Dietary dicarboxylic acids provide a nonstorable alternative fat source that protects mice against obesity
Eric S. Goetzman, … , Steven F. Dobrowolski, Birgit Schilling
Eric S. Goetzman, … , Steven F. Dobrowolski, Birgit Schilling
Published April 30, 2024
Citation Information: J Clin Invest. 2024;134(12):e174186. https://doi.org/10.1172/JCI174186.
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Dietary dicarboxylic acids provide a nonstorable alternative fat source that protects mice against obesity

Abstract

Dicarboxylic fatty acids are generated in the liver and kidney in a minor pathway called fatty acid ω-oxidation. The effects of consuming dicarboxylic fatty acids as an alternative source of dietary fat have not been explored. Here, we fed dodecanedioic acid, a 12-carbon dicarboxylic (DC12), to mice at 20% of daily caloric intake for 9 weeks. DC12 increased metabolic rate, reduced body fat, reduced liver fat, and improved glucose tolerance. We observed DC12-specific breakdown products in liver, kidney, muscle, heart, and brain, indicating that oral DC12 escaped first-pass liver metabolism and was utilized by many tissues. In tissues expressing the “a” isoform of acyl-CoA oxidase-1 (ACOX1), a key peroxisomal fatty acid oxidation enzyme, DC12 was chain shortened to the TCA cycle intermediate succinyl-CoA. In tissues with low peroxisomal fatty acid oxidation capacity, DC12 was oxidized by mitochondria. In vitro, DC12 was catabolized even by adipose tissue and was not stored intracellularly. We conclude that DC12 and other dicarboxylic acids may be useful for combatting obesity and for treating metabolic disorders.

Authors

Eric S. Goetzman, Bob B. Zhang, Yuxun Zhang, Sivakama S. Bharathi, Joanna Bons, Jacob Rose, Samah Shah, Keaton J. Solo, Alexandra V. Schmidt, Adam C. Richert, Steven J. Mullett, Stacy L. Gelhaus, Krithika S. Rao, Sruti S. Shiva, Katherine E. Pfister, Anne Silva Barbosa, Sunder Sims-Lucas, Steven F. Dobrowolski, Birgit Schilling

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Figure 10

Metabolic efficiency of DC12 oxidation.

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Metabolic efficiency of DC12 oxidation. (A) The theoretical yield of ATP...
(A) The theoretical yield of ATP from oxidizing monocarboxylic C12 through the mitochondrial FAO pathway and TCA cycle. Activation of fatty acids to CoA converts ATP to AMP, which is the energetic equivalent of 2 ATP (shown in red font). (B) Oxidizing DC12 through mitochondria yields a remnant succinate molecule, and less acetyl-CoA, FADH, and NADH. Therefore, the ATP yield is 23% lower than for C12 through the same pathway (60 versus 78). Finally, (C) oxidizing DC12 through peroxisomes, then passing the succinate, acetate, and NADH into mitochondria for complete oxidation requires a much greater cost of fatty acid activation, since each acetate must be activated to CoA at the cost of 2 ATP. The result is a nearly 50% reduction in net ATP compared with C12 in panel A. Image created with BioRender.com.