Hyperpolarized ketone body metabolism in the rat heart

Miller, Jack J.; Ball, Daniel R.; Lau, Angus Z.; Tyler, Damian J.

doi:10.1002/nbm.3912

Cited by 25 publications

(37 citation statements)

References 41 publications

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“…HP 13 C-AcAc was first reported as an imaging probe by Jensen et al 43 In that study, ethyl [1,[3][4][5][6][7][8][9][10][11][12][13] 44 This study demonstrated that metabolism of HP 13 C-ketones can be detected in the heart, and several downstream metabolites of the HP 13 C-agents were observed. We first reported with preliminary results that it is possible to correlate altered mitochondrial redox in perfused rat hearts with the production of HP-β-HB from HP-AcAc.…”

Section: Discussionmentioning

confidence: 87%

“…HP 13 C‐AcAc was first reported as an imaging probe by Jensen et al In that study, ethyl [1,3‐ 13 C]AcAc was used as a marker for decreased esterase activity in liver tumors but HP‐β‐HB was not detected. Recently, Miller et al investigated the metabolism of HP‐[1‐ 13 C]AcAc and HP[1‐ 13 C]β‐HB in isolated, perfused rat hearts as well as in vivo . This study demonstrated that metabolism of HP 13 C‐ketones can be detected in the heart, and several downstream metabolites of the HP 13 C‐agents were observed.…”

Section: Discussionmentioning

confidence: 99%

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Metabolism of hyperpolarized ¹³C‐acetoacetate to β‐hydroxybutyrate detects real‐time mitochondrial redox state and dysfunction in heart tissue

et al. 2019

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Mitochondrial dysfunction is considered to be an important component of many metabolic diseases yet there is no reliable imaging biomarker for monitoring mitochondrial damage in vivo. A large prior literature on inter‐conversion of β‐hydroxybutyrate and acetoacetate indicates that the process is mitochondrial and that the ratio reflects a specifically mitochondrial redox state. Therefore, the conversion of [1,3‐13C]acetoacetate to [1,3‐13C]β‐hydroxybutyrate is expected to be sensitive to the abnormal redox state present in dysfunctional mitochondria. In this study, we examined the conversion of hyperpolarized (HP) 13C‐acetoacetate (AcAc) to 13C‐β‐hydroxybutyrate (β‐HB) as a potential imaging biomarker for mitochondrial redox and dysfunction in perfused rat hearts. Conversion of HP‐AcAc to β‐HB was investigated using 13C magnetic resonance spectroscopy in Langendorff‐perfused rat hearts in four groups: control, global ischemic reperfusion, low‐flow ischemic, and rotenone (mitochondrial complex‐I inhibitor)‐treated hearts. We observed that more β‐HB was produced from AcAc in ischemic hearts and the hearts exposed to complex I inhibitor rotenone compared with controls, consistent with the accumulation of excess mitochondrial NADH. The increase in β‐HB, as detected by 13C MRS, was validated by a direct measure of tissue β‐HB by 1H nuclear magnetic resonance in tissue extracts. The redox ratio, NAD+/NADH, measured by enzyme assays of homogenized tissue, also paralleled production of β‐HB from AcAc. Transmission electron microscopy of tissues provided direct evidence for abnormal mitochondrial structure in each ischemic tissue model. The results suggest that conversion of HP‐AcAc to HP‐β‐HB detected by 13C‐MRS may serve as a useful diagnostic marker of mitochondrial redox and dysfunction in heart tissue in vivo.

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Section: Discussionmentioning

confidence: 87%

Section: Discussionmentioning

confidence: 99%

Metabolism of hyperpolarized ¹³C‐acetoacetate to β‐hydroxybutyrate detects real‐time mitochondrial redox state and dysfunction in heart tissue

et al. 2019

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“…Using [3‐ 13 C]acetoacetate, we were also able to observe [3‐ 13 C]β‐OHB, in which the ratio of β‐OHB to acetoacetate can be used as a measure of redox state . The amplitude of [3‐ 13 C]β‐OHB, however, appeared to be an order smaller compared with the amplitude of [1‐ 13 C]β‐OHB in the study of Miller et al, which may be attributed to the lower T 1 of [3‐ 13 C]β‐OHB as well as the diabetic state of the GK rats compared with healthy rats. In the study of ketone body metabolism, hyperpolarized 13 C β‐OHB probe may be preferable as β‐OHB is the primary circulating ketone body.…”

Section: Discussionmentioning

confidence: 62%

“…Other hyperpolarized acetoacetate probes have also been reported (i.e. [1‐ 13 C]acetoacetate and [1,3‐ 13 C 2 ]acetoacetate) . Compared to [1‐ 13 C]acetoacetate, [3‐ 13 C]acetoacetate has the advantage of having the chemical shift downfield, away from the chemical shift of metabolic products, which allows more accurate quantification.…”

Section: Discussionmentioning

confidence: 99%

Cardiac metabolic modulation upon low‐carbohydrate low‐protein ketogenic diet in diabetic rats studied in vivo using hyperpolarized ¹³C pyruvate, butyrate and acetoacetate probes

Abdurrachim

Teo

Woo

et al. 2019

Diabetes Obesity Metabolism

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Aim: To investigate the effects of long-term low-carbohydrate low-protein ketogenic diet (KD) on cardiac metabolism and diabetic cardiomyopathy status in lean diabetic Goto-Kakizaki (GK) rats.Materials and Methods: Diabetic GK rats were fed with KD for 62 weeks. Cardiac function and metabolism were assessed using magnetic resonance imaging and 13 C magnetic resonance spectroscopy ( 13 C-MRS), at rest and under dobutamine stress. 13 C-MRS was performed following injection of hyperpolarized [3-13 C]acetoacetate, [1-13 C]butyrate or [1-13 C]pyruvate to assess ketone body, short-chain fatty acid or glucose utilization, respectively. Protein expression and cardiomyocyte structure were determined via Western blotting and histology, respectively.Results: KD lowered blood glucose, triglyceride and insulin levels while increasing blood ketone body levels. In KD-fed diabetic rats, myocardial ketone body and glucose oxidation were lower than in chow-fed diabetic rats, while myocardial glycolysis and short-chain fatty acid oxidation were unaltered. Dobutamine stress revealed an increased cardiac preload and reduced cardiac compliance in KD-fed diabetic rats. Dobutamine-induced stimulation of myocardial glycolysis was more enhanced in KD-fed diabetic rats than in chow-fed diabetic rats, which was potentially facilitated via an upregulation in basal expression of proteins involved in glucose transport and glycolysis in the hearts of KDfed rats. The metabolic profile induced by KD was accompanied by cardiac hypertrophy, a trend for increased myocardial lipid and collagen content, and an increased marker of oxidative stress.Conclusion: KD seems to exacerbate diabetic cardiomyopathy in GK rats, which may be associated with maladaptive cardiac metabolic modulation and lipotoxicity. K E Y W O R D S13 C magnetic resonance spectroscopy, diabetes, hyperpolarized 13 C substrates, ketogenic diet, myocardial substrate metabolism

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“…γ-glutamyl-[1-13 C]glycine fits the essential technical requirements of a useful HP probe 24 . Thanks to localization of the GGT enzyme on the outer surface of the cell membrane, γ-glutamyl-[1-13 C]glycine metabolism occurs in the extracellular space and not in the cytosol or mitochondria as is the case for most HP probes including HP [1-13 C]pyruvate 24 and [1-13 C]dehydroascorbic acid (DHA) 34,35 , or [1,3-13 C]acetoacetate [36][37][38] , respectively. This is a significant advantage as additional transport though the cell membrane would increase the time between HP injection and enzymatic reaction and therefore decrease SNR.…”

Section: Discussionmentioning

confidence: 99%

In vivo detection of γ-glutamyl-transferase up-regulation in glioma using hyperpolarized γ-glutamyl-[1-13C]glycine

Batsios

Najac

Cao

et al. 2020

Sci Rep

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Glutathione (GSH) is often upregulated in cancer, where it serves to mitigate oxidative stress. γ-glutamyl-transferase (GGT) is a key enzyme in GSH homeostasis, and compared to normal brain its expression is elevated in tumors, including in primary glioblastoma. GGT is therefore an attractive imaging target for detection of glioblastoma. The goal of our study was to assess the value of hyperpolarized (HP) γ-glutamyl-[1-13 C]glycine for non-invasive imaging of glioblastoma. Nude rats bearing orthotopic U87 glioblastoma and healthy controls were investigated. Imaging was performed by injecting HP γ-glutamyl-[1-13 c]glycine and acquiring dynamic 13 C data on a preclinical 3T MR scanner. The signal-to-noise (SNR) ratios of γ-glutamyl-[1-13 C]glycine and its product [1-13 c]glycine were evaluated. Comparison of control and tumor-bearing rats showed no difference in γ-glutamyl-[1-13 C]glycine SNR, pointing to similar delivery to tumor and normal brain. In contrast, [1-13 c]glycine SnR was significantly higher in tumor-bearing rats compared to controls, and in tumor regions compared to normal-appearing brain. Importantly, higher [1-13 C]glycine was associated with higher GGT expression and higher GSH levels in tumor tissue compared to normal brain. Collectively, this study demonstrates, to our knowledge for the first time, the feasibility of using HP γ-glutamyl-[1-13 c]glycine to monitor GGt expression in the brain and thus to detect glioblastoma.Redox homeostasis is essential for managing oxidative stress and ensuring cell survival. Cancer cells, in particular, are often characterized by high levels of oxidative stress. This oxidative stress is the result of reactive oxygen species (ROS) that accumulate due to a variety of factors, including rapid cell proliferation, hypoxia, metabolic reprogramming and oncogenic signaling. The tripeptide glutathione (L-γ-glutamyl-L-cysteinyl-glycine, GSH) is the most abundant, non-enzymatic antioxidant molecule present in mammalian cells and plays a crucial role in regulating tumor oxidative stress due to its role in reducing ROS 1,2 . Several tumor types, including primary glioblastomas (GBMs), are characterized by elevated GSH levels, especially under hypoxic conditions 3 . Elevated GSH levels and reduced oxidative stress have also been linked to resistance to chemotherapy in GBMs 4 .GSH import is a critical step in the maintenance of both intracellular and extracellular redox status 5,6 . Although GSH can be transported out of cells and into the extracellular environment, most cells are incapable of importing intact GSH 7 . Instead, GSH is first degraded to its constituent amino acids 7,8 and the released amino acids are then transported into the cell and used as substrates for de novo GSH synthesis 6 . Specifically, GSH degradation is initiated by cleavage of the gamma-glutamyl bond 9 via the cell surface-bound glycoprotein gamma-glutamyl transpeptidase (GGT) whose catalytic site faces the extracellular environment 7,10-12 . After removal of the glutamyl group from GSH, cysteinylg...

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Hyperpolarized ketone body metabolism in the rat heart

Cited by 25 publications

References 41 publications

Metabolism of hyperpolarized ¹³C‐acetoacetate to β‐hydroxybutyrate detects real‐time mitochondrial redox state and dysfunction in heart tissue

Metabolism of hyperpolarized ¹³C‐acetoacetate to β‐hydroxybutyrate detects real‐time mitochondrial redox state and dysfunction in heart tissue

Cardiac metabolic modulation upon low‐carbohydrate low‐protein ketogenic diet in diabetic rats studied in vivo using hyperpolarized ¹³C pyruvate, butyrate and acetoacetate probes

In vivo detection of γ-glutamyl-transferase up-regulation in glioma using hyperpolarized γ-glutamyl-[1-13C]glycine

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Hyperpolarized ketone body metabolism in the rat heart

Cited by 25 publications

References 41 publications

Metabolism of hyperpolarized 13C‐acetoacetate to β‐hydroxybutyrate detects real‐time mitochondrial redox state and dysfunction in heart tissue

Metabolism of hyperpolarized 13C‐acetoacetate to β‐hydroxybutyrate detects real‐time mitochondrial redox state and dysfunction in heart tissue

Cardiac metabolic modulation upon low‐carbohydrate low‐protein ketogenic diet in diabetic rats studied in vivo using hyperpolarized 13C pyruvate, butyrate and acetoacetate probes

In vivo detection of γ-glutamyl-transferase up-regulation in glioma using hyperpolarized γ-glutamyl-[1-13C]glycine

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Metabolism of hyperpolarized ¹³C‐acetoacetate to β‐hydroxybutyrate detects real‐time mitochondrial redox state and dysfunction in heart tissue

Metabolism of hyperpolarized ¹³C‐acetoacetate to β‐hydroxybutyrate detects real‐time mitochondrial redox state and dysfunction in heart tissue

Cardiac metabolic modulation upon low‐carbohydrate low‐protein ketogenic diet in diabetic rats studied in vivo using hyperpolarized ¹³C pyruvate, butyrate and acetoacetate probes