Showing papers on "Vanadate published in 1993"

Vacuolar-type H(+)-ATPases are functionally expressed in plasma membranes of human tumor cells

Abstract: Mammalian cells generally regulate their intracellular pH (pHi) via collaboration between Na(+)-H+ exchanger and HCO3- transport. In addition, a number of normal mammalian cells have been identified that express H(+)-adenosinetriphosphatases (ATPases) in their plasma membranes. Because tumor cells often maintain a high pHi, we hypothesized that they might functionally express H(+)-ATPases in their plasma membranes. In the first phase of the present study, we screened 19 normal and tumorigenic human cell lines for the presence of plasmalemmal H(+)-ATPase activity using bafilomycin A1 to inhibit V-type H(+)-ATPase and Sch-28080 to inhibit P-type H(+)-K(+)-ATPase. Bafilomycin A1 decreased pHi in the six tumor cell lines with the highest resting pHi in the absence of HCO3-. Sch-28080 did not affect pHi in any of the human cells. Simultaneous measurement of pH in the cytoplasm and in the endosomes/lysosomes localized the activity of bafilomycin to the plasma membrane in three cell lines. In the second phase of this study, these three cell lines were shown to recover from NH4(+)-induced acid loads in the absence of Na+. This recovery was inhibited by N-ethylmaleimide, bafilomycin A1, and ATP depletion and was not significantly affected by vanadate, Sch-28080, or hexamethyl amiloride. These results indicate that a vacuolar type H(+)-ATPase is expressed in the plasma membrane of some tumor cells.

Insulin mimetic peroxovanadium complexes: preparation and structure of potassium oxodiperoxo(pyridine-2-carboxylato)vanadate(V), K2[VO(O2)2(C5H4NCOO)].2H2O, and potassium oxodiperoxo(3-hydroxypyridine-2-carboxylato)vanadate(V), K2[VO(O2)2(OHC5H3NCOO)].3H2O, and their reactions with cysteine

Abstract: The complexes potassium oxodiperoxo(pyridine-2-carboxylato)vanadate(V), K 2 [VO(O 2 ) 2 (C 5 H 4 NCOO)].2H 2 O (1), and potassium oxodiperoxo(3-hydroxypyridine-2-carboxylato)vanadate(V), K 2 [VO(O 2 ) 2 (OHC 5 H 3 NCOO)].3H 2 O (2), were prepared, and their structures were determined: 1, Cc

Calcium-hydrogen exchange by the plasma membrane Ca-ATPase of voltage-clamped snail neurons.

Abstract: The submicromolar levels of free Ca(2+) ions in animal cells are believed to be maintained in the long term by two different plasma membrane transport mechanisms. These are Na-Ca exchange, driven by the sodium gradient, and a Na-independent Ca pump, driven by ATP. There is good evidence from red blood cells, and indirect evidence from other non-neuronal preparations, that the Ca-ATPase exchanges internal Ca(2+) for external H(+). Although Ca extrusion from nerve cells is inhibited by high external pH, there as yet is no evidence for the counter-transport of H(+). We have used both pH- and calcium-sensitive microelectrodes on the cell surface, and the Ca indicator fura-2 intracellularily, to investigate how snail neurons regulate cytoplasmic free Ca(2+). We now report that in snail neurons the recovery of intracellular Ca(2+) after an increase coincides with both the expected increase in surface Ca(2+) and a decrease in surface H+. Recovery of intracellular Ca and the changes in surface pH and Ca are all blocked by intracellular vanadate. We conclude that snail neurons regulate intracellular Ca mainly by a Ca-H ATPase, and suggest that this Ca-H exchange may account for many of the reported extracellular pH changes seen with neuronal excitation.

Reactive oxygen species mediate phorbol ester-regulated tyrosine phosphorylation and phospholipase A2 activation: Potentiation by vanadate

Abstract: We have previously shown that vanadate potentiates the activating effect of phorbol ester (TPA) on cellular phospholipase A2 (PLA2) in a pathway dependent on the formation of reactive oxygen species (ROS). Here we evaluate the chain of enzymes (protein kinases and phosphatases) that participate in this process. Treatment of macrophages with vanadate plus TPA led to activation of protein kinase C (PKC) and NADPH oxidase (O2- generation in intact cells), massive cellular protein tyrosine phosphorylation, suppression of protein tyrosine phosphatase (PTP) activity and a sustained activation of protein tyrosine kinase (PTK) and myelin basic protein kinase activity (the latter three enzyme activities were assessed in cell lysates). Inhibition of ROS formation by diphenyleneiodonium (DPI) prevented PTP inhibition, PTK activation and protein tyrosine phosphorylation by vanadate plus TPA. Vanadate plus H2O2 mimicked the effect of vanadate plus TPA on PKC activation, cellular protein tyrosine phosphorylation, PTP and PTK, but their effects were resistant to DPI. Suppression of PKC activity (down-regulation; selective inhibitors) prevented the above-mentioned effects of vanadate plus TPA, but not of vanadate plus H2O2. Collectively, the results show that ROS formation induced by TPA in association with vanadate is essential in the modulation of protein tyrosine phosphorylation and PLA2 activity.

Energy transduction in the thermophilic anaerobic bacterium Clostridium fervidus is exclusively coupled to sodium ions.

Abstract: The thermophilic, peptidolytic, anaerobic bacterium Clostridium fervidus is unable to generate a pH gradient in the range of 5.5-8.0, which limits growth of the organism to a narrow pH range (6.3-7.7). A significant membrane potential (delta psi approximately -60 mV) and chemical gradient of Na+ (-Z delta pNa approximately -60 mV) are formed in the presence of metabolizable substrates. Energy-dependent Na+ efflux is inhibited by the Na+/H+ ionophore monensin but is stimulated by uncouplers, suggesting that the Na+ gradient is formed by a primary pumping mechanism rather than by secondary Na+/H+ antiport. This primary sodium pump was found to be an ATPase that has been characterized in inside-out membrane vesicles and in proteoliposomes in which solubilized ATPase was reconstituted. The enzyme is stimulated by Na+, resistant to vanadate, and sensitive to nitrate, which is indicative of an F/V-type Na(+)-ATPase. In the proteoliposomes Na+ accumulation depends on the presence of ATP, is inhibited by the ATPase inhibitor nitrate, and is completely prevented by the ionophore monensin but is stimulated by protonophores and valinomycin. These and previous observations, which indicated that secondary amino acid transport uses solely Na+ as coupling ion, demonstrate that energy transduction at the membrane in C. fervidus is exclusively dependent on a Na+ cycle.

The intensity of vanadium(V)-induced cytotoxicity and morphological transformation in BALB/3T3 cells is dependent on glutathione-mediated bioreduction to vanadium(IV)

Abstract: Cytotoxicity and morphological transformation has been studied in BALB/3T3 Cl A31-1-1 mouse embryo cells for ammonium vanadate [vanadium(V)] and vanadyl sulphate [vanadium(IV)] alone or in combination with diethylmaleate (DEM), a cellular glutathione (GSH)-depleting agent. Cells exposed for 24 h to 10(-5) M vanadium(V) alone or in combination with 3 x 10(-6) M DEM showed the characteristic hyperfine EPR signal of vanadium(IV), which was more obvious in the case of exposure to vanadium(V) alone. This suggests that the amount of vanadium(V) reduced to vanadium(IV) decreased in GSH-depleted cells. While vanadium(IV) at concentrations of 3 x 10(-6) M and 10(-5) M was not transforming in the cells, vanadium(V) showed neoplastic transforming activity (P < 0.025 and P < 0.001 for the two doses, respectively) in comparison to controls (vanadium unexposed cells). Cytotoxicity and morphological transformation in cells exposed to vanadium(V) in combination with 3 x 10(-6) M DEM were significantly more intensive (P < 0.005 and P < 0.01 for the two doses of vanadate tested) compared to the corresponding values observed in cells exposed to vanadium(V) alone. This suggests that the final transforming activity response is dependent on the intracellular GSH-mediated mechanism of reduction of vanadium(V) to vanadium(IV): (i) the extent to which vanadium(V) should be bioreduced to less toxic vanadium(IV) via intracellular GSH is a key point in determining the intensity of the observed neoplastic action; (ii) the carcinogenic potential of vanadium(V) should be strictly dependent on its intracellular persistence which could lead to changes in normal metabolic patterns of vanadium(V) in the oxidized form due to lack of GSH-mediated reduction.

Vanadate treatment restores the expression of genes for key enzymes in the glucose and ketone bodies metabolism in the liver of diabetic rats.

Abstract: Oral administration of vanadate to diabetic streptozotocin-treated rats decreased the high blood glucose and D-3-hydroxybutyrate levels related to diabetes. The increase in the expression of the P-enolpyruvate carboxykinase (PEPCK) gene, the main regulatory enzyme of gluconeogenesis, was counteracted in the liver and the kidney after vanadate administration to diabetic rats. Vanadate also counteracted the induction in tyrosine aminotransferase gene expression due to diabetes and was able to increase the expression of the glucokinase gene to levels even higher than those found in healthy animals. Similarly, an induction in pyruvate kinase mRNA transcripts was observed in diabetic vanadate-treated rats. These effects were correlated with changes on glucokinase and pyruvate kinase activities. Vanadate treatment caused a decrease in the expression of the liver-specific glucose transporter, GLUT-2. Thus, vanadate was able to restore liver glucose utilization and block glucose production in diabetic rats. The increase in the expression of the mitochondrial 3-hydroxy-3-methylglutaryl-CoA synthase (HMGCoAS) gene, the key regulatory enzyme in the ketone bodies production pathway, observed in diabetic rats was also blocked by vanadate. Furthermore, a similar pattern in the expression of PEPCK, GLUT-2, HMGCoAS, and the transcription factor CCAAT/enhancer-binding protein alpha genes has been observed. All of these results suggest that the regulation of the expression of genes involved in the glucose and ketone bodies metabolism could be a key step in the normalization process induced by vanadate administration to diabetic rats.

Phospholipase D activity in phagocytic leucocytes is synergistically regulated by G-protein- and tyrosine kinase-based mechanisms.

Abstract: The regulation of phospholipase D (PLD)-type effector enzymes by G-proteins and protein kinases/phosphatases was characterized in the U937 human promonocytic leucocyte line. PLD activity was assayed by measuring (in the presence of 1% ethanol) the accumulation of phosphatidylethanol in cells permeabilized with beta-escin, a saponin-like detergent. Basal PLD activity was very low when cells were permeabilized and incubated in cytosol-like medium containing micromolar [Ca2+]. When this medium was supplemented with exogenous MgATP or guanosine 5'-[gamma-thio]triphosphate (GTP[S]), PLD activity increased by 9- and 14-fold respectively. Cells permeabilized in the absence of exogenously added MgATP, but in the presence of 1 microM vanadate/100 microM H2O2, also exhibited a modest 12-fold increase in PLD activity. However, the simultaneous presence of either GTP[S] plus exogenous MgATP or GTP[S] plus vanadate/H2O2 (and endogenous MgATP) induced similar 60-75-fold increases in the rate and extent of phosphatidylethanol accumulation. These latter effects of vanadate/H2O2 were strongly correlated with the very rapid accumulation of multiple tyrosine-phosphorylated proteins. Other studies utilized cells which were permeabilized in the presence of GTP[S] and then washed before assay of PLD. These cells retained approximately 60% of the MgATP-regulatable PLD activity (EC50 approximately = to 100 microM MgATP) observed in freshly permeabilized non-washed cells. In the absence of GTP[S] pre-treatment, washed cells retained minimal PLD activity. Genistein, a tyrosine kinase inhibitor, significantly attenuated the ability of MgATP to stimulate PLD activity and accumulation of tyrosine-phosphorylated proteins in the washed GTP[S]-treated cells. These data suggest that PLD activity in myeloid leucocytes involves co-ordinate regulation by both G-protein(s) and tyrosine phosphorylation.

Mechanism of pervanadate stimulation and potentiation of insulin-activated glucose transport in rat adipocytes: dissociation from vanadate effect.

Abstract: Previous studies have shown that the combination of vanadate and H2O2 generates peroxide(s) of vanadate (pervanadate) that is able to mimic insulin in stimulating lipogenesis or protein synthesis and inhibiting lipolysis in rat adipocytes. Here we report that pervanadate is a potent trigger of 3-O-methylglucose transport in rat adipocytes, with an effective concentration of 5 microM and a maximum at 20 microM. Moreover, pervanadate produced an additional activation of approximately 60% on glucose influx in cells treated with maximally activating concentrations of insulin. Vanadate was ineffective in potentiating insulin-stimulated glucose uptake. Quercetin, a bioflavonoid that inhibits insulin receptor tyrosine kinase, blunted this effect of pervanadate. Treatment of adipocytes with pervanadate inhibited protein phosphotyrosyl phosphatase activity of cell extracts in a dose-dependent manner, with an ID50 of 5 microM and complete inhibition at 80 microM. In contrast, vanadate (1-800 microM) did not appreciably inhibit cell phosphotyrosyl phosphatases. The inhibitory effect of pervanadate correlated with the increase in protein phosphotyrosine accumulation, as determined by Western blotting with antiphosphotyrosine antibodies. The most prominent phosphotyrosine-containing band detected in pervanadate-treated adipocytes was that of autophosphorylated insulin receptor, identified by immunoblotting or immunoprecipitation with antiinsulin receptor antibodies. The addition of insulin to pervanadate-treated adipocytes (20 microM) caused a further increase (approximately 70%) in receptor autophosphorylation. In a cell-free system using partially purified insulin receptor devoid of tyrosine phosphatase activity, pervanadate did not stimulate the receptor autophosphorylation or interfere with the stimulating effect of insulin. These results suggest that 1) pervanadate triggers glucose uptake by increasing autophosphorylation of insulin receptor, preventing its dephosphorylation; 2) under physiological conditions, cellular protein phosphotyrosyl phosphatase activity is high, thereby significantly opposing insulin-mediated hexose transport; and 3) pervanadate has the unique ability to markedly increase maximal cell responsiveness in stimulating glucose transport achieved at a saturating insulin concentration. These findings suggest a possible clinical application in the management of glucose uptake in pathological conditions of insulin resistance and hyperinsulinemia.

Preparation of V-Mg-O catalysts: nature of active species precursors

Abstract: A series of V-Mg-O catalysts have been prepared using MgO or magnesium oxalate and aqueous solutions of vanadyl-oxalate or ammonium metavanadate as vanadium sources. After calcination, large differences in the V/Mg surface atomic ratios were observed on the different catalysts, indicating differences in the V-Mg interaction, which are related to the catalysts preparation procedure. In addition, a new preparation procedure of V-Mg-O catalysts which allows an homogeneous dispersion of vanadium along the catalyst is presented. By X-ray diffraction, IR, UV-VIS and X-ray photoelectron spectroscopic characterization of the samples before and after the calcination step, different Mg- and V-compounds have been observed. Before the calcination step, Mg(OH)2 and/or magnesium-ozalate, as well as V5+ and/or V4+ species, depending on vanadium sources and vanadium content, were observed. After the calcination step, the formation of magnesium vanadates depends only on the vanadium content of the catalysts. Mg3V2O8 is formed at low vanadium content of the catalyst and Mg3V2O8+α-Mg2V2O7 at high vanadium content. However, the crystallinity of the magnesium vanadate phases, as well as the distribution of vanadium along the support strongly depends on the preparation procedure.

A Ca2+-ATPase and a Mg2+/H+-antiporter are present on tonoplast membranes from roots of Zea mays L.

Abstract: The primary or secondary energized transport of Ca2+, Mg2+ and H+ into tonoplast membrane vesicles from roots of Zea mays L. seedlings was studied photometrically by using the fluorescent Ca2+ indicator Indo 1 and the pH indicator neutral red. The localization of an ATP-dependent, vanadate-sensitive Ca2+ pump on tonoplast-type vesicles was demonstrated by the co-migration of the Ca2+-pumping and tonoplast H+-pyrophosphatase (PPiase) activity on continuous sucrose density gradients. In ER-membrane fractions, only a low Ca2+-pumping activity could be detected. The ATP-dependent Ca2+ uptake into tonoplast vesicles (using Ca2+ concentrations from 0.8–1 μM) was completely inhibited by the Ca2+ ionophore ionomycin (1 μM) whereas the protonophore nigericin (1 μM) which eliminates ATP-dependent intravesicular H+ accumulation had no effect. Vanadate (IC50 = 43 μM) and diethylstilbesterol (IC50 = 5.2 μM) were potent inhibitors of this type of Ca2+ transport. The nucleotides GTP, UTP, ITP, and ADP gave 27%–50% of the ATP-dependent activity (K m = 0.41 mM). From these results, it was suggested that this ATP-dependent high-affinity Ca2+ transport mechanism is the only functioning Ca2+ transporter of the tonoplast under in-vivo conditions i.e. under the low cytosolic Ca2+ concentration. In contrast, the secondary energized Ca2+-transport mechanism of the tonoplast, the low-affinity Ca2+/H+-antiporter, which was reported to allow the uptake of Ca2+ in exchange for H+, functions chiefly as an Mg2+ transporter under physiological conditions because cytosolic Mg2+ is several orders of magnitude higher than the Ca2+ concentration. This conclusion was deduced from experiments showing that Mg2+ ions in a concentration range of 0.01 to 1 mM triggered a fast efflux of H+ from acid-loaded vesicles. Furthermore, the proton-pumping activity of the tonoplast H+-ATPase and H+-PPiase was found to be influenced by Ca2+ differently from and independently of the Mg2+ concentration. Calcium was a strong inhibitor for the H+-PPiase (IC50 = 18 μM, Hill coefficient nH = 1.7) but a weak one for the H+-ATPase (IC50 = 330 μM, nH = 1). From these results it is suggested that at the tonoplast membrane a functional interaction exists between (i) the Ca2+-and Mg2+-regulated H+-PPiase, (ii) the newly described high-affinity Ca2+-AT-Pase, (iii) the low-affinity Mg2+(Ca2+)/H+-antiporter and (iv) the H2+-ATPase.

Investigation of the Calcium-Transporting ATPases at the Endoplasmic Reticulum and Plasma Membrane of Red Beet (Beta vulgaris)

Abstract: Calcium-transporting ATPases were compared in endoplasmic reticulum (ER)- and plasma membrane-enriched fractions of red beet (Beta vulgaris L.) storage tissue by measuring 45Ca uptake and calcium-dependent phosphoenzyme formation. The plasma membrane fraction was prepared by aqueous two-phase partitioning of a microsomal fraction and collecting the upper phase. The ER-enriched fraction was obtained by submitting a sucrose-gradient ER-enriched fraction to aqueous two-phase partitioning and collecting the lower phase; this reduced contaminating plasma membrane, which partitioned into the upper phase. The ATP-dependent calcium uptake observed in both fractions was released by the calcium ionophore A23187. Calcium uptake showed saturation kinetics for calcium with Km values of 0.92 mmol m-3 for the ER fraction and 1.24 mmol m-3 for the plasma membrane fraction. Uptake into both fractions was inhibited by vanadate and erythrosin B, although the plasma membrane system was slightly more sensitive to both inhibitors. Cyclopiazonic acid and thapsigargin, at low concentrations, had no marked effect on uptake. The plasma membrane system was less substrate-specific for ATP than the ER system, since it was able to use GTP and ITP to drive calcium transport at up to 50% of the level obtained with ATP. Following phosphorylation with [[gamma]-32P]ATP, two high molecular mass, calcium-dependent phosphoproteins (119 and 124 kD) and a low molecular mass, calcium-independent phosphoprotein (17 kD) were observed in the plasma membrane fraction. The ER fraction showed one high molecular mass phosphoprotein (119 kD) in the presence of calcium and two low molecular mass phosphoproteins (17 and 20 kD) that showed no calcium dependence. The low molecular mass phosphoproteins were insensitive to hydroxyl-amine, but they did show turnover. The identity of these proteins is unknown, but they do not have the properties of phosphorylated intermediates of calcium-ATPases. In contrast, the high molecular mass phosphoproteins displayed properties consistent with their representing phosphorylated intermediates of E1E2-type ATPases; they were hydroxylamine-sensitive, showed rapid turnover, and were inhibited by vanadate. Because they showed calcium-dependent phosphorylation and were sensitive to erythrosin B, the 119- and 124-kD phosphoproteins may be phosphorylated intermediates of the ER and plasma membrane calcium ATPases. These phosphoproteins were characterized further with respect to inhibitor sensitivity, responses to ions, and substrate specificity.

A mitogen-responsive promoter region that is synergistically activated through multiple signalling pathways.

Abstract: A regulatory region of the human transferrin receptor gene promoter was found to be required for increased expression in response to serum or growth factors. This region contains two elements that appear to cooperate for full responsiveness. We found that sodium orthovanadate treatment of cells significantly activated expression of promoter constructs containing these elements. 12-O-Tetradecanoylphorbol-13-acetate alone induced a twofold increase in expression but acted synergistically with vanadate to generate a highly elevated level of expression. Dibutyryl cyclic AMP alone had no effect on expression, but when added together with vanadate and 12-O-tetradecanoylphorbol-13-acetate, led to superinduction of the promoter construct. Induction of expression by these reagents was delayed several hours, and the kinetics were identical to those observed for serum induction.

A Plasma Membrane-Type Ca2+-ATPase of 120 Kilodaltons on the Endoplasmic Reticulum from Carrot (Daucus carota) Cells (Properties of the Phosphorylated Intermediate)

Abstract: Cytosolic Ca2+ levels are regulated in part by Ca2+-pumping ATPases that export Ca2+ from the cytoplasm; however, the types and properties of Ca2+ pumps in plants are not well understood. We have characterized the kinetic properties of a 120-kD phosphoenzyme (PE) intermediate formed during the reaction cycle of a Ca2+-ATPase from suspension-cultured carrot (Daucus carota) cells. Only one Ca2+-dependent phosphoprotein was formed when carrot membrane vesicles were incubated with [[gamma]-32P]ATP (W.L. Hsieh, W.S. Pierce, and H. Sze [1991] Plant Physiol 97: 1535-1544). Formation of this 120-kD phosphoprotein was inhibited by vanadate, enhanced by La3+, and decreased by hydroxylamine, confirming its identification as an intermediate of a phosphorylated-type Ca2+-translocating ATPase. The 120-kD Ca2+-ATPase was most abundant in endoplasmic reticulum-enriched fractions, in which the Ca2+-ATPase was estimated to be 0.1% of membrane protein. Direct quantitation of Ca2+-dependent phosphoprotein was used to examine the kinetics of PE formation. PE formation exhibited a Km for Ca2+ of 1 to 2 [mu]M and a Km for ATP of 67 nM. Relative affinities of substrates, determined by competition experiments, were 0.075 [mu]M for ATP, 1 [mu]M for ADP, 100 [mu]M for ITP, and 250 [mu]M for GTP. Thapsigargin and cyclopiazonic acid, specific inhibitors of animal sarcoplasmic/endoplasmic reticulum Ca2+-ATPase, had no effect on PE formation; erythrosin B inhibited with 50% inhibition at <0.1 [mu]M. Calmodulin (1 [mu]M) stimulated PE formation by 25%. The results indicate that the carrot 120-kD Ca2+-ATPase is similar but not identical to animal plasma membrane-type Ca2+- ATPase and yet is located on endomembranes, such as the endoplasmic reticulum. This type of Ca2+ pump may reside on the cortical endoplasmic reticulum, which is thought to play a major role in anchoring the cytoskeleton and in facilitating secretion.