Ketogenesis prevents diet-induced fatty liver injury and hyperglycemia
David G. Cotter, Baris Ercal, Xiaojing Huang, Jamison M. Leid, D. André d’Avignon, Mark J. Graham, Dennis J. Dietzen, Elizabeth M. Brunt, Gary J. Patti, Peter A. Crawford
David G. Cotter, Baris Ercal, Xiaojing Huang, Jamison M. Leid, D. André d’Avignon, Mark J. Graham, Dennis J. Dietzen, Elizabeth M. Brunt, Gary J. Patti, Peter A. Crawford
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Research Article Hepatology

Ketogenesis prevents diet-induced fatty liver injury and hyperglycemia

Abstract

Nonalcoholic fatty liver disease (NAFLD) spectrum disorders affect approximately 1 billion individuals worldwide. However, the drivers of progressive steatohepatitis remain incompletely defined. Ketogenesis can dispose of much of the fat that enters the liver, and dysfunction in this pathway could promote the development of NAFLD. Here, we evaluated mice lacking mitochondrial 3-hydroxymethylglutaryl CoA synthase (HMGCS2) to determine the role of ketogenesis in preventing diet-induced steatohepatitis. Antisense oligonucleotide–induced loss of HMGCS2 in chow-fed adult mice caused mild hyperglycemia, increased hepatic gluconeogenesis from pyruvate, and augmented production of hundreds of hepatic metabolites, a suite of which indicated activation of the de novo lipogenesis pathway. High-fat diet feeding of mice with insufficient ketogenesis resulted in extensive hepatocyte injury and inflammation, decreased glycemia, deranged hepatic TCA cycle intermediate concentrations, and impaired hepatic gluconeogenesis due to sequestration of free coenzyme A (CoASH). Supplementation of the CoASH precursors pantothenic acid and cysteine normalized TCA intermediates and gluconeogenesis in the livers of ketogenesis-insufficient animals. Together, these findings indicate that ketogenesis is a critical regulator of hepatic acyl-CoA metabolism, glucose metabolism, and TCA cycle function in the absorptive state and suggest that ketogenesis may modulate fatty liver disease.

Authors

David G. Cotter, Baris Ercal, Xiaojing Huang, Jamison M. Leid, D. André d’Avignon, Mark J. Graham, Dennis J. Dietzen, Elizabeth M. Brunt, Gary J. Patti, Peter A. Crawford

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Figure 7

Replenishing CoASH precursors restores gluconeogenesis and TCA cycle intermediate abnormalities in the livers of ketogenesis-insufficient mice.

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Replenishing CoASH precursors restores gluconeogenesis and TCA cycle int...
(A) CoASH (pmol/mg tissue) concentrations in the livers of unperfused standard chow diet–fed ASO-treated mice or in livers perfused with the indicated substrates. n = 3–8/group. (B) Pantothenate kinase 1a and 1b (Pank1a and Pank1b) relative mRNA abundance in the livers of standard chow diet–fed ASO-treated mice. n = 8–10/group. (C) Gluconeogenesis in perfused livers of standard chow diet–fed ASO-treated mice perfused with either [13C]lactate, [13C]pyruvate, octanoic acid, cysteine, and pantothenic acid for 15 minutes (Preperfusion) or preperfused with CoASH precursors for 45 minutes with unlabeled lactate, pyruvate, cysteine, and pantothenic acid followed by 15 minutes of perfusion with [13C]lactate, [13C]pyruvate, octanoic acid, cysteine, and pantothenic acid. (D) α-KG (nmol/mg tissue), (E) glutamate (nmol/mg tissue), (F) succinate (pmol/mg tissue), and (G) CoASH (pmol/mg tissue) concentrations in the same livers as in C. n = 5–7/group. *P < 0.05, **P < 0.01, ***P < 0.001, by 2-way ANOVA.