Hexose monophosphate shunt measurement in cultured cells with [1-13C]glucose: correction for endogenous carbon sources using [6-13C] glucose.

Hexose monophosphate shunt (HMPS) activity can be measured with 1H nuclear magnetic resonance spectroscopy or gas chromatography--mass spectrometry by monitoring the differential production of [3-13C]lactate and [3-12C]lactate from the degradation of [1-13C]-glucose. Errors in measurement of HMPS activity can arise from unlabeled lactate precursors, by recycling of HMPS products, and by incomplete fractional enrichment of labeled glucose. A method utilizing cultured cells incubated with [1-13C]glucose in parallel with incubations using [6-13C]glucose to correct for all these problems is presented. In cultured rat C6 glioma and 9L gliosarcoma cells, failure to apply this correction results in an approximately twofold overestimation of HMPS activity.

31P NMR measurement of mitochondrial uncoupling in isolated rat hearts.

Mitochondrial uncoupling is often invoked as a mechanism underlying cellular dysfunction; however, it has not been possible to study this phenomenon directly in intact cells and tissues. In this paper, we report direct evaluation of mitochondrial uncoupling in the intact myocardium using 31P NMR magnetization transfer techniques. Langendorff perfused rat hearts were exposed to either a known uncoupler, 2,4-dinitrophenol (DNP), or a potential uncoupler, octanoate. Both DNP and octanoate decreased mechanical function as measured by the rate pressure product and caused an increase in the oxygen consumption rate (MVO2); with DNP this increase in MVO2 was dose-dependent. The ATP synthesis rate measured by 31P NMR, however, was not elevated commensurately with MVO2; instead, the P/O ratio declined. In contrast, the linear relationship between the ATP synthesis rate and rate pressure product was not altered by the uncoupling agents. These data demonstrate that 1) 31P NMR magnetization transfer can be utilized to measure uncoupling of oxidative phosphorylation in intact organs, 2) octanoate does not induce excess ATP utilization in the intact heart, and 3) high levels of octanoate induce mitochondrial uncoupling in the intact myocardium; and this may, in part, be the cause of the toxic effects associated with fatty acid exposure.

ATP synthesis kinetics and mitochondrial function in the postischemic myocardium as studied by 31P NMR.

The effects of ischemia on mitochondrial function and the unidirectional rate of ATP synthesis (Pi----ATP rate) were studied using a Langendorff-perfused heart preparation and 31P NMR spectroscopy. There was significant postischemic depression of mechanical function assessed as the heart rate pressure product, and the myocardial oxygen consumption rate at a given rate pressure product was elevated. Experiments performed on glucose- and pyruvate-perfused hearts demonstrated the presence of a large contribution to the unidirectional Pi----ATP rate catalyzed by glyceraldehyde-3-phosphate dehydrogenase and phosphoglycerate kinase. This rate was much greater than the maximal glucose utilization rate in the myocardium, demonstrating that the glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase reactions are near equilibrium both before and after ischemia. In the pyruvate-perfused postischemic hearts, the glycolytic contribution was eliminated and the net rate of ATP synthesis by oxidative phosphorylation was measurable. Despite the reduced mechanical function and increased myocardial oxygen consumption rate, the ratio of the net rate of ATP synthesis by oxidative phosphorylation to oxygen consumption rate (the P:O ratio) was not altered subsequent to ischemia (2.34 +/- 0.12 and 2.36 +/- 0.09 in normal and postischemic hearts, respectively). Therefore, mitochondrial uncoupling cannot be the cause of postischemic depression in mechanical function; instead, the data suggest the existence of ischemia-induced inefficiency in ATP utilization.

Substrate effects in the post-ischemic myocardium.

A study was undertaken to examine the effects of glucose versus pyruvate as the sole substrate following severe myocardial ischemia. Glycolysis usually contributes only a small amount to total ATP production and may be rate limiting in providing tricarboxylic acid (TCA) cycle substrates. Consequently, pyruvate may be a more effective substrate by bypassing glycolysis to feed directly to the TCA cycle and oxidative phosphorylation. Isolated rat hearts were studied in a retrograde (Langendorff) perfusion apparatus while in an NMR spectrometer. Rate pressure product (RPP), myocardial oxygen consumption (MVO2), and the unidirectional Pi----ATP rate were measured in control and postischemic hearts with or without the inotrope dobutamine. The undirectional Pi----ATP rate was higher in the glucose than the pyruvate hearts and the difference increased further postischemia. This increase over that of the pyruvate hearts has been attributed to a glycolytic component of ATP metabolism. Oxygen consumption was higher in pyruvate hearts at equivalent levels of performance. It thus appears that the glycolysis rate is significant and may be elevated following severe myocardial ischemia. Perfusion with pyruvate requires increased rates of oxidative phosphorylation to make up for the loss of glycolytically produced ATP. Optimal postischemic substrate delivery may require several compounds, one of which should be glucose.

31P NMR studies of ATP synthesis and hydrolysis kinetics in the intact myocardium.

The origin of the nuclear magnetic resonance (NMR)-measurable ATP in equilibrium Pi exchange and whether it can be used to determine net oxidative ATP synthesis rates in the intact myocardium were examined by detailed measurements of ATP in equilibrium Pi exchange rates in both directions as a function of the myocardial oxygen consumption rate (MVO2) in (1) glucose-perfused, isovolumic rat hearts with normal glycolytic activity and (2) pyruvate-perfused hearts where glycolytic activity was reduced or eliminated either by depletion of their endogenous glycogen or by use of the inhibitor iodoacetate. In glucose-perfused hearts, the Pi----ATP rate measured by the conventional two-site saturation transfer (CST) technique remained constant while MVO2 was increased approximately 2-fold. When the glycolytic activity was reduced, the Pi----ATP rate decreased significantly, demonstrating the existence of a significant glycolytic contribution. Upon elimination of the glycolytic component, the measured Pi----ATP rates displayed a linear dependence on MVO (micromoles of O consumption rate) with a slope of 2.36 +/- 0.15 (N = 8, standard error of the mean). This linear relationship is expected if the rate determined by CST is the net rate of ATP synthesis by the oxidative phosphorylation process, in which case the slope must equal the P:O ratio. The ATP----Pi rates and rate:MVO ratios measured by the multiple-site saturation transfer method at two MVO2 levels were equal to the corresponding Pi----ATP rates and rate:MVO ratios obtained in the absence of a glycolytic contribution. The following conclusions are drawn from these studies: (1) unless the glycolytic contribution to the ATP in equilibrium Pi exchange is inhibited or is specifically shown not to exist, the myocardial Pi in equilibrium ATP exchange due to oxidative phosphorylation cannot be studied by NMR; (2) at moderate MVO2 levels, the reaction catalyzed by the two glycolytic enzymes glyceraldehyde-3-phosphate dehydrogenase and 3-phosphoglycerate kinase is near equilibrium; (3) the ATP synthesis by the mitochondrial H+-ATPase occurs unidirectionally (i.e., the reaction is far out of equilibrium); (4) the "operative" P:O ratio in the intact myocardium under our conditions is significantly less than the canonically accepted value of 3.

113Cd NMR study of bovine prothrombin fragment 1 and factor X.

The interaction of Cd2+ with bovine prothrombin fragment 1, prothrombin intermediate 1, factor X, and a modified (Gla-domainless) factor X has been studied with 113Cd NMR. All the 113Cd resonances observed in this study were in the chemical shift range expected for oxygen ligands, suggesting that cadmium is binding at the same sites where calcium binds. Both fragment 1 and factor X displayed two major resonances, one near 10 ppm from 113Cd2+ that did not exchange rapidly with unbound 113Cd2+ (the high-affinity, or H, resonance) and one near -15 ppm from 113Cd2+ that exchanged rapidly with unbound 113Cd2+ (the low-affinity, or L, resonance). The difference between the chemical shift of the H resonance and the chemical shift range of -90 to -125 ppm that has been reported for three other small calcium-binding proteins is postulated to be due to different coordination geometries for monocarboxylate and dicarboxylate ligands; Cd2+ binds to fragment 1 and factor X through the dicarboxylate side chains of gamma-carboxyglutamate (Gla) residues. This allows contribution of only one oxygen per carboxyl group. At least one of the first few 113Cd2+ ions bound to fragment 1 did not appear in the 113Cd NMR spectrum until a total of five 113Cd2+ had been added. This could be due to exchange broadening of initial 113Cd2+ resonances due to sharing of ligands among several sites. Filling all sites would then restrict ligand exchange. Addition of Zn2+ displaced 113Cd2+ from the H resonance sites. Factor X did not display the interactions among ion binding sites proposed for fragment 1.

Dietary potentiation of the antifertility effects of 5-thio-D-glucose in male rats.

Male rats of proven fertility were fed the following diets for 28 d either with or without 0.075% 5-thioglucose (5-THG): AIN-76 diet (A76): a diet with 13% casein, 2% glucose and the balance of the calories as free corn oil fatty acids from corn oil (2G); and a similar diet, isocaloric with 2G, with the glucose level increased to 20% (20G). The diets alone without 5-THG had no influence on any of the parameters measured. Body weight gain was lower in rats fed diets containing 5-THG than in those fed diets without 5-THG. In rats fed A76, the only 5-THG effects on male reproductive tract (MRT) tissues was the appearance of testicular multinucleate giant cells (MGC). In rats fed either 2G or 20G, the MRT effects of 5-THG included the appearance of MGC, a lower number of germ cells at most stages of maturation, lower sperm counts and biochemical changes in testis slices and in germ cell preparations compared to rats not fed 5-THG. There were fewer Step 7 spermatids in rats fed 5-THG in 2 G than in those fed 5-THG in 20G. It is concluded that the MRT toxicity of 5-THG is influenced by diet, being potentiated by the low protein diet high in free fatty acids and, to a lesser extent, by low glucose levels within these diets.