1.
Effects of fish and krill oil on gene expression in peripheral blood mononuclear cells and circulating markers of inflammation: a randomised controlled trial.
Rundblad, A, Holven, KB, Bruheim, I, Myhrstad, MC, Ulven, SM
Journal of nutritional science. 2018;7:e10
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Intake of omega 3 fatty acids is associated with a reduction in cardiovascular disease (CVD) risk. Krill oil is a source of omega-3 fatty acids that has been shown to modulate gene expression in animal studies. The aim of this 8 week randomised controlled trial was to investigate the effect of fish intake and krill oil on the expression of genes related to lipid and glucose metabolism and inflammation. Thirty-six healthy adults were split into three groups. The krill group took capsules containing 4g of krill oil per day. The fish group ate fish three times a week, and the control group were given high-oleic sunflower oil (HOSO) with added astaxanthin. Blood samples were analysed for gene expression and markers of inflammation and endothelial dysfunction at the start and end of the study. Intake of krill oil significantly down-regulated the expression of 13 of the 40 genes that were analysed, including genes involved in glucose and cholesterol metabolism and fatty acid beta-oxidation. Intake of fish significantly altered the expression of just four of the genes. Intake of HOSO with added astaxanthin significantly reduced the expression of 16 genes involved in inflammation and cholesterol transport. There were no significant changes in markers of inflammation and endothelial dysfunction across the three groups, possibly due to the relatively low dose of omega-3 fatty acids given. The authors suggest that the higher levels of eicosapentaenoic acid (EPA) in krill oil compared to fish could be partly responsible for the increased beneficial effects. Monounsaturated fatty acids (MUFAs) and astaxanthin (found naturally in krill oil) may also have contributed to the findings. Further studies are needed to understand the effects of fatty acids on gene expression.
Abstract
Marine n-3 (omega-3) fatty acids alter gene expression by regulating the activity of transcription factors. Krill oil is a source of marine n-3 fatty acids that has been shown to modulate gene expression in animal studies; however, the effect in humans is not known. Hence, we aimed to compare the effect of intake of krill oil, lean and fatty fish with a similar content of n-3 fatty acids, and high-oleic sunflower oil (HOSO) with added astaxanthin on the expression of genes involved in glucose and lipid metabolism and inflammation in peripheral blood mononuclear cells (PBMC) as well as circulating inflammatory markers. In an 8-week trial, healthy men and women aged 18-70 years with fasting TAG of 1·3-4·0 mmol/l were randomised to receive krill oil capsules (n 12), HOSO capsules (n 12) or lean and fatty fish (n 12). The weekly intakes of marine n-3 fatty acids from the interventions were 4654, 0 and 4103 mg, respectively. The mRNA expression of four genes, PPAR γ coactivator 1A (PPARGC1A), steaoryl-CoA desaturase (SCD), ATP binding cassette A1 (ABCA1) and cluster of differentiation 40 (CD40), were differently altered by the interventions. Furthermore, within-group analyses revealed that krill oil down-regulated the mRNA expression of thirteen genes, including genes involved in glucose and cholesterol metabolism and β-oxidation. Fish altered the mRNA expression of four genes and HOSO down-regulated sixteen genes, including several inflammation-related genes. There were no differences between the groups in circulating inflammatory markers after the intervention. In conclusion, the intake of krill oil and HOSO with added astaxanthin alter the PBMC mRNA expression of more genes than the intake of fish.
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Crosstalk between the microbiome and epigenome: messages from bugs.
Qin, Y, Wade, PA
Journal of biochemistry. 2018;163(2):105-112
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Trillions of microbes live symbiotically in and on an individual human being, most of them inside the digestive tract and communally known as the gut microbiome. The gut microbiome plays a vital role in the individual host’s health, not only by helping digest food and harvest energy, but also by regulating immune development and influencing gene expression. Diet and factors, such as infections and the use of antibiotics, can alter the balance of the microbiome and lead to various outcomes. This paper reviewed the current understanding of the ways in which the gut microbiome is capable of altering the host’s gene expression through microbial signals, including metabolites, bile acids, inflammation and altered composition. The studies highlighted in the paper show that gut microbes communicate both with local cells in the intestines and with more distant organs, such as the liver and the cardiovascular system. Through this communication, they can regulate the expression of immune cells, cancer cells, enzymes and inflammation-related molecules. The authors concluded that these interactions, or the crosstalk between the microbes and the host, demonstrate a crucial role of the gut microbiome in the host’s response to environmental signals. However, many of the mechanisms are still unclear, so further studies are needed to explain specific microbe-derived signals, affecting host gene expression, and to deepen our understanding of how lifestyle, health status and environmental exposures, such as antibiotics, regulate the microbiome and its influence.
Abstract
Mammals exist in a complicated symbiotic relationship with their gut microbiome, which is postulated to have broad impacts on host health and disease. As omics-based technologies have matured, the potential mechanisms by which the microbiome affects host physiology are being addressed. The gut microbiome, which provides environmental cues, can modify host cell responses to stimuli through alterations in the host epigenome and, ultimately, gene expression. Increasing evidence highlights microbial generation of bioactive compounds that impact the transcriptional machinery in host cells. Here, we review current understanding of the crosstalk between gut microbiota and the host epigenome, including DNA methylation, histone modification and non-coding RNAs. These studies are providing insights into how the host responds to microbial signalling and are predicted to provide information for the application of precision medicine.
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Impact of Consuming Extra-Virgin Olive Oil or Nuts within a Mediterranean Diet on DNA Methylation in Peripheral White Blood Cells within the PREDIMED-Navarra Randomized Controlled Trial: A Role for Dietary Lipids.
Arpón, A, Milagro, FI, Razquin, C, Corella, D, Estruch, R, Fitó, M, Marti, A, Martínez-González, MA, Ros, E, Salas-Salvadó, J, et al
Nutrients. 2017;10(1)
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Our genes are not fixed. They interact constantly with the environment through dietary and lifestyle factors, which affect whether genes are expressed or not. This is often referred to as epigenetic modulation. DNA methylation is an epigenetic mechanism that adds a methyl group to DNA, thereby modifying the function of the genes and affecting gene expression. Epigenetic alterations have been associated with conditions, such as obesity, type 2 diabetes, cardiovascular disease and immunological conditions. It is suggested that epigenetic marks are reversible and can be modulated by nutrient status and certain dietary components. The aim of the current study was to explore methylation changes in genes of peripheral white blood cells in a subset of participants from the PREDIMED-Navarra randomised controlled trial. 36 participants were allocated to three groups, all consuming a Mediterranean diet. In the first group, the diet was supplemented with extra virgin olive oil (EVOO), in the second group, with mixed nuts, and the third group, which served as the control group, were advised to consume a low-fat diet. Changes in DNA methylation were analysed from blood samples at baseline and at five-year follow-up. The authors observed methylation changes in several genes, related to metabolism, glucose and energy regulation, diabetes and inflammation, after the consumption of EVOO and nuts. They concluded that the beneficial effects of Mediterranean diets that include EVOO and nuts, may, at least in part, be mediated via epigenetic mechanisms. As these foods are high in monounsaturated and polyunsaturated fats, the quality of fat may be playing an important role in this mediation.
Abstract
DNA methylation could be reversible and mouldable by environmental factors, such as dietary exposures. The objective was to analyse whether an intervention with two Mediterranean diets, one rich in extra-virgin olive oil (MedDiet + EVOO) and the other one in nuts (MedDiet + nuts), was influencing the methylation status of peripheral white blood cells (PWBCs) genes. A subset of 36 representative individuals were selected within the PREvención con DIeta MEDiterránea (PREDIMED-Navarra) trial, with three intervention groups in high cardiovascular risk volunteers: MedDiet + EVOO, MedDiet + nuts, and a low-fat control group. Methylation was assessed at baseline and at five-year follow-up. Ingenuity pathway analysis showed routes with differentially methylated CpG sites (CpGs) related to intermediate metabolism, diabetes, inflammation, and signal transduction. Two CpGs were specifically selected: cg01081346-CPT1B/CHKB-CPT1B and cg17071192-GNAS/GNASAS, being associated with intermediate metabolism. Furthermore, cg01081346 was associated with PUFAs intake, showing a role for specific fatty acids on epigenetic modulation. Specific components of MedDiet, particularly nuts and EVOO, were able to induce methylation changes in several PWBCs genes. These changes may have potential benefits in health; especially those changes in genes related to intermediate metabolism, diabetes, inflammation and signal transduction, which may contribute to explain the role of MedDiet and fat quality on health outcomes.