in the regulation of lipid homeostasis and highlight its druggable nature in NAFLD.

Project description:Nuclear receptors (NRs) play a crucial role in non-alcoholic fatty liver disease (NAFLD) and have been widely studied(Tran et al. 2018). However, the underlying mechanisms of NR regulation remain largely unclear. Here, we show that miR-20b plays a key role in modulating PPARα, a master regulator of nutrient metabolism and energy homeostasis in the pathogenesis of fatty liver(Wahli et al. 1995; Dongiovanni and Valenti 2013). Using network analysis and RNA-seq to determine the correlation between NRs and microRNA in NAFLD patients, we revealed that miR-20b directly targets PPARα. The expression of miR-20b was remarkably upregulated in free fatty acid (FA)-treated hepatocytes and the livers of both obesity-induced mice and NAFLD patients. Overexpression of miR-20b dramatically increased hepatic lipid accumulation and plasma triglyceride levels. Furthermore, miR-20b significantly reduced fatty acid oxidation and mitochondrial biogenesis by directly targeting PPARα. Fenofibrate, a specific agonist of PPARα, lost its ability to ameliorate hepatic steatosis in miR-20b-introduced mice. Finally, inhibition of miR-20b dramatically increased FA oxidation and uptake, resulting in improved insulin sensitivity and a decrease in NAFLD progression. Taken together, these results demonstrate that the novel miR-20b directly targets PPARα, plays a significant role in hepatic lipid metabolism, and presents an opportunity for the development of novel therapeutics for NAFLD.

Project description:Nonalcoholic fatty liver disease (NAFLD) is associated with an increased risk of cardiovascular disease (CVD). Liver is the major source of the circulatory proteins and alterations in plasma proteome have been implicated in atherosclerosis. We used a recently developed 2H2O-metabolic labeling method in combination with the label-free quantification to evaluate the effect of a Western diet (WD) on the dynamics of plasma proteins in LDL receptor-deficient (LDLR-/-) mice, a model of NAFLD and atherosclerosis. There were no significant changes in the expression level of total proteins due to the WD with a bulk protein mean half-life of 18.0±15.1 hours in control and 16.7±11.1 hours in WD groups. WD led to pro-inflammatory distribution of circulatory proteins analyzed in apoB-depleted plasma attributed to their increased production. The fractional catabolic rates of fast-turnover proteins with stress-response, lipid metabolism and transport functions were significantly increased with WD (P<0.05). The pathway analyses revealed that alterations in plasma proteome dynamics were related to the suppression of hepatic PPARα, which was confirmed based on reduced gene and protein expression of PPARα on WD. These changes were associated with ~4 fold increase (P<0.0001) in pro-inflammatory property of apoB-depleted plasma. In conclusion, the proteome dynamics method reveals pro-inflammatory remodeling of plasma proteome relevant to liver disease. As in vivo metrics of liver function, this approach can be used to test therapies in NAFLD and other diseases

Project description:Nonalcoholic fatty liver disease (NAFLD) is one of the most common chronic diseases globally and nonalcoholic steatohepatitis is its progressive stage with limited therapeutic options. Here a role for intestinal peroxisome proliferator-activated receptor α (PPARα)-fatty acid binding protein 1 (FABP1) in obesity-associated metabolic syndrome, fatty liver and nonalcoholic steatohepatitis via modulating dietary fat absorption was uncovered. Intestinal PPARα is highly activated accompanied by marked upregulation of FABP1 by high-fat diet (HFD) in mice and obese humans. Intestine-specific PPARα or FABP1 disruption in mice decreases HFD-induced obesity, fatty liver and nonalcoholic steatohepatitis and intestinal PPARα disruption fails to further decrease obesity and NASH. Chemical PPARα antagonism improves metabolic disorders depending on the presence of intestinal PPARα or FABP1. Translationally, GW6471 decreases human PPARα-driven intestinal fatty acid uptake and therapeutically improves obesity in PPARA-humanized, but not Ppara-null, mice. These results suggest that intestinal PPARα-FABP1 axis could be a therapeutic target for NASH.

Project description:Tamoxifen is a non-steroidal anti-estrogenic drug widely used for the treatment and prevention of breast cancer in women; however, there is evidence that tamoxifen is hepatocarcinogenic in rats, but not in mice. Additionally, it has been reported that tamoxifen may cause non-alcoholic fatty liver disease (NAFLD) in humans and experimental animals. The goals of the present study were to (i) investigate the mechanisms of the resistance of mice to tamoxifen-induced hepatocarcinogenesis, and (ii) clarify effects of tamoxifen on NAFLD-associated liver injury. Feeding female WSB/EiJ mice a 420 p.p.m. tamoxifen-containing diet for 12 weeks resulted in an accumulation of tamoxifen-DNA adducts, (E)-α-(deoxyguanosin-N2-yl)-tamoxifen (dG-TAM) and (E)-α-(deoxyguanosin-N2-yl)-N-desmethyltamoxifen (dG-DesMeTAM), in the livers. The levels of hepatic dG-TAM and dG-DesMeTAM DNA adducts in tamoxifen-treated mice were 578 and 340 adducts/108 nucleotides, respectively, while the extent of global DNA and repetitive elements methylation and histone modifications did not differ from the values in control mice. Additionally, there was no biochemical or histopathological evidence of NAFLD-associated liver injury in mice treated with tamoxifen. A transcriptomic analysis of differentially expressed genes demonstrated that tamoxifen caused predominantly down-regulation of hepatic lipid metabolism genes accompanied by a distinct over-expression of the lipocalin 13 (Lcn13) and peroxisome proliferator receptor gamma (Pparγ), which may prevent the development of NAFLD. The results of the present study demonstrate that the resistance of mice to tamoxifen-induced liver carcinogenesis may be associated with its ability to induce genotoxic alterations only without affecting the cellular epigenome and an inability of tamoxifen to induce the development of NAFLD.

Project description:Hepatosteatosis, defined as excessive intrahepatic lipid accumulation, represents the first step in the development of NAFLD. However, the molecular events directly caused by hepatic lipid build-up, in terms of its impact on liver biology and other peripheral organs, remain unclear. Carnitine palmitoyltransferase 1A (CPT1A) is the rate limiting enzyme for long chain fatty acid beta-oxidation in the liver. Here we utilise hepatocyte-specific Cpt1a knockout (LKO) mice to investigate the physiological consequences of abolishing hepatic long chain fatty acid metabolism to NAFLD and systemic metabolic homeostasis. We show that LKO mice displayed more severe hepatosteatosis but were otherwise protected against diet-induced weight gain, insulin resistance, hepatic ER stress and damage in response to high fat diets. Furthermore, increased energy expenditure accompanied by enhanced adipose tissue browning was observed in LKO mice. Mechanistically, hepatic CPT1A deficiency actives the peroxisome proliferator activator alpha (PPARα)- fibroblast growth factor 21 (FGF21) axis and the elevation of FGF21 contributes to the improved liver pathology and adipose browning in HFD-treated LKO mice. Thus, our study demonstrates that liver with deficient CPT1A expression adopts a healthy steatotic status that protects against HFD-evoked liver damage and potentiates adipose browning in an FGF21-dependent manner. Inhibition of hepatic CPT1A may serve as a viable strategy for the treatment of obesity and NAFLD.

Project description:Chronic liver diseases are worldwide on the rise. Due to the rapidly increasing incidence, in particular in Western countries, non-alcoholic fatty liver disease (NAFLD) is gaining importance. As the disease progresses it can develop into hepatocellular carcinoma. Lipid accumulation in hepatocytes has been identified as the characteristic structural change in NAFLD development, but the molecular mechanisms responsible for disease development remained unresolved. Here, we uncover a strong downregulation of the PI3K-AKT pathway and an upregulation of the MAPK pathway in primary hepatocytes from a preclinical model fed with a Western diet (WD). Dynamic pathway modeling of hepatocyte growth factor (HGF) signal transduction combined with global proteomics identifies that an elevated basal MET phosphorylation rate is the main driver of altered signaling leading to increased proliferation of WD-hepatocytes. Model-adaptation to patient-derived hepatocytes reveals a patient-specific variability in basal MET phosphorylation, which correlates with the outcome of patients after liver surgery. Thus, dysregulated basal MET phosphorylation could be an indicator for the health status of the liver and thereby inform on the risk of a patient to suffer from liver failure after surgery.

Project description:Perfluoroalkyl substances (PFAS) are man-made chemicals with suspected endocrine-disrupting properties. Exposure to perfluorooctanoic acid (PFOA) has been linked to disturbed metabolism via the liver, although the exact mechanism is not clear. Moreover, information on the metabolic effects of the new PFAS alternative GenX is limited. We tested whether low-dose exposure to PFOA and GenX induces metabolic disturbances, including NAFLD, dyslipidemia, and glucose tolerance in mice and studied the involvement of PPARα. To this end, male C57BL/6J wildtype and PPARα−/− mice were given 0.05 or 0.3 mg/kg bw/day PFOA, or 0.3 mg/kg bw/day GenX next to a high-fat diet for 20 weeks. RNA sequencing was performed on liver, next to thorough assesment of metabolic parameters. RNA sequencing revealed that whereas the effects of GenX are entirely dependent on PPARα, effects of PFOA are mostly dependent on PPARα. In the absence of PPARα, the involvement of PXR/CAR becomes more prominent. Exposure to high-dose PFOA in mice decreased body weights and increased liver weights in wildtype and PPARα−/− mice. High-dose but not low-dose PFOA reduced plasma triglycerides and cholesterol, which for triglycerides, showed PPARα dependency. PFOA and GenX increased hepatic triglycerides in a PPARα-dependent manner. Overall, we show that long-term and low-dose exposure to PFOA and GenX disrupts lipid metabolism in mice. Whereas the effects of PFOA are mediated by multiple nuclear receptors, effects of GenX are entirely mediated by PPARα. Our data underscore the potential of PFAS to disrupt metabolism by altering signaling pathways in the liver.