The Ketogenic Diet and Brain Metabolism of Amino Acids: Relationship to the Anticonvulsant Effect

Yudkoff, Marc; Daikhin, Yevgeny; Melø, Torun M; Nissim, Ilana; Sonnewald, Ursula; Nissim, Itzhak

doi:10.1146/annurev.nutr.27.061406.093722

Cited by 165 publications

(142 citation statements)

References 138 publications

(121 reference statements)

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“…29 Particularly, GABA C3 and C4 contained a doublet (D3,4) that derives from glutamate labeled in carbons 2,3 and in carbons 1,2 and 3. Although this labeling pattern is consistent with metabolism of [5,6,[7][8][9][10][11][12][13] C 3 ]heptanoate to [1,2,3-13 C 3 ]propionyl-CoA followed by entry into the TCA cycle, the identical pattern could occur as a consequence of carboxylation of [1,2,3-13 C 3 ]pyruvate derived from glucose.…”

Section: C-nuclear Magnetic Resonance Spectrasupporting

confidence: 51%

“…However, the spectra of glutamate (specifically, the doublet due to J 45 ) demonstrates that pyruvate in the brain was multiply labeled. Therefore, an alternative interpretation of both the 13 C-NMR spectra in Figure 3 and the mass spectrometry observations is simply that 13 The measured 13 C enrichment in plasma glucose shown in Figure 2 fixes the upper limit on the amount of either [2,[3][4][5][6][7][8][9][10][11][12][13] C]pyruvate or [1,2,3-13 C]pyruvate that can be present in the brain (as these are the two labeling patterns that can be metabolized to [1,2-13 C 2 ]acetyl-CoA).…”

Section: C-nuclear Magnetic Resonance Spectramentioning

confidence: 97%

“…Mass isotopomers of 13 C-glucose in plasma. Plasma 13 Cglucose was enriched from [5,6,[7][8][9][10][11][12][13] C 3 ]heptanoate in both normal and mutant (glucose transporter type I deficiency, G1D) animal groups. Data were corrected for the natural abundance of 13 C. Glucose was mostly enriched in M þ 2 (Control: 4.63%±1.5%; G1D: 5.28%±1.22%) and M þ 3 (Control: 3.65%±0.86%; G1D: 3.45%±0.69%).…”

Section: C-nuclear Magnetic Resonance Spectramentioning

confidence: 99%

“…In this work, we sought to characterize the metabolism of [5,6,7-13 C 3 ]heptanoate in the brain of normal conscious mice and of a transgenic antisense mouse model of G1D that exhibits the common epileptic phenotype typical of the human glucose transporter defect. 14 Administration of heptanoate labeled in this fashion is followed by oxidation of [5,6,7-13 C 3 ]heptanoate or [3,4,[5][6][7][8][9][10][11][12][13] C 3 ]C5-ketone derivatives in the brain without generation of [1,2-13 C 2 ]acetyl-CoA, and, consequently, without enrichment of carbons 4 or 5 of glutamine or glutamate. Using this approach, we demonstrate that plasma glucose becomes enriched with 13 C in the presence of intravenously infused [5,6,7-13 C 3 ]heptanoate as expected, indicating that the understanding of any effects of heptanoate therapy must consider its effects on glucose production.…”

Section: Introductionmentioning

confidence: 99%

“…In patients with glucose transporter type I deficiency (G1D), ketogenic diet fat (a source only of acetyl-CoA) reduces seizures, but other symptoms persist, providing the motivation for studying heptanoate metabolism. In this work, metabolism of infused [5,6,[7][8][9][10][11][12][13] C 3 ]heptanoate was examined in the normal mouse brain and in G1D by 13 C-nuclear magnetic resonance spectroscopy, gas chromatography-mass spectrometry (GC-MS), and liquid chromatography-mass spectrometry (LC-MS). In both groups, plasma glucose was enriched in 13 C, confirming gluconeogenesis from heptanoate.…”

mentioning

confidence: 99%

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Heptanoate as a Neural Fuel: Energetic and Neurotransmitter Precursors in Normal and Glucose Transporter I-Deficient (G1D) Brain

Marin‐Valencia

Good

Qian

et al. 2012

J Cereb Blood Flow Metab

128

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It has been postulated that triheptanoin can ameliorate seizures by supplying the tricarboxylic acid cycle with both acetyl-CoA for energy production and propionyl-CoA to replenish cycle intermediates. These potential effects may also be important in other disorders associated with impaired glucose metabolism because glucose supplies, in addition to acetyl-CoA, pyruvate, which fulfills biosynthetic demands via carboxylation. In patients with glucose transporter type I deficiency (G1D), ketogenic diet fat (a source only of acetyl-CoA) reduces seizures, but other symptoms persist, providing the motivation for studying heptanoate metabolism. In this work, metabolism of infused [5,6,[7][8][9][10][11][12][13] C 3 ]heptanoate was examined in the normal mouse brain and in G1D by 13 C-nuclear magnetic resonance spectroscopy, gas chromatography-mass spectrometry (GC-MS), and liquid chromatography-mass spectrometry (LC-MS). In both groups, plasma glucose was enriched in 13 C, confirming gluconeogenesis from heptanoate. Acetyl-CoA and glutamine levels became significantly higher in the brain of G1D mice relative to normal mice. In addition, brain glutamine concentration and 13 C enrichment were also greater when compared with glutamate in both animal groups, suggesting that heptanoate and/or C5 ketones are primarily metabolized by glia. These results enlighten the mechanism of heptanoate metabolism in the normal and glucosedeficient brain and encourage further studies to elucidate its potential antiepileptic effects in disorders of energy metabolism.

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Section: C-nuclear Magnetic Resonance Spectrasupporting

confidence: 51%

Section: C-nuclear Magnetic Resonance Spectramentioning

confidence: 97%

Section: C-nuclear Magnetic Resonance Spectramentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

See 3 more Smart Citations

Heptanoate as a Neural Fuel: Energetic and Neurotransmitter Precursors in Normal and Glucose Transporter I-Deficient (G1D) Brain

Marin‐Valencia

Good

Qian

et al. 2012

J Cereb Blood Flow Metab

128

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Triheptanoin for Glucose Transporter Type I Deficiency (G1D)

et al. 2014

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IMPORTANCE Disorders of brain metabolism are multiform in their mechanisms and manifestations, many of which remain insufficiently understood and are thus similarly treated. Glucose transporter type I deficiency (G1D) is commonly associated with seizures and with electrographic spike-waves. The G1D syndrome has long been attributed to energy (ie, adenosine triphosphate synthetic) failure such as that consequent to tricarboxylic acid (TCA) cycle intermediate depletion. Indeed, glucose and other substrates generate TCAs via anaplerosis. However, TCAs are preserved in murine G1D, rendering energy-failure inferences premature and suggesting a different hypothesis, also grounded on our work, that consumption of alternate TCA precursors is stimulated and may be detrimental. Second, common ketogenic diets lead to a therapeutically counterintuitive reduction in blood glucose available to the G1D brain and prove ineffective in one-third of patients.OBJECTIVE To identify the most helpful outcomes for treatment evaluation and to uphold (rather than diminish) blood glucose concentration and stimulate the TCA cycle, including anaplerosis, in G1D using the medium-chain, food-grade triglyceride triheptanoin. DESIGN, SETTING, AND PARTICIPANTSUnsponsored, open-label cases series conducted in an academic setting. Fourteen children and adults with G1D who were not receiving a ketogenic diet were selected on a first-come, first-enrolled basis.INTERVENTION Supplementation of the regular diet with food-grade triheptanoin. MAIN OUTCOMES AND MEASURESFirst, we show that, regardless of electroencephalographic spike-waves, most seizures are rarely visible, such that perceptions by patients or others are inadequate for treatment evaluation. Thus, we used quantitative electroencephalographic, neuropsychological, blood analytical, and magnetic resonance imaging cerebral metabolic rate measurements.RESULTS One participant (7%) did not manifest spike-waves; however, spike-waves promptly decreased by 70% (P = .001) in the other participants after consumption of triheptanoin. In addition, the neuropsychological performance and cerebral metabolic rate increased in most patients. Eleven patients (78%) had no adverse effects after prolonged use of triheptanoin. Three patients (21%) experienced gastrointestinal symptoms, and 1 (7%) discontinued the use of triheptanoin. CONCLUSIONS AND RELEVANCETriheptanoin can favorably influence cardinal aspects of neural function in G1D. In addition, our outcome measures constitute an important framework for the evaluation of therapies for encephalopathies associated with impaired intermediary metabolism.

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Metabolic Management of Cancer

Seyfried¹

2012

Cancer as a Metabolic Disease

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The Ketogenic Diet and Brain Metabolism of Amino Acids: Relationship to the Anticonvulsant Effect

Cited by 165 publications

References 138 publications

Heptanoate as a Neural Fuel: Energetic and Neurotransmitter Precursors in Normal and Glucose Transporter I-Deficient (G1D) Brain

Heptanoate as a Neural Fuel: Energetic and Neurotransmitter Precursors in Normal and Glucose Transporter I-Deficient (G1D) Brain

Triheptanoin for Glucose Transporter Type I Deficiency (G1D)

Metabolic Management of Cancer

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