A Low-Fat Diet Containing Heated Soybean Oil Promotes Hyperglycemia in C57BL/6J Mice

Middleton, Olivia Lane

10 July 2013

A Low-fat Diet Containing Heated Soybean Oil Promotes Hyperglycemia in C57BL/6J Mice Introduction: The metabolic effects of consuming mildly oxidized lipids as compared to highly oxidized lipids are not well documented. Consumption of highly oxidized polyunsaturated fatty acids, even in a low-fat diet, may be a threat to one’s health. Previous studies in our lab have shown that mice consuming soybean oil heated for 3 hours, compared to unheated, gain less body weight, but more fat pad mass, and 3T3-L1 adipocytes treated with soybean oil heated for ≥ 6 hours have abrogated triglyceride accumulation. Another study showed that rats fed highly oxidized oil (heated > 24 hrs), as compared to fresh soybean oil and fish oil, had lower fat pad mass and weight gain but developed glucose intolerance. This suggested that the extent of lipid oxidation determined the subsequent metabolic risk. Objective: Our aim, in the current study, is to investigate if a low-fat diet with soybean oil heated for increasing time points (3h, 6h and 9h) alter fat mass and glucose tolerance. Methods: Six week old, male, C57BL/6J mice were randomly divided into six groups (n=8/group). Three groups were fed a low fat diet with soybean oil heated for 3 (3hr-HO), 6 (6hr-HO), or 9 (9hr-HO) hours for 16 weeks. Another three groups were pair-fed to each of the 3hr-HO, 6hr-HO and 9hr-HO groups with a low-fat diet containing unheated oil (PF-UHO). Food consumption was recorded every 3-4 days, and body weights were recorded weekly. Soy oil in the diets was analyzed for products of oxidation. At 16 weeks, blood glucose levels were measured after a 6 hour fast; fat pad and liver weights were recorded, and blood was collected by cardiac puncture for serum insulin analysis. Results: Final weight gain was not significantly different between all HO groups as a percent of their respective PF groups (p >0.05). The feeding efficiency for 3hr, 6hr, and 9hr-HO groups as a percent of PF was 92.75, 113.02, and 111.28, respectively. Mean weights of all fat pads for HO groups decreased with heating time as a percent of PF, although these differences were not statistically significant. Blood glucose was lowest in the 3hr-HO group and significantly increased from 3hr-HO group to 6hr-HO group (p=0.021) as a percent of PF. Serum insulin levels decreased for the HO groups as heating time increased, although these differences were not statistically significant. Conclusion: Consuming a diet with increasing amounts of oxidized lipids decreased fat pad mass and insulin levels, while increasing fasting glucose levels. This paradoxical relationship between increased glucose in the presence of decreased insulin in c57BL/6J mice could be due to either reduced insulin secretion or increased insulin resistance. Further research in our lab will aim to analyze triglyceride accumulation in the liver and muscle cells of these mice to determine if oxidized lipids promote ectopic fat deposition.

dietary oxidized lipids

hyperglycemia

mice

heated oil

oxidized fat

soybean

Determination of Oxidized Lipids in Commonly Consumed Foods and Their Binding Affinity for PPARγ

Skinner, Joanna P

06 May 2012

Background: Foods rich in polyunsaturated fatty acids (PUFA) are susceptible to oxidation through heating or storage. Oxidized lipids are known to act as ligands for a transcription factor (PPAR-gamma) that affects adipocyte differentiation and insulin sensitivity. Objective: The purpose of this study was to determine the amounts of oxidation products of a variety of PUFA containing foods over time, and to determine whether extracted fats from these foods act as ligands for PPAR-gamma. Method: To study the effect of room-temperature storage on oxidation, 5 foods (walnuts, sunflower seeds, ground flax, fish oil capsules, and infant formula) were purchased and stored at room temperature for 1, 2, and 3 months. To determine oxidation levels in fried foods, French fries and chicken nuggets were used. Fat was extracted from each food and the levels of oxidation products were analyzed by spectrophotometry and kits designed to measure oxidation products. Using a fluorescence polarization-based ligand screening assay kit, fat extracted from foods was analyzed for its binding affinity for PPAR-gamma. Results: Among foods stored at room temperature, the levels of oxidation products did not change significantly with time. Most foods exhibited the highest levels of oxidation at the purchase date. Infant formula and ground flax demonstrated higher levels of oxidation products than did other foods. In preliminary ligand binding assays, extracted fat from French fries showed the greatest binding affinity for PPAR-gamma; a select few other oils showed slight affinity. Discussion: Surprisingly, storage time did not affect oxidation levels. The greatest amount of oxidation may occur during pre-purchase storage conditions. The processing of formula and ground flax may be the cause of the relatively higher oxidation levels in those foods. The binding affinity for PPAR-gamma demonstrated by French fries needs further investigation. Conclusion: Certain oxidized lipids from foods may act as ligands for PPAR-gamma. Further research is required not only to determine which component of these PUFA-containing foods activates PPAR-gamma but also to determine whether that component acts as an agonist or antagonist for PPAR-gamma.

Oxidized Lipids

PPAR-Gamma

Obesity

Polyunsaturated Fatty Acids

Oxidized soybean oil alters the expression of PPAR gamma and target genes in 3T3-L1 cells

Dingels, Nicole Katherine

15 November 2012

Background: The typical western diet contains foods with modest amounts of lipid oxidation products. Previous work by us and others have demonstrated that mildly oxidized lipids promote a gain in fat mass while highly oxidized lipids decrease fat mass in rodents and triglyceride (TAG) accumulation in 3T3-L1 cells. Adipocyte differentiation is regulated by a key nuclear transcription factor known as PPARγ. Objective: To investigate if the alterations in triglyceride accumulation in 3T3-L1 cells pretreated with oxidized soy oil are due to 1) a change in PPARg DNA interactions 2) changes in the expression of SREBP-1c, PPARg, and/or its target genes. Main Methods: Confluent 3T3-L1 cells were pretreated for 24hours with 0.01% soy oil (SO) which was either unheated (unheated SO) or heated for 3, (3h-SO), 6 (6h-SO), or 9hours (9h-SO). The effect of 24hour soy oil exposure was assessed at several time points throughout the differentiation process. Alterations in PPARg DNA interaction was assessed using a PPARγ transcription factor assay kit while alterations in the expression of genes upstream and downstream of PPARγ was determined by RT-PCR. Primary and secondary products of oxidation within the SO were determined by spectrophotometry. Results: The 6hr-SO contained the greatest concentration of peroxides whereas both the 6hr-SO and 9hr-SO contained a significantly higher concentration of conjugated dienes and aldehydes.Nuclear extracts from 3T3-L1 cells pretreated with 6h-SO demonstrated the greatest reduction in PPARγ DNA binding. Compared to the unheated SO and mildly oxidized 3h-SO, cells treated with the 6h-SO had a significant reduction in SREBP-1c, PPARg, LPL, and GLUT4 expression occurring early in the differentiation process. Variations in the gene expression of 6hr-SO pretreated cells persisted within partially differentiated and mature adipocytes. Conclusions: Pre-treatment of preadipocytes with soy oil heated for ³ 6h greatly decreases the activity of PPARγ in the nucleus and adipogenic gene expression . These changes seen in early differentiation seem to correlate the best with the phenotype of reduced triglyceride accumulation seen in mature adipocytes.

PPAR gamma

oxidized lipids

gene expression

adipocyte differentiation

triglyceride accumulation

3T3-L1 cells

The role of the mitochondrial membrane system in apoptosis : the influence of oxidative stress on membranes and their interactions with apoptosis-regulating Bcl-2 proteins

Lidman, Martin

January 2015

Apoptosis is a crucial process in multicellular organisms in sculpting them, especially during embryogenesis. In addition, apoptosis is responsible for the clearance of harmful or damaged cells which can otherwise be detrimental to the organism. The Bcl-2 family proteins are key players in the regulation of the intrinsic pathway of the apoptotic machinery. This family consists of three subfamilies with B-cell CLL/lymphoma 2 (Bcl-2) protein itself representing anti-apoptotic members, the Bcl-2-associated X protein (Bax), and pro-apoptotic BH3-only signaling proteins. The interplay between pro- and anti-apoptotic proteins on the mitochondrial membranes is central to the balance between the life and death decision of whether the membrane should be permeabilized or not. The cytosolic Bax protein can upon cellular stress translocate to the mitochondrial membrane where it can either carry out its action of forming homo-oligomers that cause outer membrane permeabilization or be inhibited there by the anti-apoptotic membrane protein Bcl-2. Upon mitochondrial outer membrane permeabilization (MOMP) apoptogenic factors leak out from the intermembrane space (IMS) of the mitochondria, leading to caspase activation and ultimately cell death. A common stress signal initiating apoptosis is an increased formation of reactive oxygen species (ROS in the mitochondria, who can cause oxidative damage to lipid membranes. This membrane damage presumably influences the lipid landscape and the membrane features and hence the interactions of the Bcl-2 family proteins with each other and the mitochondrial outer membrane (MOM). To investigate the significance of membrane oxidation on the behavior of the Bcl-2 family proteins, especially Bax, synthetically produced oxidized phospholipids (OxPls) were incorporated in MOM-mimicking vesicles. Differential scanning calorimetry (DSC), nuclear magnetic resonance (NMR) spectroscopy and circular dichroism (CD) spectroscopy revealed a major perturbation in membrane organization in the presence of OxPls. These changes in membrane properties increase the affinity of Bax to its target membrane and enable its partial penetration and formation of pores, as fluorescence leakage assays confirmed. However, in the absence of BH3-only proteins these pores are not sufficiently large for the release of apopototic factors such as cytochrome C (CytC). To understand the inhibition of Bax by the full-length Bcl-2 protein, suitable detergent solubilizing conditions were carefully chosen to enable the measurement of their direct binding to each other outside the membrane, by an antimycin A2 fluorescence assay. The observed protein-protein interaction was confirmed by surface plasmon resonance (SPR). An established protocol for the reconstitution of Bcl-2 into stable proteoliposomes now paves the way for structural studies of this key protein, in its membrane environment near physiological conditions; information essential for understanding its function, on a molecular level, and its potential as a cancer drug target.

Bax

Bc-2

apoptosis

mitochondria

membranes

oxidized lipids

NMR

calorimetry

circular dichroism

Pokročilé fluorescenční metody aplikované ve výzkumu biomolekul (lipidových membrán a DNA) / Advanced fluorescence techniques applied on biomolecules (lipid membranes and DNA)

Beranová, Lenka

January 2013

The thesis describes time dependent fluorescence shift method and fluorescence correlation spectroscopy method (FCS) with its extensions FLCS, Z-scan FCS and dual-focus FCS applied on specific problems in DNA and lipid research. Compaction mechanism of a DNA molecule smaller than a resolution of a confocal microscope was elucidated. The process was revealed to be "all or non" for a polycation spermine as a condenser in contrast with the gradual compaction caused by a cationic surfactant. Biophysical properties of a phospholipid bilayer influenced by presence of oxidized phospholipids with truncated sn-2 chain were explored. The dynamics of hydrated functional groups in the headgroup region was proved to get faster while the hydration of the headgroup region increased. These effects are in relation with the reorientation of the short sn-2 chains observed in molecular dynamics simulations. Presence of oxidized species may also influence the lateral diffusion of the lipids - a slight increase of the diffusion coefficient was observed. Decrease of hydration and mobility in the headgroup region was found as an influence of heavy water on the phospholipid membrane. These finding are in line with molecular dynamics simulations which show longer lifetimes of hydrogen bonds between water and lipid molecules in...

Regulation von oxidativem Stress durch biomechanische Kräfte und fettreiche Ernährung im Herz-Kreislaufsystem

Göttsch, Claudia

09 March 2007

Erkrankungen des Herz-Kreislaufsystems sind trotz erheblicher Fortschritte in Diagnostik und Therapie noch immer die häufigste Todesursache in Deutschland. Neben bekannte Risikofaktoren wie Hypercholesterinämie, Hyperlipoproteinämie, Diabetes mellitus, Adipositas, Bewegungsmangel, Stress und hohem Alter wird eine pathophysiologisch erhöhte Bildung reaktiver Sauerstoffspezies (ROS) als Ursache für deren Entstehung diskutiert. NAD(P)H-Oxidasen, von denen 7 Isoformen der katalytischen Nox-Untereinheiten bekannt sind, stellen dabei die Hauptquelle für vaskuläre Superoxidanionen und oxidativen Stress dar. In dieser Arbeit konnte die vorrangige Bedeutung eines intrazellulär lokalisierten Nox4-haltigen NAD(P)H-Oxidase-Komplexes für die konstitutive Radikalbildung in primären humanen Endothelzellen nachgewiesen werden. Weiterhin konnte gezeigt werden, dass durch chronische Applikation der biomechanischen Kräfte Schubspannung und Dehnung oxidativer Stress in humanen Endothelzellen in vitro vermindert werden kann. Die Herabregulation der Superoxidanionen-Bildung sowie die vermehrte Freisetzung von NO durch chronische Applikation biomechanischer Kräfte trägt zur positiven Balance von NO/Superoxidanionen und zum vasoprotektiven Potential physiologischer Schubspannung bzw. Dehnung bei. Durch Nox4-Promotordeletionsanalysen und Mutationsstudien konnte der Transkriptionsfaktor AP-1 als entscheidend für die schubspannungsabhängige Herabregulation von Nox4 identifiziert werden. Durch Stimulation von Endothelzellen bzw. murinen Gefäßringen mit oxidiertem LDL konnte dagegen die vaskuläre ROS-Bildung in vitro und ex vivo induziert werden. Zur weiteren Aufklärung des Mechanismus der LDL-induzierten ROS-Bildung in vivo und des Einflusses von NAD(P)H-Oxidasen wurden C57BL/6 (Wildtyp)- und Nox2-/--Mäuse 10 Wochen lang mit einer fettreichen Diät (Western diet) gefüttert und anschließend der Einfluss dieser Fütterung auf die NAD(P)H-Oxidase-Expression und ROS-Bildung analysiert. In der Aorta thoracalis beider Mausstämme zeigte sich durch das fettreiche Futter ein signifikanter Anstieg der NAD(P)H-Oxidase-Aktivität im Vergleich zum Standardfutter. Durch Western diet-Fütterung wurde die Nox4-mRNA-Expression in der A. thoracalis von Nox2-/--Mäuse und die p22phox-mRNA-Expression in beiden Mausstämmen induziert. Die Analyse weiterer Organe (Herz, Niere) zeigte keine Induktion von NAD(P)H-Oxidase-Untereinheiten durch Western diet-Fütterung. Zusammenfassend sprechen die Ergebnisse der vorliegenden Arbeit für eine entscheidende Rolle der Nox4-haltigen NAD(P)H-Oxidase bei der vaskulären Radikalbildung in vitro und in vivo. / Cardiovascular diseases are the most common causes of death in Germany. Beside the known risk factors hypercholesteremia, hyperlipoproteinemia, diabetes mellitus, obesity, sedentary lifestyle, stress and high age, a pathophysiologically increased formation of reactive oxygen species (ROS) are discussed as cause of development of cardiovascular diseases. Nicotine adenine dinucleotide phosphate (NADPH) oxidase complexes have been identified as main source of oxidative stress and vascular superoxide anions. There are 7 known isoforms of the catalytic Nox subunit of the NADPH oxidase. In this dissertation it was shown that NADPH oxidase subunit Nox4 is the major Nox isoform in human endothelial cells. Nox4 could be localized in the perinuclear space. Overexpression of Nox4 enhanced endothelial superoxide anion formation. Furthermore, a reduction of oxidative stress could be demonstrated by chronic application of the biomechanical forces laminar shear stress and cyclic strain in endothelial cells in vitro. The observed downregulation of superoxide anion formation and upregulation of NO formation by application of biomechanical forces contribute to the positive balance between NO and superoxide anion and the vasoprotective potential of physiological shear stress and cyclic strain. Molecular cloning and functional analysis of the human Nox4 promoter revealed that an AP-1 binding site is essential for downregulation of Nox4 by laminar shear stress. On the other hand stimulation of endothelial cells and murine vessels with oxidized lipids caused an upregulation of vascular ROS production in vitro and ex vivo. In order to examine the mechanism of LDL induced ROS formation and the influence of NADPH oxidase, C57BL/6 (wild-type) and Nox2-/- mice were feed with a diet high in fat and sugar (Western-type diet) for 10 weeks. After feeding, the influence of diet on the expression of NADPH oxidase and ROS production was analyzed in the A. thoracalis. Both mice strains showed a significant upregulation of aortic ROS production in comparison to normal chow. The mRNA expression of aortic Nox4 was induced in Nox2-/- mice. Furthermore, the aortic p22phox mRNA expression was upregulated in both mice strains. The analysis of other organs (heart, kidney) showed no influence of the Western-type diet. In conclusion, the results demonstrate a major role of a Nox4 containing NADPH oxidase in the vascular radical formation in vitro and in vivo.

oxidativer Stress

Endothel

NAD(P)H-Oxidase

reaktive Sauerstoffspezies (ROS)

Schubspannung

Dehnung

oxidierte Lipide

oxidative stress

endothelium

NADPH oxidase

reactive oxygen species

laminar shear stress

cyclic strain

oxidized lipids

ddc:540

rvk:WW 7700

Oxidativer Stress

Endothel

NADH-Oxidase

Reaktive Sauerstoffspezies

Schubspannung

Dehnung

Lipide

Regulation von oxidativem Stress durch biomechanische Kräfte und fettreiche Ernährung im Herz-Kreislaufsystem

Göttsch, Claudia

27 February 2007

Erkrankungen des Herz-Kreislaufsystems sind trotz erheblicher Fortschritte in Diagnostik und Therapie noch immer die häufigste Todesursache in Deutschland. Neben bekannte Risikofaktoren wie Hypercholesterinämie, Hyperlipoproteinämie, Diabetes mellitus, Adipositas, Bewegungsmangel, Stress und hohem Alter wird eine pathophysiologisch erhöhte Bildung reaktiver Sauerstoffspezies (ROS) als Ursache für deren Entstehung diskutiert. NAD(P)H-Oxidasen, von denen 7 Isoformen der katalytischen Nox-Untereinheiten bekannt sind, stellen dabei die Hauptquelle für vaskuläre Superoxidanionen und oxidativen Stress dar. In dieser Arbeit konnte die vorrangige Bedeutung eines intrazellulär lokalisierten Nox4-haltigen NAD(P)H-Oxidase-Komplexes für die konstitutive Radikalbildung in primären humanen Endothelzellen nachgewiesen werden. Weiterhin konnte gezeigt werden, dass durch chronische Applikation der biomechanischen Kräfte Schubspannung und Dehnung oxidativer Stress in humanen Endothelzellen in vitro vermindert werden kann. Die Herabregulation der Superoxidanionen-Bildung sowie die vermehrte Freisetzung von NO durch chronische Applikation biomechanischer Kräfte trägt zur positiven Balance von NO/Superoxidanionen und zum vasoprotektiven Potential physiologischer Schubspannung bzw. Dehnung bei. Durch Nox4-Promotordeletionsanalysen und Mutationsstudien konnte der Transkriptionsfaktor AP-1 als entscheidend für die schubspannungsabhängige Herabregulation von Nox4 identifiziert werden. Durch Stimulation von Endothelzellen bzw. murinen Gefäßringen mit oxidiertem LDL konnte dagegen die vaskuläre ROS-Bildung in vitro und ex vivo induziert werden. Zur weiteren Aufklärung des Mechanismus der LDL-induzierten ROS-Bildung in vivo und des Einflusses von NAD(P)H-Oxidasen wurden C57BL/6 (Wildtyp)- und Nox2-/--Mäuse 10 Wochen lang mit einer fettreichen Diät (Western diet) gefüttert und anschließend der Einfluss dieser Fütterung auf die NAD(P)H-Oxidase-Expression und ROS-Bildung analysiert. In der Aorta thoracalis beider Mausstämme zeigte sich durch das fettreiche Futter ein signifikanter Anstieg der NAD(P)H-Oxidase-Aktivität im Vergleich zum Standardfutter. Durch Western diet-Fütterung wurde die Nox4-mRNA-Expression in der A. thoracalis von Nox2-/--Mäuse und die p22phox-mRNA-Expression in beiden Mausstämmen induziert. Die Analyse weiterer Organe (Herz, Niere) zeigte keine Induktion von NAD(P)H-Oxidase-Untereinheiten durch Western diet-Fütterung. Zusammenfassend sprechen die Ergebnisse der vorliegenden Arbeit für eine entscheidende Rolle der Nox4-haltigen NAD(P)H-Oxidase bei der vaskulären Radikalbildung in vitro und in vivo. / Cardiovascular diseases are the most common causes of death in Germany. Beside the known risk factors hypercholesteremia, hyperlipoproteinemia, diabetes mellitus, obesity, sedentary lifestyle, stress and high age, a pathophysiologically increased formation of reactive oxygen species (ROS) are discussed as cause of development of cardiovascular diseases. Nicotine adenine dinucleotide phosphate (NADPH) oxidase complexes have been identified as main source of oxidative stress and vascular superoxide anions. There are 7 known isoforms of the catalytic Nox subunit of the NADPH oxidase. In this dissertation it was shown that NADPH oxidase subunit Nox4 is the major Nox isoform in human endothelial cells. Nox4 could be localized in the perinuclear space. Overexpression of Nox4 enhanced endothelial superoxide anion formation. Furthermore, a reduction of oxidative stress could be demonstrated by chronic application of the biomechanical forces laminar shear stress and cyclic strain in endothelial cells in vitro. The observed downregulation of superoxide anion formation and upregulation of NO formation by application of biomechanical forces contribute to the positive balance between NO and superoxide anion and the vasoprotective potential of physiological shear stress and cyclic strain. Molecular cloning and functional analysis of the human Nox4 promoter revealed that an AP-1 binding site is essential for downregulation of Nox4 by laminar shear stress. On the other hand stimulation of endothelial cells and murine vessels with oxidized lipids caused an upregulation of vascular ROS production in vitro and ex vivo. In order to examine the mechanism of LDL induced ROS formation and the influence of NADPH oxidase, C57BL/6 (wild-type) and Nox2-/- mice were feed with a diet high in fat and sugar (Western-type diet) for 10 weeks. After feeding, the influence of diet on the expression of NADPH oxidase and ROS production was analyzed in the A. thoracalis. Both mice strains showed a significant upregulation of aortic ROS production in comparison to normal chow. The mRNA expression of aortic Nox4 was induced in Nox2-/- mice. Furthermore, the aortic p22phox mRNA expression was upregulated in both mice strains. The analysis of other organs (heart, kidney) showed no influence of the Western-type diet. In conclusion, the results demonstrate a major role of a Nox4 containing NADPH oxidase in the vascular radical formation in vitro and in vivo.

info:eu-repo/classification/ddc/540

ddc:540