Project description:We demonstrate that expression of key markers of keratinocyte differentiation is suppressed by exposure to sodium arsenite. Folate deficiency exacerbates this effect. In addition, cancer-related cell movement genes, and growth and proliferation genes are altered. Several redox-sensitive transcription factors are implicated in mediating these gene expression changes due to arsenic treatment and folate deficiency. Experiment Overall Design: K6/ODC mice were maintained on either a folate deficient or folate sufficient diet and exposed to 0, 1, or 10 ppm sodium arsenite in the drinking water for 30 days. Total RNA was isolated from skin samples and gene expression analyzed using Affymetrix Mouse 430 2.0 GeneChips. Data from 24 samples, with four mice in each of the six treatment groups, were analyzed.

Project description:This study tested the anti-inflammatory potential of a green tea extract rich in polyphenols (GrTP) in the colon of the multi-drug resistance targeted mutation (Mdr1a-/-) mouse model of IBD. A colonic histological injury score was determined for each mouse to establish the effect of GrTP on inflammation. Insights into mechanisms responsible for changes in inflammation were gained using transcriptome (microarray) and proteome (2-D gel electrophoresis and LCMS protein identification) analyses. A total of 24 male Mdr1a-/- mice purchased from Taconic (Hudson, NY, USA) at 4-5 weeks of age were used for this study. 12 mice were randomly assigned to each of two different dietary groups: control (AIN-76A powdered diet), or GrTP (AIN-76A + 0.6% green tea polyphenol). At 21 and 24 weeks of age, mice were euthanized and colon samples taken for histological and microarray analyses. The total histology score (HIS) in the colon was determined according to previously described criteria. Total RNA was isolated using TRIzol reagent. Colon RNA from four Mdr1a-/- mice on the GrTP diet (with low HIS) was compared with colon RNA from four Mdr1a-/- mice on the AIN-76A diet (with high HIS). All individual RNA samples were hybridized against a common reference RNA on separate slides. The reference RNA was prepared using equimolar RNA extracts from small intestine, colon, kidney and liver of normal healthy growing Swiss mice plus RNA extracts from Swiss mouse fetuses.

Project description:Monounsaturated fatty acid (MUFA) oleic acid (OA) has been reported to reverse saturated fatty acid palmitic acid (PA)-induced hepatic insulin resistance (IR). However, the detailed molecular mechanism remains elusive. In addition, previous research also showed that -3 polyunsaturated fatty acid (PUFA) eicosapentaenoic acid (EPA), exerted opposite effects to PA in muscle IR, but whether it plays the same role in hepatic IR and the possible mechanism involved needs to be further explored. Here, we confirmed that EPA reversed PA-induced IR in HepG2 cells and compared the proteome change after different free fatty acids (FFAs) treatments. For MUFA, 234 proteins were identified as differentially expressed proteins, and their functions were mainly related to response to stress and endogenous stimuli, lipid metabolic process and protein binding. For PUFA, the PA-induced expression change of 1326 proteins could be reversed by EPA and 415 of them were mitochondrial proteins, which covered most of the functional proteins in oxidative phosphorylation (OXPHOS) and tricarboxylic acid cycle (TCA). Mechanism study revealed that c-Jun and ROS played a role in OA- and EPA-reversed PA-induced IR, respectively. EPA or OA alleviated PA-induced abnormal ATP production, ROS generation, and calcium content. Importantly, H2O2-activated production of ROS increased the expression of c-Jun, further resulting in IR of HepG2 cells. Besides, we provided more feasible candidates as potential c-Jun-targeted “responders” for FFAs treatments. Taken together, we demonstrated that ROS/c-Jun is a common pathway to different FFAs-regulated IR in HepG2 cells.

Project description:Monounsaturated fatty acid (MUFA) oleic acid (OA) has been reported to restore saturated fatty acid palmitic acid (PA)-induced hepatic insulin resistance (IR). However, the detailed molecular mechanism remains elusive. In addition, -3 polyunsaturated fatty acid (PUFA) such as Eicosapentaenoic acid (EPA) has also exerted opposite effects to PA in muscle IR. But whether it plays the same role in hepatic IR and the possible mechanism involved needs to be further explored. Here, we compared the proteome change of HepG2 cells after different fatty acids treatment.

Project description:A total of 30 male IL10-/- (B6.129P2-Il10<tm1Cgn>/J) and 30 male C57 control (C57BL/6J) mice were obtained from The Jackson Laboratory (Bar Harbor, Maine, USA). All mice were between 28 and 35 days of age at the start of the study. For convenience and consistency in reporting, their age was defined as 35 days or 5 weeks of age. The mice were housed individually in standard shoebox size cages containing untreated wood shavings and maintained in an air-conditioned animal room with a 12-h light-dark cycle. Animals had free access to water and were fed an AIN-76A standard powder diet prepared in-house. This study was approved by the AgResearch Ruakura Animal Ethics Committee in Hamilton, New Zealand according to the Animal Protection Act (1960) and Animal Protection Regulations (1987) and amendments. Four days after arrival, all mice were inoculated orally with a mixture of Enterococcus faecalis strains and bacteria commonly found in the intestinal lumen to obtain a more consistent and reproducible intestinal inflammation. Mice were randomly assigned to five sampling groups (7, 8.5, 10, 12 and 14 weeks of age). Experiment Overall Design: For the comparison of gene expression levels, colonic RNA of IL10-/- and C57 at 7 and 12 weeks of age were compared because of a low HIS variability in the colon within those time points. A reference design with 15 arrays was used, where each individual RNA sample was hybridized with a reference sample onto the array, in a total of 3 or 4 biological replicates per treatment. Reference RNA was prepared by pooling equal amounts of purified total RNA extracted from small intestine, colon, kidney, liver and fetuses from normal, healthy Swiss mice.

Project description:Farmed and wild Atlantic salmon was given either vegetable oil (low DHA and EPA) feed or fish oil (high in DHA and EPA) feed or phospholipid (high in phospholipid) feed from start of feeding. We sampled and RNAseq two tissues (pyloric caeca and liver) on day 0, day 48, day 65 and day 94 after initial feeding.

Project description:To profile the expression of circulating miRNAs in a mouse model of diet-induced obesity (DIO) with subsequent weight-reduction with low-fat diet (LFD), eighteen C57BL/6 male mice were grouped into three subgroups as: (1) Control: the mice fed with the standard AIN-76A (fat: 11.5 kcal%) diet for 12 wks; (2) DIO: the mice fed with 58 kcal% high-fat diet for 12 wks; (3) DIO+LFD: the mice fed with high-fat diet for 8 wks to induce obesity, then changed to 10.5 kcal% low-fat diet for subsequent 4 wks. C57BL/6 mice were purchased from BioLasco (Taipei, Taiwan). All housing conditions were maintained, and surgical procedures, including analgesia, were performed in an Association for Assessment and Accreditation of Laboratory Animal Care International (AAALAC)-accredited SPF facility according to national and institutional guidelines. In this experiment, eighteen C57BL/6 wild type male mice were randomly grouped into three subgroups (n=6 in each group): (1) Control: the control mice were fed ad libitum a standard AIN-76A (fat: 11.5 kcal%) diet for 12 wks; (2) DIO: the mice were fed ad libitum a 58 kcal% HFD (D12331; Research Diets Inc., New Brunswick, NJ) for 12 wks to induce obesity; (3) DIO+LFD: the mice fed ad libitum a 58 kcal% HFD (D12331) for 8 wks to induce obesity, then continued the feeding of 10.5 kcal% LFD (D 12329; Research Diets Inc.) for additional 4 wks. Weight measurements were performed on a weekly basis to for these three groups of mice. Evaluation of blood glucose levels was performed at the beginning and in the end of the experiment to confirm that the HFD-fed mice developed an obese and insulin resistant phenotype. After the end of experiment at 12w, all mice were killed. The abdominal WAT of each mice was removed and weighted. Paraffin-embedded abdominal WAT was sectioned at 5 M-NM-<m and stained with hematoxylin and eosin to measure mean adipocyte area. A volume of 1 mL of whole blood was collected into a plain tube and allowed to clot for 1 hour. The sera samples were aliquoted after centrifugation at 3,000 M-CM-^W g for 10 minutes and stored at M-bM-^HM-^R80M-BM-0C until further analysis.

Project description:This study assessed gene expression changes associated with inflammation in the colon tissue of multi-drug resistance targeted mutation (Mdr1a-/-) mice, a model of human IBD. It also tested the anti-inflammatory potential of curcumin in the colon of these mice with a particular focus on the proteome. A colonic histological injury score was determined for each mouse to assess the level of colon inflammation in Mdr1a-/- mice, and to establish the effect of curcumin on inflammation. Insights into mechanisms of colonic inflammation in the Mdr1a-/- mice were gained using transcriptome (microarray) and proteome (2-D gel electrophoresis and LCMS protein identification) analyses. These data were compared to changes in the colon proteome in response to curcumin, and to previously described transcriptomic analyses [Nones et al, PMID: 18761777; GSE10684] in response to curcumin, in this model. A total of 24 male Mdr1a-/- mice, and 24 male FVB/N mice, purchased from Taconic (Hudson, NY, USA) at 4-5 weeks of age, were used for this study. 12 mice were randomly assigned to each of two different dietary groups: control (AIN-76A powdered diet), or curcumin (AIN-76A + 0.2% curcumin). At 21 and 24 weeks of age, mice were euthanized and colon samples taken for histological, microarray, and proteomics analyses. The total histology score (HIS) in the colon was determined according to previously described criteria. Total RNA was isolated using TRIzolM-BM-. reagent. Colon RNA from four Mdr1a-/- mice (with high HIS) on the control diet (i.e. AIN-76A powdered diet) was compared with colon RNA from four FVB/N mice with low HIS also on the control diet (i.e. AIN-76A powdered diet). All individual RNA samples were hybridized against a common reference RNA on separate slides. The reference RNA was prepared using equimolar RNA extracts from small intestine, colon, kidney and liver of normal healthy growing Swiss mice plus RNA extracts from Swiss mouse fetuses. These data were compared with previously reported transcriptomics analysis of colon RNA from the same four Mdr1a-/- mice on the AIN-76A diet (with high HIS) compared with colon RNA from four Mdr1a-/- mice on the curcumin diet (with low HIS; Nones et al 2009, PMID: 18761777)

Project description:Dietary supplementation with ω-3 polyunsaturated fatty acids (ω-3 PUFAs), specifically the fatty acids docosahexaenoic acid (DHA; 22:6 ω-3) and eicosapentaenoic acid (EPA; 20:5 ω-3), is known to have beneficial health effects including improvements in glucose and lipid homeostasis and modulation of inflammation. To evaluate the efficacy of two different sources of ω-3 PUFAs, we performed gene expression profiling in the liver of mice fed diets supplemented with either fish oil or krill oil. We found that ω-3 PUFA supplements derived from a phospholipid krill fraction (krill oil) downregulated the activity of pathways involved in hepatic glucose production as well as lipid and cholesterol synthesis. The data also suggested that krill oil-supplementation increases the activity of the mitochondrial respiratory chain. Surprisingly, an equimolar dose of EPA and DHA derived from fish oil modulated fewer pathways than a krill oil-supplemented diet and did not modulate key metabolic pathways regulated by krill oil, including glucose metabolism, lipid metabolism and the mitochondrial respiratory chain. Moreover, fish oil upregulated the cholesterol synthesis pathway, which was the opposite effect of krill supplementation. Neither diet elicited changes in plasma levels of lipids, glucose or insulin, probably because the mice used in this study were young and were fed a low fat diet. Further studies of krill oil supplementation using animal models of metabolic disorders and/or diets with a higher level of fat may be required to observe these effects. Twenty-one microarrays: three diets (CO, FO, KO) x seven mice per diet x one microarray per mouse

Project description:The aim of this study was to evaluate whether the dietary treatment with olive oil phenols modifies the profile of microRNA and gene expression in different areas of the aging mouse brain and to correlate these changes with the cognitive and motor changes observed in the same aging animals. C57Bl/6J mice were fed from middle age to senescence with extra-virgin olive oil (10% wt/wt dry diet) rich in polyphenols (H-EVOO group, total polyphenol dose/day, 6mg/kg) or with the same extra-virgin olive oil deprived of phenolic compounds (L-EVOO group). By whole gene expression analysis we identified 53 genes differentially expressed in the cortex of H-EVOO mice compared to L-EVOO mice and no genes differentially expressed in the cerebellum. Gene Set Expression analysis (GSEA) found 6 gene sets significantly modulated by the dietary treatments in cortex, like the agrin-related postsynaptic differentiation gene set, involved in cholinergic synaptic differentiation and maintenance, exerting effects on axonal and dendritic growth. miRNA profiling found only 6 miRNA differentially modulated after 12 months of feeding and 63 after six months. Among them we noted miRNAs previously associated to neurodegenerative disorders such as mir101, 8.5 time more expressed in the cortex of L-EVOO fed mice compared to the H-EVOO group and no expressed in young mice. We extended our analysis on cortex harvested from transgenic TgCRND8 mice, a model of Alzheimer's disease, observing an overall down-regulation of miRNAs compared to mice of the same age. On the contrary, the H-EVOO fed mice cortex showed expression profiles similar to those of young mice, results supporting our previous data demonstrating that extra virgin olive oil rich in polyphenols may improve some age-related dysfunctions.