Ion transport across isolated antral mucosa of the rabbit

Isotopic fluxes of Na, Cl, and K were measured across isolated antral mucosa under short-circuit conditions. HCO3 fluxes were also measured with either isotopic and/or pH-stat methods. Net secretion of all four ions was observed. HCO3 secretion is due to a transmural process requiring metabolic energy. Secretion of endogenous HCO3 was not observed, and the unidirectional mucosal-to-serosal flux of HCO3 was negligible. There appears to be a close relationship between HCO3 secretion and the unidirectional mucosal-to-serosal Cl flux, but not relationships were observed between the unidirectional serosal-to-mucosal flux or either unidirectional Na flux. The bulk of HCO3 secretion is independent of the unidirectional Cl fluxes, but there is a fraction of HCO3 transport that is dependent on unidirectional Cl transport. However, HCO3 transport is not measurably influenced by inhibition of net Cl (and Na) transport per se.     

Control of glucose utilization in working perfused rat heart

Metabolic control analyses of glucose utilization were performed for four groups of working rat hearts perfused with Krebs-Henseleit buffer containing 10 mM glucose only, or with the addition of 4 mM D-beta-hydroxybutyrate/1 mM acetoacetate, 100 nM insulin (0.05 unit/ml), or both. Net glycogen breakdown occurred in the glucose group only and was converted to net glycogen synthesis in the presence of all additions. The flux of [2-3H]glucose through P-glucoisomerase (EC 5.3.1.9) was reduced with ketones, elevated with insulin, and unchanged with the combination. Net glycolytic flux was reduced in the presence of ketones and the combination. The flux control coefficients were determined for the portion of the pathway involving glucose transport to the branches of glycogen synthesis and glycolysis. Major control was divided between the glucose transporter and hexokinase (EC 2.7.1.1) in the glucose group. The distribution of the control was slightly shifted to hexokinase with ketones, and control at the glucose transport step was abolished in the presence of insulin. Analysis of the pathway from 3-P-glycerate to pyruvate determined that the major control was shared by enolase (EC 4.2.1.1) and pyruvate kinase (EC 2.7.1.40) in the glucose group. Addition of ketones, insulin, or the combination shifted the control to P-glycerate mutase (EC 5.4.2.1) and pyruvate kinase. These results illustrate that the control of the metabolic flux in glucose metabolism of rat heart is not exerted by a single enzyme but variably distributed among enzymes depending upon substrate availability, hormonal stimulation, or other changes of conditions.     

Temperature dependence of the coupling efficiency of rat liver oxidative phosphorylation: role of adenine nucleotide translocator

We have reinvestigated the temperature dependence of the coupling efficiency of energy conversion in isolated rat liver mitochondria. We observed that respiratory control increased with temperature. Moreover, in the same conditions, the ATP/O ratio increased. The measurement of the control coefficients of adenine nucleotide translocator on respiratory and ATP synthesis rates showed that at 28 degrees C, this translocator exerted the same control (about 0.5) on both fluxes. At 4 degrees C, it no longer exerted control on respiratory flux when its control on ATP synthesis flux came close to 1. In addition, ATP/O ratio values and control coefficients on ATP synthesis flux were bound by a unique linear relationship irrespective of temperature. In conclusion, the decrease in ATP/O ratio with temperature is a direct consequence of an increase in the kinetic control exerted by the adenine nucleotide translocator on ATP synthesis.     

Characterization of rice endo-beta-glucanase genes (Gns2-Gns14) defines a new subgroup within the gene family

Because of its importance to cell function, the free-energy metabolism of the living cell is subtly and homeostatically controlled. Metabolic control analysis enables a quantitative determination of what controls the relevant fluxes. However, the original metabolic control analysis was developed for idealized metabolic systems, which were assumed to lack enzyme-enzyme association and direct metabolite transfer between enzymes (channelling). We here review the recently developed molecular control analysis, which makes it possible to study non-ideal (channelled, organized) systems quantitatively in terms of what controls the fluxes, concentrations, and transit times. We show that in real, non-ideal pathways, the central control laws, such as the summation theorem for flux control, are richer than in ideal systems: the sum of the control of the enzymes participating in a non-ideal pathway may well exceed one (the number expected in the ideal pathways), but may also drop to values below one. Precise expressions indicate how total control is determined by non-ideal phenomena such as ternary complex formation (two enzymes, one metabolite), and enzyme sequestration. The bacterial phosphotransferase system (PTS), which catalyses the uptake and concomitant phosphorylation of glucose (and also regulates catabolite repression) is analyzed as an experimental example of a non-ideal pathway. Here, the phosphoryl group is channelled between enzymes, which could increase the sum of the enzyme control coefficients to two, whereas the formation of ternary complexes could decrease the sum of the enzyme control coefficients to below one. Experimental studies have recently confirmed this identification, as well as theoretically predicted values for the total control. Macromolecular crowding was shown to be a major candidate for the factor that modulates the non-ideal behaviour of the PTS pathway and the sum of the enzyme control coefficients.     

The UI octoson--a new class of ultrasonic echoscope

Glucokinase, phosphoglucomutase and glucose-1-phosphate uridylyltransferase are the three enzymes involved in a microsomic pathway for the synthesis of UDP glucose. Evidence is given, in this paper, for the localization of these three enzymes in a Golgi-rich fraction of rat liver. This fraction is prepared, from smooth microsomes, by the means of a discontinuous four-step sucrose gradient. Three of the lighter fractions (d = 1.08-1.13) are enriched in the Golgi markers (galactosyltransferase, sialytransferase and thiamin pyrophosphatase), especially the one with density 1.13. The three enzymes we are interested in are enriched in the two upper hands (d 1.08-1.11), which display an activity for the biosynthesis of UDP-glucose from glucose equivalent to the one obtained in a crude microsomic preparation, and which are not contaminated by other subcellular components.     

Effect of nicotinic acid on cholera-induced fluid movement and unidirectional sodium fluxes in rabbit jejunum

Cholera toxin produces intestinal secretion and elevation of intestinal cyclic AMP. Nicotinic acid has been shown to prevent these responses. The effect of nicotinic acid on cholera toxin-induced secretion could be caused by decreased plasma-to-lumen flux, increased lumen-to-plasma flux, or a combination of both. The purpose of this study was to define the effects of nicotinic acid on net fluid movement and unidirectional sodium fluxes in rabbit jejunal loops exposed to cholera toxin. In the untreated animals receiving no nicotinic acid, the cholera toxin-exposed loops secreted 0.91 ml/cm/4h above the control loops receiving no cholera toxin (p < 0.01). On the other hand, pretreatment with 100 mg/kg nicotinic acid caused a striking decrease in secretion in the cholera toxin loop, so that the cholera toxin loop was not significantly different from the control loop. Unidirectional sodium fluxes in untreated animals showed that cholera toxin caused an increase in the plasma-to-lumen flux and a decrease in the lumen-to-plasma flux. Both effects were abolished by pretreating the animals with nicotinic acid. These studies indicate that nicotinic acid prevents cholera toxin-induced secretion by restoring the unidirectional fluxes to control levels.     

Application of a U-13C-labeled amino acid tracer in lactating dairy goats for simultaneous measurements of the flux of amino acids in plasma and the partition of amino acids to the mammary gland

A preliminary study was conducted using lactating British Saanen goats (n = 5) at 109 to 213 d in milk that yielded 1.67 to 3.68 kg of milk/d to examine the application of a U-13C-labeled amino acid (AA) mixture obtained from hydrolyzed algal proteins as a tracer for measuring plasma flux (n = 5) and partition to the mammary gland (n = 3; arteriovenous difference) of 13 AA simultaneously. Except for Ile and Ser, there was incomplete (6 to 54%) equilibration of the tracer with AA from packed blood cells (> 90% erythrocytes) during the 6-h infusions. This result agreed with the large ratio of packed cells to gradients for plasma AA concentration that was also observed. However, net mass and isotope removals by the mammary gland were predominantly from plasma, indicating that the erythrocytes did not participate in kinetic exchanges. Plasma AA fluxes (millimoles per kilogram of metabolizable protein intake per kilogram of body weight 0.75) differed among goats that consumed different protein sources; however, overall rates were lowest for Met (5 to 14) and His (8 to 17) and highest for Leu (48 to 70) and Ala (53 to 88). On average, 25% of plasma flux was partitioned to the mammary gland. Less than 20% of His, Ser, Phe, and Ala were directed to the mammary gland; 20 to 30% of Arg, Thr, Tyr, and Leu were directed to the mammary gland; and 30 to 40% of Pro, Ile, Lys, and Val were directed to the mammary gland. The unidirectional AA flux in the mammary gland (AA apparently available for protein syntheses, oxidation, and metabolite formation) did not match the pattern that is required for casein synthesis, suggesting differences in the metabolic requirements of AA for nonmilk protein synthesis.     

Sodium chloride transport across the chicken coprodeum. Basic characteristics and dependence on sodium chloride intake

1. The transport characteristics of the chicken coprodeum have been examined in vitro using the isolated mucosa. The short-circuit current (I(sc)), the transepithelial electrical potential difference (p.d.), the unidirectional transmural fluxes (J(ms), J(sm)) of sodium and chloride measured in the short-circuited state, and the unidirectional influx of sodium and chloride across the brush border membrane measured under open-circuit conditions have been studied. The effect of the sodium chloride contents of the diet on these parameters have been investigated.2. The isolated mucosa depends functionally on the presence of glucose in the incubation media. This dependence reflects the need of glucose as a fuel. There is no indication of coupling between transport of sugars and sodium across the brush border membrane. For preparations from chickens on a low sodium diet a very high and stable I(sc) can quantitatively be accounted for by the net transport of sodium. Influx of sodium across the brush border membrane is not significantly different from the net flux of sodium. By feeding the chickens a high sodium diet the I(sc) is reduced by more than 95%, the net transport of sodium is abolished, and the transepithelial electrical conductance is reduced by more than 50%.3. Both unidirectional transepithelial fluxes of chloride, and the serosa to mucosa flux of sodium appear to proceed through a paracellular shunt.4. Under the conditions of the low sodium diet the paracellular pathway appears to be anion selective. Whereas, under the conditions of the high sodium regimen the paracellular route appears to be cation selective. After adaptation to a high sodium diet the influx of sodium across the brush border membrane is only moderately reduced. Consequently the decisive event in the adaptation must be localized elsewhere.     

Reversibility of glycolysis in leaves of C4-plants

A conversion of the reaction of two cytoplasmic glycolysis enzymes, phosphoglycerate mutase and phosphopyruvate hydratase, is necessary for sucrose synthesis from pyruvate in leaves of C4-plants in the light, when phosphoenolpyruvate synthesis from pyruvate and phosphoglycerate reduction can be carried out by chloroplasts. Leaves of C4-plants differ from those of C3-plants in a higher activity of cytoplasmic glycolysis enzymes, which are distributed irregularly in two assimilatory tissues. The ratio of pyruvate kinase and enolase reaction activities is high in parenchyma linings of vascular fascicles (where mitochondria are concentrated), and it is low in mesophyl tissue, where phosphoglucerate in equilibrium phosphoenolpyruvate reaction is included into photosynthetic metabolism. The data obtained on isolated mesophyl protoplasts have shown that the reaction equilibrium is sharply shifted into the direction of phosphoenolpyruvate formation from phosphoglycerate. However, the incorporation of 14C into sugars is not completely inhibited in the atmosphere of N2-A possibility of incorporation of tri-carbon fragments into sugars in photosynthesizing leaves via conversion of enolase reaction and via alternative pathways is discussed.     

Purification and properties of citrate lyase ligase from Streptococcus diacetilactis

Citrate lyase ligase (acetate: SH--[acyl-carrier protein] enzyme ligase (AMP) from Streptococcus diacetilactis was purified 920-fold with a yield of 6.3%. The molecular weight of the enzyme was estimated to be 41000; the ligase consisted of one polypeptide chain. The acetylation of 1 mol of deacetyl-citrate lyase to enzymatically active citrate lyase required 6 mol ATP. The formation of AMP and pyrophosphate in the acetylation reaction was demonstrated. Citrate lyase ligase was specific for the lyase from S. diacetilacitis and did not acetylate lyases from Rhodopseudomonas gelatinosa and Enterobacter aerogenes. The substract acetate and ATP could be replaced by propionate and dATP, repectively. The reaction rates for ATP, acetate and deacetyl-citrate lyase followed Michaelis-Menten kinetics (Km values: 26 micron for ATP, 25 mM for acetate and 38 nM for deacetyl-citrate lyase).     

Adenosine triphosphate citrate lyase mediates hypocitraturia in rats

Chronic metabolic acidosis increases proximal tubular citrate uptake and metabolism. The present study addressed the effect of chronic metabolic acidosis on a cytosolic enzyme of citrate metabolism, ATP citrate lyase. Chronic metabolic acidosis caused hypocitraturia in rats and increased renal cortical ATP citrate lyase activity by 67% after 7 d. Renal cortical ATP citrate lyase protein abundance increased by 29% after 3 d and by 141% after 7 d of acid diet. No significant change in mRNA abundance could be detected. Hypokalemia, which causes only intracellular acidosis, caused hypocitraturia and increased renal cortical ATP citrate lyase activity by 28%. Conversely, the hypercitraturia of chronic alkali feeding was associated with no change in ATP citrate lyase activity. Inhibition of ATP citrate lyase with the competitive inhibitor, 4S-hydroxycitrate, significantly abated hypocitraturia and increased urinary citrate excretion fourfold in chronic metabolic acidosis and threefold in K+-depletion. In summary, the hypocitraturia of chronic metabolic acidosis is associated with an increase in ATP citrate lyase activity and protein abundance, and is partly reversed by inhibition of this enzyme. These results suggest an important role for ATP citrate lyase in proximal tubular citrate metabolism.     

Quantitative studies of enzyme-substrate compartmentation, functional coupling and metabolic channelling in muscle cells

Some historical aspects of development of the concepts of functional coupling, metabolic channelling, compartmentation and energy transfer networks are reviewed. Different quantitative approaches, including kinetic and mathematical modeling of energy metabolism, intracellular energy transfer and metabolic regulation of energy production and fluxes in the cells in vivo are analyzed. As an example of the system with metabolic channelling, thermodynamic aspects of the functioning the mitochondrial creatine kinase functionally coupled to the oxidative phosphorylation are considered. The internal thermodynamics of the mitochondrial creatine kinase reaction is similar to that for other isoenzymes of creatine kinase, and the oxidative phosphorylation process specifically influences steps of association and dissociation of MgATP with the enzyme due to channelling of ATP from adenine nucleotide translocase. A new paradigm of muscle bioenergetics-the paradigm of energy transfer and feedback signaling networks based on analysis of compartmentation phenomena and structural and functional interactions in the cell is described. Analysis of the results of mathematical modeling of the compartmentalized energy transfer leads to conclusion that both calcium and ADP, which concentration changes synchronously in contraction cycle, may simultaneously activate oxidative phosphorylation in the muscle cells in vivo. The importance of the phosphocreatine circuit among other pathways of intracellular energy transfer network is discussed on the basis of the recent data published in the literature, with some experimental demonstration. The results of studies of perfused rat hearts with completely inhibited creatine kinase show significantly decreased work capacity and respectively, energy fluxes, in these hearts in spite of significant activation of adenylate kinase system (Dzeja et al. this volume). These results, combined with those of mathematical analysis of the energy metabolism of hearts of transgenic mice with switched off creatine kinase isoenzymes confirm the importance of phosphocreatine pathway for energy transfer for cell function and energetics in mature heart and many other types of cells, as one of major parts of intracellular energy transfer network and metabolic regulation.     

Leishmania major-like parasite, a pathogenic agent of cutaneous leishmaniasis in Paraguay

Leishmania parasites isolated from two patients with cutaneous leishmaniasis from geographically different localities in Paraguay have been characterized by enzyme electrophoresis (zymodeme) and digestion profiles of kinetoplast DNA with restriction enzymes (schizodeme). Both Paraguayan isolates showed identical zymodeme profiles to each other using 14 enzymes (glutamic pyruvate transaminase, glutamic oxaloacetic transaminase, enolase, fumarate hydratase, glucose phosphate isomerase, glucose-6-phosphate dehydrogenase, malate dehydrogenase, malic enzyme, mannose phosphate isomerase, nucleoside phosphorylase, peptidase-D, 6-phosphogluconate dehydrogenase, phosphoglucomutase, and pyruvate kinase). Although two Paraguayan isolates showed different zymodeme profiles from those of six Leishmania reference strains of Old and New World Leishmania species, they showed identical zymodeme profiles to those of an L. major-like parasite from Ecuador. These observations were confirmed by schizodeme analysis using three restriction endonucleases (Msp I, Hae III, and Taq I). These results indicate that Leishmania parasites isolated in Paraguay are identified as an L. major-like parasite, and it is necessary to consider the existence of L. major-like parasites when classifying Leishmania isolates from the New World.     

Converting enzyme inhibition causes hypocitraturia independent of acidosis or hypokalemia

BACKGROUND: Angiotensin II stimulates the proximal tubular Na/H antiporter and increases proximal tubular cell pH. Because intracellular pH may affect urinary citrate excretion and enzymes responsible for renal citrate metabolism, the present studies examined the effect of enalapril, an angiotensin converting enzyme inhibitor, on the activity of renal cortical ATP citrate lyase and urinary citrate excretion. METHODS: Enalapril was given to rats (15 mg/kg/day) for seven days and to humans (10 mg twice daily) for 10 days. Blood and 24-hour urine samples were obtained in both groups. Renal cortical tissue from rats was analyzed for enzyme activity. RESULTS: In rats, enalapril decreased urinary citrate excretion by 88%. The change in urinary citrate was not associated with a difference in plasma pH, bicarbonate nor potassium concentration. However, similar to metabolic acidosis and hypokalemia, enalapril caused a 42% increase in renal cortical ATP citrate lyase activity. When given to humans, enalapril significantly decreased urinary citrate excretion and urine citrate concentration by 12% and 16%, respectively, without affecting plasma pH or electrolytes. CONCLUSIONS: Enalapril decreases urinary citrate in rats and humans. This is due, at least in part, to increases in cytosolic citrate metabolism through ATP citrate lyase in rats similar to that seen with chronic metabolic acidosis and hypokalemia. The effects of enalapril on urinary citrate and renal cortical ATP citrate lyase occur independently of acidosis or hypokalemia but may be due to intracellular acidosis that is common to all three conditions.     

Amino acid metabolism and the energetics of growth

The nonessential amino acids are involved in a large number of functions that are not directly associated with protein synthesis. Recent studies using a combination of transorgan balance and stable isotopic tracers have demonstrated that a substantial portion of the extra-splanchnic flux of glutamate, glutamine, glycine and cysteine derives from tissue synthesis. A key amino acid in this respect is glutamic acid. Little glutamic acid of dietary origin escapes metabolism in the small intestinal mucosa. Furthermore, because glutamic acid is the only amino acid that can be synthesized by mammals by reductive amination of a ketoacid, it is the ultimate nitrogen donor for the synthesis of other nonessential amino acids. Because the synthesis of glutamic acid and its product glutamine involve the expenditure of adenosine triphosphate (ATP), it seems possible that nonessential amino acid synthesis might have a significant bearing on the energetics of protein synthesis and, hence, of protein deposition. This paper discusses the topic of the energy cost of protein deposition, considers the metabolic physiology of amino acid oxidation and nonessential amino acid synthesis, and attempts to combine the information to speculate on the overall impact of amino acid metabolism on the energy exchanges of animals.     

Mechanisms of cell damage and enzyme release

Release of intracellular enzymes to the extracellular space is a marker of cell damage in various diseases, e.g. liver, heart and muscle diseases. In the normal state the plasma membrane is impermeable to enzymes, and enzyme release, therefore, indicates a severe change of the membrane integrity. This review deals with the present knowledge about cellular changes leading to enzyme release, which may be caused either by energy depletion, e.g. in ischemia or shock, or by a direct membrane damage as caused by various toxins and inflammatory products. Inhibition of the energy metabolism results in ATP depletion leading to fluxes of Na+, K+ and Cl- down their gradients across the membrane and swelling of the cell. Subsequently Ca2+ leak into the cell activating phospholipases and the formation of eicosanoids, affecting the cytoskeleton and, perhaps, activating the formation of oxidants. The exact "point of no return" is not known but an uncontrolled Ca2+ activity in the cell probably has an important role in initiating the irreversible changes. The result of these reactions and probably other unknown reactions as well is damage to the membrane. This is evident morphologically at first by the formation of blebs that appears in the reversible phase, and later on by rupturing of the membrane, a sign of irreversible damage. A very small part of the enzyme release may occur in the reversible phase when blebs detach with resealing of the membrane, but the substantial part of enzyme release occurs as a result of irreversible cell damage when ATP has decreased to a low level and a serious disruption of the membrane integrity has taken place. All the secondary affections of the membrane during energy depletion may also occur as a primary direct membrane damage that more or less may affect the energy metabolism secondarily. The cell damage and enzyme release after some types of direct membrane damage is almost independent of the cellular energy metabolism whereas other types of direct membrane damage are counteracted by the cell by energy consuming reactions and, therefore, the final cell damage is a concerted action of the direct membrane damage and the energy depletion. This also means that a direct membrane damage may be more severe for the cell in energy depleted states than in the normal state. As in energy dependent cell damage the substantial part of enzyme release after a direct membrane damage is due to irreversible cellular changes. It appears that although the knowledge of the molecular basis of cell damage and enzyme release has grown there are still many questions to be answered about these complex processes.     

Increased oxidative and delayed glycogenolytic ATP synthesis in exercising skeletal muscle of obese (insulin-resistant) Zucker rats

1. To examine metabolic correlates of insulin resistance in skeletal muscle, we used 31P magnetic resonance spectroscopy to study glycogenolytic and oxidative ATP synthesis in leg muscle of lean and obese Zucker rats in vivo during 6 min sciatic nerve stimulation at 2 Hz. 2. The water content of resting muscle was reduced by 21 +/- 7% in obese (insulin-resistant) animals compared with lean animals, whereas the lipid content was increased by 140 +/- 70%. These results suggest that intracellular water content was reduced by 17% in obese animals. 3. During exercise, although twitch tensions were not significantly different in the two groups, rates of total ATP synthesis (expressed per litre of intracellular water) were 48 +/- 20% higher in obese animals, suggesting a 50 +/- 8% reduction in intrinsic "metabolic efficiency'. Changes in phosphocreatine and ADP concentration were significantly greater in obese animals than in lean animals, whereas changes in intracellular pH did not differ. 4. These results imply that oxidative ATP synthesis during exercise is activated earlier in obese animals than in lean animals. This difference was not fully accounted for by the greater increase in the concentration of the mitochondrial activating signal ADP. Neither the post-exercise recovery kinetics of phosphocreatine nor the muscle content of the mitochondrial marker enzyme citrate synthase was significantly different in the two groups. The increased oxidative ATP synthesis in exercise must therefore be due to altered kinetics of mitochondrial activation by signals other than ADP. 5. Thus, the insulin-resistant muscle of obese animals may compensate for its decreased efficiency (and consequent increased need for ATP) by increased reliance on oxidative ATP synthesis.     

Dramatic differences in the binding of UDP-galactose and UDP-glucose to UDP-galactose 4-epimerase from Escherichia coli

UDP-galactose 4-epimerase catalyzes the interconversion of UDP-galactose and UDP-glucose during normal galactose metabolism. Within recent years the enzyme from Escherichia coli has been studied extensively by both biochemical and X-ray crystallographic techniques. One of several key features in the catalytic mechanism of the enzyme involves the putative rotation of a 4'-ketopyranose intermediate within the active site region. The mode of binding of UDP-glucose to epimerase is well understood on the basis of previous high-resolution X-ray crystallographic investigations from this laboratory with an enzyme/NADH/UDP-glucose abortive complex. Attempts to prepare an enzyme/NADH/UDP-galactose abortive complex always failed, however, in that UDP-glucose rather than UDP-galactose was observed binding in the active site. In an effort to prepare an abortive complex with UDP-galactose, a site-directed mutant protein was constructed in which Ser 124 and Tyr 149, known to play critical roles in catalysis, were substituted with alanine and phenylalanine residues, respectively. With this double mutant it was possible to crystallize and solve the three-dimensional structures of reduced epimerase in the presence of UDP-glucose or UDP-galactose to high resolution. This study represents the first direct observation of UDP-galactose binding to epimerase and lends strong structural support for a catalytic mechanism in which there is free rotation of a 4'-ketopyranose intermediate within the active site cleft of the enzyme.     

Triosephosphate isomerase deficiency: predictions and facts

Deficiencies in around 20 enzymes, associated with widely different degrees of severity and complexity, have been identified for human erythrocytes. The fact that glycolysis is crucial for erythrocyte function is reflected by the large number of inherited glycolytic enzymopathies. Triosephosphate isomerase (TPI) deficiency, a rare autosomal disease, is usually associated with nonspherocytic hemolytic anemia, progressive neurologic dysfunction, and death in childhood. The two affected Hungarian brothers studied by us have less than 3% TPI activity and enormously (30-50-fold) increased dihydroxyacetone phosphate (DHAP) concentration in their erythrocytes. The well-established concept of the metabolic control theory was used to test the contribution of TPI and some related enzymes to the control of a relevant segment of the glycolytic pathway in normal and deficient cells. Deviation indices, DEJ = (delta J/delta E) E(r)/J(r), which give a good estimation of flux control coefficients using a single large change in enzyme activity, were determined from the fluxes in the absence and presence of exogeneous enzymes. We found that PFK and aldolase are the enzymes that predominantly control the flux, however, the quantitative values depend extensively on the pH: DEJ values are 0.85 and 0.14 at pH 8.0 and 0.33 and 0.67 at pH 7.2 for aldolase and PFK, respectively. Neither the flux rates nor the capacities of the enzymes seem to be significantly different in normal and TPI deficient cells. There is a discrepancy between DHAP levels and TPI activities in the deficient cells. In contrast to the experimental data the theoretical calculations predict elevation in DHAP level at lower than 0.1% of the normal value of TPI activity. Several possibilities suggested fail to explain this discrepancy. Specific associations of glycolytic enzymes to band-3 membrane proteins with their concomitant inactivation have been demonstrated. We propose that the microcompartmentation of TPI that could further decrease the reduced isomerase activity of the deficient cells, is responsible for the high DHAP level.     

Quantitative analysis of some mechanisms affecting the yield of oxidative phosphorylation: dependence upon both fluxes and forces

The purpose of this work was to show how the quantitative definition of the different parameters involved in mitochondrial oxidative phosphorylation makes it possible to characterize the mechanisms by which the yield of ATP synthesis is affected. Three different factors have to be considered: (i) the size of the different forces involved (free energy of redox reactions and ATP synthesis, proton electrochemical difference); (ii) the physical properties of the inner mitochondrial membrane in terms of leaks (H+ and cations); and finally (iii) the properties of the different proton pumps involved in this system (kinetic properties, regulation, modification of intrinsic stoichiometry). The data presented different situations where one or more of these parameters are affected, leading to a different yield of oxidative phosphorylation. (1) By manipulating the actual flux through each of the respiratory chain units at constant protonmotive force in yeast mitochondria, we show that the ATP/O ratio decreases when the flux increases. Moreover, the highest efficiency was obtained when the respiratory rate was low and almost entirely controlled by the electron supply. (2) By using almitrine in different kinds of mitochondria, we show that this drug leads to a decrease in ATP synthesis efficiency by increasing the H+/ATP stoichiometry ofATP synthase (Rigoulet M et al. Biochim Biophys Acta 1018: 91-97, 1990). Since this enzyme is reversible, it was possible to test the effect of this drug on the reverse reaction of the enzyme i.e. extrusion of protons catalyzed by ATP hydrolysis. Hence, we are able to prove that, in this case, the decrease in efficiency of oxidative phosphorylation is due to a change in the mechanistic stoichiometry of this proton pump. To our knowledge, this is the first example of a modification in oxidative phosphorylation yield by a change in mechanistic stoichiometry of one of the proton pumps involved. (3) In a model of polyunsaturated fatty acid deficiency in rat, it was found that non-ohmic proton leak was increased, while ohmic leak was unchanged. Moreover, an increase in redox slipping was also involved, leading to a complex picture. However, the respective role of these two mechanisms may be deduced from their intrinsic properties. For each steady state condition, the quantitative effect of these two mechanisms in the decrease of oxidative phosphorylation efficiency depends on the values of different fluxes or forces involved. (4) Finally the comparison of the thermokinetic data in view of the three dimensional-structure of some pumps (X-ray diffraction) also gives some information concerning the putative mechanism of coupling (i.e. redox loop or proton pump) and their kinetic control versus regulation of mitochondrial oxidative phosphorylation.