Regulation of adenine nucleotide concentration at endothelium-fluid interface by viscous shear flow.

The action of adenine nucleotides on vascular endothelial cells is apparently mediated by the local flow conditions. Because nucleotides are sequentially degraded from ATP-->ADP-->AMP-->adenosine by ecto-enzymes at the endothelial surface, it has been hypothesized that the observed flow effect is caused by the flow-dependent change of nucleotide concentration at the cell surface. In this study, we have calculated the concentration profiles of adenine nucleotides at the cell surface under flow conditions encountered in an in vitro parallel-plate flow system, as has been used in several related experimental studies. When medium containing uniformly distributed ATP is perfused over endothelial monolayers, our results show that ATP concentration in the cell vicinity gradually decreases in the streamwise direction as a result of enzymatic degradation. This hydrolysis of ATP results in the generation of ADP, and ADP concentration in turn gradually increases at the cell surface. The concentration profiles of nucleotides are dependent on the levels of applied wall shear rate. As the corresponding shear stress increases from 0.1 to 30 dynes/cm2, ATP concentration at the cell surface at the center of coverslip increases from 0.66 to 0.93. Under no-flow conditions, our model predicts a steady decline of ATP concentration and a transient increase of ATP-derived ADP, comparable to the published results of previous experiments. These numerical results, combined with our recent experimental data, provide insights into the cellular mechanisms by which hemodynamic flow modulates the effects of vasoactive agents on endothelium.     

Evidence supporting the Nucleotide Axis Hypothesis: ATP release and metabolism by coronary endothelium

The Nucleotide Axis Hypothesis, defined and supported herein, proposes that ATP stimulates the release of vasoactive mediators from endothelium, including ATP itself. Here, we show rapid endothelium-dependent, agonist-stimulated ATP elaboration in coronary vessels of guinea pigs. Measurement of extracellular ADP metabolism in intact vessels results in the time- and substrate-dependent formation of ATP in the coronary perfusate in amounts greater than can be accounted for by release from endothelium alone. ATP formation by endothelial cells is saturable (K(M) = 38.5 micromol/l, where K(M) is substrate concentration at which rate is half-maximal.) and trypsin-sensitive, membranes from [gamma-(32)P]ATP-labeled cells support ADP-dependent transphosphorylation by a 20-kDa protein, Western blots reveal the presence of a nucleoside diphosphate kinase (NDPK) of approximately 20 kDa in endothelial membranes, and analysis of NDPK antibody binding by flow cytometry is consistent with the presence of an ecto-NDPK on cardiac endothelial cells. Sequencing of the endothelial cell ecto-NDPK reveals a predicted amino acid sequence with 85% identity to human Nm23-H1 and consistent with a protein whose properties may confer membrane association as well as sites of regulation of activity. Our data underscore the potential importance of a nucleotide axis in cardiac blood vessels.     

Volume-regulated anion channels serve as an auto/paracrine nucleotide release pathway in aortic endothelial cells

Mechanical stress induces auto/paracrine ATP release from various cell types, but the mechanisms underlying this release are not well understood. Here we show that the release of ATP induced by hypotonic stress (HTS) in bovine aortic endothelial cells (BAECs) occurs through volume-regulated anion channels (VRAC). Various VRAC inhibitors, such as glibenclamide, verapamil, tamoxifen, and fluoxetine, suppressed the HTS-induced release of ATP, as well as the concomitant Ca(2+) oscillations and NO production. They did not, however, affect Ca(2+) oscillations and NO production induced by exogenously applied ATP. Extracellular ATP inhibited VRAC currents in a voltage-dependent manner: block was absent at negative potentials and was manifest at positive potentials, but decreased at highly depolarized potentials. This phenomenon could be described with a "permeating blocker model," in which ATP binds with an affinity of 1.0 +/- 0.5 mM at 0 mV to a site at an electrical distance of 0.41 inside the channel. Bound ATP occludes the channel at moderate positive potentials, but permeates into the cytosol at more depolarized potentials. The triphosphate nucleotides UTP, GTP, and CTP, and the adenine nucleotide ADP, exerted a similar voltage-dependent inhibition of VRAC currents at submillimolar concentrations, which could also be described with this model. However, inhibition by ADP was less voltage sensitive, whereas adenosine did not affect VRAC currents, suggesting that the negative charges of the nucleotides are essential for their inhibitory action. The observation that high concentrations of extracellular ADP enhanced the outward component of the VRAC current in low Cl(-) hypotonic solution and shifted its reversal potential to negative potentials provides more direct evidence for the nucleotide permeability of VRAC. We conclude from these observations that VRAC is a nucleotide-permeable channel, which may serve as a pathway for HTS-induced ATP release in BAEC.     

Effects of altering the ATP/ADP ratio on pump-mediated Na/K and Na/Na exchanges in resealed human red blood cell ghosts

Resealed human red blood cell ghosts were prepared to contain a range of ADP concentrations at fixed ATP concentrations and vice versa. ATP/ADP ratios ranging from approximately 0.2 to 50 were set and maintained (for up to 45 min) in this system. ATP and ADP concentrations were controlled by the addition of either a phosphoarginine- or phosphocreatine-based regenerating system. Ouabain-sensitive unidirectional Na efflux was determined in the presence and absence of 15 mM external K as a function of the nucleotide composition. Na/K exchange was found to increase to saturation with ATP (K 1/2 approximately equal to 250 microM), whereas Na/Na exchange (measured in K-free solutions) was a saturating function of ADP (K 1/2 approximately equal to 350 microM). The elevation of ATP from approximately 100 to 1,800 microM did not appreciably affect Na/Na exchange. In the presence of external Na and a saturating concentration of external K, increasing the ADP concentration at constant ATP was found to decrease ouabain-sensitive Na/K exchange. The decreased Na/K exchange that still remained when the ADP/ATP ratio was high was stimulated by removal of external Na. Assuming that under normal substrate conditions the reaction cycle of the Na/K pump is rate-limited by the conformational change associated with the release of occluded K [E2 X (K) X ATP----E1 X ATP + K], increasing ADP inhibits the rate of these transformations by competition with ATP for the E2(K) form. A less likely alternative is that inhibition is due to competition with ATP at the high-affinity site (E1). The acceleration of the Na/K pump that occurs upon removing external Na at high levels of ADP evidently results from a shift in the forward direction of the transformation of the intermediates involved with the release of occluded Na from E1P X (Na). Thus, the nucleotide composition and the Na gradient can modulate the rate at which the Na/K pump operates.     

The hydrolysis of extracellular adenine nucleotides by cultured endothelial cells from pig aorta. Feed-forward inhibition of adenosine production at the cell surface

The time course of the extracellular reaction sequence ATP----ADP----AMP----adenosine has been examined during recirculation of substrate solutions over cultured pig aortic endothelial cells attached to polystyrene beads. This permits the study of reactions at volume to cell surface ratios approaching those of small blood vessels. When endothelial cells were presented with an initial bolus of ATP, high concentrations of the intermediates ADP and AMP developed before significant conversion of AMP to adenosine occurred. Further, the higher the initial ATP concentration, the slower the conversion of AMP to adenosine. Kinetic constants for each reaction were estimated by fitting simulated reaction curves to observed time courses. Apparent Km values estimated in this way agreed well with those reported for initial velocity measurements (ATPase = 300 microM; ADPase = 240 microM; and 5'-nucleotidase = 26 microM). The ratio of maximum velocities was ATPase:ADPase:AMPase = 6:1.5:1, with absolute values varying among cell batches. The data could only be fitted if the model incorporated inhibition of 5'-nucleotidase by ATP or ADP, and satisfactory fitting was achieved with a Ki value for ADP of 5 microM. These kinetic properties maximize the time separation of the intermediate pools. In vivo, at sites of platelet degranulation, they would create a time gap proportional to the size of the initial release between release of ADP (a proaggregatory milieu) and the appearance of adenosine (an anti-aggregatory milieu).     

Involvement of cell surface ATP synthase in flow-induced ATP release by vascular endothelial cells

Endothelial cells (ECs) release ATP in response to shear stress, a mechanical force generated by blood flow, and the ATP released modulates EC functions through activation of purinoceptors. The molecular mechanism of the shear stress-induced ATP release, however, has not been fully elucidated. In this study, we have demonstrated that cell surface ATP synthase is involved in shear stress-induced ATP release. Immunofluorescence staining of human pulmonary arterial ECs (HPAECs) showed that cell surface ATP synthase is distributed in lipid rafts and co-localized with caveolin-1, a marker protein of caveolae. Immunoprecipitation indicated that cell surface ATP synthase and caveolin-1 are physically associated. Measurement of the extracellular metabolism of [(3)H]ADP confirmed that cell surface ATP synthase is active in ATP generation. When exposed to shear stress, HPAECs released ATP in a dose-dependent manner, and the ATP release was markedly suppressed by the membrane-impermeable ATP synthase inhibitors angiostatin and piceatannol and by an anti-ATP synthase antibody. Depletion of plasma membrane cholesterol with methyl-beta-cyclodextrin (MbetaCD) disrupted lipid rafts and abolished co-localization of ATP synthase with caveolin-1, which resulted in a marked reduction in shear stress-induced ATP release. Pretreatment of the cells with cholesterol prevented these effects of MbetaCD. Downregulation of caveolin-1 expression by transfection of caveolin-1 siRNA also markedly suppressed ATP-releasing responses to shear stress. Neither MbetaCD, MbetaCD plus cholesterol, nor caveolin-1 siRNA had any effect on the amount of cell surface ATP synthase. These results suggest that the localization and targeting of ATP synthase to caveolae/lipid rafts is critical for shear stress-induced ATP release by HPAECs.     

Adenine nucleotides modulate phosphatidylcholine metabolism in aortic endothelial cells

ATP and ADP, in concentrations ranging from 1-100 microM, increased the release of [3H]choline and [3H]phosphorylcholine (P-choline) from bovine aortic endothelial cells (BAEC) prelabelled with [3H]choline. This action was detectable within 5 minutes and was maintained for at least 40 minutes. ATP and ADP were equiactive, and their action was mimicked by their phosphorothioate analogs (ATP gamma S and ADP beta S) and adenosine 5'-(beta, gamma imido) triphosphate (APPNP), but not by AMP, adenosine, and adenosine 5'-(alpha, beta methylene)triphosphate (APCPP): these results are consistent with the involvement of P2Y receptors. ATP also induced an intracellular accumulation of [3H]choline: the intracellular level of [3H]choline was increased 30 seconds after ATP addition and remained elevated for a least 20 minutes. The action of ATP on the release of choline metabolites was reproduced by bradykinin (1 microM), the tumor promoter phorbol 12-myristate 13-acetate (PMA, 50 nM), and the calcium ionophore A23187 (0.5 microM). Down-regulation of protein kinase C, following a 24-hour exposure of endothelial cells to PMA, abolished the effects of PMA and ATP on the release of choline and P-choline, whereas the response to A23187 was maintained. These results suggest that in aortic endothelial cells, ATP produces a sustained activation of a phospholipase D hydrolyzing phosphatidylcholine. The resulting accumulation of phosphatidic acid might have an important role in the modulation of endothelial cell function by adenine nucleotides. Stimulation of phospholipase D appears to involve protein kinase C, activated following the release of diacylglycerol from phosphatidylinositol bisphosphate by a phospholipase C coupled to the P2Y receptors (Pirotton et al., 1987a).     

Involvement of inositol 1,4,5-trisphosphate and calcium in the action of adenine nucleotides on aortic endothelial cells

ADP and ATP, in the 1-100 microM range of concentrations, increased the formation of inositol phosphates in bovine aortic endothelial cells. The accumulation of inositol trisphosphate in response to adenine nucleotides was rapid (maximum at 15 s) and transient. This material was identified as the biologically active isomer inositol 1,4,5-trisphosphate on the basis of its retention time by high-performance liquid chromatography on an anion-exchange resin. AMP and adenosine have no effect on inositol phosphates. The action of ATP and ADP was mimicked with an equal potency and activity by their phosphorothioate analogs, ATP gamma S and ADP beta S, and with a lower potency by adenosine 5'-(beta,gamma-imido)triphosphate, whereas adenosine 5'-(alpha,beta-methylene)triphosphate, was inactive. In the same range of concentrations, ADP and ATP induced an efflux of 45Ca2+ from prelabeled bovine aortic endothelial cells and increased the fluorescence emission by cells loaded with quin-2. Here, too, AMP and adenosine were completely inactive. The outflow of 45Ca2+ induced by ADP was partially maintained in a calcium-free medium. These data suggest that in aortic endothelial cells, P2-purinergic receptors, of the P2Y subtype, are coupled to the hydrolysis of phosphatidylinositol bisphosphate by a phospholipase C. It is likely that the release of prostacyclin and endothelium-derived relaxing factor in response to ADP and ATP is a consequence of this initial event.     

Heterogeneous response of microvascular endothelial cells to shear stress

We investigated changes in calcium concentration in cultured bovine aortic endothelial cells (BAECs) and rat adrenomedulary endothelial cells (RAMECs, microvascular) in response to different levels of shear stress. In BAECs, the onset of shear stress elicited a transient increase in intracellular calcium concentration that was spatially uniform, synchronous, and dose dependent. In contrast, the response of RAMECs was heterogeneous in time and space. Shear stress induced calcium waves that originated from one or several cells and propagated to neighboring cells. The number and size of the responding groups of cells did not depend on the magnitude of shear stress or the magnitude of the calcium change in the responding cells. The initiation and the propagation of calcium waves in RAMECs were significantly suppressed under conditions in which either purinergic receptors were blocked by suramin or extracellular ATP was degraded by apyrase. Exogenously applied ATP produced similarly heterogeneous responses. The number of responding cells was dependent on ATP concentration, but the magnitude of the calcium change was not. Our data suggest that shear stress stimulates RAMECs to release ATP, causing the increase in intracellular calcium concentration via purinergic receptors in cells that are heterogeneously sensitive to ATP. The propagation of the calcium signal is also mediated by ATP, and the spatial pattern suggests a locally elevated ATP concentration in the vicinity of the initially responding cells.     

ADP release is rate limiting in steady-state turnover by the dynein adenosinetriphosphatase

The kinetics of the product release steps in the pathway of ATP hydrolysis by dynein were investigated by examining the rate and partition coefficient of phosphate-water 18O exchange under equilibrium and steady-state conditions. Dynein catalyzed both medium and intermediate phosphate-water oxygen exchange with a partition coefficient of 0.30. The dependence of the rate of loss of the fully labeled phosphate species on the concentration of ADP was hyperbolic, with an apparent Kd for the binding of ADP to dynein of 0.085 mM. The apparent second-order rate constant for phosphate binding to the dynein-ADP complex was 8000 M-1 s-1. The time course of medium phosphate-water oxygen exchange during net ATP hydrolysis was examined in the presence of an ATP regeneration system. The observed rate of loss of P18O4 was comparable to the rate observed at saturating ADP which implies that ADP release is rate limiting for dynein in the steady state. Product inhibition of the dynein ATPase was also examined. ADP inhibited the enzyme competitively with a Ki of 0.4 mM. Phosphate was a linear noncompetitive mixed-type inhibitor with a Ki of 11 mM. These data were fit to a model in which phosphate release is fast and is followed by rate-limiting release of ADP, allowing us to define each rate constant in the pathway. A discrepancy between the total free energy calculated compared to the known free energy of ATP hydrolysis suggests that there is an additional step in the pathway, perhaps involving a change in conformation of the enzyme-ADP state preceding ADP release.     

Physiological concentrations of ADP stimulate the release of prostacyclin from bovine aortic endothelial cells

ADP (0.2-200 microM) stimulated the synthesis of prostacyclin (PGI2), as reflected by the release of 6-keto-prostaglandin F1 alpha (6-K-PGF1 alpha), in endothelial cells cultured from bovine aorta. This effect of ADP was mimicked by ATP, whereas AMP and adenosine were completely inactive. The release of 6-K-PGF1 alpha triggered by ADP was rapid and onset (within 5 min), transient (10 min) and followed by a period of refractoriness to a new ADP challenge. Growing and confluent cells were equally responsive to ADP. ADP stimulated the release of free arachidonic acid from the endothelial cells. ADP could thus exert two opposite actions on platelet aggregation in vivo: a direct stimulation and an inhibition mediated by PGI2. This last action might contribute to limit thrombus formation to areas of endothelial cell damage.     

Pre-steady state kinetic studies on H(+)-ATPase from Candida albicans.

The mechanism of ATP hydrolysis by plasma membrane H(+)-ATPase from Candida albicans has been investigated by following the kinetics of H(+) liberation/absorption and the UV difference spectrum in a stopped flow spectrophotometer. A distinct pre-steady state phase of ATP hydrolysis could be defined. While the rapid mixing of P(i) and ATPase produced no transient pH changes, the mixing of ADP leads to the release of 1 H(+) per molecule of ATPase. Rapid mixing of ATP with ATPase releases about 2 H(+) per molecule of ATPase, of which around 1.3 H(+) are reabsorbed. The magnitudes of both H(+) release and absorption were found to be independent of ATP concentration. The rate of H(+) release (k(f)) shows ATP dependence while the rate of H(+) absorption is independent of ATP concentration. The rate of H(+) liberation with ADP, on a concentration basis, was far less as compared with ATP, indicating a low affinity of the ATPase for ADP. No change in the difference spectrum was observed with ADP. The stoichiometry of ATP binding to PM-ATPase was found to be unity from UV-difference spectrum studies. The k(f) values for H(+) release and for the appearance of a difference spectrum following the addition of ATP were found to be similar beyond a 1:1 ratio of ATP:ATPase. The results obtained lead us to propose a 4-step kinetic scheme for the mechanism of ATP hydrolysis.     

Oxidative stress and adenine nucleotide control of mitochondrial permeability transition

Mitochondria can initiate apoptosis by releasing cytochrome c after undergoing a calcium-dependent permeability transition (MPT). Although the MPT is enhanced by oxidative stress and prevented by adenine nucleotides such as adenosine 5'-diphosphate (ADP), the hypothesis has not been tested that oxidants regulate the effects of exogenous adenine nucleotides on the MPT and cytochrome c release. We found that cytochrome c release from intact rat liver mitochondria depended strictly on pore opening and not on membrane potential, and that MPT-enhancing oxidative stress also augmented cytochrome c release. At low oxidative stress, micromolar (ADP) and low adenosine 5'-triphosphate (ATP)/ADP ratio inhibited the MPT and cytochrome c release, whereas ATP or high ATP/ADP had only a slight effect. In freshly isolated mitochondria, the time to half-maximal MPT was related to the log of the ATP/ADP ratio. This function was shifted to shorter times by oxidative stress which decreased ADP protection and caused ATP to accelerate the calcium-dependent MPT. By comparison, mitochondria treated with reducing agents and those isolated from septic rats were protected from the MPT by both nucleotides. These results indicate that oxidation-sensitive site(s) in the membrane regulate the effects of adenine nucleotides on the MPT. The oxidant-based differences in the effects of ADP and ATP on the pore support the novel hypothesis that failure of the cell to consume ATP and provide adequate ADP at the adenine nucleotide transporter during oxidative stress predisposes to cytochrome c release and initiation of apoptosis.     

Adenine nucleotide binding sites on beef heart F1-ATPase. Specificity of cooperative interactions between catalytic sites

Cooperative interactions between nucleotide binding sites on beef heart mitochondrial F1-ATPase have been studied by measuring substrate-promoted release of 5'adenylyl-beta,gamma-imidodiphosphate (AMP-PNP) from a single high affinity site. The site is initially loaded by incubating F1 with an equimolar amount of the nonhydrolyzable ATP analog. When unbound [3H]AMP-PNP is removed and the complex diluted to a concentration below the Kd, release of ligand shows an apparent absolute requirement for medium ADP. Release is biphasic with the extent of release during the initial rapid phase dependent on the concentration of medium ADP. Although phosphate alone has no effect, it enhances the rapid phase of ADP-promoted release over 2-fold with a half-maximal effect at 60 micrometers P1. The binding of efrapeptin (A23871) to the F1.AMP-PNP complex completely prevents ADP-promoted dissociation. Although AMP-PNP release also occurs in the presence of medium ATP, the F1.AMP-PNP complex does not dissociate if an ATP-regenerating system of sufficient capacity to prevent accumulation of medium ADP is added. Consistent with an inability of nucleoside triphosphate to promote release is the failure of medium, nonradioactive AMP-PNP to affect retention of the 3H-labeled ligand. The stability of F1.AMP-PNP complex in the absence of medium nucleotide and the highly specific ability of ADP plus P1 to promote rapid release of the ATP analog are interpreted as support for an ATP synthesis mechanism that requires substrate binding at one catalytic site for product release from an adjacent interacting site.     

Kinetics and mechanism of action of muscle pyruvate kinase

1. The mechanism of rabbit muscle pyruvate kinase was investigated by measurements of fluxes, isotope trapping, steady-state velocity and binding of the substrates. All measurements were made at pH8.5 in Tris/HCl buffer and at 5mm-free Mg(2+). 2. Methods of preparing [(32)P]phosphoenolpyruvate from [(32)P]P(i) in high yield and determining [(32)P]-phosphoenolpyruvate and [8-(14)C]ADP are described. 3. The ratio Flux of ATP to ADP/Flux of ATP to phosphoenolpyruvate (measured at equilibrium) increased hyperbolically with ADP concentration from unity to about 2.1 at 2mm-ADP, but was unaffected by phosphoenolpyruvate concentration. Since the ratio is greater than unity, one pathway for the addition of substrates must involve phosphoenolpyruvate adding first to the enzyme in a rate-limiting step. However, the substrates must also add in the alternative order, because of the non-linear increase in the ratio with ADP concentration and because the rate of increase is very much less than that predicted from the steady-state velocity data for an ordered addition. The lack of influence of phosphoenolpyruvate on the ratio is consistent with the rapid addition of ADP in the alternative pathway. At low ADP concentrations the alternative pathway contributes less than 33% to the total reaction. 4. Isotope trapping was observed with [(32)P]phosphoenolpyruvate, confirming that when phosphoenolpyruvate adds first to the enzyme it is in a rate-limiting step. The release of phosphoenolpyruvate from the ternary complex must also be a slow step. Trapping was not observed with [8-(14)C]ADP, hence the addition of ADP to the free enzyme must be rapid unless its dissociation constant is very large (>20mm). 5. Binding studies showed that 4mol of [(32)P]phosphoenolpyruvate binds to 1mol of the enzyme, probably unligated to Mg(2+), with a dissociation constant appropriate to the mechanism indicated above. Binding of [8-(14)C]ADP could not be detected, and hence the binding of ADP occurs by a low-affinity step. The latter is also demanded by the steady-state velocity data. 6. The ratio Flux of phosphoenolpyruvate to ATP/Flux of phosphoenolpyruvate to pyruvate (determined from the incorporation of label into phosphoenolpyruvate from [3-(14)C]-pyruvate or [gamma-(32)P]ATP during the forward reaction) did not differ significantly from unity. Steady-state velocity data predicted grossly different flux ratios for ordered dissociations of the products, and the results indicate that the dissociation must be rapid and random. The data also exclude a Ping-Pong mechanism. 7. Permissible rate constants for the above mechanism are calculated. The results indicate a high degree of cooperativity in binding, whatever the order of addition of substrate.     

Properties of ATP tightly bound to catalytic sites of chloroplast ATP synthase

Under steady state photophosphorylating conditions, each ATP synthase complex from spinach thylakoids contains, at a catalytic site, about one tightly bound ATP molecule that is rapidly labeled from medium 32Pi. The level of this bound [32P]ATP is markedly reduced upon de-energization of the spinach thylakoids. The reduction is biphasic, a rapid phase in which the [32P] ATP/synthase complex drops about 2-fold within 10 s, followed by a slow phase, kobs = 0.01/min. A decrease in the concentration of medium 32Pi to well below its apparent Km for photophosphorylation is required to decrease the amount of tightly bound ATP/synthase found just after de-energization and before the rapid phase of bound ATP disappearance. The [32P]ATP that remains bound after the rapid phase appears to be mostly at a catalytic site as demonstrated by a continued exchange of the oxygens of the bound ATP with water oxygens. This bound [32P]ATP does not exchange with medium Pi and is not removed by the presence of unlabeled ATP. The levels of tightly bound ADP and ATP arising from medium ADP were measured by a novel method based on use of [beta-32P]ADP. After photophosphorylation and within minutes after the rapid phase of bound ATP loss, the measured ratio of bound ADP to ATP was about 1.4 and the sum of bound ADP plus ATP was about 1/synthase. This ratio is smaller than that found about 1 h after de-energization. Hence, while ATP bound at catalytic sites disappears, bound ADP appears. The results suggest that during and after de-energization the bound ATP disappears from the catalytic site by hydrolysis to bound ADP and Pi with subsequent preferential release of Pi. These and related observations can be accommodated by the binding change mechanism for ATP synthase with participation of alternating catalytic sites and are consistent with a deactivated state arising from occupancy of one catalytic site on the synthase complex by an inhibitory ADP without presence of Pi.     

Chronic hypoxia changes the ratio of endothelin to ATP release from rat aortic endothelial cells exposed to high flow.

Endothelial cells isolated from the thoracic aorta of normoxic and chronically hypoxic rats were perfused (0.5 ml min-1) and stimulated by increased flow rate (3.0 ml min-1). The release of ATP, endothelin and vasopressin was investigated. During periods of high flow rate, endothelial cells isolated from normoxic rats increased their release of ATP and endothelin. In comparison, in hypoxic rats, ATP release during the period of high flow rate was less, whereas endothelin release was greater. Vasopressin release was not increased during periods of stimulation in either group of animals. These results suggest that, under conditions of reduced arterial oxygen tension, a dynamic balance between ATP and endothelin release could regulate the response of vessels to shear stress.     

Kinetic, binding and ultrastructural properties of the beef heart adenine nucleotide carrier protein after incorporation into phospholipid vesicles

1. ADP/ATP transport has been reconstituted by incorporation of the purified carrier protein in liposomes filled with ATP. The transport was assayed by uptake of [14C]ADP into the liposomes, and by release of ATP as determined by a luminescence technique. [14C]ADP uptake was strictly dependent on internal ATP. 2. The simplest phospholipid system capable of yielding high rates of ADP/ATP transport was a mixture of phosphatidylethanolamine and cariolipin (92: 8, w/w). 3. ADP/ATP transport in the reconstituted system proceeded by exchange-diffusion with a 1/1 stoichiometry. The specificity for aDP and ATP was absolute. The capacity and the rate of exchange depended on the concentration of ATP present in liposomes. The rate of transport at 20 degrees C, at 20 mM internal ATP, routinely ranged between 300 and 1000 nmol of nucleotide exchanged per min/mg of added carrier protein. The apparent Km value for external ADP was around 10 microM. 4. The ADP/ATP exchange in the reconstituted system was rather stable to ageing. It dropped by only 20% after 1 day of ageing at 20 degrees C. Divalent cations (Mg2+, Mn2+, Ca2+) at concentrations higher than 1 to 2 mM had a deleterious effect on ADP/ATP transport, concomitant with the release of internal ATP and accumulation of multilamellar vesicles. 5. Atractyloside behaved as a competitive inhibitor and carboxyatractyloside as a non-competitive inhibitor. Bongkrekic acid required a slightly acidic pH to be inhibitory. The data concerning atractyloside, carboxyatractyloside and bongkrekic acid were similar to those obtained with whole mitochondria, suggesting that the carrier protein in liposomes has the same asymmetrical arrangement as in the mitochondria. 6. The percentage of competent carrier protein in liposomes was calculated from dose-response data concerning the inhibition of ADP/ATP transport by atractyloside or carboxyatractyloside, and from the amount of bound [3H]-atractyloside removable by ADP. By both methods, 3 to 6% of the added carrier protein was found to be competent in ADP/ATP transport, based on the assumption that the binding of one atractyloside or carboxyatractyloside molecule per 30000 molecular weight carrier unit results in complete inhibition of transport. 7. Freeze-fracture electron microscopy showed that the ADP/ATP carrier protein-lipid preparations are formed by small vesicles, most of which give rise to smooth fracture faces (probably pure lipid vesicles). Only a small percentage of the vesicles (2 to 4% depending on the amount of carrier protein added) were clearly particulated. About 90% of the particulated vesicles showed no more than 2 particles per vesicle and only 5% more than 5 particles per vesicle. The distribution of the particles between convex and concave fracture faces was asymmetric; about 2/3 of the protein molecules were anchored at the external surface of the vesicles and only 1/3 at the internal one...     

Increased free calcium in endothelial cells under stimulation with adenine nucleotides

The release of vasodilating substances from the vascular endothelium has been postulated to depend on a rise in the level of intracellular free calcium (Cai++). We measured Cai++ in intact monolayers of calf endothelial cells, grown in culture, that were loaded with the fluorescent calcium indicator quin 2. Fluorescence (excitation wavelength 340 nm, emission wavelength 492 nm) was calibrated by raising Cai++ to a maximum with the calcium ionophore ionomycin (0.1 microM) and by lowering it to a minimum with ionomycin plus manganese (0.4 mM), which quenches quin 2 fluorescence completely. Loss of fluorescent dye from the cells was calculated from fluorescence at the isosbestic excitation wavelength (365 nm). Resting Cai++ was 71 +/- 3 (SEM) nM. ATP (adenosine-5'-triphosphate) raised Cai++ dose-dependently and reversibly to 458 +/- 60 nM at a concentration of 10 microM, and at 0.1 mM to values close to those that occurred under ionomycin. ADP (A-5'-PP) and AMP (A-5'-P) had smaller effects with a maximal Cai++ of 287 +/- 72 nM at 30 microM ADP and 176 +/- 17 nM at 0.1 mM AMP. At these concentrations, ADP and AMP attenuated significantly the increase of Cai++ under ATP (10 microM). Adenosine (0.1 or 0.3 mM) and acetylcholine (0.1 to 30 microM) enhanced Cai++ inconsistently, by a maximum of 50 nM. These effects were abolished by theophylline and atropine, respectively. In the absence of extracellular calcium, ATP still raised Cai++, although endothelial responsiveness declined after repetitive stimulations. We conclude that activation of purinergic receptors increases intracellular free calcium in endothelial cells, and that this increase is probably an essential trigger for synthesis of prostacyclin and the labile endothelium-derived relaxant factor.     

KCl -Permeabilized Pancreatic Islets: An Experimental Model to Explore the Messenger Role of ATP in the Mechanism of Insulin Secretion

Our previous work has demonstrated that islet depolarization with KCl opens connexin36 hemichannels in β-cells of mouse pancreatic islets allowing the exchange of small metabolites with the extracellular medium. In this study, the opening of these hemichannels has been further characterized in rat islets and INS–1 cells. Taking advantage of hemicannels’opening, the uptake of extracellular ATP and its effect on insulin release were investigated. 70 mM KCl stimulated light emission by luciferin in dispersed rat islets cells transduced with the fire-fly luciferase gene: it was suppressed by 20 mM glucose and 50 μM mefloquine, a specific connexin36 inhibitor. Extracellular ATP was taken up or released by islets depolarized with 70 mM KCl at 5 mM glucose, depending on the external ATP concentration. 1 mM ATP restored the loss of ATP induced by the depolarization itself. ATP concentrations above 5 mM increased islet ATP content and the ATP/ADP ratio. No ATP uptake occurred in non-depolarized or KCl-depolarized islets simultaneously incubated with 50 μM mefloquine or 20 mM glucose. Extracellular ATP potentiated the secretory response induced by 70 mM KCl at 5 mM glucose in perifused rat islets: 5 mM ATP triggered a second phase of insulin release after the initial peak triggered by KCl-depolarization itself; at 10 mM, it increased both the initial, KCl-dependent, peak and stimulated a greater second phase of secretion than at 5 mM. These stimulatory effects of extracellular ATP were almost completely suppressed by 50 μM mefloquine. The magnitude of the second phase of insulin release due to 5 mM extracellular ATP was decreased by addition of 5 mM ADP (extracellular ATP/ADP ratio = 1). ATP acts independently of K_ATP channels closure and its intracellular concentration and its ATP/ADP ratio seems to regulate the magnitude of both the first (triggering) and second (amplifying) phases of glucose-induced insulin secretion.