Impaired ketogenesis and increased acetyl-CoA oxidation promote hyperglycemia in human fatty liver
Justin A. Fletcher, Stanisław Deja, Santhosh Satapati, Xiaorong Fu, Shawn C. Burgess, Jeffrey D. Browning
Justin A. Fletcher, Stanisław Deja, Santhosh Satapati, Xiaorong Fu, Shawn C. Burgess, Jeffrey D. Browning
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Research Article Hepatology Metabolism

Impaired ketogenesis and increased acetyl-CoA oxidation promote hyperglycemia in human fatty liver

Abstract

Nonalcoholic fatty liver disease (NAFLD) is a highly prevalent, and potentially morbid, disease that affects one-third of the US population. Normal liver safely accommodates lipid excess during fasting or carbohydrate restriction by increasing their oxidation to acetyl-CoA and ketones, yet lipid excess during NAFLD leads to hyperglycemia and, in some, steatohepatitis. To examine potential mechanisms, we studied flux through pathways of hepatic oxidative metabolism and gluconeogenesis using 5 simultaneous stable isotope tracers in ketotic (24-hour-fasted) individuals with a wide range of hepatic triglyceride content levels (0%–52%). Ketogenesis was progressively impaired as hepatic steatosis and glycemia worsened. Conversely, the alternative pathway for acetyl-CoA metabolism, oxidation in the tricarboxylic acid (TCA) cycle, was upregulated in NAFLD as ketone production diminished and positively correlated with rates of gluconeogenesis and plasma glucose concentrations. Increased respiration and energy generation that occurred in liver when β-oxidation and TCA cycle activity were coupled may explain these findings, inasmuch as calculated hepatic oxygen consumption was higher during fatty liver and highly correlated with gluconeogenesis. These findings demonstrate that increased glucose production and hyperglycemia in NAFLD is a consequence not of acetyl-CoA production per se, but rather of how acetyl-CoA is further metabolized in liver.

Authors

Justin A. Fletcher, Stanisław Deja, Santhosh Satapati, Xiaorong Fu, Shawn C. Burgess, Jeffrey D. Browning

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Figure 1

Hepatic TG content, insulin sensitivity, and biochemical response to a 24-hour fast.

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Hepatic TG content, insulin sensitivity, and biochemical response to a 2...
(A) Hepatic TG content was measured by 1H-MRS and is shown by rank (range: 0%–52%; n = 40). (B) Using a hepatic TG cutoff of 5%, the population was dichotomized into control (n = 17) and NAFLD (n = 24) groups. The NAFLD group was further separated into tertiles of liver fat, with tertiles 1–3 having mean hepatic TG content of 6% ± 1% (n = 7), 13% ± 2% (n = 8), and 30% ± 4% (n = 8), respectively (P < 0.004). (C) Mean glucose disposal rates (M value) during H-E clamp were significantly lower in the NAFLD group (n = 20), consistent with insulin resistance. (D) Respiratory quotients were similar in control (n = 15) and NAFLD (n = 20) subjects and declined from 12 (left bars) to 24 hours (right bars) of fasting, consistent with fasting physiology. (E) Plasma glucose concentrations at 12 and 24 hours of fasting were higher in NAFLD subjects (n = 22) compared with controls (n = 16) and declined in both groups as the fasting duration increased. (F) Plasma insulin and (G) glucagon concentrations as well as (H) glucagon/insulin ratio at 12 and 24 hours of fasting are shown for control (n = 15) and NAFLD (n = 19) subjects. Fasting changes in concentrations of plasma insulin and glucagon, as well as the glucagon/insulin ratio, were observed in both groups; however, insulin was consistently higher, and glucagon/insulin ratio lower, among NAFLD subjects. Plasma concentrations of glucose, insulin, and glucagon were similar among the tertiles of liver fat. Significance was determined using 2-tailed Student’s t test for paired and unpaired data and 1-way ANOVA and 2-way repeated-measures ANOVA when appropriate.