Project description:Using the GENIPOL flounder cDNA microarray, we assessed the temporal transcriptomic responses of Platichthys flesus to model toxicants over a 16 day timespan. Immature fish were treated by intraperitoneal injection with cadmium chloride (50 micrograms/kg in saline), 3-methylcholanthrene (25mg/kg in olive oil), Aroclor 1254 (50mg/kg in olive oil), tert-butyl-hydroperoxide (5mg/kg in saline), lindane (25 mg/kg in olive oil), perfluoro-octanoic acid (100mg/kg in olive oil), olive oil or saline (0.9%). Hepatic gene expression changes were determined 1,2,4,8 and 16 days post-injection in comparison with time-matched carrier controls.

Project description:HLA-B27 transgenic rats, experimental model of chronic colitis, fed with a diet in which the lipid component was provided by corn oil (CO group), extra-virgin olive oil rich in phenols, 718.8 mg of total phenols/kg of olive oil (EVOO group) or the same extra-virgin olive oil, deprived of phenolic compounds but retaining other minor components such as a-tocopherol (ROO group).

Project description:The current study was designed to determine if dietary fatty acid concentration and composition affects the development and progression of nonalcoholic fatty liver disease. Male SD rats were overfed diets low (5%) or high (70%) fat diets via total enteral nutrition where the fat source was olive oil (monounsaturated), or corn oil (polyunsaturated). Overfeeding 5% corn oil produced little steatosis relative to feeding 5% olive oil. This was associated with lower fatty acid synthesis and reduced SREBP-c signaling in the 5% corn oil group. Overfeeding 70% fat diets increased steatosis and lead to increased liver necrosis in the 70% corn oil but not olive oil group. Increased injury after feeding polyunsaturated fat diets was linked to peroxidizability of hepatic free fatty acids and triglycerides and appearance of peroxidaized lipid products HETES and HODES previously linked to clinical nonalcoholic steatohepatitis. Male SD rats were overfed diets low (5%) or high (70%) fat diets via total enteral nutrition where the fat source was olive oil (monounsaturated) or corn oil (polyunsaturated).

Project description:Proteins and peptides are minor components of vegetal oils. The presence of these compounds in virgin olive oil was first reported in 2001, but the nature of the olive oil proteome is still a puzzling question for food science researchers. In this project, we have compiled for a first time a comprehensive proteomic dataset of olive fruit and fungal proteins that are present at low but measurable concentrations in a vegetable oil from a crop of great agronomical relevance as olive (Olea europaea L.). Accurate mass nLC-MS data were collected in high definition direct data analysis (HD-DDA) mode using the ion mobility separation step. Protein identification was performed using the Mascot Server v2.2.07 software (Matrix Science) against an ad hoc database made of olive protein entries. Starting from this proteomic record, the impact of these proteins on olive oil stability and quality could be tested. Moreover, the effect of olive oil proteins on human health and their potential use as functional food components could be also evaluated. In addition, this dataset provides a resource for use in further functional comparisons across other vegetable oils, and also expands the proteomic resources to non-model species, thus also allowing further comparative inter-species studies.

Project description:Some studies have shown that acute intake of high-phenol virgin olive oil reduces pro-inflammatory, pro-oxidant and pro-thrombotic states, but nowadays still remains unclear if those effects attributed to its phenolic fraction could be exerted at transcriptional level in vivo. Two virgin olive oil-based breakfasts with high (398 ppm) and low (70 ppm) content of phenolic compounds were administered to twenty patients (9 men and 11 women) with metabolic syndrome following a double-blinded random crossover design. Prior to the first breakfast intervention, participants followed a 6-week washout period in which they were instructed to not take vitamins, soy supplements, or any drug. To eliminate the potential effect that might exist in their usual dietary habits, all subjects followed a low-fat, carbohydrate rich (CHO) diet during this period and untill the end of the study. In the 24 h before each breakfast intervention, participants were instructed to avoid consuming phenol-rich foods such as fruit or juices, wine, grape juice, chocolate, coffee, tea, olive oil, or soya, and to refrain from intense physical exercise during that period. After a 12 h fasting and following a randomized sequential crossover design with one-week washout period, participants reported to the hospital and received two fat meals consisting of 60 g of white bread, 40 mL of VOO (CANOLIVA®, Antonio Cano e Hijos™, Córdoba, Spain) with high (398 ppm) or low (70 ppm) content in phenolic compounds, and 60,000 IU of vitamin A per m2 of body surface. Olive oil with low content in phenolic compounds was obtained as a result of extraction by physical procedures of most of the phenolic compounds in the high-phenol olive oil, so that both oils kept a similar composition of the remaining macro- and micronutrients. Throughout the 4-h duration of the study, the subjects performed no physical activity, nor did they consume anything but water. Gene expression was performed on peripheral blood mononuclear cells (PBMCs) at postprandial period (4 hours after breakfast) by microarray analysis and verified by qRT-PCR. Two sets of dye-swaped experiments were performed making a total of four technical replicates per subject. Each of the hybridizations compared total RNA from PBMCs obtained 4h after the intake of virgin olive oil with high phenolic content vs. total RNA from PBMCs obtained 4h after low-phenol virgin olive oil consumption.

Project description:Mice were treated with CCl4,APAP or olive oil for 24 h, protein changes were detected by mass spectrometry

Project description:We used microarray analysis to examine which genes are differentially expressed in mice that received a combination of fish oil and indomethacin. We fed low density lipoprotein receptor knock-out (LDLR-/-) mice with 6% of olive oil (control) or fish oil diets in the presence or absence of indomethacin for 12 weeks. We collected total RNA from liver samples and pooled 6 RNA samples in each group for Affymetrix microarrays.

Project description:The acute response four hours after a fat load of extra virgin olive oil was investigated using DNA microarrays. Hepatic gene expression was analysed in Wistar Rats. Male rats, weighing 250- 300 g (purchased from Charles River, Barcelona, Spain), were used for experiments. Rats, housed in sterile filter-top cages (3-4 per cage), were acclimatized in a room maintained at 20ºC with a 12-h light-dark cycle for 10 days, allowed ad libitum access to water and standard chow diet (Pascual S.A., Barcelona, Spain), and fasted for 18 h before experiments. Two study groups were established: a) The control group did not receive any fat meal. The other group was fed 5 ml of olive oil (Aceites Toledo, Spain) as a bolus and sacrificed 4 hours after the feeding, respectively. This amount represents the use of a dose of 16 mL olive oil/ kg.

Project description:Since the liver is the central organ of metabolism, changes in diet have a great impact on this organ and overall on health with aging. It is well known that dietary fat source strongly influences many parameters of the hepatic mitochondria. These changes includes modification of lipid composition of mitochondrial membrane, affecting the mtETC functions, oxidative stress and mtDNA alterations. We used microarrays to detail the changes in gene expression provides by feeding lifelong on different dietary fat sources, and identified distinct classes of up and down-regulated genes during aging under different dietary conditions. Rats were fed lifelong on a normolipidic diet (4% w/w) with virgin olive, sunflower or fish oil as dietary fat source. At 6 and 24 months, animals were killed and liver were removed for RNA extraction and hybridization on Affymetrix microarrays. We sought to obtain changes in gene expression due to both aging and dietary conditions. There were 6 experimental groups (virgin olive oil at 6 months, sunflower oil at 6 months, fish oil at 6 months, virgin olive oil at 24 months, sunflower oil at 24 months and fish oil at 24 months. 3 animals were studied of each experimental group, so a total of 18 samples were analyzed.

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.