A nuclear magnetic resonance study of the role of phosphoenol pyruvate carboxykinase (PEPCK) in the glucose metabolism of Dipetalonema viteae

13C-NMR has been applied to the study of the metabolism of [1-13C]glucose by macrofilariae of Dipetalonema viteae under conditions of restricted glucose supply. In a medium buffered with 13C-labelled bicarbonate, succinate labelled in the carboxyl position is formed in good yield. Quinolinic acid, a known inhibitor of phosphoenol pyruvate carboxykinase (PEPCK) has been shown to suppress the formation of labelled succinate from [1-13C]glucose. Both sets of experiments support the formation of succinate through the PEPCK-mediated carboxylation of phosphoenol pyruvate, followed by the operation of a partial tricarboxylic acid cycle.     

An investigation of the glucose metabolism of Brugia pahangi and Dipetalonema viteae by nuclear magnetic resonance spectroscopy

This study followed the metabolism of [¹³C]glucose under anaerobic and aerobic conditions in the adult filarial nematodes Brugia pahangi and Dipetalonema viteae using non-invasive ¹³C nuclear magnetic resonance techniques. Adult B. pahangi and D. viteae showed a rapid uptake of labelled glucose which remained linear over at least 4 h. Both species of worm removed significantly more glucose from the medium under aerobic conditions than under anaerobic conditions. The principal product of metabolism, under both anaerobic and aerobic conditions, was lactate, which accounted for 62–71% of the original [¹³C]glucose. Examination of the maintenance medium following worm incubation revealed a further excretory product which was identified as succinate. This product accounted for 1–2% of labelled glucose in adult B. pahangi and 2–5% in adult D. viteae. The presence of succinate as an excretory product suggests that a partial reversed tricarboxylic acid cycle is active in these filarial nematodes. A further peak was identified in the worm homogenate and identified as trehalose. The disaccharide was not an excretory product and occurred only within the worm. The peak accounted for 13–14% of the ¹³C-labelled glucose in B. pahangi and 15–16% in D. viteae. Trehalose has not been previously recorded in either of these nematodes and is likely to have a storage function.     

Carbohydrate metabolism of the rat C6 glioma. An in vivo 13C and in vitro 1H magnetic resonance spectroscopy study

Surface coil 13C nuclear magnetic resonance (NMR) spectroscopy was used to investigate the in vivo carbohydrate metabolism of rat C6 gliomas during and after infusion with [1-13C] glucose. In vivo 1H-decoupled 13C NMR spectra of the glioma following infusion with [1-13C]glucose revealed the direct production of [3-13C]lactic acid, [1-13C]glycogen, and [4-13C], [3-13C], and [2-13C]glutamate/glutamine. Lactate levels of in vivo gliomas increased and reached steady state levels during [1-13C]glucose infusion, and decreased following termination of infusion. Complementary in vitro studies using supernatant media collected from C6 glioma cells incubated with media containing [1-13C] or [6-13C]glucose and glutamine were examined by 1H NMR spectroscopy. The [3-(13C/12C)]lactate ratios obtained from 1H spectra of supernatant media containing [1-13C]glucose revealed the percentage of glucose metabolized through the hexose monophosphate shunt to be 10.01 +/- 0.85% (n = 3), while similar measurements of media containing [6-13C]glucose and glutamine showed that glutaminolysis contributed 9.0 +/- 1.0% of total lactate production under these conditions. Enzymatic analysis of media determined lactate production to be 139 +/- 9 nmol per 10(6) cells per h (n = 4). These measurements demonstrate the ability of NMR to monitor brain tumor carbohydrate metabolism both in vitro and in vivo.     

31P and 13C NMR studies of isolated perfused hematopoietic cells from leukemic mice

The myeloproliferative leukemic virus (MPLV) induces within 2-3 weeks a massive infiltration of the adult mouse liver by hematopoietic leukemic cells. Since the metabolism of the infiltrated organ might be correlated with an interaction of two cell populations, it was decided to study the isolated hematopoietic cells separately. The metabolism of these cells embedded in an agarose gel and perfused with labeled substrates was investigated using 31P and 13C NMR. Using [1-13C]glucose as precursor, sequential 13C NMR spectra showed that the hematopoietic cells were able to store glucose as [1-13C]glycogen and to metabolize it through the glycolytic pathway to give [3-13C]lactate as sole end-product. The liver neoglucogenic substrates: [2-13C]pyruvate and [3-13C]alanine are not metabolized by these cells. This suggests that the tricarboxylic acid cycle was not efficient. To investigate further the glycolytic properties of the cells, 10 mM sodium azide was added to the medium containing [1-13C]glucose. When compared to the aerobic conditions, a 40% decrease of nucleotides (0.10 vs 0.17 mumole NTP/10(9) cells), a degradation of [1-13C]glycogen and an increase of ca 35% of the glycolytic rate were observed. The analysis of 13C NMR spectra of the perfusates at the end of the perfusion indicates a total conversion of [1-13C]glucose into [3-13C]lactate and [3-13C]pyruvate under anaerobic conditions. These results permit a better understanding of the metabolism of the perfused leukemic livers which are extensively infiltrated by these hematopoietic cells.     

Evidence for the occurrence of respiratory electron transport in adult Brugia pahangi and Dipetalonema viteae

Mixed-sex adult stages of Brugia pahangi and Dipetalonema viteae, in the absence of exogenous substrate, consumed oxygen at rates of 4.18 +/- 0.38 and 2.12 +/- 0.20 ngatoms O2 min-1 mg-1 dry wt. respectively. When calculated on a unit dry weight basis the endogenous O2 consumption rates (E-QO2) of mature adult male macrofilariae of B. pahangi and D. viteae were significantly greater than those of mature females, although the E-QO2 calculated per individual worm was essentially similar irrespective of sex. When assayed as separate unisexual groups, the oxygen uptake of male and female macrofilariae of both species was inhibited by classical inhibitors of respiratory electron transport (RET), and showed classical substrate bypass phenomena in response to succinate and ascorbate, N,N,N',N'-tetramethyl-p-phenylenediamine with respect to the RET inhibitors rotenone (inhibitor of complex I) and antimycin A (inhibitor of complex III). Since male worms elicited similar responses to the classical RET inhibitors as did mixed-sex and/or adult female populations, the possibility that developmental stages contained within the female filariids were contributing in any significant manner to the overall responses observed with the RET inhibitors can be discounted. Such responses as observed with live-intact macrofilariae are normally elicited only by mitochondrial preparations and suggest that the cuticles of both species are permeable to rotenone, succinate, antimycin A, N,N,N',N'-tetramethyl-p-phenylenediamine, azide and cyanide. The uncoupler 2,4-dinitrophenol stimulated the endogenous rate of oxygen consumption (E-QO2) of intact B. pahangi at 33-160 microM, indicating the probable occurrence of RET-coupled oxidative phosphorylation. Higher concentrations of 2,4-dinitrophenol proved inhibitory. Respiratory studies on subcellular fractions substantiated the responses elicited by the intact parasites, suggesting the presence of antimycin A-sensitive and -insensitive RET pathways capable of utilising alpha-glycerophosphate, succinate, and malate as substrates. Both B. pahangi and D. viteae macrofilariae therefore probably possess branched RET-pathways bifurcating on the substrate side of RET-complex III. The rates of substrate oxidation in terms of QO2 mg-1 mitochondrial protein compare well with those observed with other nematode parasites.     

Involvement of brain lactate in neuronal metabolism

The involvement of brain lactate in neuronal metabolism was analyzed by ex vivo NMR spectroscopy with rats under the effects of pentobarbital, alphachloralose or morphine, which were infused with a solution of either [1-(13)C]glucose+lactate or glucose+[3-(13)C]lactate for 20 min. Electroencephalogram recordings indicated different brain electrical activity levels under the three drugs with a clear distinction between pentobarbital, on the one hand, and alphachloralose and morphine on the other. Labeling of metabolites in brain perchloric acid extracts and of blood glucose and lactate was determined by (13)C- and/or (1)H-observed/(13)C-edited-NMR spectroscopy. The following were found: (i) the ratio between glutamate C3 and C4 (13)C-enrichments increased from pentobarbital to alphachloralose and morphine whatever the labeled precursor, indicating a link between metabolic and electrical activity; (ii) under glucose+[3-(13)C]lactate infusion, alanine C3 and acetyl-CoA C2 enrichments were higher than that of lactate C3, revealing the occurrence of an isotopic dilution of the brain exogenous lactate (arising from blood) by lactate from brain (endogenous lactate); the latter was synthesized from glycolysis in a compartment other than the neurons; (iii) the contributions of labeled glucose and lactate to acetyl-CoA C2 enrichment indicated that the involvement of blood glucose relative to that of blood lactate to brain metabolism was correlated with brain activity. It can therefore be concluded that the brain electrical activity-dependent increase in the contribution of blood glucose relative to that of blood lactate to brain metabolism occurred partly via the increase in the metabolism of lactate generated from astrocytic glycolysis. This conclusion supports the hypothesis of an astrocyte-neuron lactate shuttle component in the coupling mechanism between cerebral activity and energy metabolism.     

Lactate metabolism in the isolated perfused rat kidney: relations to renal function and gluconeogenesis.

In the intact dog, decreases in both glomerular filtration rate and net renal Na+ reabsorption due to raised ureteral pressure were not associated with a decrease in renal lactate oxidation rate, although total renal CO2 production decreased in proportion to the changes in net renal reabsorption of Na+ and glomerular filtration rate. 2. In order to determine whether, in the absence of other added substrates, the metabolism of lactate supports only the 'basal' renal metabolism or can enhance renal function as well, the rate of lactate utilization and decarboxylation by the isolated perfused rat kidney have been quantified in relation to renal function and one measure of renal basal metabolism, glucose production. 3. The perfusate was Krebs-Ringer bicarbonate (pH 7-35-7-48) with Fraction V bovine serum albumin, 6g/100 ml. L-(+)-lactate was added to raise the lactate concentration from endogenous levels to 2-5, 5-0 or 10 mM. 4. We determined: net lactate utilization rate, lactate decarboxylation rate (14CO2 produced from L-(+)-[U-14C]lactate), net glucose production rate, and net re-absorptive rate of Na+. 5. The apparent Km and Vmax for lactate oxidation were 2-1 mM and 1-29 mumole.g-1.min-1 respectively. There was no apparent maximum for total lactate utilization rate due to continuing increases in glucose production rate as lactate concentration was raised. At ca. 10 mM lactate, glucose production accounted for about half of the total lactate utilized. Therefore the basal energy requirements of the kidney need not be constant since glucose production increases as lactate concentration is raised. 6. Both lactate oxidation rate and lactate utilization rate were significantly correlated with the net reabsorption of Na+ by the renal tubules, with the percentage of filtered Na+ reabsorbed and with the glomerular filtration rate. The major fraction of the net renal reabsorption of Na+ was probably supported by the metabolism of substrates either bound to albumin or derived from renal tissue since the percentage of filtered Na+ reabsorbed increased from ca. 78%, when no lactate was added, to 97% when initial lactate concentration was 10 mM. Therefore, addition of lactate increased both the basal mebabolism and tubular function. However, these observations do not permit us to conclude whether it was the presence of lactate, or its utilization by oxidative or by other pathways which enhanced net renal reabsorption of Na+ and the glomerular filtration rate.     

In a medium containing glucose, lactate carbon is incorporated by gonococci predominantly into fatty acids and glucose carbon incorporation is increased: implications regarding lactate stimulation of metabolism

The reason for stimulation by lactate of metabolism of gonococci growing in a medium containing glucose, which enhances pathogenicity by increasing growth rate, lipopolysaccharide (LPS) synthesis and protein formation, has been investigated. Tricine dodecylpolyacrylamide gel electrophoresis (SDS-PAGE) and thin layer chromatography (TLC) on homogenates of gonococci grown in this medium with [14C]lactate showed that lactate carbon was preferentially incorporated into lipid and LPS. Nuclear magnetic resonance (NMR) spectroscopy on lipid extracted from gonococci grown in the glucose containing medium with [13C]lactate showed that lactate carbon was incorporated into fatty acid moieties and not into ethanolamine or glycerol moieties. In contrast, NMR on lipid from gonococci grown with [13C]glucose indicated glucose carbon in both moieties. When unlabelled lactate was added, lipid synthesis from [l3C]glucose was stimulated and small amounts of different fatty acids were formed. The NMR data shows that gluconeogenesis from lactate carbon does not occur in the presence of glucose, suggesting that lactate is used solely for rapid production, via pyruvate, of acetyl CoA, the precursor not only for fatty acid synthesis but also for the constituents and products of the citric acid cycle, including ATP. The rapid formation of a high level of acetyl CoA is the probable reason for the stimulation of metabolism and oxygen uptake by lactate. 14C label on LPS was detected in its fatty acids. Most proteins that stained with silver in tricine SDS-PAGE were not significantly labelled by [14C]lactate in the glucose-containing medium. Two of three appreciably labelled proteins were identified by N-terminal sequencing as GroEL and porin 1B, and one of the two less labelled proteins was similar to peroxiredoxin type proteins. There were no signs of specific induction of these proteins by lactate and their labelling was consistent with fatty acids in attached lipid.     

Metabolism of [1,3-(13)C]glycerol-1,2,3-tris(methylsuccinate) and glycerol-1,2,3-tris(methyl[2,3-(13)C]succinate) in hepatocytes from Goto-Kakizaki rats

The metabolism of [1,3-(13)C]glycerol-1,2,3-tris(methylsuccinate) and glycerol-1,2,3-tris(methyl[2,3-(13)C] succinate) was examined in hepatocytes prepared from hereditarily diabetic Goto-Kakizaki rats. Over 120 min incubation in the presence of one of the two (13)C-labelled esters (2.5 mM), the output of (13)C-enriched glucose averaged 57.1 +/- 18.5 and 54.1 +/- 22.7 nmol per 10(6) cells, when expressed as [1,3-(13)C]glycerol and [2,3-(13)C] succinate equivalent, respectively. In the case of [1,3-(13)C]glycerol-1,2,3-tris(methyl-succinate), the molecules of glucose were symmetrically labelled. In the case of glycerol-1,2,3-tris(methyl[2,3-(13)C] succinate), however, both the single-labelled and double-labelled isotopomers of glucose contained more (13)C atoms in their C(6)-C(5)-C(4) than C(1)-C(2)-C(3) moiety. These findings indicate that glycerol-1,2,3-tris(methylsuccinate), recently proposed as a novel insulinotropic tool for the treatment of non-insulin-dependent diabetes mellitus, is efficiently metabolized in hepatocytes from diabetic rats, the high rate of gluconeogenesis coinciding with channelling of D-glyceraldehyde-3-phosphate between glyceraldehyde-3-phosphate dehydrogenase and phosphofructoaldolase.     

Estimating gluconeogenesis by NMR isotopomer distribution analysis of [13C]bicarbonate and [1-13C]lactate

The gluconeogenic contribution to glucose production in livers isolated from rats fasted for 24 h was determined by 13C-NMR isotopomer distribution analysis of secreted glucose enriched from 99% [13C]bicarbonate (n = 4) and 99% [1-13C]lactate (n = 4). Experiments with 3% 2H2O were also performed, allowing the gluconeogenic contribution to be measured by the relative 2H enrichments at positions 5 and 2 of glucose. From 13C-NMR analyses, the contribution of gluconeogenesis to glucose output was estimated to be 93 +/- 3% for [13C]bicarbonate perfusion and 91 +/- 3% for [1-13C]lactate perfusion, in good agreement with the 2H-NMR analysis of the gluconeogenic contribution to glucose production (100 +/- 1% and 99 +/- 1%, respectively) and consistent with the expected negligible contribution from glycogenolysis. These results indicate that 13C-NMR analysis of glucose 13C-isotopomer distribution from either [13C]bicarbonate or [1-13C]lactate precursor provides realistic estimates of the gluconeogenic contribution to hepatic glucose output.     

1H- and 13C-NMR spectroscopic study of the metabolites in young adult Angiostrongylus cantonensis maintained in vitro

1H- and 13C-nuclear magnetic resonance (NMR) spectroscopy were used to study metabolites excreted by young adult Angiostrongylus cantonensis maintained aerobically in the presence of D-[13C6]glucose. End-products of glucose metabolism identified and quantitated by means of 1H-NMR were lactate, acetate and alanine, in the molar ratio of 1:0.13:0.05 for males and 1:0.07:0.04 for females. 13C-NMR analyses proved that all the three products originated from the glucose present in the medium.     

Metabolism of D-[1,2-13C]glucose and alpha-D-[1,2-13C]glucose pentaacetate in tumoral pancreatic islet cells

Tumoral pancreatic islet cells of the RINm5F line were incubated, in groups of 25x106 cells each, for 120 min at 37 degrees C in media (5. 0 ml) containing either alpha-D-[1,2-13C]glucose pentaacetate (1.7 mM) or both D-[1,2-13C]glucose (1.7 mM) and acetate (8.5 mM). In both cases, the amounts of 13C-enriched metabolites (D-glucose, L-lactate and acetate) and non-enriched metabolites (acetate) recovered in the incubation medium after incubation were close to the initial amount of esterified or non-esterified D-[1, 2-13C]glucose and acetate, respectively. The 13C-enriched metabolites corresponded mainly to double-labelled D-[1, 2-13C]glucose, L-[2,3-13C]lactate and [1,2-13C]acetate. The output of L-[2,3-13C]lactate and [1,2-13C]acetate was about 3-4 times lower in the cells exposed to alpha-D-[1,2-13C]glucose pentaacetate than in those incubated with unesterified D-[1,2-13C]glucose. These findings indicate that, despite extensive hydrolysis of alpha-D-[1, 2-13C]glucose pentaacetate in the RINm5F cells, the hexose moiety of the ester is less efficiently metabolized than unesterified D-[1, 2-13C]glucose tested at the same molar concentration (1.7 mM) in the presence of 8.5 mM acetate. Thus, a higher utilization of the hexose moiety of alpha-D-glucose pentaacetate than that of unesterified D-glucose, as previously documented in isolated pancreatic islets, represents a far-from-universal situation.     

Probing carbohydrate metabolism using hyperpolarized 13C‐labeled molecules

Glycolysis is a fundamental metabolic process in all organisms. Anomalies in glucose metabolism are linked to various pathological conditions. In particular, elevated aerobic glycolysis is a characteristic feature of rapidly growing cells. Glycolysis and the closely related pentose phosphate pathway can be monitored in real time by hyperpolarized ¹³C‐labeled metabolic substrates such as ¹³C‐enriched, deuterated D‐glucose derivatives, [2‐¹³C]‐D‐fructose, [2‐¹³C] dihydroxyacetone, [1‐¹³C]‐D‐glycerate, [1‐¹³C]‐D‐glucono‐δ‐lactone and [1‐¹³C] pyruvate in healthy and diseased tissues. Elevated glycolysis in tumors (the Warburg effect) was also successfully imaged using hyperpolarized [U‐¹³C₆, U‐²H₇]‐D‐glucose, while the size of the preexisting lactate pool can be measured by ¹³C MRS and/or MRI with hyperpolarized [1‐¹³C]pyruvate. This review summarizes the application of various hyperpolarized ¹³C‐labeled metabolites to the real‐time monitoring of glycolysis and related metabolic processes in normal and diseased tissues.     

N-acetylation of serotonin, octopamine and dopamine by adult Brugia pahangi

The metabolism of biogenic amines by the filarial worm, Brugia pahangi, was investigated by incubating cut worms with radio-labelled amine substrates. Two-dimensional thin-layer chromatography and analysis on two high-performance liquid chromatography systems showed that [14C]5-hydroxytryptamine was metabolised to a less polar compound that was identified as N-acetyl 5-hydroxytryptamine. N-Acetyloctopamine and N-acetyldopamine were also formed when cut B. pahangi were incubated with [14C]octopamine and [3H]dopamine, respectively. N-Acetyltransferase activity towards 5-hydroxytryptamine was readily detected in nematode homogenates. This enzyme was localised in a 50,000 x g supernatant and required the addition of the co-substrate, acetyl CoA, for activity. No evidence was obtained for the involvement of monoamine oxidases in the metabolism of 5-HT in these filarial worms.     

NMR study on [1-13C]glucose metabolism in the rat brain during hypoxia

The metabolism of [1-13C]glucose in the rat brain during hypoxia was investigated by 13C NMR spectroscopy. Male Wistar rats, weighing 100-120g, were anesthetized with ketamine (50 approximately 75 mg/kg i.p.) and ventilated mechanically with a mixture of 30% oxygen, 69.5% nitrogen and 0.5% halothane. [1-13C]glucose (250 mg/kg) was infused twice, at 10 minute intervals, through the femoral vein. For the control group (n = 4), the oxygen concentration of the inspiratory gas was maintained at 30% by vol throughout the experiments. For the hypoxia group (n = 6), the oxygen concentration in the inspiratory gas was reduced to 6-7% (93-94% nitrogen) and maintained for 30 min following [1-13C]glucose infusion. 13C NMR spectra were measured by a gated proton-decoupling method without a nuclear Overhauser effect. The [1-13C]glucose infusion gave apparent signals of the C1 carbon in the alpha- and beta-anomers of [1-13C]glucose at 92.7 and 96.7 ppm, respectively. Signals of the C2, C3 and C4 carbon atoms in glutamate and/or glutamine (glx) also appeared at 55, 27 and 34 ppm, respectively. The intensity of glx-C2 and glx-C3 signals increased later than that of glx-C4. The time lag between the different glx signals may reflect the turnover rate of the TCA cycle. Under the hypoxic condition, the signal of C3 carbon in lactate appeared at 21 ppm and increased. The alpha-glucose signal diminished during hypoxia, whereas the beta-glucose signal kept its intensity. The difference in changes of the signal intensity between alpha- and beta-glucose suggests that alpha-glucose is consumed more than beta-glucose in the hypoxic brain.     

Ketone bodies effectively compete with glucose for neuronal acetyl‐CoA generation in rat hippocampal slices

Ketone bodies can be used for cerebral energy generation in situ, when their availability is increased as during fasting or ingestion of a ketogenic diet. However, it is not known how effectively ketone bodies compete with glucose, lactate, and pyruvate for energy generation in the brain parenchyma. Hence, the contributions of exogenous 5.0 mM [1‐¹³C]glucose and 1.0 mM [2‐¹³C]lactate + 0.1 mM pyruvate (combined [2‐¹³C]lactate + [2‐¹³C]pyruvate) to acetyl‐CoA production were measured both without and with 5.0 mM [U‐¹³C]3‐hydroxybutyrate in superfused rat hippocampal slices by ¹³C NMR non‐steady‐state isotopomer analysis of tissue glutamate and GABA. Without [U‐¹³C]3‐hydroxybutyrate, glucose, combined lactate + pyruvate, and unlabeled endogenous sources contributed (mean ± SEM) 70 ± 7%, 10 ± 2%, and 20 ± 8% of acetyl‐CoA, respectively. With [U‐¹³C]3‐hydroxybutyrate, glucose contributions significantly fell from 70 ± 7% to 21 ± 3% (p < 0.0001), combined lactate + pyruvate and endogenous contributions were unchanged, and [U‐¹³C]3‐hydroxybutyrate became the major acetyl‐CoA contributor (68 ± 3%) – about three‐times higher than glucose. A direct analysis of the GABA carbon 2 multiplet revealed that [U‐¹³C]3‐hydroxybutyrate contributed approximately the same acetyl‐CoA fraction as glucose, indicating that it was less avidly oxidized by GABAergic than glutamatergic neurons. The appearance of superfusate lactate derived from glycolysis of [1‐¹³C]glucose did not decrease significantly in the presence of 3‐hydroxybutyrate, hence total glycolytic flux (Krebs cycle inflow + exogenous lactate formation) was attenuated by 3‐hydroxybutyrate. This indicates that, under these conditions, 3‐hydroxybutyrate inhibited glycolytic flux upstream of pyruvate kinase. Copyright © 2015 John Wiley & Sons, Ltd.     

Effect of perfusate glucose concentration on rat lung glycolysis.

We investigated the relationship between perfusate concentration of glucose and its utilization and lactate production derived from exogenous glucose and from metabolism of endogenous substrates. Isolated rat lungs were ventilated with 5% CO2 in air and perfused for 100 min with Krebs-Ringer bicarbonate buffer containing 3% bovine serum albumin, 10(-2) U/ml insulin, [U-14C]glucose and [5-3H]glucose. Glucose utilization, total lactate production, [14C]lactate production, and 3H2O production were measured. The apparent Km and Vmax for glucose utilization were 3.4 mM and 72.5 mumol/g dry wt per h, respectively. Lactate production from endogenous substrates, calculated as the difference between total and [14C]lactate, was 37.6 +/- 2.2 mumol/g dry wt (n = 36); it was unaffected by perfusate glucose concentration and by omission of insulin, but increased threefold with anoxia. Lactate production from 1.5 mM glucose was significantly less (P less than 0.02) with insulin omitted. Glycogen content was unchanged during perfusion without glucose. These results suggest that: 1) protein catabolism contributes to lung lactate production; 2) glucose utilization by lung is not maximal at resting physiological glucose concentrations; and 3) insulin is required at low glucose concentrations for maximal glycolytic rates.     

In vivo single-shot, proton-localized 13C MRS of rhesus monkey brain

A single-shot, proton-localized, polarization transfer (13)C spectroscopic method was proposed and implemented on a 4.7 T scanner for studying rhesus monkey brains. The polarization transfer sequence was mostly adiabatic, minimizing signal loss due to B(1) inhomogeneity. RF pulses in polarization transfer were also used for voxel selection of protons with gradient fields. The transferred (13)C magnetization was refocused by additional refocusing adiabatic pulses. With the intravenous infusion of D-[1-(13)C]glucose solution, (13)C NMR spectra from a 30 mL voxel were acquired for the resonances of C1 of glucose, C2,3,4 of glutamate and glutamine. The time-resolved turnover of glutamate, glutamine and aspartate from intravenously infused D-[1-(13)C]glucose at a temporal resolution of 12 min was demonstrated with excellent spectral resolution and signal-to-noise ratio. Typically, the half-height linewidth of the decoupled (13)C peaks was approximately 4 Hz. Data obtained with infusion of sodium [2-(13)C]acetate using the proposed polarization transfer method and data from the carboxylic carbon region using non-localized acquisition are also presented.     

Metabolism of 13C-enriched D-fructose in hepatocytes from Goto-Kakizaki rats

This study aims at assessing the conversion of exogenous D-[1-13C]fructose, D-[2-13C]fructose or D-[6-13C]-fructose (10 mM) to 13C-enriched and either hydrogenated or deuterated D-glucose, L-lactate and L-alanine released by rat liver cells prepared from Goto-Kakizaki rats and incubated for 120 min in the presence of unlabelled D-glucose (also 10 mM) and D2O. The results of this study are relevant to the relative contribution of fructokinase and hexokinase isoenzyme to the phosphorylation of D-fructose, the capacity of D-glucose to confer to glucokinase positive cooperativity towards D-fructose, the circulation of D-fructose 6-phosphate in the pentose phosphate pathway, the regulation of the cytosolic NADD/NADH ratio, the respective fate of D-fructose-derived D-glyceraldehyde and dihydroxyacetone phosphate, the deuteration of fructose-derived glycolytic intermediates at the phosphoglucoisomerase, phosphomannoisomerase, enolase, pyruvate kinase and glutamate-alanine transaminase levels, and the unequal generation of L-[1-13C]lactate by cells exposed to D-[1-13C]fructose or D-[6-13C]fructose versus D-[2-13C]-fructose.     

Assessing the influence of isoflurane anesthesia on cardiac metabolism using hyperpolarized [1‐13C]pyruvate

Isoflurane is a frequently used anesthetic in small‐animal dissolution dynamic nuclear polarization‐magnetic resonance imaging (DNP‐MRI) studies. Although the literature suggests interactions with mitochondrial metabolism, the influence of the compound on cardiac metabolism has not been assessed systematically to date. In the present study, the impact of low versus high isoflurane concentration was examined in a crossover experiment in healthy rats. The results revealed that cardiac metabolism is modulated by isoflurane concentration, showing increased [1‐¹³C]lactate and reduced [¹³C]bicarbonate production during high isoflurane relative to low isoflurane dose [average differences: +16% [1‐¹³C]lactate/total myocardial carbon, –22% [¹³C]bicarbonate/total myocardial carbon; +51% [1‐¹³C]lactate/[¹³C]bicarbonate]. These findings emphasize that reproducible anesthesia is important when studying cardiac metabolism. As the depth of anesthesia is difficult to control in an experimental animal setting, careful study design is required to exclude confounding factors.