In vivo electrical stimulation alters sensitivity of the brain (Na+ + K+)ATPase toward inhibition by vanadate

It has recently been shown that electrical stimulation of the brain cortex in vivo blocks invasion of cortical spreading depression (SD) into the stimulated area. The effect has been interpreted as a result of activating a K+ pumping mechanism that prevents the accumulation of this ion in the extracellular space to the high levels required for SD propagation. In the present experiments (Na+ + K+)ATPase activity was determined in the electrically stimulated region of the rat brain cortex. When ATP preparations containing vanadate were used as substrate, elevation of K concentration in the assay medium from 2 to 20 mM inhibited enzyme activity in homogenates from the normal cortex but not that from homogenates of the electrically stimulated cortical region. With vanadate-free ATP (Boehringer) as a substrate, slight stimulation by 20 mM K+ has been observed in both cases. Vanadate (0.25 microM) added to the assay medium containing Boehringer ATP and 20 mM K+ inhibited ATPase activity from the normal cortex but not that from the stimulated cortical area. Electrical stimulation may activate (Na+ + K+)ATPase at least partly by diminution of its susceptibility toward the inhibitory action of vanadate.     

Vanadate stimulation of IGF binding to rat adipocytes

Preincubation of adipocytes with insulin (10 ng/ml) stimulated binding of IGF-II to maximal levels of 160% above controls. Vanadate also augmented IGF-II binding with an increase of 126% above controls at a concentration of 1 mM. Coincubation of vanadate (1 mM) with a maximal stimulatory dose of insulin (10 ng/ml) produced no additive effect. However, at submaximal doses of insulin (0.1 ng/ml) the effect of vanadate was additive. Amiloride, a potent inhibitor of the insulin receptor kinase, inhibited the effects of both vanadate and insulin. The data are consistent with an effect of vanadate via a similar sequence of steps to that of insulin; perhaps involving activation of the insulin receptor kinase.     

Ecto-phosphatase activities on the cell surface of the amastigote forms of Trypanosoma cruzi

Live Trypanosoma cruzi amastigotes hydrolyzed p-nitrophenylphosphate (PNPP), phospho-amino-acids and 32P-casein under physiologically appropriate conditions. PNPP was hydrolysed at a rate of 80 nmol.mg-1.h-1 in the presence of 5 mM MgCl2, pH 7.2 at 30 degrees C. In the absence of Mg2+ the activity was reduced 40% and we call this basal activity. At saturating concentration of PNPP, half-maximal PNPP hydrolysis was obtained with 0.22 mM MgCl2. Ca2+ had no effect on the basal activity, could not substitute Mg2+ as an activator and in contrast inhibited the PNPP hydrolysis stimulated by Mg2+ (I50 = 0.43 mM). In the absence of Mg2+ (basal activity) the stimulating half concentration (S0.5) for PNPP was 1.57 mM, while at saturating MgCl2 concentrations the corresponding S0.5 for PNPP for Mg(2+)-stimulated phosphatase activity (difference between total minus basal phosphatase activity) was 0.99 mM. The Mg-dependent PNPP hydrolysis was strongly inhibited by sodium fluoride (NaF), vanadate and Zn2+ but not by tartrate and levamizole. The Mg-independent basal phosphatase activity was insensitive to tartrate, levamizole as well NaF and less inhibited by vanadate and Zn2+. Intact amastigotes were also able to hydrolyse phosphoserine, phosphothreonine and phosphotyrosine but only the phosphotyrosine hydrolysis was stimulated by MgCl2 and inhibited by CaCl2 and phosphotyrosine was a competitive inhibitor of the PNPP hydrolysis stimulated by Mg2+. The cells were also able to hydrolyse 32P-casein phosphorylated on serine and threonine residues but only in the presence of MgCl2. These results indicate that in the amastigote form of T. cruzi there are at least two ectophosphatase activities, one of which is Mg2+ dependent and can dephosphorylate phospho-amino acids and phosphoproteins under physiological conditions.     

Cell-free stimulation of the insulin-sensitive cAMP phosphodiesterase by the joint actions of ATP and the soluble fraction from insulin-treated rat liver

The insulin-sensitive cAMP phosphodiesterase (PDE) from rat adipocytes was stimulated 60-70% upon incubation with 2 mM ATP and the soluble fraction (Fraction S-1) from insulin-treated rat liver. The effect of ATP was partially mimicked by ATP-gamma-S or GTP, but not by AMP-PNP. The PDE-stimulating activity in Fraction S-1 was preserved in the presence of 50 mM sodium phenyl phosphate, 50 mM sodium fluoride, and 0.1 mM sodium vanadate. The PDE-stimulating activity was not inhibited with either 0.5 mM H-7 or 5 microM PKI-(5-24)-peptide, but was blocked with 1 mM Kemptide. The active component in Fraction S-1 may be a phosphorylated compound, which, in the presence of ATP, may mediate the hormonal action on PDE.     

Insulin-like effects of vanadate on glucose uptake and on maturation in Xenopus laevis oocytes.

Vanadate, an inhibitor of phosphotyrosyl phosphatases that exerts insulin-like effects in intact cells, stimulated both maturation and glucose uptake in isolated Xenopus laevis oocytes. Vanadate enhanced the effects of insulin/IGF-I and progesterone on maturation in a dose-dependent manner, with an effective concentration of 750 microM and a maximum at 2 mM, whereas, in the absence of hormone, activation of maturation was seen at 10 mM vanadate. Further, vanadate at 2 mM increased glucose uptake, but this effect was not additive to that of the hormone. In cell-free systems, vanadate caused a 12-fold stimulation of autophosphorylation of the oocyte IGF-I receptor in the absence, but not in the presence, of IGF-I and inhibited largely, but not totally, receptor dephosphorylation induced by an extract of oocytes rich in phosphotyrosyl phosphatase activities. These effects were dose dependent, with effective concentrations of 50-100 microM and maxima at 2 mM. Moreover, using an acellular assay to study the effect of vanadate on the activation of maturation promoting factor (MPF), we found that vanadate at 2 mM stimulated the activation of the MPF H1 kinase. This suggests that vanadate did not prevent dephosphorylation of p34cdc2 on tyrosine residues. Vanadate thus exerted insulin-like effects in oocytes, including stimulation of maturation. These effects might result from a direct or indirect action of vanadate on the IGF-I receptor kinase and on MPF activity.     

Vanadate stimulates D-glucose transport into sarcolemmal vesicles from rat skeletal muscles.

Vanadate is known to have various insulin-like actions including activation of D-glucose uptake into the skeletal muscle and adipose tissue. In this study, we examined the effect of orthovanadate on D-glucose uptake into sarcolemmal vesicles prepared from rat hind limb skeletal muscles. In the presence of 10 mM vanadate, the initial rate of D-glucose uptake into sarcolemmal vesicles was enhanced 4-5 times above the basal value. Half-maximal concentration for this effect of vanadate was 3 mM. The D-glucose uptake was also stimulated by metavanadate, but not by selenite, selenate, or molybdate. When vanadate was removed from the vesicles by dilution and centrifugation, D-glucose uptake into the vesicles returned to the basal level, indicating that the effect of vanadate was reversible. Saturation curves showed that the Vmax value for the D-glucose uptake was enhanced more than 4-fold by 10 mM vanadate. Therefore, the activation of D-glucose uptake was due, at least in part, to a large increase in the Vmax value. These results suggest that vanadate increases the intrinsic activity (turnover number) of skeletal muscle glucose transporters in a reversible manner.     

Metabolism of added orthovanadate to vanadyl and high-molecular-weight vanadates by Saccharomyces cerevisiae

The effect of vanadium oxides on living systems may involve the in vivo conversion of vanadate and vanadyl ions. The addition of 5 mM orthovanadate (VO4(3-), V(V)), a known inhibitor of the (Na,K)-ATPase, to yeast cells stopped growth. In contrast, the addition of 5 mM vanadyl (VO2+, V(IV) stimulated growth. Orthovanadate addition to whole cells is known to stimulate various cellular processes. In yeast, both ions inhibited the plasma membrane Mg2+ ATPase and were transported into the cell as demonstrated with [48V]VO4(3-) and VO2+. ESR spectroscopy has been used to measure the cell-associated paramagnetic vandyl ion, while 51V NMR has detected cell-associated diamagnetic vanadium (e.g. V(V)). Cells were exposed to both toxic (5 mM) and nontoxic (1 mM) concentrations of vanadate in the culture medium. ESR showed that under both conditions, vanadate became cell associated and was converted to vanadyl which then accumulated in the cell culture medium. 51V NMR studies showed the accumulation of new cell-associated vanadium resonances identified as dimeric vanadate and decavanadate in cells exposed to toxic amounts of medium vanadate (5 mM). These vanadate compounds did not accumulate in cells exposed to 1 mM vanadate. These studies confirm that the inhibitory form of vanadium usually observed in in vitro experiments is vanadate, in one or more of its hydrated forms. These data also support the hypothesis that the stimulatory form of vanadium usually observed in whole cell experiments is the vanadyl ion or one or more of its liganded derivatives.     

Vanadate activates pentose phosphate pathway and glycolysis, and raises fructose 2,6-bisphosphate concentration in slices of lactating rat mammary gland.

In mammary gland slices from lactating rats, vanadate increased the rate of glucose oxidation via the pentose phosphate pathway by 36% and raised the glucose flux via glycolysis by 47%. Furthermore, vanadate increased the fructose 2,6-bisphosphate (Fru-2,6-P2) level by 33%. The effect of vanadate on glucose oxidation was compared to the effect of insulin. The present data indicate that 0.5mM vanadate has an effect on glucose utilization similar to that of insulin but does not reach the same level.     

An ATP-driven proton pump in clathrin-coated vesicles

Clathrin containing coated vesicles prepared from bovine brain catalyzed ATP-driven proton translocation and a 32Pi-ATP exchange reaction. Both activities were measured in the presence of 5 micrograms of oligomycin/mg of protein which completely inhibited these reactions catalyzed by submitochondrial particles. Analyses performed during the purification procedure demonstrated that the oligomycin-resistant pump was concentrated and highly purified in the fractions containing coated vesicles. Moreover, vesicles precipitated by either monoclonal or polyclonal antibodies against clathrin contained the H+ pump activity. Dicyclohexylcarbodiimide (0.5 mM) and N-ethylmaleimide (1 mM) added to the assay mixture inhibited the pump completely, whereas neither vanadate, sodium azide, efrapeptin, or mitochondrial ATPase inhibitor had an effect.     

Melatonin inhibits the contractile effect of vanadate in the isolated pulmonary arterial rings of rats: possible role of hydrogen peroxide

The effect and possible mechanism of action of vanadate on the isolated pulmonary arterial rings of normal rats were studied. Pulmonary arterial rings contracted in response to vanadate (0.1-1 mM) in a concentration-dependent manner. Preincubation of the pulmonary arterial rings with 1 mM melatonin significantly reduced the contractile effect of vanadate by more than 60%. Furthermore, addition of hydrogen peroxide (50 microM) or enzymatic generation of hydrogen peroxide by the addition of glucose oxidase (10 U/mL) to the medium containing glucose produced remarkable increases in the pulmonary arterial tension, 46.2 +/- 7.3 and 78.7 +/- 9.7 g tension/g tissue, respectively. Similarly, incubation of the pulmonary arterial rings with 1 mM melatonin significantly reduced the contractile responses of the arterial rings to hydrogen peroxide and glucose/glucose oxidase to 25.7 +/- 2.9 and 24.7 +/- 4.4 g tension/g tissue, respectively. Vanadate, in vitro, significantly stimulated the oxidation of NADH by xanthine oxidase, and the rate of oxidation was increased by increasing either time or vanadate concentration. Similarly, addition of melatonin to a reaction mixture containing xanthine oxidase and vanadate significantly inhibited the rate of NADH oxidation in a concentration-dependent fashion. The results of the present study indicated that vanadate induced contraction in the isolated pulmonary arterial rings, which was significantly reduced by melatonin. Furthermore, the contractile effect of vanadate on the pulmonary arterial rings may be attributed to the intracellular generation of hydrogen peroxide.     

Inhibition by vanadate of cyclic AMP production in rat corpora lutea incubated in vitro

Vanadate, a normal constituent of cells, has been reported to affect a variety of enzymes involved in phosphate transfer; the findings regarding adenylate cycle vary with the tissue and experimental system. In the corpus luteum, cyclic AMP (cAMP) stimulates steroidogenesis; and prostaglandin F2 alpha, which induces luteal regression, inhibits luteinizing hormone (LH)-induced cAMP accumulation. We examined the influence of orthovanadate on cAMP concentration in isolated corpora lutea from pseudopregnant rats. With 2 mM vanadate, basal cAMP level was unaffected, but LH-induced cAMP accumulation was inhibited by 45-68%. Lower doses of vanadate (0.2-1 mM) were almost as effective. When added simultaneously with LH, vanadate was inhibitory within 25 min, but no inhibition occurred when vanadate was added for 30 min to tissue pretreated with LH for 60 min. The decrease in cAMP accumulation was observed also when corpora lutea were exposed to vanadate in the presence of the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (0.5 mM), indicating that vanadate inhibits cAMP synthesis. Vanadate may increase cytosolic calcium by inhibiting ion pumps in cell membranes. Thus, we examined the effect of vanadate in corpora lutea incubated in calcium-depleted medium and found that vanadate still inhibited cAMP formation. Vanadyl sulfate (0.4 and 2 mM) reduced the LH-induced cAMP accumulation as effectively as vanadate. Thus, the use of vanadate as a tool for exploring physiological regulators of luteal adenylate cyclase should be considered.     

Comparison of inositol phosphates accumulation induced by different effectors in rat thyroid slices.

Rat thyroid slices were submitted to different effectors and hormones in order to investigate their action on the phosphatidylinositol metabolism. Fluoride and vanadate induced a clear increase of the inositol phosphates with half maximal stimulation at 7 mM and 8 mM respectively. The inositol bisphosphate (IP2) and inositol trisphosphate (IP3) accumulation induced by vanadate was relatively higher than that observed in the case of fluoride stimulation. Carbachol stimulated also the generation of inositol phosphates with half maximal activation at 2.5 x 10(-6) M. In the same conditions, no significant effect on inositol phosphates production could be detected by the action of TSH or TRH.     

Rapid Sequestration and Degradation of Somatostatin Analogues by Isolated Brain Microvessels

Somatostatin (SRIF) is a putative peptide neurotransmitter that may interact with brain capillaries following neurosecretion of the peptide. The present studies investigate the binding and metabolism of SRIF analogues in isolated bovine brain microvessels. 125I-[Tyr1]SRIF was rapidly degraded by capillary aminopeptidase with a half-time of approximately 3 min at 23 degrees C. The microvessel aminopeptidase had a low affinity and high capacity for the peptide, Km = 76 microM and Vmax = 74 nmol min-1 mgp-1. 125I-[Tyr11]SRIF was converted to free iodotyrosine at a much slower rate, presumably by a lower-activity endopeptidase. 125I-[Try11]SRIF was rapidly bound by microvessels, whereas another basic peptide, [Tyr8]bradykinin, or an acidic peptide, CCK8, or a neutral peptide, leucine enkephalin, were bound to a considerably less extent. The binding of 125I-[Tyr11]SRIF to the capillaries was nonsaturable up to a concentration of 1 microgram/ml of unlabeled peptide, and the binding reaction was extremely rapid, reaching equilibrium within 5 s at either 0 degrees C or 37 degrees C. Approximately 20% of the SRIF bound by the microvessels was resistant to acid wash and presumably represented internalized peptide. In addition, the 125I-[Tyr11]SRIF bound rapidly to the endothelial cytoskeleton remaining after a 1% Triton X-100 extraction of the microvessels. The peptide-cytoskeletal binding reaction was nonsaturable up to 1 microgram/ml of unlabeled [Tyr11]SRIF, but it was inhibited by 0.5% polylysine or 0.8 M KCl and was stimulated by 1 mM dithiothreiotol. These studies suggest that brain microvessels rapidly sequester and degrade SRIF analogues and that this may represent one mechanism for rapid inactivation of the neuropeptides subsequent to neurosecretion.     

Evidence for a regulatory action of vanadate on protein phosphorylation in brain microvessels

We investigated the action of vanadate on protein phosphorylation in microvessels isolated from rat brain. We found that a stimulation of protein phosphorylation from 32P-ATP occurs, in the presence of different concentrations of vanadate, 10(-3) M being the most effective dose. This action was time-dependent, and it was more evident after 60 s of treatment. The contribution of ATPase inhibition caused by vanadate appears to be negligible. In addition a stimulation of cAMP-dependent protein kinase activity was observed. The pattern of protein phosphorylation showed that exposure to 10(-3) M vanadate resulted in a nonspecific stimulation of protein phosphorylation concomitantly with a selective inhibition of the 55 KDa protein phosphorylation. The nature of this protein is also discussed.     

Vanadate stimulation of insulin release in normal mouse islets.

The effects of vanadate (Na3VO4) on pancreatic B-cell function were studied in normal mouse islets. Vanadate did not affect basal insulin release but potentiated the effect of 7-30 mM glucose at concentrations of 0.1-1 mM. This effect was progressive and slowly reversible. It was abolished by omission of extracellular Ca2+ but unaffected by blockers of adrenergic or muscarinic receptors. Comparison of the changes in membrane potential, 86Rb efflux and 45Ca efflux that vanadate and ouabain produced in B-cells made it possible to exclude the hypothesis that vanadate increases insulin release by blocking the sodium pump. Vanadate was also without effect on cAMP levels. On the other hand, it markedly changed the characteristics of the Ca(2+)-dependent electrical activity and of the oscillations of cytoplasmic Ca2+ recorded in B-cells stimulated by 15 mM glucose. In the steady state, Ca2+ influx was increased by vanadate, and this resulted in a rise in cytoplasmic Ca2+. The exact mechanisms underlying these changes could not be established but a blockade of K channels was excluded. In the presence of LiCl, vanadate markedly increased inositol phosphate levels in islet cells. This effect was attenuated but not suppressed by omission of Ca2+. A small increase in inositol bisphosphate was still produced by vanadate in the absence of LiCl. These results suggest that vanadate both stimulates phosphoinositide breakdown and inhibits inositol phosphate degradation. In conclusion, vanadate does not induce insulin release, but markedly potentiates the stimulation by glucose. This property is not due to an inhibition of the sodium pump or to a rise in cAMP concentration. It results from a complex interplay between changes in B-cell membrane potential, phosphoinositide metabolism and Ca2+ handling.     

Vanadate-induced inhibition of renin secretion is unrelated to inhibition Na,K-ATPase activity

There is evidence that three inhibitors of Na,K-ATPase activity--ouabain, K-free extracellular fluid, and vanadate--inhibit renin secretion by increasing Ca2+ concentration in juxtaglomerular cells, but in the case of vanadate, it is uncertain whether the increase in Ca2+ is due to a decrease in Ca2+ efflux (inhibition of Ca-ATPase activity, or inhibition of Na,K-ATPase activity, followed by an increase in intracellular Na+ and a decrease in Na-Ca exchange) or to an increase in Ca2+ influx through potential operated Ca channels (inhibition of electrogenic Na,K transport, followed by membrane depolarization and activation of Ca channels). In the present experiments, the rat renal cortical slice preparation was used to compare and contrast the effects of ouabain, of K-free fluid, and of vanadate on renin secretion, in the absence and presence of methoxyverapamil, a Ca channel blocker. Basal renin secretory rate averaged 7.7 +/- 0.3 GU/g/60 min, and secretory rate was reduced to nearly zero by 1 mM ouabain, by K-free fluid, by 0.5 mM vanadate, and by K-depolarization (increasing extracellular K+ to 60 mM). Although 0.5 microM methoxyverapamil completely blocked the inhibitory effect of K-depolarization, it failed to antagonize the inhibitory effects of ouabain, of K-free fluid, and of vanadate. A concentration of methoxyverapamil two hundred times higher (100 microM) completely blocked the inhibitory effects of vanadate, but still failed to antagonize the effects of ouabain and of K-free fluid. Collectively, these observations demonstrate that vanadate-induced inhibition of renin secretion cannot be attributed entirely to Na,K-ATPase inhibition, since in the presence of methoxyverapamil, the effect of vanadate differed from the effects of either ouabain (a specific Na,K-ATPase inhibitor) or K-free fluid. Moreover, it cannot be attributed entirely to a depolarization-induced influx of Ca2+ through potential-operated Ca channels, since methoxyverapamil antagonized K-depolarization-induced inhibition of renin secretion much more effectively than it antagonized vanadate-induced inhibition.     

Vanadate affects nuclear division and induces aberrantly-shaped cells during subsequent cytokinesis in Tetrahymena

Sodium orthovanadate at 0.1-5.0 mM affected cell proliferation of Tetrahymena in a dose-dependent manner. At 1 h the cell increment was 76-12% of the control (100%), but after lag periods in 1-5 mM the growth rate remained at 76% of control in 0.1 mM vanadate and at 64-61% of control in 0.2-5.0 mM vanadate. Endocytosis was affected in both a time- and dose-dependent manner; an increasing number of cells did not form vacuoles. Cell motility increased initially in 0.1 mM vanadate but decreased later as it did in 0.5-2.0 mM vanadate where the proportion of immobile cells increased with time. Cell divisions occurred at all concentrations but macronuclear elongation was disturbed and subsequent cytokinesis resulted in daughter cells containing the entire G2 macronucleus, a large or small portion of it, or no nucleus at all. Moreover, odd cell shapes appeared with time. The size of the cell and nucleus increased but there was great variation with disturbed cytoplasm/nucleus ratios. Treated cells had dilated rough endoplasmic reticulum that included dense material, presumed to be vanadate, which was not seen in control cells. Scant amounts of dense material were found in dense granules, small vacuoles, and abundantly in contractile vacuoles. It is argued that interference with proper microtubular function is the main effect of vanadate.     

Effect of ammonia on amino acid uptake by brain microvessels

NH+4 ions, at a concentration (0.25 mM) similar to that found in the plasma of patients with hepatic encephalopathy, cause, in vitro, a significant stimulation of the uptake by brain microvessels of large neutral amino acids, without any effect on the uptake of alpha-methylaminoisobutyric acid, glutamic acid, or lysine. Such a stimulation occurs essentially through an increase of the maximal transport capacity (Vmax) of the saturable component. It is apparently mediated by the intracellular formation of glutamine, which is then exchanged, through the L-system of transport, for large neutral amino acids such as leucine, phenylalanine, or tyrosine. At higher concentrations (greater than or equal to 0.5 mM), NH+4 ions cause also a decrease of carrier affinity for neutral amino acids, which counteracts the stimulatory effect on their uptake.     

Vanadate binding to the (Na + K)-ATPase

A particulate (Na + K)-ATPase preparation from dog kidney bound [⁴⁸V]-ortho-vanadate rapidly at 37°C through a divalent cation-dependent process. In the presence of 3 mM MgCl₂ theK _d was 96 nM; substituting MnCl₂ decreased theK _d to 12 nM but the maximal binding remained the same, 2.8 nmol per mg protein, consistent with 1 mol vanadate per functional enzyme complex. Adding KCl in the presence of MgCl₂ increased binding, with aK _0.5 for KCl near 0.5 mM; the increased binding was associated with a drop inK _d for vanadate to 11 nM but with no change in maximal binding. Adding NaCl in the presence of MgCl₂ decreased binding markedly, with anI ₅₀ for NaCl of 7 mM. However, in the presence of MnCl₂ neither KCl nor NaCl affected vanadate binding appreciably. Both the nonhydrolyzable, ,-imido analog of ATP and nitrophenyl phosphate, a substrate for the K-phosphatase reaction that this enzyme also catalyzes, decreased vanadate binding at concentrations consistent with their acting at the low-affinity substrate site of the enzyme; the presence of KCl increased the concentration of each required to decrease vanadate binding. Oligomycin decreased vanadate binding in the presence of MgCl₂, whereas dimethyl sulfoxide and ouabain increased it. With inside-out membrane vesicles from red blood cells vanadate inhibited both the K-phosphatase and (Na + K)-ATPase reactions; however, with the K-phosphatase reaction extravesicular K⁺ (corresponding to intracellular K⁺) both stimulated catalysis and augmented vanadate inhibition, whereas with the (Na + K)-ATPase reaction intravesicular K⁺ (corresponding to extracellular K⁺) both stimulated catalysis and augmented vanadate binding.