The effects of pro- and anti-atherosclerotic factors on intracellular nucleotide concentration in murine endothelial cells

Abstract

Endothelial cell activation and dysfunction could lead to endothelial injury that is an important factor in the development of vascular diseases. Vascular injury is strongly associated with disturbed endothelial cell energetics and pyridine nucleotide pool. This study aimed to evaluate the effects of inflammatory stimuli (IL-6, LPS), uric acid, hyperglycemia, fatty acids, flavonoids, statins and nonsteroidal anti-inflammatory drugs on cellular concentration of adenosine triphosphate (ATP), adenosine diphosphate (ADP) and nicotinamide adenine dinucleotide (NAD⁺) in cultured endothelial cells. Murine-immortalized heart endothelial cells (H5V cells) were treated with different concentrations of pro- and anti-atherosclerotic factors and intracellular concentration of nucleotides were measured using high performance liquid chromatography. Intracellular ATP concentration in H5V cells was not changed by inflammatory stimuli (IL-6 and LPS), uric acid, glucose, atorvastatin, acetylsalicylic acid, monounsaturated and polyunsaturated fatty acids. Only high concentration of palmitic acid (1?mM) and kaempferol (>0.1?mM) decreased intracellular ATP concentration. The concentration of intracellular ADP has not been altered by any of tested compounds. In turn, intracellular NAD⁺ pool was modified only by polyunsaturated fatty acids and atorvastatin. Linoleic acid, docosahexaenoic acid and atorvastatin increased cellular NAD⁺ concentration. Tested compounds have a small influence on murine endothelial cell energetics, but polyunsaturated fatty acids and atorvastatin increased intracellular NAD⁺ concentration that could be an important protective mechanism against endothelial cell injury.     

Is adenosine a second metabolic substrate for human red blood cells?

Adenosine is present in the micromolar range in human plasma. In this study, metabolism of adenosine, which was maintained between 0.62 +/- 0.03 and 2.92 +/- 0.43 microM by means of a continuous infusion using a Harvard infusion pump, was investigated in human red blood cells. It was found that lactate production increases linearly as the adenosine concentration was raised. Cells infused with an average adenosine concentration of 2 microM produced lactate comparable to that produced by 5 mM glucose. The extent to which ATP concentration is maintained by adenosine also depends on its concentration. After a 4 h infusion with an average adenosine concentration of 0.7 microM, ATP content amounts to 75% of the glucose control. Raising the adenosine infusion concentration to 1.5 microM results in a full maintenance of ATP levels and at concentrations higher than 1.5 microM, adenosine produces a net synthesis of ATP. A net synthesis of ATP also occurs with adenosine concentration below 1.5 microM, if supplemented with glucose. In contrast, inosine infusion provides only a partial support of ATP and fails to produce a net synthesis of ATP in the presence of glucose. In addition, the presence of purine nucleoside and glucose together influence the metabolism of each other, depending on inorganic phosphate content (Pi). At a Pi concentration of 1 mM, the glucose consumption rate is reduced by approx. 25% by purine nucleoside infusion and vice versa. In sharp contrast, glucose consumption at 16 mM Pi is potentiated by adenosine. These findings suggest that plasma adenosine contributes significantly to human red cell energetics, even though it is present at a concentration several orders of magnitude lower than glucose.     

Ischemic preconditioning preserves proton leakage from mitochondrial membranes but not oxidative phosphorylation during heart reperfusion

The aim of this study was to evaluate the role of mitochondria in the recovery of cardiac energetics induced by ischaemic preconditioning at reperfusion. Isolated rat hearts were aerobically perfused (control), subjected to global ischaemia and reperfusion (reperfusion), or subjected to 3 brief cycles of ischaemia/reperfusion and then to the protocol of reperfusion (preconditioning). At the end of the perfusion, antimycin A was delivered to the heart for 25 min, to inhibit mitochondrial respiration and stimulate glycolysis. The increased amount of lactate released in the coronary effluent was correlated with the number of viable cells producing this end-product of glycolysis. Preconditioned hearts released 18% more lactate than reperfused hearts (p < 0.05). This result indicates that preconditioning partially preserved cell viability, as was also evidenced by the MTT assay performed on cardiac biopsies. The difference between antimycin A-stimulated and basal lactate concentration, representing the contribution of mitochondria to the overall energetics of cardiac tissue, was also 18% more elevated in the preconditioned hearts than in the reperfused hearts (p < 0.01). The study of the respiratory function of mitochondria isolated at the end of perfusion, showed that preconditioning did not improve the oxygen-dependent production of ATP (state 3 respiration, ADP/O). On the contrary, state 4 respiration, which is related to proton leakage, was 35.0% lower in the preconditioned group than reperfusion group (p < 0.05). Thus, preconditioning ameliorates cardiac energetics by preserving cell death, but without affecting mitochondrial oxidative phosphorylation. Mitochondria can contribute to cell survival by the attenuation of proton leak from inner membrane.     

Interactions between intracellular chloride concentrations, intracellular pH and energetic status in rat lactotrope cells in primary culture

Rat lactotrope cells in primary cultures have a higher intracellular Cl- concentration ([Cl-]i) than that predicted by a passive distribution across the membrane. This suggests that active cellular mechanisms ensure this ionic equilibrium. In this study, we examined the interactions between pHi, [Cl-]i regulation and cell energetics. We analyzed: 1. the interactions between extracellular Cl- concentrations, [Cl-]i and cellular energy; 2. the influence of [Cl-]i on respiratory chain function; 3. the correlation with glycolysis and; 4. the role played by pHi in these cellular mechanisms. We show that low [Cl-]i decreases ATP cell content, ATP/ADP ratio and modify phosphorylative oxidations. ATP production is rather due to the anaerobic pathway of the glucose metabolism than the aerobic one and depends also on other metabolic substrates among which glutamine probably has a special role. Finally, pHi appears as a determinant in the balance between aerobic and anaerobic pathways. These results are discussed in relation to the role of Cl- in normal and pathological (effect of hypoxia on mature and immature neurons) cell situations.     

Calixarene-dependent hydrolysis of ATP. II. The catalytic properties of reaction stimulated by calixarene C-107

In this paper we have investigated nonenzimatic hydrolysis of ATP stimulated by calixarene C-107. It has been shown the dependences of the kinetic characteristics from reagent concentration: the maximal value released Pi did not depend on ATP concentration and linearly increased with the growth of calixarene concentration. Besides the growth concentration of ATP or calixarene increased the maximum instantaneous velocity of the reaction and decreased characteristic time. It was identified that univalent cation of Na+, K+, Li+, choline+ and bivalent cation of Ca2+ or Mg2+ did not influence the reaction of ATP hydrolysis, in the presence of other bivalent cation the inhibition of the reaction occurred in line with the sequence: Cu2+ > Ba2+ > Pb2+ > Sr2+ > Ni2+ = Zn2+ > Mn2+ > > Co2+. The alkalization in the range of pH 6.0-8.0 stimulated the ATP hydrolysis. The magnitude of activation energy of the reaction was 50.7 +/- 8.9 kilojoules per mole. The specificity for nucleoside tri- and di-phosphates was not observed. Obtained data can be useful for designing the synthetic ATP-hydrolyzing catalysts and also for subsequent investigation of kinetics, energetics and mechanism of both enzymatic and nonenzymatic ATP hydrolysis reaction.     

A simple theory of motor protein kinetics and energetics. II

A three-state stochastic model of motor protein [Qian, Biophys. Chem. 67 (1997) pp. 263-267] is further developed to illustrate the relationship between the external load on an individual motor protein in aqueous solution with various ATP concentrations and its steady-state velocity. A wide variety of dynamic motor behavior are obtained from this simple model. For the particular case of free-load translocation being the most unfavorable step within the hydrolysis cycle, the load-velocity curve is quasi-linear, V/Vmax = (cF/Fmax-c)/(1-c), in contrast to the hyperbolic relationship proposed by A.V. Hill for macroscopic muscle. Significant deviation from the linearity is expected when the velocity is less than 10% of its maximal (free-load) value--a situation under which the processivity of motor diminishes and experimental observations are less certain. We then investigate the dependence of load-velocity curve on ATP (ADP) concentration. It is shown that the free load Vmax exhibits a Michaelis-Menten like behavior, and the isometric Fmax increases linearly with ln([ATP]/[ADP]). However, the quasi-linear region is independent of the ATP concentration, yielding an apparently ATP-independent maximal force below the true isometric force. Finally, the heat production as a function of ATP concentration and external load are calculated. In simple terms and solved with elementary algebra, the present model provides an integrated picture of biochemical kinetics and mechanical energetics of motor proteins.     

The mitochondrial ADP/ATP carrier: functional and structural studies in the route of elucidating pathophysiological aspects

The mitochondrial ADP/ATP carrier plays a central role in aerobic cell energetics by providing to the cytosol the ATP generated by oxidative phosphorylation. Though discovered around 40 years ago owing to the existence of unique inhibitors and in spite of numerous experimental approaches, this carrier, which stands as a model of the mitochondrial solute carriers keeps some long-standing mystery. There are still open challenging questions among them the precise ADP/ATP transport mechanism, the functional oligomeric state of the carrier and relationships between human ADP/ATP carrier dysfunctioning and pathologies. Deciphering the 3D structure of this carrier afforded a considerable progress of the knowledge but requires now additional data focused on molecular dynamics from this static picture. State of the art in this topic is reviewed and debated in this paper in view of better comprehending origin of the discrepancies in these questions and, finally, the multiple physiological roles of this carrier in eukaryotic cell economy.     

Energetics of muscle contraction: the whole is less than the sum of its parts

Understanding muscle energetics is a problem in optimizing supply of ATP to the demands of ATPases. The complexity of reactions and their fluxes to achieve this balance is greatly reduced by recognizing constraints imposed by the integration of common metabolites at fixed stoichiometry among modular units. ATPase is driven externally. Oxidative phosphorylation and glycogenolysis are the suppliers. We focus on their regulation which involves different controls, but reduces to two principles that enable facile experimental analysis of the supply and demand fluxes. The ratio of concentration of phosphocreatine (PCr) to ATP, not their individual values, sets the range of achievable concentrations of ADP in resting and active muscle (at fixed pH) in different cell types. This principle defines the fraction of available flux of oxidative phosphorylation utilized (at fixed enzyme activities). Then the kinetics of PCr recovery defines the kinetics of oxygen supply and substrate utilization. The second principle is the constancy of PCr and H(+) (lactate) production by glycogenolysis due to the coupling of ATPase and glycolysis. This principle enables glycogenolytic flux to be measured from intracellular proton loads. Further simplification occurs because the magnitude of the interacting fluxes and metabolite concentrations are specified within narrow limits when both the resting and active fluxes are quantified. Thus there is a small set of rules for assessing and understanding the thermodynamics and kinetics of muscle energetics.     

Examination of the nucleotide‐linked assembly mechanism of E. coli ClpA

Escherichia coli ClpA is a AAA+ (ATPase Associated with diverse cellular Activities) chaperone that catalyzes the ATP‐dependent unfolding and translocation of substrate proteins targeted for degradation by a protease, ClpP. ClpA hexamers associate with one or both ends of ClpP tetradecamers to form ClpAP complexes. Each ClpA protomer contains two nucleotide‐binding sites, NBD1 and NBD2, and self‐assembly into hexamers is thermodynamically linked to nucleotide binding. Despite a number of studies aimed at characterizing ClpA and ClpAP‐catalyzed substrate unfolding and degradation, respectively, to date the field is unable to quantify the concentration of ClpA hexamers available to interact with ClpP for any given nucleotide and total ClpA concentration. In this work, sedimentation velocity studies are used to quantitatively examine the self‐assembly of a ClpA Walker B variant in the presence of ATP. In addition to the hexamerization, we observe the formation of a previously unreported ClpA dodecamer in the presence of ATP. Further, we report apparent equilibrium constants for the formation of each ClpA oligomer obtained from direct boundary modeling of the sedimentation velocity data. The energetics of nucleotide binding to NBD1 and NBD2 are revealed by examining the dependence of the apparent association equilibrium constants on free nucleotide concentration.     

Inhibitory effects of Bcl-2 on mitochondrial respiration

In contrast to the well-established anti-apoptotic effect of Bcl-2 protein, we have recently demonstrated that Bcl-2 overexpression by vaccinia virus causes apoptosis in BSC-40 cells, while it prevents apoptosis in HeLa G cells. Given the key role of mitochondria in the process of apoptosis, we focused on effects of Bcl-2 expression on mitochondrial energetics of these two cell lines. In this study we present data indicating that BSC-40 cells derive their ATP mainly from oxidative phosphorylation whereas HeLa G cells from glycolysis. More importantly, we show that in both cell lines, Bcl-2 inhibits mitochondrial respiration and causes a decrease of the ATP/ADP ratio. However, it appears that BSC-40 cells cannot sustain this decrease and die, while HeLa G cells survive, being adapted to the low ratio of ATP/ADP maintained by glycolysis. Based on this observation, we propose that the outcome of Bcl-2 expression is determined by the type of cellular ATP synthesis, namely that Bcl-2 causes apoptosis in cells relying on oxidative phosphorylation.     

Flavaspidic acid: effects on cell respiration and oxidative phosphorylation in isolated hepatocytes.

Flavaspidic acid-N-Methyl-glucaminate caused a concentration-dependent increase in oxygen consumption and decrease in ATP concentration, and an increased incorporation of ¹⁴C-oleate, ¹⁴C-octanoate and ¹⁴C-glucose into ¹⁴CO₂ in isolated rat hepatocyte suspensions. Mitochondrial respiratory control ratio and P:O ratio were decreased by flavaspidic acid, indicating an uncoupling of oxidative phosphorylation. Although this agent remains a useful probe for the study of hepatic transport and metabolism of long chain fatty acids and other organic anions, conditions under which it is employed must be designed so as to avoid the potentially confusing effects of its adverse influence on cell energetics.     

Aminoacyl-tRNA synthetases: inter-site interaction as a possible proofreading mechanism

Smooth muscle cell energetics of taenia caeci during relaxation, activity and maximal contraction were investigated using ³¹P-NMR. In relaxed muscle obtained in calcium-free medium, [ATP], [phosphocreatine] and [sugar phosphate] were 4.4 mM, 7.7 mM and 2.8 mM, respectively. There was only a small difference in the energetics of spontaneously active and maximally contracted muscles, but under both conditions substantial changes occurred as compared with relaxed muscles. The internal pH in relaxed muscle was found to be 7.05, which acidified to 6.5 during contraction. The level of sugar phosphates was found to be not a limiting factor in energetics.     

Fast and reliable determination of intracellular ATP from cells cultured in 96-well microplates

Due to its fundamental role in cellular energetics, metabolic regulation and cellular signalling, determination of intracellular adenosine-5'-triphosphate (ATP) is an irreplaceable tool in the characterization of cellular physiology. Classical protocols describing the measurement of ATP from cells usually suffer from the use of relatively high reaction volumes and the according use of cuvettes for ATP determination, thus making them impractical for processing high sample numbers. We therefore present two methods for the fast and reliable measurement of intracellular ATP levels of cells cultured in 96-well microplates. The procedures are compared with each other concerning detection limit, dynamic range, precision and practicability. Both methods described allow the fast and standardized measurement of intracellular ATP using the 96-well microplate format that is applicable for both, high-throughput cell culture and subsequent determination of intracellular ATP.     

Detection of local ATP release from activated platelets using cell surface-attached firefly luciferase

We have developed a method for measuring the local concentrationof ATP at the extracellular surface of live cells. This method relieson the specific attachment to the cell surface of a chimeric proteinthat consists of the IgG-binding domain ofStaphylococcus aureus protein A fusedin-frame with the complete sequence for firefly luciferase (proA-luc).Expression of proA-luc in Escherichia coli and its one-step affinity purification arestraightforward. Attachment to cells is demonstrated to be specific andantibody dependent using several suspended and adherent cell types.Light production by cell surface-attached luciferase is continuous, linearly related to ATP concentration, and sufficient to provide nanomolar sensitivity. The spatial resolution of this method enables the observation of strictly local changes in extracellular ATP duringits secretion from activated platelets. Furthermore, the activity ofcell-attached luciferase is relatively refractory to the inclusion ofnucleotidases in the medium, arguing for its effectiveness in cellsystems possessing potent ecto-ATPases.

     

Modular control analysis of effects of chronic hypoxia on mouse heart

Modular control analysis (MoCA; Diolez P, Deschodt-Arsac V, Raffard G, Simon C, Santos PD, Thiaudiere E, Arsac L, Franconi JM. Am J Physiol Regul Integr Comp Physiol 293: R13-R19, 2007) was applied here on perfused hearts to describe the modifications of the regulation of heart energetics induced in mice exposed to 3-wk chronic hypoxia. MoCA combines 31P-NMR spectroscopy and modular (top down) control analysis to describe the integrative regulation of energy metabolism in the intact beating heart, on the basis of two modules [ATP/phosphocreatine (PCr) production and ATP/PCr consumption] connected by the energetic intermediates. In contrast with previous results in rat heart, in which all control of contraction was on ATP demand, mouse heart energetics presented a shared control of contraction between ATP/PCr-producing and -consuming modules. In chronic hypoxic mice, the decrease in heart contractile activity and PCr-to-ATP ratio was surprisingly associated with an important and significant higher response of ATP/PCr production (elasticity) to PCr changes compared with control hearts (-10.4 vs. -2.46). By contrast, no changes were observed in ATP/PCr consumption since comparable elasticities were observed. Since elasticities determine the regulation of energetics of heart contraction, the present results show that this new parameter may be used to uncover the origin of the observed dysfunctions under chronic hypoxia conditions. Considering the decrease in mitochondrial content reported after exposure to chronic hypoxia, it appears that the improvement of ATP/PCr production response to ATP demand may be viewed as a positive adaptative mechanism. It now appears crucial to understand the very processes responsible for ATP/PCr producer elasticity toward the energetic intermediates, as well as their regulation.     

The House Building of Caddis Larvae: A Source of Projects for Schools

Protoplasmic streaming (cyclosis) in plant cells has long been presented as a purely qualitative exercise in microscopy. Using simple formulae, it is possible to determine the energetics of this process (in terms of ATP hydrolysis) and its relation to the total energy expenditure of the plant cell. This exercise can provide a valuable integration of physicochemical principles and microscopical observation.     

Intracellular adenosine triphosphate as a measure of human tumor cell viability and drug modulated growth

Summary Adenosine triphosphate is the primary energy unit for cells, and levels of this compound offer a potential marker for cell viability and growth. The availability of a bioluminescence assay allows for a rapid, sensitive, and reproducible measurement of ATP. A method is described for the quantification of intracellular ATP levels in human cancer cells. ATP levels were linearly related to the number of viable cells and increased with time in human cancer cell line cultures correlating with growth kinetics. The effect of 5-fluorouracil, doxorubicin, methotrexate, cytosine arabinoside, nitrogen mustard, melphalan, vinblastine, and cisplatin on the growth of human cancer cell lines was studied utilizing ATP levels. ATP levels and colony formation in agar of drug-exposed cells were compared. Overall there was a significant correlation between drug effects on colony formation and ATP levels. The ATP assay is rapid, simple, reproducible, and a relatively inexpensive method of quantifying drug effects on malignant cells. This makes it a potentially useful method for screening new anticancer drugs in human cancer cell lines.     

Energetics of heart mitochondria during acute phase of Trypanosoma cruzi infection in rats

The energetics of heart mitochondria was studied in the acute phase of Trypanosoma cruzi infection in rats. Wistar rats were infected with 2 × 10⁵ trypomastigote forms of the Y strain of T. cruzi, and heart mitochondria and submitochondrial particles isolated after 7 and 25 days of infection. Ultrastructure of mitochondria seemed to be preserved, but cytochrome c levels were significantly depressed. Respiratory control ratios (RCR) were decreased for glutamate and succinate oxidations, as a consequence of inhibition of respiration in state 3 and/or of stimulation of respiration in state 4. Stimulation of hydrolytic activity of FoF1-ATPase by energization of mitochondria was approx. 2-fold higher in relation to controls. Mitochondrial ATP concentration remained constant. In conclusion, during the acute phase of T. cruzi infection in rats there is an energy impairment at the level of heart mitochondria, but their ultrastructure and ATP concentration seem to be preserved; the maintenance of ATP may be due to an adaptative mechanism of the cell which includes inhibition of the hydrolytic activity of FoF1-ATPase.     

Kinetics and energy aspects of the effect of incubation medium dielectric permeability on the catalytic and transporting activity of Mg2+-ATP-dependent Ca2+ pump plasma membranes

The results suggest that changes in polarity of the incubation medium markedly affect the activity of transport Ca2+, Mg(2+)-ATPase solubilized from smooth muscle cell plasma membranes and that the electrostatic interactions between the enzyme active center and specific ligands (MgADP-, in particular) significantly contribute to the energetics of ATP hydrolysis.     

Patterns in the distribution of intracellular ATP concentration in relation to coordination of amoeboid cell behavior in Physarum polycephalum

The Physarum plasmodium reacts tactically to external stimuli. The cell behavior of this giant amoeboid cell was studied by analysing intracellular ATP concentration. The two-dimensional (2D) spatial distribution of ATP depended on cell shape: a polar pattern for a unidirectionally migrating plasmodium, a bowl shape for a circular plasmodium, a hump shape for an oval plasmodium, or a wavy pattern for plasmodia stimulated with blue light or confined in a small chamber, etc. Local external stimulation brought about new patterns of ATP distribution. The ATP concentrations around the stimulated frontal region were reduced by about a half stimulation with KCl (repellent) or casamino acids (attractant). In both cases, migration was inhibited. Migration velocity increased almost linearly with increasing concentration of intracellular ATP above the threshold (about 20 micrograms/mg protein). Under anaerobic conditions or at low temperatures, the intracellular ATP oscillated slowly with a periodicity of about 30 min. Pattern formations in the intracellular ATP concentration and amoeboid coordination are discussed in terms of coupled chemical oscillators in a self-organizing system.