Kinetic control of mitochondrial ATP synthesis

In order to gain a clearer understanding of the kinetic control of ATP synthesis, rat liver and rat heart mitochondria were incubated under conditions that resulted in various rates of net ATP synthesis or ATP hydrolysis. Radiolabeled phosphate was included in the incubation media, and exchange rates between phosphate and ATP were determined as a function of rates of net ATP synthesis. Since ATP synthase is a highly reversible enzyme, the catalyzed reaction was expected to approach equilibrium especially at low rates of respiration and net ATP synthesis. Thus ADP + Pi V1 in equilibrium V2 ATP. If V1 is the rate of incorporation of radiolabeled phosphate into ATP, then net ATP synthesis (or hydrolysis) is V1 - V2. Since V1 and V1 - V2 could be measured, it was possible to calculate V2. V1 doubled in the transition from zero to maximal net ATP synthesis, whereas V2 decreased by over 90% when the rate of ATP synthesis was high due to high-media ADP. In heart mitochondria at 37 degrees C when respiration increased from 104 +/- 10 to 842 +/- 51 nanoatoms of O2/(min X mg), incorporation of [33P]phosphate into ATP (V1) increased from 1,100 +/- 60 to 1,978 +/- 121 and V2 decreased from 1,100 to near zero. These data demonstrate that mitochondrial ATP synthesis does not occur near equilibrium under physiological conditions and relatively high rates of ATP synthesis. A reaction with a high ratio of forward to reverse flux is obviously not near equilibrium. The important most sensitively controlled reaction appears to be V2, ATP hydrolysis. Possible mechanisms of kinetic control of V2 are discussed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Point-of-care versus central testing of hemoglobin during large volume blood transfusion

Hypoxic preconditioning (HPC) may protect multiple organs from various injuries. We hypothesized that HPC would reduce lung injury in patients undergoing thoracoscopic lobectomy. In a prospective randomized controlled trial, 70 patients undergoing elective thoracoscopic lobectomy were randomly allocated to the HPC group or the control group. Three cycles of 5-min hypoxia and 3-min ventilation applied to the nondependent lung served as the HPC intervention. The primary outcome was the PaO2/FiO2 ratio. Secondary outcomes included postoperative pulmonary complications, pulmonary function, and duration of hospital stay. HPC significantly increased the PaO2/FiO2 ratio compared with the control at 30 min after one-lung ventilation and 7 days after operation. Compared with the control, it also significantly improved postoperative pulmonary function and markedly reduced the postoperative hospital stay duration. No significant differences between groups were observed in the incidence of pulmonary complications or overall postoperative morbidity. HPC improves postoperative oxygenation, enhances the recovery of pulmonary function, and reduces the duration of hospital stay in patients undergoing thoracoscopic lobectomy. This study was registered in the Chinese Clinical Trial Registry (ChiCTR-IPR-17011249) on April 27, 2017.     

Kinetic analysis of dynamic 13C NMR spectra: metabolic flux, regulation, and compartmentation in hearts.

Control of oxidative metabolism was studied using 13C NMR spectroscopy to detect rate-limiting steps in 13C labeling of glutamate. 13C NMR spectra were acquired every 1 or 2 min from isolated rabbit hearts perfused with either 2.5 mM [2-13C]acetate or 2.5 mM [2-13C]butyrate with or without KCl arrest. Tricarboxylic acid cycle flux (VTCA) and the exchange rate between alpha-ketoglutarate and glutamate (F1) were determined by least-square fitting of a kinetic model to NMR data. Rates were compared to measured kinetics of the cardiac glutamate-oxaloacetate transaminase (GOT). Despite similar oxygen use, hearts oxidizing butyrate instead of acetate showed delayed incorporation of 13C label into glutamate and lower VTCA, because of the influence of beta-oxidation: butyrate = 7.1 +/- 0.2 mumol/min/g dry wt; acetate = 10.1 +/- 0.2; butyrate + KCl = 1.8 +/- 0.1; acetate + KCl = 3.1 +/- 0.1 (mean +/- SD). F1 ranged from a low of 4.4 +/- 1.0 mumol/min/g (butyrate + KCl) to 9.3 +/- 0.6 (acetate), at least 20-fold slower than GOT flux, and proved to be rate limiting for isotope turnover in the glutamate pool. Therefore, dynamic 13C NMR observations were sensitive not only to TCA cycle flux but also to the interconversion between TCA cycle intermediates and glutamate.     

Nitrogen shuttling between neurons and glial cells during glutamate synthesis

The relationship between neuronal glutamate turnover, the glutamate/glutamine cycle and de novo glutamate synthesis was examined using two different model systems, freshly dissected rat retinas ex vivo and in vivo perfused rat brains. In the ex vivo rat retina, dual kinetic control of de novo glutamate synthesis by pyruvate carboxylation and transamination of alpha-ketoglutarate to glutamate was demonstrated. Rate limitation at the transaminase step is likely imposed by the limited supply of amino acids which provide the alpha-amino group to glutamate. Measurements of synthesis of (14)C-glutamate and of (14)C-glutamine from H(14)CO(3) have shown that (14)C-amino acid synthesis increased 70% by raising medium pyruvate from 0.2 to 5 mM. The specific radioactivity of (14)C-glutamine indicated that approximately 30% of glutamine was derived from (14)CO(2) fixation. Using gabapentin, an inhibitor of the cytosolic branched-chain aminotransferase, synthesis of (14)C-glutamate and (14)C-glutamine from H(14)CO(3)(-) was inhibited by 31%. These results suggest that transamination of alpha-ketoglutarate to glutamate in Müller cells is slow, the supply of branched-chain amino acids may limit flux, and that branched-chain amino acids are an obligatory source of the nitrogen required for optimal rates of de novo glutamate synthesis. Kinetic analysis suggests that the glutamate/glutamine cycle accounts for 15% of total neuronal glutamate turnover in the ex vivo retina. To examine the contribution of the glutamate/glutamine cycle to glutamate turnover in the whole brain in vivo, rats were infused intravenously with H(14)CO(3)(-). (14)C-metabolites in brain extracts were measured to determine net incorporation of (14)CO(2) and specific radioactivity of glutamate and glutamine. The results indicate that 23% of glutamine in the brain in vivo is derived from (14)CO(2) fixation. Using published values for whole brain neuronal glutamate turnover, we calculated that the glutamate/glutamine cycle accounts for approximately 60% of total neuronal turnover. Finally, differences between glutamine/glutamate cycle rates in these two model systems suggest that the cycle is closely linked to neuronal activity.     

Effects of adenosine receptor antagonism on protein tyrosine phosphatase in rat skeletal muscle

Earlier studies have shown that whole body adenosine receptor antagonism increases skeletal muscle insulin sensitivity in insulin-resistant Zucker rats. To find which steps in the insulin signaling pathway are influenced by adenosine receptors, muscle from lean and obese Zucker rats, treated for 1 week with the adenosine receptor antagonist, 1,3-dipropyl-8-(4-acrylate)-phenylxanthine (BWA1433), were analyzed. All rats were first anesthetized and injected intravenously (i.v.) with 1 IU of insulin. About 3 min later the gastrocnemius was freeze clamped. Insulin receptors were partially purified on wheat germ agglutinin (WGA) columns and insulin receptor kinase activity measured in control and BWA1433-treated lean and obese Zucker rats. Protein tyrosine phosphatase (PTPase) activity was also analyzed in subcellular fractions, including the cytosolic fraction, a high-speed particulate fraction and the insulin receptor fraction eluted from WGA columns. Administration of BWA1433 increased insulin receptor kinase activity in obese but not lean Zucker rats. PTPase activities were higher in the untreated obese rat muscle particulate fractions than in the lean rat particulate fractions. The BWA1433 administration lowered the PTPase activity of the obese rats but not the lean rats. Although the PTPase activity in WGA eluate fractions containing crude insulin receptors were similar in lean and obese animals, BWA1433 administration was found to lower the PTPase activities in the fractions obtained from obese but not from the lean rats. PTPases may be upregulated in muscles from obese rats due to activated adenosine receptors. Adenosine receptor blockade, by reducing PTPase activity, may thereby increase insulin signaling.     

Ammonia formation in isolated rat liver mitochondria

Studies of isolated rat liver mitochondria were undertaken in order to evaluate the importance of glutamate transport, oxidation reduction state, and product inhibition on the rates of formation of ammonia from glutamate. Uptake and efflux of glutamate across the mitochondrial membrane were measured isotopically in the presence of rotenone. Efflux was stimulated by H+ in the mitochondrial matrix and was found to be first order with respect to matrix glutamate except when the matrix pH was unphysiologically low. The data suggest that the Km of matrix glutamate for efflux is decreased by H+. Matrix H+ also appeared to stimulate glutamate uptake, but the effect was to increase both the Km of medium glutamates and Vmax. Mitochondria were incubated at 15 and 28 degrees C with glutamate and malonate. Under these conditions, glutamate was metabolized only by the deamination pathway. Flux was evaluated by assay of ammonia formation. Oxidation reduction state was varied with ADP and uncoupling agents. Matrix alpha-ketoglutarate was varied either by the omission of malonate from the incubation media or by adding alpha-ketoglutarate to the external media. Influx and efflux of glutamate could be calculated from previously determined transport parameters. The difference between calculated influx and efflux was found to be equal to ammonia formation under all conditions. It was, therefore, possible to evaluate the relative contributions of oxidation reduction state, transport, and product inhibition as effectors of ammonia formation. The contribution of transport was relatively small while oxidation reduction state exerted a large influence. alpha-Ketoglutarate was found to be a potent competitive inhibitor of ammonia production and glutamate dehydrogenase. Inhibition of glutamate dehydrogenase by alpha-ketoglutarate was judged to be a potentially important modulator of metabolic fluxes.     

Kinetic studies of ATP synthase: The case for the positional change mechanism

The mitochondrial ATP synthases shares many structural and kinetic properties with bacterial and chloroplast ATP synthases. These enzymes transduce the energy contained in the membrane's electrochemical proton gradients into the energy required for synthesis of high-energy phosphate bonds. The unusual three-fold symmetry of the hydrophilic domain, F₁, of all these synthases is striking. Each F₁ has three identical subunits and three identical subunits as well as three additional subunits present as single copies. The catalytic site for synthesis is undoubtedly contained in the subunit or an , interface, and thus each enzyme appears to contain three identical catalytic sites. This review summarizes recent isotopic and kinetic evidence in favour of the concept, originally proposed by Boyer and coworkers, that energy from the proton gradient is exerted not directly for the reaction at the catalytic site, but rather to release product from a single catalytic site. A modification of this binding change hypotheses is favored by recent data which suggest that the binding change is due to a positional change in all three subunits relative to the remaining subunits of F₁ and F₀ and that the vector of rotation is influenced by energy. The positional change, or rotation, appears to be the slow step in the process of catalysis and it is accelerated in all F₁F₀ ATPases studied by substrate binding and by the proton gradient. However, in the mammalian mitochondrial enzyme, other types of allosteric rate regulation not yet fully elucidated seem important as well.     

Glutamate transprot in rat kidney mitochondria

The quantitative characteristics of [U-14C]glutamate transport were determined in rotenone-inhibited energized rat kidney mitochondria at pH 7.0 and 28 degrees C. Glutamate efflux was observed to be first order with respect to matrix glutamate with a rate constant of 0.457 min-1. Uptake kinetic studies indicated that the Km of external glutamate was 1.4 mM and the Vmax 3.2 nmol/mg X min. These kinetic values were found to be unchanged at pH 6.6 or in mitochondria obtained from kidneys of chronically acidotic rats. Parallel studies of glutamate deamination were performed in which mitochondria were incubated in state 3, state 4, and with carbonyl cyanide p-trifluoromethoxyphenylhydrazone, in the presence of malonate. The oxidative deamination of glutamate determined with 1 and 10 mM glutamate never exceeded the simultaneously measured rate of glutamate transport. No glutamate was detectable within the mitochondrial matrix under the conditions of these metabolic experiments. The studies indicate that the glutamate hydroxyl transporter is quite slow and rate limiting for the oxidative deamination of external glutamate in rat kidney mitochondria.     

31P NMR saturation-transfer study of the in situ kinetics of the mitochondrial adenine nucleotide translocase

The exchange of intramitochondrial ATP (ATP(in)) for extramitochondrial ATP (ATP(out)) was measured by using 31P NMR spectroscopy over a range of temperatures in isolated rat liver mitochondria oxidizing glutamate and succinate in the presence of external ATP but no added ADP (state 4). The rate of this exchange is more than an order of magnitude faster than rates reported previously that were determined by using isotopic techniques in the presence of oligomycin, the potent ATPase inhibitor. Differences are ascribed in part to the low levels of matrix ATP present in oligomycin-treated mitochondria. The addition of oligomycin to mitochondrial suspensions decreases intramitochondrial ATP levels from 17 +/- 3 (SEM) nmol/mg of protein in state 4 to 1.51 +/- 0.1 nmol/mg of protein in the presence of inhibitor at 8 degrees C. Simultaneously, transporter flux falls from 960 +/- 55 nmol/min.mg to undetectable levels (less than 300 nmol/min.mg). Although transport rates are much faster when measured by saturation-transfer than by conventional isotopic methods, the enthalpy values obtained by determining the effect of temperature on flux are very similar to those reported in the past that were determined by using isotopic techniques. Intramitochondrial ATP content regulates the rate of the ATP(in)/ATP(out) exchange. At 18 degrees C, the concentration of internal ATP that produces half-maximal transport rate is 6.6 +/- 0.12 nmol/mg of mitochondrial protein. The relationship between substrate concentration and flux is sigmoidal and is 90% saturated at 11.3 +/- 0.18 nmol/mg of mitochondrial protein.(ABSTRACT TRUNCATED AT 250 WORDS)