Project description:To elucidate the molecular mechanisms behind corneal angiogenesis in Dscr-1-/- mice, we performed microarray analysis using intact corneas from B6, Dscr-1-/- mice, ApoE-/- mice, Dscr-1-/- and ApoE-/- double null mutant mice and sutured corneas from B6, Dscr-1-/- and Dscr-1 Tg mouse.

Project description:Apolipoprotein E-knock out (apoE-KO) mouse is known as a model animal for atherosclerosis accompanied by spontaneous hypercholesterolemia. When apoE-KO mice were fed a chow supplemented with 1.25% cholesterol (high-Chol diet), cholesterol and bile acids were highly increased in the liver within a week. However, the amount of triacylglycerol (TG) in very low-density lipoprotein (VLDL), but not in the liver, was reduced by 78%. The epididymal adipose tissue was almost diminished in the long term. Cholesterol metabolism is tightly regulated by both cholesterol and its metabolites in the mammalian liver, but the regulatory mechanism of TG synthesis remains to be elucidated. To evaluate the impact of high-Chol diet for 1 week on gene expression in the liver of apoE-KO mice, DNA microarray analysis was performed with comparison to apoE-KO mice fed a normal chow. We found that mRNA expression related to lipid metabolism was suppressed by the high-Chol diet in the liver of apoE-KO mice, which includes beta-oxidation and glycerol-3-phosphate (G3P) pathway for TG synthesis. In particular, the mRNA and protein expression of lipin-1 and lipin-2 was markedly decreased. PGC-1?, which up-regulates the transcription of lipin-1, was also suppressed. Lipin is reported to function as a coactivator of PGC-1? and is an inducible amplifier of PPAR?, indicating that the suppression of genes involved in beta-oxidation could be induced by suppression of the lipins. These data using apoE-KO mice indicate that cholesterol and its metabolites are involved in regulating TG metabolism through a suppression of lipin-1 and lipin-2 in the liver. This research provides evidence for the mechanism of lipin expression in the liver. Apo E-KO mice at 10 weeks of age were fed normal chow (control) or high-Chol diet containing 1.25% cholesterol for 1 week. Three independent experiments were performed at each diet.

Project description:Loss of Down syndrome critical region-1 leads to cholesterol metabolic dysfunction that exaggerates hypercholesterolemia in ApoE-null background

Project description:Apolipoprotein E-knock out (apoE-KO) mouse is known as a model animal for atherosclerosis accompanied by spontaneous hypercholesterolemia. When apoE-KO mice were fed a chow supplemented with 1.25% cholesterol (high-Chol diet), cholesterol and bile acids were highly increased in the liver within a week. However, the amount of triacylglycerol (TG) in very low-density lipoprotein (VLDL), but not in the liver, was reduced by 78%. The epididymal adipose tissue was almost diminished in the long term. Cholesterol metabolism is tightly regulated by both cholesterol and its metabolites in the mammalian liver, but the regulatory mechanism of TG synthesis remains to be elucidated. To evaluate the impact of high-Chol diet for 1 week on gene expression in the liver of apoE-KO mice, DNA microarray analysis was performed with comparison to apoE-KO mice fed a normal chow. We found that mRNA expression related to lipid metabolism was suppressed by the high-Chol diet in the liver of apoE-KO mice, which includes beta-oxidation and glycerol-3-phosphate (G3P) pathway for TG synthesis. In particular, the mRNA and protein expression of lipin-1 and lipin-2 was markedly decreased. PGC-1α, which up-regulates the transcription of lipin-1, was also suppressed. Lipin is reported to function as a coactivator of PGC-1α and is an inducible amplifier of PPARα, indicating that the suppression of genes involved in beta-oxidation could be induced by suppression of the lipins. These data using apoE-KO mice indicate that cholesterol and its metabolites are involved in regulating TG metabolism through a suppression of lipin-1 and lipin-2 in the liver. This research provides evidence for the mechanism of lipin expression in the liver.

Project description:Purpose: HIF1a inhibitor PX-478 prevents hypercholesterolemia in ApoE-/- mice fed Western diet for 3 months. The goal of this study was to determine the mechanisms in the liver through which PX-478 regulates cholesterol. Methods: 4-week old ApoE-/- mice were fed a Western diet and injected intraperitoneally, bi-weekly with either PX-478 (40 mg/kg) or Saline for 3 months. The livers of 3 PX-478-treated mice and 4 Saline-treated mice were used for this RNA-seq study. Results: We identified 800+ differentially expressed genes in the PX-478-treated ApoE-/- mice livers relative to the saline-treated control livers. A subset of these genes were found to play important roles in cholesterol regulation and were further validated by qPCR analysis. Conclusions: Our study details potential hepatic cholesterol regulating mechanisms for HIF1a inhibitor PX-478. These results, coupled with our findings on the effect of PX-478 on two different mouse models of atherosclerosis, demonstrate that PX-478 is a potential anti-atherogenic and anti-hypercholesterolemic drug.

Project description:Strain differences influence susceptibility to atherosclerosis. Apolipoprotein E-null mice on a DBA/2J genetic background (DBA-apoE) and C57BL/6 (B6-apoe) are highly susceptible to atherosclerosis in the aortic root area compared with those on a 129S6/SvEvTac background (129-apoE). To explore strain-specific differences affecting the susceptibility to atherosclerosis, we performed microarray analysis of aortic arch and root from wild type mice of each strains.

Project description:Aortic arch profiling of Apoe-/- mice fed a high fat diet (HFD, Harlan Teklad 88137, 21% fat, 0.15% cholesterol) starting at 8 weeks of age for 8, 16, and 24 weeks. B6 mice fed HFD for 16 weeks starting at 8 weeks of age were used as controls. Apoe-/- mice were fed a high fat diet (HFD, Harlan Teklad 88137, 21% fat, 0.15% cholesterol) starting at 8 weeks of age for 8, 16, and 24 weeks. B6 mice fed HFD for 16 weeks starting at 8 weeks of age were used as controls. At each time point, 9 mice were studied. Mice were euthanized at each time point and whole aorta (from aortic root to renal bifurcation) of each mouse was immediately collected and flash-frozen in liquid N2. Mice were fasted overnight prior to euthanasia. the aortic arches of three mice in the same study group were pooled, resulting in three pools per study group.

Project description:Objective: Although relationships between smoking and cardiovascular diseases (CVD), and CVD and lipids are established, direct impact of cigarette smoke (CS) on lipidomes remains elusive. We investigated the effect of 6 month smoke exposure on a well-established mouse model for human atherogenesis, Apoe mouse plasma, liver, and aorta molecular lipid profiles and liver transcriptome. // Methods: Plasma, liver, and aorta samples from Apoe mice exposed to CS or fresh air for 6 months were extracted for lipids using robotic-assisted method and analyzed by mass spectrometry. Gene expression of samples from the same livers was obtained on microarrays. Development of atherosclerosis in aorta was further assessed by plaque size measurement in the aortic arch and lipoprotein measurements in plasma and in the plaque. // Results: CS increased most lipid classes and molecular lipid species in tissues evaluated. In plasma, free cholesterol, ceramides, cerebrosides, and majority of phospholipids were increased in CS-exposed mice. In liver, CS elevated several lipid species including free and esterified cholesterol, triacylglycerols, phospholipids, sphingomyelins, and ceramides. In aorta, more than 2-fold higher cholesteryl ester (CE), lysophosphatidylcholine, and glucosyl/galactosylceramide levels were recorded in mice exposed to CS compared to mice exposed to fresh air. Moreover, CS exposure induced a significant decrease in several plasma CE and phosphatidylcholine species that contained polyunsaturated fatty acids. Genes involved in amino acid and lipid metabolism showed perturbed transcription profiles in liver. // Conclusion: These data reveal molecular details accompanying the increase in plaque size, sign of atherogenesis in Apoe mice, which is accelerated by CS exposure.

Project description:The goal of this study is to determine whether A1 adenosine receptor (ADORA1) plays a role in atherosclerosis development and its possible mechanisms. This dataset compares gene expression (aortas) of ADORA1 knockout mice to ADORA1+APOE double-knockout mice. Mice deficient in both ADORA1 and APOE (DKO) demonstrated reduced atherosclerotic lesions in aortic arch (en face), aortic root, and innominate arteries when compared to (APOE-KO) of the same age. Treating APOE-KO with the ADORA1 antagonist DPCPX also achieved concentration-dependent reduction in lesions. The total plasma cholesterol and triglyceride levels were not different between DKO and APOE-KO, however, higher triglyceride was observed in DKO fed a high-fat diet. DKO also were heavier than APOE-KO. Plasma cytokine levels (IL-5, IL-6, and IL-13) were significantly lower in DKO. Proliferating cell nuclear antigen (PCNA) expression was also significantly reduced in the aorta from DKO. Despite smaller lesions in DKO, the composition of the innominate artery lesions and cholesterol loading and effusion [export] from bone-marrow-derived macrophages from DKO were not different from APOE-KO.

Project description:The most common genetic risk factor for late onset Alzheimer Disease (AD) is the APOE4 allele, with evidence for gain- and loss-of-function as a primary mechanism. ApoE knockout in mice abrogates AD phenotypes but causes severe atherosclerosis due to the role of liver ApoE in cholesterol homeostasis. Previous attempts to therapeutically block brain-specific ApoE in adult models of AD only modestly reduced ApoE expression and no significant impact on amyloid burden. Here, we optimized a divalent siRNA (di-siRNA) to selectively silence ApoE in brain (>2 months). By measuring transcriptomic changes upon knockdown of ApoE in the CNS in multiple mouse models of AD, we find that ApoE knockdown results in an upregulation of the innate immune response, likely through activation of microglia. Additionally, we find that the changes in the transcriptome were similar, but not identical, two weeks and two months post-treatment. We find that mild reduction of ApoE in the liver does not cause widespread transcriptomic changes, but near complete knockdown of ApoE in the liver results in the dysregulation of many lipid metabolism-related pathways.