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An Isocaloric Nordic Diet Modulates RELA and TNFRSF1A Gene Expression in Peripheral Blood Mononuclear Cells in Individuals with Metabolic Syndrome-A SYSDIET Sub-Study.
Ulven, SM, Holven, KB, Rundblad, A, Myhrstad, MCW, Leder, L, Dahlman, I, Mello, VD, Schwab, U, Carlberg, C, Pihlajamäki, J, et al
Nutrients. 2019;11(12)
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Metabolic syndrome (MetS) alongside other related risk factors has been implicated as increasing an individual’s risk for cardiovascular disease and type 2 diabetes. MetS is associated with chronic low-grade inflammation and raised blood lipid levels, which have been shown to improve in individuals when put on a Nordic diet (ND). In this sub-study of the SYSDIET study, which was a 18-24 week randomised controlled multi centre study, the aim was to examine the effect of a ND compared to a control diet (CD) on genes that are involved in the production of inflammatory molecules and lipids. Blood samples of 88 obese participants from the SYSDIET study were analysed for various inflammatory molecule producing genes and lipid molecule producing genes. The results showed that compared to CD, ND increased the presence of the inflammatory gene RELA, but decreased the presence of inflammatory gene TNFRSF1A. No differences were observed in other inflammatory genes and no differences were observed in lipid producing genes. It was concluded that consuming a ND compared to a CD may affect the production of inflammatory genes; however further studies are required to determine if the ND improves the amount of blood lipids because of an altered presence of lipid producing genes. The implication of this for practitioners is that further research of the SYSDIET is needed. In addition, a Nordic diet may improve inflammation in obese individuals because of a reduction in the production of inflammatory genes.
Abstract
A healthy dietary pattern is associated with a lower risk of metabolic syndrome (MetS) and reduced inflammation. To explore this at the molecular level, we investigated the effect of a Nordic diet (ND) on changes in the gene expression profiles of inflammatory and lipid-related genes in peripheral blood mononuclear cells (PBMCs) of individuals with MetS. We hypothesized that the intake of an ND compared to a control diet (CD) would alter the expression of inflammatory genes and genes involved in lipid metabolism. The individuals with MetS underwent an 18/24-week randomized intervention to compare a ND with a CD. Eighty-eight participants (66% women) were included in this sub-study of the larger SYSDIET study. Fasting PBMCs were collected before and after the intervention and changes in gene expression levels were measured using TaqMan Array Micro Fluidic Cards. Forty-eight pre-determined inflammatory and lipid related gene transcripts were analyzed. The expression level of the gene tumor necrosis factor (TNF) receptor superfamily member 1A (TNFRSF1A) was down-regulated (p = 0.004), whereas the nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) subunit, RELA proto-oncogene, was up-regulated (p = 0.016) in the ND group compared to the CD group. In conclusion, intake of an ND in individuals with the MetS may affect immune function.
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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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Changes in LDL Oxidative Status and Oxidative and Inflammatory Gene Expression after Red Wine Intake in Healthy People: A Randomized Trial.
Di Renzo, L, Marsella, LT, Carraro, A, Valente, R, Gualtieri, P, Gratteri, S, Tomasi, D, Gaiotti, F, De Lorenzo, A
Mediators of inflammation. 2015;2015:317348
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It is recognised that inflammation and oxidative stress may play a role in the development of heart disease. Red wine has previously been shown to lower inflammation and improve antioxidant status. This small, randomised, crossover trial aims to investigate if resveratrol in red wine causes these effects. The trial involved twenty-four healthy adults who took part in the four intervention arms, with a three week washout period in between. Blood markers and genomic information were measured at (1) baseline and after each intervention: (2) a high-fat McDonald’s meal (McDM), (3) McDM + red wine and (4) just red wine. While eating McDM alone raised markers of oxidative stress, having red wine with McDM lowered markers. The authors concluded that having red wine with a meal could reduce the levels of inflammation and oxidative stress normally seen after eating. It was suggested that moderate red wine consumption (2 drinks a day for men and 1 drink a day for women) could potentially lower the risk of heart disease, but longer term studies are needed before definite conclusions can be drawn.
Abstract
Postprandial oxidative stress is characterized by an increased susceptibility of the organism towards oxidative damage after consumption of a meal rich in lipids and/or carbohydrates. Micronutrients modulate immune system and exert a protective action by reducing low density lipoproteins (LDL) oxidation via induction of antioxidant enzymes. We evaluated the gene expression of oxidative stress (HOSp), inflammasome (HIp), and human drug metabolism pathways (HDM) and ox-LDL level at baseline and after the intake of red wine naturally enriched with resveratrol (NPVRW), in association with or without a McDonald's meal (McDM). The ox-LDL levels significantly increase comparing baseline (B) versus McDM and decreased comparing McDM versus McDM + NPVRW (P ≤ 0.05). Percentages of significant genes expressed after each nutritional intervention were the following: (1) B versus McDM, 2.88% HOSp, 2.40% of HIp, and 3.37% of HDMp; (2) B versus McDM + NPVRW, 1.44% of HOSp, 4.81% of HIp, and 0.96% of HDMp; (3) McDM versus McDM + NPVRW, 2.40% of HOSp, 2.40% of HIp, and 5.77% of HDMp; (4) B versus NPVRW, 4.80% HOSp, 3.85% HIp, and 3.85% HDMp. NPVRW intake reduced postprandial ox-LDL and the expression of inflammation and oxidative stress related genes. Chronic studies on larger population are necessary before definitive conclusions.