Inhibition of sarcolemmal FAT/CD36 by sulfo-N-succinimidyl oleate rapidly corrects metabolism and restores function in the diabetic heart following hypoxia/reoxygenation

Mansor, Latt Shahril; Fialho, Maria da Luz Sousa; Yea, G; Coumans, Will A.; West, James A.; Kerr, Matthew; Carr, Carolyn A.; Luiken, Joost J. F. P.; Glatz, Jan F. C.; Evans, Rhys; Griffin, Julian L.; Tyler, Damian J.; Clarke, Kieran; Heather, Lisa C.

doi:10.1093/cvr/cvx045

Cited by 53 publications

(69 citation statements)

References 54 publications

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“…Some authors speculate that the upregulation of the nuclear receptor transcription factor PPARα and its coactivators PGC-1α/β is one of the preliminary requirements for metabolic switch from glucose to FA consumption in IR and diabetic hearts (Schilling, 2015 ; Lee et al, 2017 ). This agrees with an increased level of PPARα as well as the total (+38%) and sarcolemmal (+26%) FAT/CD36 content in the diabetic animal hearts (Mansor et al, 2017 ). On the contrary, lowered PGC-1α expression was observed in diabetic human blood and myocardium (Fabregat-Andres et al, 2016 ) as well as in the animal models of T2DM (ob/ob mice) and diabetic dyslipidemia (db/db mice) (Buchanan et al, 2005 ).…”

Section: Fatty Acid Transporter Proteinssupporting

confidence: 80%

“…Interestingly, PPARα and FAT/CD36 deficient mice [α-myosin heavy chain (MHC)-PPARα/CD36 −/− ] were not only protected from lipid imbalance in the myocardium, but also demonstrated an enhanced glucose uptake and FATP1 gene expression (Yang et al, 2007 ). Nevertheless, direct inhibition of plasma membrane FAT/CD36 by sulfo-N-succinimidyl oleate was sufficient to restore normal substrate metabolism and prevent lipotoxicity (Mansor et al, 2017 ). PPARγ overexpression in transgenic mice contributed to cardiac dysfunction encompassing an increase in FAT/CD36 level, FA uptake and intracellular lipid accumulation with rosiglitazone treatment even aggravating the lipotoxic effects.…”

Section: Fatty Acid Transporter Proteinsmentioning

confidence: 99%

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The Implication of PGC-1α on Fatty Acid Transport across Plasma and Mitochondrial Membranes in the Insulin Sensitive Tissues

2017

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PGC-1α coactivator plays a decisive role in the maintenance of lipid balance via engagement in numerous metabolic processes (i.e., Krebs cycle, β-oxidation, oxidative phosphorylation and electron transport chain). It constitutes a link between fatty acids import and their complete oxidation or conversion into bioactive fractions through the coordination of both the expression and subcellular relocation of the proteins involved in fatty acid transmembrane movement. Studies on cell lines and/or animal models highlighted the existence of an upregulation of the total and mitochondrial FAT/CD36, FABPpm and FATPs content in skeletal muscle in response to PGC-1α stimulation. On the other hand, the association between PGC-1α level or activity and the fatty acids transport in the heart and adipocytes is still elusive. So far, the effects of PGC-1α on the total and sarcolemmal expression of FAT/CD36, FATP1, and FABPpm in cardiomyocytes have been shown to vary in relation to the type of PPAR that was coactivated. In brown adipose tissue (BAT) PGC-1α knockdown was linked with a decreased level of lipid metabolizing enzymes and fatty acid transporters (FAT/CD36, FABP3), whereas the results obtained for white adipose tissue (WAT) remain contradictory. Furthermore, dysregulation in lipid turnover is often associated with insulin intolerance, which suggests the coactivator's potential role as a therapeutic target.

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Section: Fatty Acid Transporter Proteinssupporting

confidence: 80%

Section: Fatty Acid Transporter Proteinsmentioning

confidence: 99%

The Implication of PGC-1α on Fatty Acid Transport across Plasma and Mitochondrial Membranes in the Insulin Sensitive Tissues

2017

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“…The rats were housed in a 12:12 hour light/dark cycle in animal facilities at the University of Oxford. A model of Type II diabetes mellitus (T2DM) characterized by hyperglycaemia, hyperinsulinemia and hyperlipidaemia was induced based on a previously published protocol . Briefly, 24 age‐matched female Wistar rats (11 weeks of age at start of study) were divided into two groups: a control group receiving normal chow (12% calories from fat, 22% from protein and 66% from carbohydrates) and a T2DM group receiving a high fat diet for nine weeks (60% calories from fat, 35% from protein, 5% from carbohydrate).…”

Section: Methodsmentioning

confidence: 99%

Assessing the optimal preparation strategy to minimize the variability of cardiac pyruvate dehydrogenase flux measurements with hyperpolarized MRS

Timm¹,

Apps

Miller

et al. 2018

NMR in Biomedicine

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Hyperpolarized [1‐13C] pyruvate MRS can measure cardiac pyruvate dehydrogenase (PDH) flux in vivo through 13C‐label incorporation into bicarbonate. Using this technology, substrate availability as well as pathology have been shown to modulate PDH flux. Clinical protocols attempt to standardize PDH flux with oral glucose loading prior to scanning, while rodents in preclinical studies are usually scanned in the fed state. We aimed to establish which strategy was optimal to maximize PDH flux and minimize its variability in both control and Type II diabetic rats, without affecting the pathological variation being assessed. We found similar variances in the bicarbonate to pyruvate ratio, reflecting PDH flux, in fed and fasted/glucose‐loaded animals, which showed no statistically significant differences. Furthermore, fasting/glucose loading did not alter the low PDH flux seen in Type II diabetic rats. Overall this suggests that preclinical cardiac hyperpolarized magnetic resonance studies could be performed either in the fed or in the fasted/glucose‐loaded state. Centres planning to start new clinical studies with cardiac hyperpolarized magnetic resonance in man may find it beneficial to run small proof‐of‐concept trials to determine whether metabolic standardizations by oral or intravenous glucose load are beneficial compared with scanning patients in the fed state.

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“…By down‐regulating CD36 expression and by triggering internalization of CD36, vitamin E can reduce the accumulation of intracellular lipids and contribute to the protective effects of αT and αTP against lipotoxicity occurring during high‐fat induced development of atherosclerosis, inflammation, obesity, NASH, and the metabolic syndrome (Fig. ) . The activation of CD36 can affect a variety of metabolic functions relevant for lipid homeostasis, as demonstrate with the growth hormone releasing peptides hexarelin that regulates LXRα, PGC1α/PPARγ, INSIG1/2, and fatty acid metabolic enzymes in monocytes/macrophages, liver and adipose tissue .…”

Section: Modulation Of Cd36/fat Scavenger Receptor/fatty Acids Transpmentioning

confidence: 99%

Vitamin E: Regulatory Role on Signal Transduction

Zingg

2018

IUBMB Life

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Vitamin E modulates signal transduction pathways by several molecular mechanisms. As a hydrophobic molecule located mainly in membranes it contributes together with other lipids to the physical and structural characteristics such as membrane stability, curvature, fluidity, and the organization into microdomains (lipid rafts). By acting as the main lipid‐soluble antioxidant, it protects other lipids such as mono‐ and poly‐unsaturated fatty acids (MUFA and PUFA, respectively) against chemical reactions with reactive oxygen and nitrogen species (ROS and RNS, respectively) and prevents membrane destabilization and cellular dysfunction. In cells, vitamin E affects signaling in redox‐dependent and redox‐independent molecular mechanisms by influencing the activity of enzymes and receptors involved in modulating specific signal transduction and gene expression pathways. By protecting and preventing depletion of MUFA and PUFA it indirectly enables regulatory effects that are mediated by the numerous lipid mediators derived from these lipids. In recent years, some vitamin E metabolites have been observed to affect signal transduction and gene expression and their relevance for the regulatory function of vitamin E is beginning to be elucidated. In particular, the modulation of the CD36/FAT scavenger receptor/fatty acids transporter by vitamin E may influence many cellular signaling pathways relevant for lipid homeostasis, inflammation, survival/apoptosis, angiogenesis, tumorigenesis, neurodegeneration, and senescence. Thus, vitamin E has an important role in modulating signal transduction and gene expression pathways relevant for its uptake, distribution, metabolism, and molecular action that when impaired affect physiological and patho‐physiological cellular functions relevant for the prevention of a number of diseases. © 2018 IUBMB Life, 71(4):456–478, 2019

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Inhibition of sarcolemmal FAT/CD36 by sulfo-N-succinimidyl oleate rapidly corrects metabolism and restores function in the diabetic heart following hypoxia/reoxygenation

Cited by 53 publications

References 54 publications

The Implication of PGC-1α on Fatty Acid Transport across Plasma and Mitochondrial Membranes in the Insulin Sensitive Tissues

The Implication of PGC-1α on Fatty Acid Transport across Plasma and Mitochondrial Membranes in the Insulin Sensitive Tissues

Assessing the optimal preparation strategy to minimize the variability of cardiac pyruvate dehydrogenase flux measurements with hyperpolarized MRS

Vitamin E: Regulatory Role on Signal Transduction

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