Dehydrogenase regulation of metabolite oxidation and efflux from mitochondria in intact hearts

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Dehydrogenase regulation of metabolite oxidation and efflux from mitochondria in intact hearts

J. Michael O'Donnell¹, Chris Doumen³, Kathryn F. Lanoue³, Lawrence T. White¹, Xin Yu¹, Nathaniel M. Alpert², and E. Douglas Lewandowski¹

¹ Nuclear Magnetic Resonance Center and ² Positron-Emission Tomography Laboratory, Department of Radiology, Massachusetts General Hospital, Harvard Medical School, Boston, Massachusetts 02129; and ³ Department of Molecular and Cellular Physiology, Pennsylvania State University Medical School, Hershey, Pennsylvania 17033

ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

To test how $alpha$ -ketoglutarate dehydrogenase ( $alpha$ -KGDH) activity influences the balance between oxidative flux and transmitochondrialmetabolite exchange, we monitored these rates in isolated mitochondriaand in perfused rabbit hearts at an altered kinetics (K_m) of $alpha$ -KGDHfor $alpha$ -ketoglutarate ( $alpha$ -KG). In isolated mitochondria, relativeK_m dropped from 0.23 mM at pH = 7.2 to 0.10 mM at pH 6.8 (P <0.05), and $alpha$ -KG efflux decreased from 126 to 95 nmol · min¹ · mg¹. In intact hearts, K_m was reduced with low intracellular pH,while matching control workload and respiratory rate with increasedCa²⁺ (pH_i = 7.20, perfusate CaCl₂ = 1.5 mM; pH_i = 6.89, perfusateCaCl₂ = 3 ± 1 mM). Sequential ¹³C nuclear magnetic resonance spectra from hearts oxidizing [2-¹³C]acetate provided tricarboxylic acid cycle flux and the exchangerate between $alpha$ -KG and cytosolic glutamate (F₁). Tricarboxylicacid cycle flux was 10 µmol · min¹ · g¹ in both groups, but F₁ fell from a control of 9.3 ± 0.6 to 2.8± 0.4 µmol · min¹ · g¹ at low K_m. The results indicate that increased activity of $alpha$ -KGDHoccurs at the expense of $alpha$ -KG efflux during support of normalworkloads.

metabolic regulation; tricarboxylic acid cycle; myocardium; nuclear magnetic resonance

	INTRODUCTION

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IN THIS STUDY, we examined the potential for metabolic coordination between the mitochondrial dehydrogenase reactions andmetabolite influx and efflux across the mitochondrial membranein intact functioning hearts. In particular, this work focusedon the coordination between the rate-limiting dehydrogenase ofthe first span of the tricarboxylic acid (TCA) cycle, $alpha$ -ketoglutaratedehydrogenase ( $alpha$ -KGDH), and metabolite transport via the $alpha$ -ketoglutarate-malateexchanger on the mitochondrial membrane. Although already establishedin the isolated mitochondrial preparation (12, 31), the roleof the mitochondrial dehydrogenases in coordinating TCA cycleflux (V_TCA) and the metabolite exchange rates between the cytosoland mitochondria has yet to be demonstrated in the intact beatingheart. Thus a combination of flux measurements from the dynamicmode ¹³C nuclear magnetic spectroscopy (NMR) of the intact heart andradiotracer analysis of isolated heart mitochondria provides newinsight into coordinating intermediary metabolism between thecytosol and mitochondria to support cardiac function.

Two exchange proteins of the mitochondrial membrane provide one mechanism by which cytosolic metabolites exchange with mitochondrialmetabolites: the reversible $alpha$ -ketoglutarate-malate exchanger andthe unidirectional glutamate-aspartate exchanger. These two transportersmay function separately, but when operating in tandem, they formthe malate-aspartate shuttle (10). The exchange of metabolitesbetween mitochondria and cytosol may then be coordinated withmitochondrial TCA cycle activity at the level of the enzyme $alpha$ -ketoglutaratedehydrogenase ( $alpha$ -KGDH). $alpha$ -KGDH oxidizes $alpha$ -ketoglutarate to formsuccinyl CoA within the TCA cycle. In this manner, $alpha$ -KGDH regulatesV_TCA through the second span of the cycle (23) and competeswith the mitochondrial membrane transporter for $alpha$ -ketoglutarate(11). The subsequent efflux and transamination of $alpha$ -ketoglutarate,via the glutamate-oxaloacetate transaminase (GOT), produces cytosolicglutamate. This balance between V_TCA and metabolite exchange ratescan be evaluated by analysis of dynamic ¹³C NMR spectra of carbon isotope enrichment of glutamate in theintact heart (33-35). In the isolated mitochondria, the unidirectionalinflux or efflux of $alpha$ -ketoglutarate and malate across the mitochondrialmembrane can also be measured with ambiguity for comparison tothe isotope kinetics in the intact heart. Such a combined informationcan be interpreted to define changes in the activity of the enzymescoordinating these processes.

We have previously shown that the rate of the transaminase GOT is much too fast to be a rate-determining component of theobserved interconversion rate between $alpha$ -ketoglutarate and glutamatein intact hearts by directly measuring the activities of the mitochondrialand cytosolic isozymes of GOT in rabbit myocardium (34). Instead,the much slower rate of interconversion can be attributed notto the transaminase but rather to the transport processes thatbring $alpha$ -ketoglutarate out of the mitochondria for transaminationwith the large cytosolic glutamate pool.

Subsequent work from our laboratory has determined that ¹³C NMR methods are sensitive to both V_TCA and rates of metabolite transportbetween the mitochondria and cytosol in intact functioning hearts(33-35). Unlike more traditional assay and isolation techniques,¹³C NMR spectroscopy provides an approach to characterize the activityof the TCA cycle, exchange rates, and potentially the kineticsof specific enzymes in the intact tissue under normal, diseased,or altered function.

In this study, alteration of the kinetics (K_m) of the key rate-limiting enzyme of the TCA cycle, $alpha$ -KGDH, was studied in bothintact hearts and isolated mitochondria. As the substrate concentrationat which the reaction for the given enzyme reaches half-maximalvelocity, K_m served as a kinetic index of the substrate-enzymeaffinity. The affinity of $alpha$ -KGDH for the substrate $alpha$ -ketoglutaratewas increased (i.e., a reduction in K_m) by reducing intramitochondrialpH and increasing calcium content. Combined studies of $alpha$ -ketoglutarateoxidation and efflux from isolated rabbit heart mitochondria andNMR assessment of stable isotope enrichment of glutamate provideda unique opportunity to study the balance between $alpha$ -ketoglutaratetransport and oxidation as a function of the affinity of the $alpha$ -KGDHfor its substrate. The analysis presented here indicates thatchanges in the kinetic parameters of $alpha$ -ketoglutarate oxidationrates mediate changes in $alpha$ -ketoglutarate efflux from mitochondriaat constant V_TCA. For the first time, we establish the influenceof pH and Ca²⁺ on the cardiac $alpha$ -KGDH in the intact heart, while demonstratingthe role this dehydrogenase plays in coordinating cytosolic metabolismwith that oxidative energy production pathways.

	MATERIALS AND METHODS

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Isolated Heart Model

Isolated hearts were prepared as previously described in a number of earlier studies (13, 18, 32, 34, 35). DutchBelted rabbits (500 g) were injected with heparin (20 U) and anesthetizedwith ketamine (500 U) and Telozol (200 U). Hearts were excisedfrom the rabbits and retrograde perfused via aortic cannulationwith a modified, phosphate-free Krebs-Henseleit buffer solutioncontaining (in mM) 116 NaCl, 4 KCl, 1.5 CaCl₂, 1.2 MgSO₄, 1.2NaHPO₄, 25 NaHCO₃, and 5 glucose and oxygenated with 95% O₂-5%CO₂. The hydrostatic perfusion column was 100 cm, and temperatureof the buffer at the myocardium was maintained at 37°C. A latexballoon containing water was inserted into the left ventricle.The balloon was connected to a pressure transducer to enable themonitoring of left ventricular developed pressure (LVDP) and heartrate (HR) throughout each experiment. The end-diastolic pressureof the heart was set at 5-10 mmHg by adjusting the volume of theballoon. Myocardial oxygen consumption (M $V$ O₂) was calculatedfrom the difference in O₂ content of perfusion medium in the supplyline, and coronary effluent was collected from the pulmonary artery(21).

Perfusate pH was reduced from 7.2 to 6.6 by decreasing the buffer content of bicarbonate to 6 mM. As previously reported,there is a simultaneous reduction in LVDP and HR at low pH (32).To maintain normal V_TCA rates at this low pH, supplemental CaCl₂was added to the perfusate to normalize the rate-pressure product(RPP) and match control levels of M $V$ O₂ (32). With the metabolicdemands of the heart normalized, we then utilized ¹³C NMR spectroscopy to monitor V_TCA and the interconversion between $alpha$ -ketoglutarate and glutamate in response to reduced K_m of $alpha$ -KGDHfor $alpha$ -ketoglutarate.

Experimental Protocol

All hearts were perfused with the modified Krebs-Henseleit buffer containing 5 mM unlabeled glucose. Coronary effluent wasdiscarded, and the hearts were given 10 min to stabilize rate-pressureproduct (RPP = HR × LVDP) before the buffer substrate was switchedfrom the glucose to 2.5 mM unenriched acetate. The buffer substratewas then switched from unlabeled acetate to a recirculated reservoirof 2.5 mM enriched [2-¹³C]acetate (Isotec, Miamisburg, OH) for 40 min to ensure steady-stateisotopic enrichment at the end point of the protocol (13, 18).Subsequent ³¹P and ¹³C NMR spectra were acquired from two experimental groups: a controlgroup (buffer pH = 7.3 ± 0.1, n = 7) and a group with increasedaffinity of $alpha$ -KGDH for $alpha$ -ketoglutarate (i.e., a reduction in K_m)by perfusing at low pH and increased buffer CaCl₂ to normalizecardiac function and respiratory rates as described above (bufferpH = 6.6 ± 0.1, CaCl₂ = 3.0 ± 1.0 mM; n = 7). The hearts werethen removed from the magnet, freeze-clamped, and prepared forbiochemical assays and high-resolution ¹³C NMR analysis.

NMR Measurements

For NMR analysis, perfused hearts were positioned in a 20-mm broad-band probe and placed in a 9.4-T/89-mm vertical-bore superconductingNMR magnet. The magnet was interfaced to a Bruker MSL 400 systemfor data acquisition. Magnetic field homogeneity was optimizedby first shimming all hearts to a proton linewidth of 15-30 Hz.After 10 min of shimming, we acquired a ³¹P spectrum of heart to establish heart viability, high-energyphosphate content, and intracellular pH. ³¹P NMR spectra were acquired in 128 scans using a 161-MHz, 45°excitation pulse, a 1.8-s repetition time, 35 parts/min sweepwidth, and 8 K data set. Postprocessing of the summed free inductiondecay (FID) NMR data included 20-Hz line broadening, Fourier transformation,and phase correction. Peak assignments were made with referenceto the well-established resonance signals of phosphocreatine and $alpha$ -, $beta$ -, and $gamma$ -ATP. Intracellular pH was calculated based on thechemical shift of the inorganic phosphate signal as describedpreviously (20).

Carbon spectra were acquired at 100 MHz with a bilevel broad-band decoupling scheme (14). Carbon spins were nutated witha 45° excitation pulse, 64-scans per 2.5-min spectrum, 10,000-Hzsweep width, and 8 K data set. Proton excitation at 400 MHz, 0.5W during the interpulse delay, and 7.0 W for 17 µs was appliedto irradiate carbon-proton coupling and produce nuclear Overhauserenhancement of carbon signal. Postprocessing of the summed FIDvalues NMR data included 20-Hz line broadening, Fourier transformation,and phase correction. Natural abundant ¹³C NMR signal was subtracted from subsequent ¹³C-enriched spectra. Resonance signals were identified by chemicalshift values (parts/min) referenced to dioxane at 67.4 parts/min.The signal intensity of each resonance was determined by curvefitting the peak to a Lorentzian curve and integrating the areaof the fit (NMR1 software, Tripos, St. Louis, MO).

Tissue Chemistry

After perfusion experiments, hearts were freeze-clamped, cooled in liquid nitrogen, and then ground to a powder form. Onegram of tissue was added to 2 g of 6% perchloric acid. After 10min, the sample was centrifuged, the pellet was discarded, andthe supernatant pH was adjusted to 7.2. An aliquot of this extractwas used for biochemical analysis. Glutamate, $alpha$ -ketoglutarate,citrate, and aspartate concentrations were determined from spectrophotometricand fluorometric techniques (1, 30). The remainder of theextract was lyophilized and resuspended in D₂O for high-resolutionNMR analysis.

The pH response of GOT activity from the cytosol of rabbit hearts was determined using methods to measure maximal reactionvelocity of the isolated isoenzymes as previously described (15,34). Separated cytosolic fractions of homogenized rabbit myocardiumwere tested for GOT activity, and the K_m for each substrate wasdetermined under two different pH conditions, 7.2 and 6.8.

High-Resolution ¹³C NMR

¹³C NMR high-resolution spectra of heart extracts were acquired with a 5-mm ¹³C probe and 9.4-T Bruker spectrometer system. Carbons were givena 45° excitation pulse, at a 1.8-s repetition, with a 100 parts/minsweep width, 32 K data set, and 3,000 or 6,000 scans per spectrum.Broad-band proton decoupling was applied throughout the collection.Postprocessing of the summed FID values included 1-Hz line broadening,Fourier transformation, and phase correction. Spectra were analyzedto determine the fraction of [2-¹³C]acetyl CoA entering the TCA cycle (F_c) and the ratio of anapleroticflux to citrate synthase (y) (18). Although it has already beendemonstrated that fractional enrichment of acetyl CoA (F_c) hasno bearing on actual flux measurements (33, 34), the potentialfor pH effects needed to be assessed. In vitro ¹³C NMR spectra also allowed the end-point fractional enrichmentof glutamate to be determined as described elsewhere (13).

Kinetic Model and Analysis

The V_TCA and interconversion rate (F₁) between cytosolic glutamate and mitochondrial $alpha$ -ketoglutarate were determined by fitting¹³C NMR data to a kinetic model of metabolic activity. We presentonly a brief account of the model here, whereas details are extensivelyreported elsewhere (33, 34).

Hearts are provided [2-¹³C]acetate, which contributes to the formation of acetyl CoA enriched at the C2 position for entry intothe TCA cycle. As shown in Fig. 1, this places the label at C4of $alpha$ -ketoglutarate. $alpha$ -Ketoglutarate can be transaminated to formglutamate where the label is incorporated into the C4. The bulkof the ¹³C NMR-observed glutamate pool is cytosolic (9), and the rateof the exchange has been shown to be largely determined by thephysical transport of $alpha$ -ketoglutarate across the mitochondrialmembrane (34). $alpha$ -Ketoglutarate could also be oxidized by thedehydrogenase. Oxidation of $alpha$ -ketoglutarate shifts the label toC2 or C3 of the symmetric succinate molecule. As the carbon labelis recycled within the pathway and reenters the first span ofthe cycle, the labeled carbon will label either C2 or C3 of $alpha$ -ketoglutarateand glutamate.

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Fig. 1. Diagram of labeling scheme within tricarboxylic acid (TCA) cycle and related metabolites in isolated heart as observed by dynamic ¹³C nuclear magnetic resonance (NMR) spectroscopy. [2-¹³C]acetate enters TCA cycle via [2-¹³C]acetyl CoA. * Initial sites of ¹³C labeling at C4 positions of citrate, $alpha$ -ketoglutarate, and glutamate. $dagger$ Recycling of ¹³C within TCA cycle results in appearance of label at secondary C2 and C3 positions with equal probability.

Kinetic equations describing the presteady-state labeling of glutamate and other key metabolic pools were derived by the principleof mass conservation. This kinetic model is composed of nine differentialequations defining the flux through each compartment and includesconsiderations of anaplerotic flux (33, 34). Metabolic poolsizes were also required as input parameters. The concentrationsof glutamate, aspartate, citrate, and $alpha$ -ketoglutarate were determinedby enzymatic assays. The concentration of metabolite pools knownto be too small to influence the flux measurements, such as malateand oxaloacetate, was taken from the literature values obtainedfrom hearts perfused under similar substrate conditions: 0.60mM malate and 0.04 mM oxaloacetate (23, 28, 33). V_TCA andthe F₁ between cytosolic glutamate and mitochondrial $alpha$ -ketoglutaratewere determined by nonlinear least-square fitting of the modelto ¹³C NMR data of glutamate C2 and C4 enrichment.

Isolated Mitochondria Experiments

Heart mitochondria were prepared from Dutch Belted rabbits according to the method of Chance and Hagihara (2) with fewmodifications. The animals were of the same age and size as forparallel NMR experiments on intact rabbit hearts. The initialfine mince of heart tissue was suspended in isolation medium consistingof 225 mM sucrose, 75 mM mannitol, 5 mM 3-(N-morpholino)propanesulfonicacid (pH 7.0), 0.1 mM EDTA, and 0.5 mg/1 ml of the proteinasenagarse (Sigma protease P4789). The tissue was rapidly dispersedwith a Tekmar tissumizer set at low speed. The homogenate wasthen diluted 10-fold with isolation medium without nagarse. Mitochondriawere separated from the homogenate by differential centrifugationomitting nagarse in subsequent washes (2). The isolated mitochondriahad respiratory control ratios ranging from 7.0 to 10.0.

Subsequent experiments with the mitochondria were carried out in incubation media consisting of 120 mM KCl, 30 mM 3-(N-morpholino)propanesulfonicacid, 20 mM KH₂PO₄, 5 mM NaCl, 2 mM MgCl₂, 10 U/ml hexokinase,and 20 mM glucose. Phosphate concentration in the media was highbecause it was consumed at a rate of 2.5 µmol · ml¹ · min¹ over 4 min. However, because the dicarboxylate carrier for theexchange of malate and inorganic phosphate is virtually absentin heart mitochondria, the phosphate concentration of the bufferhad no effect on the activity of the $alpha$ -ketoglutarate-malate exchanger(25). The pH was adjusted to pH 7.2 (medium A) or pH 6.8 (mediumB), and experiments were performed at 37°C.

The relative affinity of $alpha$ -KGDH for the substrate $alpha$ -ketoglutarate was determined by following the rate of $alpha$ -ketoglutarateoxidation. To measure O₂ consumption, 0.5 mg mitochondrial proteinwas added to a stirred, temperature-equilibrated, closed glasschamber fitted with a Clark electrode. Decreases of O₂ in thechamber were measured polarographically. A double-reciprocal plotof oxygen consumption versus initial $alpha$ -ketoglutarate concentrationwas prepared. Oxygen utilization was measured at six concentrationsof $alpha$ -ketoglutarate ranging from 0.02 to 1.0 mM, and the apparentK_m was determined from the $alpha$ -ketoglutarate concentration thatproduced one-half the maximum oxygen consumption.

Other experiments were designed to measure individual reactions involved in the metabolism of $alpha$ -ketoglutarate. In these experimentsmitochondria were incubated under one of the following four conditionsfor media at pH 7.2 or pH 6.8: condition IA, 2.5 mM [2,3-³H]glutamate, 2.5 mM [2-¹⁴C]pyruvate, 0.2 mM $alpha$ -ketoglutarate, and 5 mM malate (pH 7.2);condition IB, same as condition IA but adjusted to pH 6.8; conditionIIA, 2.5 mM [2,3-³H]glutamate, 2.5 mM pyruvate, 0.2 $alpha$ -[U-¹⁴C]ketoglutarate, and 5 mM malate (pH 7.2); or condition IIB, sameas condition IIA but adjusted to pH 6.8. This allowed us to trackthe fate of $alpha$ -ketoglutarate generated by isocitrate dehydrogenase(from [¹⁴C]pyruvate) or by aspartate aminotransferase (from [2,3-³H]glutamate) or by transport across the mitochondrial membrane(from medium $alpha$ -[U-¹⁴C]ketoglutarate under similar incubation conditions with differingpH). Products of the ³H- and ¹⁴C-labeled substrates were separated by ion exchange chromatographyusing Dowex 1 chloride columns (17) and quantified by double-labelcounting in a liquid scintillation counter. The design, rationale,and procedures for calculating fluxes from these labeled substrateshave been described previously in a study of effects of Ca²⁺ and H⁺ on $alpha$ -ketoglutarate metabolism in liver and kidney mitochondria(26).

Statistical Analysis

Data set comparisons were performed with Student's unpaired, two-tailed t-test. Differences in mean values were consideredstatistically significant at a probability level of <5% (P < 0.05).For analysis of paired transaminase enzymes from the same heartsat two different pH values, the paired t-test was applied.

	RESULTS

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Studies in Isolated Mitochondria

pH effects on $alpha$ -ketoglutarate metabolism and efflux. The relative affinity of $alpha$ -KGDH for the substrate $alpha$ -ketoglutarate asassessed by K_m was determined at normal (pH 7.2) and low pH (pH6.8) in isolated mitochondria by following the rate of $alpha$ -ketoglutarateoxidation. At an incubation medium pH of 7.2, K_m was 0.23 ± 0.06mM, and at pH 6.8, K_m was 0.10 ± 0.03 mM. The reduction in K_mindicates that the affinity of $alpha$ -KGDH for the substrate $alpha$ -ketoglutarateincreases with a drop in pH. The decrease in the K_m of $alpha$ -KGDHwith increasing proton concentration has been reported previouslyfor intact mitochondria from kidney (26) and is now here confirmedin intact cardiac mitochondria.

Subsequent experiments with isolated mitochondria were designed to find out whether the increase in the affinity of $alpha$ -KGDHfor its substrate, $alpha$ -ketoglutarate, significantly changes theratio between the amount of $alpha$ -ketoglutarate that proceeds aroundthe citric acid cycle compared with the amount that effluxes fromthe mitochondria. To establish the pH-dependent reduction in theK_m of $alpha$ -KGDH for heart mitochondria and to measure the influenceof altered $alpha$ -ketoglutarate oxidation on $alpha$ -ketoglutarate effluxrates, we incubated isolated rabbit heart mitochondria in thestandard incubation media plus 2.5 mM [2-¹⁴C]pyruvate, 0.2 mM $alpha$ -ketoglutarate, 2.5 mM [2,3-³H]glutamate, 5 mM malate, 1 mM ADP, 20 mM glucose, and 10 U ofhexokinase. The hexokinase trap kept ADP high and respirationmaximal. High malate concentration trapped ¹⁴C cycling around the citric acid cycle and ensured that no ¹⁴CO₂ was generated from pyruvate. From data shown in Table 1,the amount of [¹⁴C]glutamate formed from [¹⁴C]pyruvate in 4 min demonstrates that at both normal and low pH,a factor of seven to nine times more carbon from pyruvate leavesthe mitochondria as $alpha$ -[¹⁴C]ketoglutarate than leaves as [¹⁴C]glutamate.

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Table 1. Formation of [¹⁴C]glutamate vs. formation of $alpha$ -[¹⁴C]ketoglutarate from [2-¹⁴C]pyruvate in isolated mitochondria

From the condensation reaction catalyzed by citrate synthase, the ¹⁴C from pyruvate labels citrate, isocitrate, and then $alpha$ -ketoglutarate.At this point, the radiolabel can enter one of three pathways,which were quantified by chromatographic separation of the ¹⁴C-labeled metabolites. One pathway involves transport of the $alpha$ -ketoglutarateout of the mitochondria through the $alpha$ -ketoglutarate-malate exchangetransporter. Without any added malate in the media to enable thistransport, no $alpha$ -ketoglutarate will accumulate in the suspension.A second pathway for the $alpha$ -[¹⁴C]ketoglutarate is oxidation to form succinate and malate. A thirdpathway is the transamination inside the mitochondria via themitochondrial GOT enzyme to form [¹⁴C]glutamate, a small portion of which can leave the mitochondriavia the slow glutamate-hydroxyl carrier. In detecting these labeledmetabolites in the mitochondrial suspension, it is the metabolitesthat are in the media and not inside the mitochondria that aremeasured, because the intramitochondrial volume in the suspensionis only 0.1% of the total volume. As shown in Table 1, the amountof [¹⁴C]glutamate formed from [¹⁴C]pyruvate in the mitochondria and released into the media wasvery small relative to the amount of $alpha$ -[¹⁴C]ketoglutarate that accumulated in the suspension media. Thusany glutamate formed in the mitochondria is only a small fractionof that which would be detected in the cytosol of the intact heartsas opposed to the larger pool of glutamate produced in the cytosolfrom $alpha$ -ketoglutarate.

The products of $alpha$ -KGDH were also monitored in similar experiments, and the results are shown in Table 2. As described abovein the MATERIALS AND METHODS, the incubation conditions differedwith respect to pH (either 6.8 or 7.2) and with respect to whetherpyruvate or $alpha$ -ketoglutarate was labeled with ¹⁴C. All three substrates (pyruvate, glutamate, and $alpha$ -ketoglutarate)contribute to the flux through $alpha$ -KGDH, and flux from each wasdetermined by measuring the amount of ¹⁴C and ³H in the $alpha$ -KGDH products succinate and malate. These constitutethe major end products, since fumarate and succinyl CoA couldnot be detected in these experiments and since malate blockedfurther cycling. Also shown in Table 2 is the rate of effluxof $alpha$ -ketoglutarate generated by each substrate compared with itsrate of oxidation in the citric acid cycle by $alpha$ -KGDH. The dataindicate that lowering the K_m of $alpha$ -KGDH increases the percentageof $alpha$ -ketoglutarate that is oxidized without first entering theexternal medium, where in intact cells it would be immediatelyconverted to glutamate. Generation of matrix $alpha$ -ketoglutarate fromglutamate was lower than generation of $alpha$ -ketoglutarate from pyruvateor from transport of medium $alpha$ -ketoglutarate into the matrix. Whentotal flux from all substrates through $alpha$ -KGDH is compared withtotal $alpha$ -ketoglutarate efflux, the decrease in pH from 7.2 to 6.8changes the oxidation-to-efflux ratio from 1.02 to 1.92.

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Table 2. Mitochondrial $alpha$ -[¹⁴C]KG oxidation and efflux

Isolated Heart Studies

Cardiac performance. Contractile function, intracellular pH, and oxygen consumption of isolated perfused hearts were all monitored.The control group displayed a mean workload of 17,100 ± 4,100mmHg · beats · min¹, intracellular pH 7.05, and M $V$ O₂ 19.4 ± 3.7 µmol · min¹ · g¹. In the second group, reducing buffer pH to 6.6 resulted in a30 ± 10% decline in RPP before augmentation with Ca²⁺. Increasing Ca²⁺ to 3.0 ± 1.0 mM elevated RPP to control values (18,200 ± 5,600mmHg · beats · min¹) and M $V$ O₂ (24.0 ± 4.1 µmol · min¹ · g¹). At this performance level, intracellular pH was 6.89 ± 0.04.Bioenergetic state was similar in both groups, as revealed by³¹P NMR spectra. Phosphocreatine-to-ATP ratios in both groups werecontrol = 2.00 ± 0.52 and low pH group = 2.01 ± 0.37.

Flux measurements from intact hearts. Representative proton-decoupled ¹³C spectra (time-enrichment curves) of an isolated heart perfusedwith buffer pH adjusted to 6.6 and increased CaCl₂ content anda heart perfused under control conditions are shown in Fig. 2,A and B, respectively. Control spectra are similar to data previouslypresented (13, 14, 35). The signal intensities arising fromthe glutamate C2 and C4 resonances were curve fit to a Lorentzianline shape and plotted as a function of time. Figure 3 shows thistime course of glutamate enrichment. These curves were fit toa single exponential, and time constants were evaluated for therise of each curve. The time constants for the glutamate C4 andC2 of the control group were 9.4 and 16.5 min, respectively. Forhearts perfused with buffer pH 6.6 and increased CaCl₂ content,glutamate C4 and C2 enrichment time constants were 9.4 and 11.8min, respectively. These time constants are not a direct indexof V_TCA, because labeling of the glutamate is dependent on boththe cycle flux and the exchange of label between $alpha$ -ketoglutarateand glutamate pools (34). It should be noted, however, thatthe time constant for the C4 for either group are similar, whereasthe C2 time constants reveal a slower enrichment rate in controls.

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Fig. 2. Dynamic ¹³C NMR spectra of isolated rabbit hearts perfused with 2.5 mM [2-¹³C]acetate for buffer pH 6.6, 3.0 ± 1.0 mM CaCl₂ (A), and buffer pH 7.2, 1.5 mM CaCl₂ (B). Peak assignments include GLU-C2, second carbon of glutamate; GLU-C4, fourth carbon of glutamate; GLU-C3, third carbon of glutamate; ACE-C2, second carbon of acetate. PPM, Parts/min.

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Fig. 3. Time course of glutamate ¹³C enrichment from both NMR measurements of intact hearts and kinetic analysis. Open squares, glutamate C4 enrichment; filled squares, glutamate C2 enrichment; solid lines, least-squares fitting of the model to enrichment curves. A: buffer pH 7.2, 1.5 mM CaCl₂; B: buffer pH 6.6, 3.0 ± 1.0 mM CaCl₂.

The results of kinetic analysis of the enrichment of glutamate provided V_TCA and the F₁ between mitochondria $alpha$ -ketoglutarateand cytosolic glutamate pools (33, 34). The experimental perturbationsand findings are summarized in Fig. 4. V_TCA was similar in controlhearts and in hearts with the reduced K_m of $alpha$ -KGDH: control group= 10.0 ± 0.2 µmol · min¹ · g¹; low K_m group = 10.1 ± 0.4 µmol · min¹ · g¹. However, the F₁ values of interconversion between $alpha$ -ketoglutarateand glutamate, which represent $alpha$ -ketoglutarate efflux, were significantlyreduced with the reduction in the K_m of $alpha$ -KGDH. Control valuesfor F₁ were 9.3 ± 0.6 µmol · min¹ · g¹ versus 2.8 ± 0.4 µmol · min¹ · g¹ at the low K_m (P < 0.05). These results indicate that mitochondrial $alpha$ -ketoglutarate exchange with cytosolic glutamate is significantlyreduced when the affinity of $alpha$ -KGDH for $alpha$ -ketoglutarate is increased.This result of reduced F₁ is attributed to the K_m change in thedehydrogenases, because GOT is not sufficiently affected by pHchanges over physiological range, as discussed below and elsewhere(5), and the transporter is also insensitive to pH (22).

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Fig. 4. Schematic summary of experimental findings for intact hearts. Relative affinity, K_m, of $alpha$ -ketoglutarate dehydrogenase ( $alpha$ -KGDH) for $alpha$ -ketoglutarate ( $alpha$ -KG) was significantly reduced (P < 0.05) in isolated mitochondria incubated with media at pH 7.2 (*) compared with mitochondria incubated with media pH 6.8 ( $ddager$ ). In intact hearts, (perfusion condition: *, buffer pH 7.2, 1.5 mM CaCl₂; and $dagger$ , buffer pH 6.6, 3.0 ± 1.0 mM CaCl₂), reduction in $alpha$ -KG exchange rate (P < 0.05), along with observed drop in cytosolic glutamate (P < 0.05), indicates that at a fixed TCA cycle rate lowered K_m of $alpha$ -KG dehydrogenase for $alpha$ -KG reduced availability of $alpha$ -KG for transporter-dependent efflux to cytosol and conversion to glutamate.

Metabolite content and in vitro measurements. Steady-state metabolite contents are listed in Table 3. Control values arein agreement with those previously reported (15, 34). Citrate, $alpha$ -ketoglutarate, and aspartate levels were not statistically differentbetween experimental groups. However, total glutamate contentwas 38% reduced in the hearts perfused at low pH and increasedCaCl₂. As shown in previous studies (15, 34) and confirmedin Table 1, the cytosolic GOT enzyme is the critical isoformof the transaminase that accounts for the observed exchange of $alpha$ -[¹³C]ketoglutarate with the NMR-detected glutamate pool in the cytosol.Despite published data showing only a very shallow dependenceon pH across a wider range from 6.0 to 8.0 (5), in our experimentsthe kinetic values for the cytosolic GOT in both groups were actuallyreduced slightly by 24% from a mean of 0.46 ± 0.07 µmol · min¹ · mg total heart protein¹ at pH 7.2 (n = 6) to 0.35 ± 0.08 µmol · min¹ · mg total heart protein¹ at pH 6.8 (n = 6) (P < 0.05). From the double-displacement reactionkinetics, this small but significant drop in the activity of thecytosolic GOT corresponded to calculated flux rates of 105 µmol· min¹ · g dry wt¹ at pH 7.2 and 80 µmol · min¹ · g dry wt¹ at pH 6.8 (15). The slightly reduced GOT flux clearly remainedtoo fast, by 29-fold in comparison with F₁, to account for the70% reduction of F₁ at low pH. These data are consistent withour previous observations that flux through GOT is much too fastto account for the observed values of interconversion between $alpha$ -ketoglutarate and glutamate (15, 34).

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Table 3. Steady-state metabolite content in intact hearts

In addition, high-resolution in vitro ¹³C NMR spectra of tissue extracts revealed that substrate utilization under these conditionswas not affected by the percentage of acetyl groups entering theTCA cycle at citrate synthase that are enriched with ¹³C. The percentage of total acetyl CoA derived from exogenous ¹³C-enriched acetate was 92% in controls and 90% at low pH. Thevalues were not different between groups, and moreover, this valuedoes not affect the measurements of flux through the TCA cycle(33, 34). The relative contribution of anaplerotic flux intothe TCA cycle versus that at citrate synthase was not differentin either group (only ranging from 4 to 8%) and did not contributeto the differences observed in the flux measurements from intacthearts.

Comparison of $alpha$ -ketoglutarate oxidation and efflux in the two preparations. Corresponding values for $alpha$ -ketoglutarate oxidationand efflux are catalogued in Table 4. Values for F₁ from intacthearts are shown as measurements of $alpha$ -ketoglutarate efflux rates,because $alpha$ -ketoglutarate influx-efflux across the mitochondrialmembrane is known to predominate the rate contributions to F₁(34). The relative changes in the ratio of $alpha$ -ketoglutarate effluxto oxidation are consistent with a change in the K_m of $alpha$ -KGDHin the intact heart, as was confirmed for the isolated mitochondria.

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Table 4. Effect of altered K_m at fixed tricarboxylic acid cycle flux rates on $alpha$ -KG oxidation vs. efflux in intact hearts

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Early work by Randle et al. (23) suggested that the TCA cycle operated along two spans: acetyl CoA to $alpha$ -ketoglutarate controlledby citrate synthase, and $alpha$ -ketoglutarate to oxaloacetate controlledby $alpha$ -KGDH. This scheme permits a redistribution of carbons betweencycle intermediates in the mitochondria during transition statesof heart workload. Thus $alpha$ -KGDH balances flux through the two spansof the TCA cycle. In addition, $alpha$ -ketoglutarate is a common intermediateamong different pathways within the mitochondria and cytosol.Thus competition for $alpha$ -ketoglutarate between further oxidationin the TCA cycle and efflux to the cytosol is partly regulatedby $alpha$ -KGDH. This adjustment of cytosolic and mitochondrial $alpha$ -ketoglutaratelevels by $alpha$ -KGDH is an important factor in coordinating flux withthe $alpha$ -ketoglutarate-malate transporter.

In the present study, the effects of altering the enzyme-substrate affinity of a rate-limiting dehydrogenase enzyme of theTCA cycle on metabolite exchange across the mitochondrial membranewere studied in both intact hearts and isolated mitochondria.In experiments on intact perfused hearts, metabolic rates weredetermined by fitting a kinetic model of isotope enrichment tothe dynamic ¹³C spectra acquired from hearts. We have already demonstrated ina previous study that the measured activity of the glutamate oxaloacetatetransaminase is much too fast to account for the observed ratesof interconversion between $alpha$ -[¹³C]ketoglutarate from the mitochondria and glutamate in the cytosol(34), indicating that $alpha$ -ketoglutarate efflux from mitochondriais the rate-determining step in the ¹³C labeling of the large cytosolic glutamate pool. By combiningadditional ¹³C NMR experiments on intact hearts with radioisotope studies ofisolated mitochondria, we were able to examine the balance betweenrates of $alpha$ -ketoglutarate oxidation and efflux in the current study.

The results from isolated hearts are consistent with those from the isolated mitochondria to indicate that increasing theaffinity of $alpha$ -KGDH for the substrate $alpha$ -ketoglutarate (i.e., adecrease in K_m) increased $alpha$ -ketoglutarate oxidation relative tothe rate of efflux from the mitochondria for exchange with cytosolicglutamate. With the same workload in both groups of hearts maintained,oxygen consumption and V_TCA were held relatively constant despitealtering the enzyme affinity with pH. The influence of shiftingthe balance between $alpha$ -ketoglutarate oxidation and $alpha$ -ketoglutarateefflux from the mitochondria was evident in the reduced valuesfor the F₁ between $alpha$ -ketoglutarate and glutamate and the observeddrop in glutamate. These results demonstrate the link betweenmitochondrial and cytosolic metabolites at this branch point betweenoxidation metabolism and metabolic communication between the mitochondriaand the cytosol.

Competition for substrate by the $alpha$ -ketoglutarate transporter and $alpha$ -KGDH exists by virtue of their apparent K_m values (11,26, 27). Earlier work reported that the reversible, nonelectrogenic,pH-insensitive $alpha$ -ketoglutarate-malate transporter of the mitochondrialmembrane has an apparent K_m of 1.5 mM for $alpha$ -ketoglutarate on thematrix side of the carrier (3, 22, 24), whereas the K_mof $alpha$ -KGDH for $alpha$ -ketoglutarate was reported as 0.67 mM (11).This makes both oxidation and efflux very sensitive to regulationby the $alpha$ -ketoglutarate concentration in the mitochondrial matrix.The transamination via GOT has been shown by others to be pH insensitivefrom pH 6 to 8 (5). In this study, we actually did find thatthe cytosolic GOT isozyme showed a 24% reduction in activity atlow pH, but this relatively small drop in activity is not sufficientto produce any measurable effect on the interconversion rate between $alpha$ -ketoglutarate and glutamate (F₁) in the heart. Instead, thisdrop in cytosolic GOT activity at pH 6.8 would need to be at least96.5% to affect the observed F₁. In addition, the $alpha$ -ketoglutaratetransporter is already known to be pH independent (8, 22).Therefore, the observed changes were due to the effect of pH inreducing the K_m of the $alpha$ -KGDH.

In this study, we report on the effect of pH on the K_m of $alpha$ -KGDH in isolated cardiac mitochondria. These values have beenpreviously reported for liver and kidney mitochondria (16, 26).The pH of the bathing medium was reduced from 7.2 to 6.8, andthe rate of $alpha$ -ketoglutarate oxidation was followed as a functionof oxygen consumption. Under our conditions, the relative indexK_m of $alpha$ -KGDH affinity was 0.23 mM at pH 7.2, and at pH 6.8, K_mreduced to 0.10 mM. In addition, the K_m of $alpha$ -KGDH for the substrate, $alpha$ -ketoglutarate, has been shown to be largely influenced by changesin intramitochondrial Ca²⁺ (6, 19, 29). Wan et al. (29) increased matrix free Ca²⁺ from 0 to 0.64 mM and reported the apparent K_m for $alpha$ -ketoglutaratedecreased from 2.5 to 0.6 mM. Thus increasing either H⁺ or Ca²⁺ content increased the activity of $alpha$ -KGDH, as reported by others(26, 29). In the present study, ¹³C-NMR spectroscopy provided a noninvasive means of studying suchmetabolic regulation in the intact beating heart.

The analogous experiment to alter the K_m of $alpha$ -KGDH for $alpha$ -ketoglutarate was performed in the intact functioning heart. Energydemand and oxygen consumption were held constant by careful regulationof buffer pH and CaCl₂ content. Decreasing buffer pH resultedin an initial 30 ± 10% reduction in heart RPP. This is consistentwith results previously reported for the isolated perfused heart(32). The reduction may be due to the influence of H⁺ on contractile processes that occur after the interaction betweenCa²⁺ and troponin (4). At the low buffer pH 6.6, ³¹P NMR spectra revealed an intracellular pH of 6.89. IncreasingCaCl₂ content of the buffer returned the RPP, energy demand, andM $V$ O₂ to normalized values. The increase in intracellular Ca²⁺ and H⁺ has been shown to increase both intramitochondrial Ca²⁺ and H⁺ content (7, 29). In the isolated, perfused rabbit heartexperiment, the affinity of $alpha$ -KGDH for $alpha$ -KG was altered by changingintracellular pH and Ca²⁺ content without changing net flux through the enzyme reaction.

Kinetic analysis of dynamic ¹³C NMR data provided V_TCA and F₁ between $alpha$ -ketoglutarate and glutamate. Figure 4 shows the resultswith reference to the TCA cycle and transport pathways first illustratedin Fig. 1. Several important points can be inferred from thesedata. First, V_TCA was driven by the energetic demands of the matchedworkloads in both groups of hearts (control group, RPP = 17,000± 4,100 mmHg · beats · min¹; reduced K_m group, RPP = 18,200 ± 5,600 mmHg · beats · min¹). Therefore, the perturbations of pH and Ca²⁺ were observed at fixed TCA cycle rates (control group, V_TCA =10.0 ± 0.2 µmol · min¹ · g¹; reduced K_m group, V_TCA = 10.1 ± 0.4 µmol · min¹ · g¹). Second, the reduction in the interconversion rate between $alpha$ -ketoglutarateand glutamate (control group, F₁ = 9.3 ± 0.6 µmol · min¹ · g¹; reduced K_m group, F₁ = 2.8 ± 0.4 µmol · min¹ · g¹), along with the observed drop in cytosolic glutamate (controlgroup, [Glu] = 29.1 ± 3.0 mmol/g; reduced K_m group, [Glu] = 17.7± 3.0 mmol/g), suggests that the dehydrogenase was able to outcompete the membrane transporter for $alpha$ -ketoglutarate. This wouldbe possible if the affinity of the dehydrogenase for $alpha$ -ketoglutaratehad increased (i.e., a decrease in K_m) with the drop in pH andincrease in Ca²⁺. At a constant V_TCA, this probably slowed the rate of $alpha$ -ketoglutarateefflux for interconversion with glutamate in the cytosol. Theobserved reduction in the total glutamate pool in response tolowered pH is consistent with this hypothesis.

The result of the relative increase in the ratio $alpha$ -ketoglutarate oxidation to efflux from the mitochondria followed by conversionto cytosolic glutamate is that labeled $alpha$ -ketoglutarate is recycledto succinate at a rate faster than that at which it is convertedto glutamate. This change accelerates the mixing of the labelfrom the C4 to the C2 position within the TCA cycle relative tothe exchange of $alpha$ -ketoglutarate with the glutamate pool. Thiscondition, along with the reduction in glutamate pool size, causedthe time difference between labeling at C4 and C2 of glutamateto become reduced without changes in net V_TCA. This perturbationresulted in little if any difference in the rate of appearanceof ¹³C at the C4 position of glutamate (time constant = 9.4 min), whereaslabeling at the C2 position occurred at an increased rate thatwas associated with a reduction in the time constant from 16.5to 11.8 min. The results of our kinetics analysis also accountedfor this perturbation by demonstrating no change in V_TCA withthe reduction in F₁.

Although experiments with isolated mitochondria were intended to confirm the effectiveness of the protocol to manipulate K_m(26), it is of interest that the pH response in the ratios of $alpha$ -ketoglutarate oxidation to efflux were closely matched betweenintact hearts and isolated mitochondria metabolizing labeled glutamate.In these instances (see Table 2), oxidation-to-efflux ratiosat normal pH were 1.28 in isolated mitochondria and 1.08 in intacthearts, and oxidation-to-efflux ratios at low pH were 3.76 inisolated mitochondria versus 3.57 in intact hearts. In the isolatedmitochondria, the ratio of $alpha$ -ketoglutarate oxidation to effluxvaried somewhat depending on the source of the $alpha$ -ketoglutarateand on pH. However, the pH effect was largest when $alpha$ -ketoglutaratewas generated by aspartate aminotransferase via [2,3-³H]glutamate. This is probably due to compartmentation within themitochondria. As noted in the results, the production of matrix $alpha$ -ketoglutarate from glutamate in isolated mitochondria was lowerthan the production of $alpha$ -ketoglutarate from pyruvate or from the $alpha$ -ketoglutarate entering from the medium. The aminotransferase,therefore, may have had access to a particular pool of $alpha$ -KGDHthat was not available to the other substrates and was thereforeless saturated than pools of $alpha$ -KGDH near the $alpha$ -ketoglutarate translocaseor near isocitrate dehydrogenase. Thus the effect of the pH changemay have been largest on this least saturated pool of $alpha$ -KGDH,as may be expected for the intact functioning heart, which showedstrikingly similar ratios to that observed in mitochondria metabolizinglabeled glutamate. In any event, it seems likely that the substrate-relateddifferences in the effect of pH on the oxidation-to-efflux ratiowas due to lack of mixing and slow diffusion in the mitochondrialmatrix. In each instance, independent of the source of the $alpha$ -ketoglutarategenerated in the matrix, a decrease in pH substantially changedthe percentage of the $alpha$ -ketoglutarate, which continues on in thecitric acid cycle without exciting the mitochondria.

In conclusion, sequential ¹³C NMR spectra were obtained from intact hearts under conditions of normal and altered $alpha$ -KGDH kineticsduring perfusion with [2-¹³C]acetate. Dynamic ¹³C NMR analysis revealed the balance between mitochondria TCA cyclerates and metabolite exchange between the mitochondria and cytosol.The data indicate that elevated H⁺ and Ca²⁺ content increased $alpha$ -ketoglutarate oxidation and reduced $alpha$ -ketoglutarateefflux from the mitochondria and isotope exchange with cytosolicglutamate. These results indicate that ¹³C NMR is sensitive to changes in kinetic parameters of the TCAcycle dehydrogenases within the mitochondria of intact heartsas confirmed by our parallel experiments in mitochondria.

	ACKNOWLEDGEMENTS

This work was supported by National Heart, Lung, and Blood Institute Grants RO1 HL-49244 (to E. D. Lewandowski), RO1 HL-56178(to E. D. Lewandowski), and P01 HL-18708-21 (to K. F. LaNoue)and was performed during the tenure of an Established InvestigatorAward from the American Heart Association to E. D. Lewandowski.The findings of this study have been presented, in part, in abstractform at the 69th Scientific Sessions of the American Heart Association.

	FOOTNOTES

Address for reprint requests: E. D. Lewandowski, NMR Center, Massachusetts General Hospital, Bldg. 149, 13th St., Charlestown, MA 02129.

Received 7 July 1997; accepted in final form 15 October 1997.

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