Quantification of ATP-producing and consuming processes of Ehrlich ascites tumour cells

ATP production of Ehrlich ascites tumour cells was estimated on the basis of their coupled respiration and lactate formation. ATP-consuming processes were assessed from the effects of selective inhibitors of RNA synthesis, protein synthesis and proteolysis, Na+/K+-ATPase on respiration. The extent of protein synthesis and proteolysis were also determined directly. From these values and those of the inhibition of respiration by selective inhibitors, a P/O ratio of 2.2 was calculated. About 75% of the total ATP consumption could be assigned to specific processes. The major ATP-consuming processes of tumour cells in an amino-acid-enriched medium, in which they are in an approximate steady state, are protein synthesis with about 30% of total ATP consumption, and Na+/K+-ATPase with about 20%, while RNA synthesis, ATP-dependent proteolysis and Ca2+-ATPase contribute about 10% each. In an amino-acid-free glucose medium, protein synthesis is reduced to a third, with a corresponding decrease of respiration, whereas the rate of the other ATP-consuming processes is unchanged.     

ConA induced changes in energy metabolism of rat thymocytes

The influence of ConA on the energy metabolism of quiescent rat thymocytes was investigated by measuring the effects of inhibitors of protein synthesis, proteolysis, RNA/DNA synthesis, Na⁺K⁺-ATPase, Ca²⁺-ATPase and mitochondrial ATP synthesis on respiration. Only about 50% of the coupled oxygen consumption of quiescent thymocytes could be assigned to specific processes using two different media. Under these conditions the oxygen is mainly used to drive mitochondrial proton leak and to provide ATP for protein synthesis and cation transport, whereas oxygen consumption to provide ATP for RNA/DNA synthesis and ATP-dependent proteolysis was not measurable. The mitogen ConA produced a persistent increase in oxygen consumption by about 30% within seconds. After stimulation more than 80% of respiration could be assigned to specific processes. The major oxygen consuming processes of ConA-stimulated thymocytes are mitochondrial proton leak, protein synthesis and Na⁺K⁺-ATPase with about 20% each of total oxygen consumption, while Ca²⁺-ATPase and RNA/DNA synthesis contribute about 10% each. Quiescent thymocytes resemble resting hepatocytes in that most of the oxygen consumption remains unexplained. In contrast, the pattern of energy metabolism in stimulated thymocytes is similar to that described for Ehrlich Ascites tumour cells and splenocytes, which may also be in an activated state. Most of the oxygen consumption is accounted for, so the unexplained process(es) in unstimulated cells shut(s) off on stimulation.     

ConA induced changes in energy metabolism of rat thymocytes

The influence of ConA on the energy metabolism of quiescent rat thymocytes was investigated by measuring the effects of inhibitors of protein synthesis, proteolysis, RNA/DNA synthesis, Na⁺K⁺-ATPase, Ca²⁺-ATPase and mitochondrial ATP synthesis on respiration. Only about 50% of the coupled oxygen consumption of quiescent thymocytes could be assigned to specific processes using two different media. Under these conditions the oxygen is mainly used to drive mitochondrial proton leak and to provide ATP for protein synthesis and cation transport, whereas oxygen consumption to provide ATP for RNA/DNA synthesis and ATP-dependent proteolysis was not measurable. The mitogen ConA produced a persistent increase in oxygen consumption by about 30% within seconds. After stimulation more than 80% of respiration could be assigned to specific processes. The major oxygen consuming processes of ConA-stimulated thymocytes are mitochondrial proton leak, protein synthesis and Na⁺K⁺-ATPase with about 20% each of total oxygen consumption, while Ca²⁺-ATPase and RNA/DNA synthesis contribute about 10% each. Quiescent thymocytes resemble resting hepatocytes in that most of the oxygen consumption remains unexplained. In constrast, the pattern of energy metabolism in stimulated thymocytes is similar to that described for Ehrlich Ascites tumour cells and splenocytes, which may also be in an activated state. Most of the oxygen consumption is accounted for, so the unexplained process(es) in unstimulated cells shut(s) off on stimulation.     

Respiratory energy demand for protein turnover and ion transport in wheat leaves upon water deficit

The effect of water stress on the respiratory energy demand for the main biosynthetic and transport processes was estimated in the leaves of spring wheat ( Triticum aestivum L. cv. San Pastore) acclimated and non-acclimated to drought. ATP-consuming processes were assessed from the effects of selective inhibitors of RNA synthesis, protein synthesis and proteolysis, Ca²⁺-ATPase and P-type ATPases on respiration. The proportions of energy consumed by these processes were compared with the theoretical ATP production calculated from the rate of oxygen consumption measured manometrically. Respiratory energy production increased significantly in both acclimated leaves and in leaves stressed by drought. In the fully grown wheat leaves, Ca²⁺-dependent reactions and protein turnover consumed about 37% and 34% of the total respiratory energy, respectively. The costs of ion transport constituted another 15% of the total ATP production. Both acclimation and drought stress in non-acclimated leaves resulted in a decrease of leaf sensitivity towards inhibitors of RNA and protein syntheses as well as a decrease in Ca²⁺-mediated processes; but also in an increase of leaf sensitivity towards inhibitors of proteolysis and ouabain-sensitive ATPase in non-acclimated plants. This indicates a shift in ATP input into the energy-requiring processes towards greater expenses for ion transport upon water deficit. However, in acclimated leaves under drought stress, distribution of respiratory energy became almost the same as in control plants.     

The connection between ionophore-mediated Ca-movements and intermediary metabolism in human red cells. I. Relationships between Ca-loading, ATP-consumption and glycolytic flux

Human red cells (RBC) were loaded with moderate amounts of Ca²⁺ by the ionophore A23187. Quantitative relationships between Ca²⁺-loading, ATP consumption and glycolytic flux were established. 1. Ca²⁺-loading is accompanied by ATP depletion. A maximum ATP consumption of approximately 10 mmoles/l RBC/h was estimated. 2. There is a positive correlation between lactate formation and Ca²⁺-loading. This is linear from 1.4 to about 4 mmoles lactate/l RBC/h. 3. Ca²⁺-induced glycolytic stimulation seems not to be mediated by adenine nucleotides. A wide range of energy charges and very different adenine nucleotide patterns were associated with the same stimulation of lactate production. 4. The turnover of the (Ca²⁺-Mg²⁺)-ATPase and its share in the Ca²⁺-stimulated ATP consuming processes were estimated with inhibitors. 1 mM La³⁺ inhibited both Ca²⁺-outward transport and ATP consumption by 80%. The remaining 20% of the ATP consumption was accounted for by the (Na⁺-K⁺)-ATPase. 5. A Ca²⁺ extrusion to ATP consumption molar ratio of 2:1 was found. However, when ATP consumption was due to the breakdown of previously accumulated glycolytic intermediates, the ratio dropped to about 1.     

The connection between ionophore-mediated Ca2+-movements and intermediary metabolism in human red cells. I. Relationships between Ca2+-loading,ATP-consumption and glycolytic flux

Human red cells (RBC) were loaded with moderate amounts of Ca²⁺ by the ionophore A23187. Quantitative relationships between Ca²⁺-loading, ATP consumption and glycolytic flux were established. 1. Ca²⁺-loading is accompanied by ATP depletion. A maximum ATP consumption of approximately 10 mmoles/l RBC/h was estimated. 2. There is a positive correlation between lactate formation and Ca²⁺-loading. This is linear from 1.4 to about 4 mmoles lactate/l RBC/h. 3. Ca²⁺-induced glycolytic stimulation seems not to be mediated by adenine nucleotides. A wide range of energy charges and very different adenine nucleotide patterns were associated with the same stimulation of lactate production. 4. The turnover of the (Ca²⁺-Mg²⁺)-ATPase and its share in the Ca²⁺-stimulated ATP consuming processes were estimated with inhibitors. 1 mM La³⁺ inhibited both Ca²⁺-outward transport and ATP consumption by 80%. The remaining 20% of the ATP consumption was accounted for by the (Na⁺-K⁺)-ATPase. 5. A Ca²⁺ extrusion to ATP consumption molar ratio of 2:1 was found. However, when ATP consumption was due to the breakdown of previously accumulated glycolytic intermediates, the ratio dropped to about 1.     

Balancing of mitochondrial and glycolytic ATP production and of the ATP-consuming processes of Ehrlich mouse ascites tumour cells in a high phosphate medium

A balance of energy budgeting of Ehrlich mouse ascites tumour cells including mitochondrial and glycolytic ATP production and about 80% of ATP consumption in a high phosphate medium is presented. In the share of glycolysis was about one-third of the total ATP production, more than twice that found in a low phosphate medium. The extent of a single energy reaction was assessed from the decrease of coupled oxygen consumption and lactate formation following the specific inhibition of this process. The inhibitory effects on coupled respiration and glycolysis were identical for the energy consuming processes measured: protein turnover, Na+/K(+)-ATPase, Ca2(+)-transport and RNA synthesis.     

ATP utilizing reactions of human erythrocyte membranes and the influence of modulator proteins

The ATP production of human erythrocytes in the steady state (approximately 2 mmoles . 1 cells-1 . h-1, 37 degrees C, pHi 7.2) is maintained by glycolysis and the ATP consumption is essentially limited to the cell membrane. About 25% of the ATP consumption is used for ion transport ATPases. The bulk of the ATP consuming processes in intact erythrocytes remains poorly understood. "Isotonic" erythrocyte membranes prepared under approximate intracellular conditions after freeze-thaw hemolysis have high (Ca2+, Mg2+)-ATPase activities (80% of the total membrane ATPase activity). There is a great discrepancy between the high capacity of the (Ca2+, Mg2+)-ATPase in isotonic membranes and the actual activity in the intact cell. The (Ca2+, Mg2+)-ATPase of isotonic membranes has a "high" Ca2+-affinity (Ka less than 0.5 microM) and a "low" Mg-ATP affinity (Km approximately 760 microM). This state of (Ca2+, Mg2+)-ATPase is caused by the association of calmodulin and 30000 Dalton polypeptides (ATP affinity modulator protein). Hypotonic washings of isotonic membranes result in a loss of the 30 kD polypeptides. EGTA (0.5 mM) extracts derived from isotonic membranes contain the 30 kD modulator protein and restore the properties of the (Ca2+, Mg2+)-ATPase of hypotonic membrane preparations to the isotonic characteristics. The Mg-ATP affinity modulator protein is assumed to form a complex with calmodulin and (Ca2+, Mg2+)-ATPase.     

Control of respiration and oxidative phosphorylation in isolated rat liver cells

NAD(P)H fluorescence, mitochondrial membrane potential and respiration rate were measured and manipulated in isolated liver cells from fed and starved rats in order to characterize control of mitochondrial respiration and phosphorylation. Increased mitochondrial NADH supply stimulated respiration and this accounted for most of the stimulation of respiration by vasopressin and extracellular ATP. From the response of respiration to NADH it was estimated that the control coefficient over respiration of the processes that supply mitochondrial NADH was about 0.15-0.3 in cells from fed rats. Inhibition of the ATP synthase with oligomycin increased the mitochondrial membrane potential and decreased respiration in cells from fed rats, while the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone had the opposite effect. There was a unique relationship between respiration and membrane potential irrespective of the ATP content of the cells indicating that phosphorylation potential controls respiration solely via phosphorylation (rather than by controlling NADH supply). From the response of respiration to the mitochondrial membrane potential (delta psi M) it was estimated that the control coefficients over respiration rate in cells from fed rats were: 0.29 by the processes that generate delta psi M, 0.49 by the process of ATP synthesis, transport and consumption, and 0.22 by the processes that cycle protons across the inner mitochondrial membrane other than via ATP synthesis (e.g. the passive proton leak). Control coefficients over the rate of mitochondrial ATP synthesis were 0.23, 0.84 and -0.07, respectively, by the same processes. The control distribution in cells from starved rats was similar.     

Transient responses of hybridoma cells to nutrient additions in continuous culture: I. Glucose pulse and step changes

Glucose and glutamine are the main nutrients used by mammalian cells in culture. Each provides unique biosynthetic precursors but are complementary for production of other metabolites and energy. The transient and steady-state responses of hybridoma growth and metabolism to glucose pulse and step changes have been examined. Metabolic quotients are reported for oxygen, glucose, lactate, ammonia, glutamine, alanine, and other amino acids. The glucose consumption rate increased by 100-200% immediately after glucose was added to the reactor, and the increased glycolytic ATP production appears to be responsible for the concurrent rapid decrease in the oxygen consumption rate. The effects on glutamine consumption were delayed, probably due to buffering by the TCA cycle and interrelated pathways. A period of increased biosynthetic activity, as evidenced by an increase in the estimated specific ATP production rate and lower by-product yields from glutamine, preceded the increase in cell concentration after the glucose step change. The biosynthetic yield of cells from ATP was calculated, and it was estimated that maintenance accounted for about 60% of the energy used by the cells at a specific growth rate of 0.66 day(-1). The estimated 22% ATP production due to glycoysis was twice as great as that before the step change.     

Heterogeneity of globin protein synthesis in bone marrow cells of patients with homozygous beta-thalassemia from Tadzhikistan

The synthesis of globin proteins in blood reticulocytes of homozygous beta-thalassemic patients from Tadzhikistan has been previously studied. beta-thalassemia with sharp repression of beta-globin protein synthesis (alpha/beta greater than 10) has been shown to be most representative for the region. In this work, the synthesis of globin proteins has been studied in bone marrow cells of homozygous beta-thalassemic patients. Comparison of data on globin synthesis in bone marrow cells and in blood reticulocytes of the patients has revealed that in some cases the disbalance of chain synthesis in both cell types is equal. In other cases the disbalance in bone marrow cells is less than in blood cells, indicating the instability of beta-globin mRNA that is partially degrading in the process of cell maturation. Homozygous beta-thalassemic cases with low content of Hb F in blood cells (5-10%), with substantial disbalance of alpha and beta-globin synthesis and marked production of gamma-globins in bone marrow cells and in blood reticulocytes are of special interest. It has been assumed that parallel to beta-thalassemia some instability of gamma-globin proteins takes place in these patients.     

Proteolysis of mitochondria in reticulocytes during maturation is ubiquitin-dependent and is accompanied by a high rate of ATP hydrolysis

The ATP-dependent breakdown of mitochondria-containing stroma proceeds via the ubiquitin-requiring pathway. The proteolysis is linked to a large ATP-cleaved consumption amounting to 1 ATP per peptide bond or more. Proteins of mitochondria-containing stroma are much better substrates of ATP-ubiquitindependent proteolysis than heat-denatured ones. Hemin suppresses both proteolysis and ATP hydrolysis.     

Do pyrimidine nucleotides regulate translatability of globin mRNA as purine nucleotides do?

1. When rabbit globin mRNA was incubated with rabbit reticulocyte lysate in the presence of various concentrations of nucleotides, globin synthesis was inhibited or stimulated dependent on dose. 2. Pyrimidine nucleotides inhibited protein synthesis at 0.3 mM, whereas 2 mM of purine nucleotides were required to cause similar inhibition. 3. Adenosine mono- and diphosphate inhibited globin synthesis at a concentration of only 1 mM; however, the sequence is AMP greater than ADP greater than ATP. 4. Translation arrest by these nucleotides was instantaneous. 5. These results suggest that these nucleotides may provide a structural component for maintaining the integrity, the conformation of mRNA or of the messenger ribonucleoprotein (mRNP).     

Identification and partial purification of an ATP-stimulated alkaline protease in rat liver.

Extracts from rat liver contain a sulfhydryl-dependent endoprotease which degrades [methyl-14C]globin or 125I-hemoglobin to acid-soluble peptides. This enzyme was isolated from the 100,000 x g supernatant of the homogenate. It showed a pH optimum between 7.5 and 9.5 and very little activity below pH 7.0. The enzyme has an apparent molecular weight of 550,000 as determined on Sepharose 6B column chromatography and sucrose density gradient centrifugation. ATP, at physiological concentrations, as well as pyrophosphate, stimulated the protease activity in these partially purified preparations up to 3-fold. Nonionic detergents such as Triton X-100 increased proteolytic activity and the stimulation by ATP. Other nucleotide triphosphates and ADP also increased proteolysis but less effectively than ATP. Sodium phosphate, creatine phosphate, and EDTA had no stimulatory effect.     

Interaction between the synthesis of alpha and beta globin.

We have examined the relationship between alpha and beta globin chain syntheses by utilizing the distribution of isoleucyl residues in rabbit hemoglobin. The alpha globin chain contains three isoleucyl residues while the beta chain of certain rabbits contains no isoleucine. O-Methyl-L-threonine, an isoleucine isostere, inhibits incorporation of radiolabeled amino acids into alpha chains in rabbit reticulocytes. When alpha chain synthesis is inhibited by 50-85%, beta synthesis is stimulated by 15-50%. The excess labeled beta chains are not distinguishable from authentic beta chains by any of the following criteria: (a) carboxymethyl cellulose chromatography in sodium phosphate-urea buffers, (b) electrophoresis on polyacrylamide gels containing sodium dodecyl sulfate, and (c) electrophoresis of methionine-containing tryptic peptides. The stimulation of beta synthesis continues after the pool of excess alpha chains has been exhausted by preincubation with O-methyl-L-threonine. The stimulation does not occur, however, when 1 mM 2-mercaptoethanol is added to the incubation medium or when the cells are excessively diluted in the incubation mixture. The rates of beta chain initiation and elongation during stimulation have been compared to the rates during normal synthesis. Although both rates are increased, the rate of elongation increases more than initiation, suggesting that initiation is the rate-limiting step in increased beta chain production. The stimulation of beta synthesis when alpha synthesis is inhibited is interpreted as resulting from relief of competition between alpha and beta mRNAs for limiting components of the protein synthetic apparatus.     

A heat-stable polypeptide component of an ATP-dependent proteolytic system from reticulocytes

The degradation of denatured globin in reticulocyte lysates is markedly stimulated by ATP. This system has now been resolved into two components, designated fractions I and II, in the order of their elution from DEAE-cellulose. Fraction II has a neutral protease activity but is stimulated only slightly by ATP, whereas fraction I has no proteolytic activity but restores ATP-dependent proteolysis when combined with fraction II. The active principle of fraction I is remarkably heat-stable, but it is non-dialysable, precipitable with ammonium sulfate and it is destroyed by treatment with proteolytic enzymes. In gel filtration on Sephadex-G-75, it behaves as a single component with a molecular weight of approximately 9,000.     

Cerebral metabolic disturbances in the brain during acute liver failure: from hyperammonemia to energy failure and proteolysis

Several observations suggest that patients with fulminant hepatic failure may suffer from disturbances in cerebral metabolism that can be related to elevated levels of arterial ammonia. One effect of ammonia is the inhibition of the rate limiting TCA cycle enzyme alpha-ketoglutarate dehydrogenase (alphaKGDH) and possibly also pyruvate dehydrogenase, but this has been regarded to be of no quantitative importance. However, recent studies justify a revision of this point of view. Based on published data, the following sequence of events is proposed. Inhibition of alphaKGDH both enhances the detoxification of ammonia by formation of glutamine from alpha-ketoglutarate and reduces the rate of NADH and oxidative ATP production in astrocytic mitochondria. In the astrocytic cytosol this will lead to formation of lactate even in the presence of sufficient oxygen supply. Since the aspartate-malate shuttle is compromised, there is a risk of depletion of mitochondrial NADH and ATP unless compensatory mechanisms are recruited. One likely compensatory mechanism is the use of amino acids for energy production. Branched chain amino acids, like isoleucine and valine can supply carbon skeletons that bypass the alphaKGDH inhibition and maintain TCA cycle activity. Large-scale consumption of certain amino acids can only be maintained by cerebral proteolysis, as has been observed in these patients. This hypothesis provides a link between hyperammonemia, ammonia detoxification by glutamine production, cerebral lactate production, and cerebral catabolic proteolysis in patients with FHF.