Abstract
Intracellular lipids and their synthesis contribute to the mechanisms and complications of obesity-associated diseases. We describe an NMR approach that provides an abbreviated lipidomic analysis with concurrent lipid biosynthetic fluxes. Following deuterated water administration, positional isotopomer analysis by deuterium NMR of specific lipid species was used to examine flux through de novo lipogenesis (DNL), FA elongation, desaturation, and TG-glycerol synthesis. The NMR method obviated certain assumptions regarding sites of enrichment and exchangeable hydrogens required by mass isotope methods. The approach was responsive to genetic and pharmacological gain or loss of function of DNL, elongation, desaturation, and glyceride synthesis. BDF1 mice consuming a high-fat diet (HFD) or matched low-fat diet for 35 weeks were examined across feeding periods to determine how flux through these pathways contributes to diet induced fatty liver and obesity. HFD mice had increased rates of FA elongation and glyceride synthesis. However DNL was markedly suppressed despite insulin resistance and obesity. We conclude that most hepatic TGs in the liver of HFD mice were formed from the reesterification of existing or ingested lipids, not DNL.
Highlights
Intracellular lipids and their synthesis contribute to the mechanisms and complications of obesity-associated diseases
There was no significant difference in the enrichment of N-Acetyl-para-amino benzoic acid (PABA) when compared with that of body water (Fig. 2)
Despite a 4-fold lower de novo lipogenesis (DNL), glyceride synthesis was increased by 50% and was consistent with the elevated hepatic TG content of high-fat diet (HFD) mice. These data were even more dramatic in adipose, where the percent of new glyceride was increased by 25% and the mass of new TG was elevated 2-fold. These findings indicate that the HFD suppressed DNL and desaturase flux but did not suppress FA elongation and stimulated TG synthesis in BDF1 mice
Summary
Intracellular lipids and their synthesis contribute to the mechanisms and complications of obesity-associated diseases. Nonalcoholic fatty liver disease (NAFLD) is associated with obesity/insulin resistance in humans and is due in part to this elevated de novo lipogenesis (DNL) [6]. Studies in lipogenic flux in obese and insulin-resistant rodent models consuming a high-fat diet (HFD) have found increased [7], no change [8], and decreased lipogenesis [9,10,11]. Journal of Lipid Research Volume 55, 2014 2541 examination of these species, in addition to DNL, is likely important in the context of disease
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