Showing papers on "Vanadate published in 1987"

Effect of length and cross-bridge attachment on Ca2+ binding to cardiac troponin C

Abstract: The sensitivity of skinned cardiac muscle bundles to Ca2+ is a function of sarcomere length. Ca2+ sensitivity is increased as fiber length is extended along the ascending limb of the force-length curve and it has been suggested that this phenomenon makes a major contribution to the steep force-length relationship that exists in living cardiac muscle. To gain greater insight into the mechanism behind the length dependence of Ca2+ sensitivity isotopic measurements of Ca2+ binding to detergent-extracted bovine, ventricular muscle bundles were made under conditions in which troponin C was the only major Ca2+ binding species. Experiments were designed to determine whether 1) Ca2+-troponin C affinity varies in the sarcomere length range corresponding to the ascending limb of the force-length curve, and 2) Ca2+ binding correlates with length per se or with changes in the number of length-dependent cross-bridge attachments. Measurements were made of Ca2+ binding in the rigor and relaxed states. The latter state was produced by suppressing actin-myosin interaction with the phosphate analogue, sodium vanadate. After vanadate treatment it is possible to obtain a complete Ca2+ saturation curve in the presence of physiological MgATP concentrations and at constant sarcomere length. The results show that the binding of Ca2+ to the regulatory site of cardiac troponin C is length dependent but this length dependence is actually a dependence on the number of attached cross bridges.

Characterization of the Na+‐stimulated ATPase of Propionigenium modestum as an enzyme of the F1F0 type

Abstract: The ATP-hydrolyzing activity of Propionigenium modestum was extracted from the membranes with Triton X-100 or by incubation with EDTA at low ionic strength. The ATPase in the Triton extract was highly sensitive to dicyclohexylcarbodiimide but not to vanadate. These properties are characteristic for enzymes of the F1F0 type. The ATPase was specifically activated by Na+ ions yielding a 15-fold increase in catalytic activity at 5 mM Na+ concentration. The additional presence of 1% Triton X-100 caused a further 1.5–fold activation. In the absence of Na+ Triton stimulated the ATPase about 13-fold. The Triton-stimulated ATPase was further activated about 1.5–2-fold by Na+ addition. The ATPase extracted by the low-ionic-strength treatment was purified to homogeneity by fractionation with poly(ethylene glycol) and gel chromatography. The enzyme had the characteristic F1-ATPase subunit structure with Mr values of 58000 (α), 56000 (β), 37600 (γ), 22700 (δ), and 14000 (ɛ). The F1-ATPase was not stimulated by Na+ ions. The membrane-bound ATPase was reconstituted from the purified F1 part and F1-depleted membranes, thus further indicating an F1F0 structure for the ATPase of P. modestum. Upon reconstitution the ATPase recovered its stimulation by Na+ ions, suggesting that the binding site for Na+ is localized on the membrane-bound F0 part of the enzyme complex.

The Ca2+-Transport ATPase of Plant Plasma Membrane Catalyzes a nH+/Ca2+ Exchange

Abstract: Microsomal vesicles from 24-hour-old radish (Raphanus sativus L.) seedlings accumulate Ca(2+) upon addition of MgATP. MgATP-dependent Ca(2+) uptake co-migrates with the plasma membrane H(+)-ATPase on a sucrose gradient. Ca(2+) uptake is insensitive to oligomycin, inhibited by vanadate (IC(50) 40 micromolar) and erythrosin B (IC(50) 0.2 micromolar) and displays a pH optimum between pH 6.6 and 6.9. MgATP-dependent Ca(2+) uptake is insensitive to protonophores. These results indicate that Ca(2+) transport in these microsomal vesicles is catalyzed by a Mg(2+)-dependent ATPase localized on the plasma membrane. Ca(2+) strongly reduces DeltapH generation by the plasma membrane H(+)-ATPase and increases MgATP-dependent membrane potential difference (Deltapsi) generation. These effects of Ca(2+) on DeltapH and Deltapsi generation are drastically reduced by micromolar erythrosin B, indicating that they are primarily a consequence of Ca(2+) uptake into plasma membrane vesicles. The Ca(2+)-induced increase of Deltapsi is collapsed by permeant anions, which do not affect Ca(2+)-induced decrease of DeltapH generation by the plasma membrane H(+)-ATPase. The rate of decay of MgATP-dependent DeltapH, upon inhibition of the plasma membrane H(+)-ATPase, is accelerated by MgATP-dependent Ca(2+) uptake, indicating that the decrease of DeltapH generation induced by Ca(2+) reflects the efflux of H(+) coupled to Ca(2+) uptake into plasma membrane vesicles. It is therefore proposed that Ca(2+) transport at the plasma membrane is mediated by a Mg(2+)-dependent ATPase which catalyzes a nH(+)/Ca(2+) exchange.

The search for a hypothalamic Na+,K+-ATPase inhibitor.

Abstract: Accumulating experimental evidence suggests that natriuresis in response to intravascular volume expansion is promoted by an endogenous regulator of Na+,K+-adenosine triphosphatase (ATPase). Efforts to purify this substance by a number of laboratories have as yet been unsuccessful. The properties of partially purified inhibitors from plasma, urine, and tissue often fail to possess the characteristics thought to be consistent with those of a physiological regulator. These include potency (Ki of approximately 1 nM), reversibility of inhibition, specificity for Na+,K+-ATPase, and responsiveness to relevant physiological stimuli. Two rather different candidate substances, extracted from urine and hypothalamus, have been purified to a high degree. Neither is a peptide, and both are of low molecular weight and resistant to acid hydrolysis. The substance from urine is rather nonpolar and interacts with digoxin-specific antibodies, while that from hypothalamus is polar and does not appear to share epitopes with the cardiac glycosides. On the serosal surface of the toad urinary bladder, the hypothalamic substance causes a reversible inhibition of Na+ transport, inhibits rubidium uptake in red blood cells by acting on the membrane's exterior surface, inhibits binding of ouabain to purified Na+,K+-ATPase, and reversibly inhibits hydrolysis of adenosine 5'-triphosphate by the enzyme with a Ki of 1.4 nM. The hypothalamic inhibitor may be differentiated from ouabain by their respective ionic requirements for optimal inhibition of enzymatic activity, and although both ouabain and the hypothalamic inhibitor fix Na+,K+-ATPase in its E2 conformation, the hypothalamic inhibitor does not promote phosphorylation of the enzyme by inorganic phosphate in the presence of Mg2+. Ionic requirements for inhibition also differentiate the hypothalamic inhibitor from vanadate ion, as does the inhibitor's activity in the presence of norepinephrine. Further enzymological and physiological studies will be facilitated by structural characterizations of the inhibitory substances and by the availability of a method to measure their concentrations in physiological fluids.

Latency of Plasma Membrane H-ATPase in Vesicles Isolated by Aqueous Phase Partitioning : Increased substrate Accessibility or Enzyme Activation.

Abstract: The properties of the plasma membrane H + -ATPase and the cause of its latency have been studied using a highly purified plasma membrane fraction from oat ( Avena sativa L., cv Victory) roots, prepared by aqueous two-phase partitioning. The ATPase has a maximum specific activity (at 37°C) in excess of 4 micromoles inorganic phosphate per milligram protein per minute in the presence of nondenaturing surfactants. It is inhibited by more than 90% by vanadate, is specific for ATP, has a pH optimum of 6.5, and is stimulated more than 4-fold by 50 millimolar K + in the presence of low levels of the nondenaturing surfactants Triton X-100 and lysolecithin. This `latent9 activity is usually explained as being a result of the inability of ATP to reach the ATPase in right-side out, sealed vesicles, until they are disrupted by surfactants. Consistent with this idea, trypsin digestion significantly inhibited the ATPase only in the presence of the surfactants. Electron spin resonance spectroscopy volume measurements confirmed that surfactant-free vesicles were mostly sealed to molecules similar to ATP. However, the Triton to protein ratio required to disrupt vesicle integrity completely is 10-fold less than that needed to promote maximum ATPase activity. We propose that plasma membrane ATPase activation is due not solely to vesicle disruption and accessibility of ATP to the ATPase but to the surfactants activating the ATPase by altering the lipid environment in its vicinity or by removing an inhibitory subunit.

The E1→E2 transition of Ca2+-transporting ATPase in sarcoplasmic reticulum occurs without major changes in secondary structure: a circular-dichroism study

Abstract: C.d. spectroscopy was used to investigate the structures of Ca2+-ATPase (Ca2+-transporting ATPase) in the E1 and E2 states in native, in fluorescein isothiocyanate (FITC)-labelled and in solubilized sarcoplasmic reticulum (SR) preparations. The E1 state was stabilized by 100 microM-Ca2+ and the E2 state by 0.5 mM-Na3 VO4 and 0.1 mM-EGTA. There were no significant differences detected in the c.d. spectra and the calculated secondary structures between the E1 and E2 states in any of the three types of preparations. The FITC-labelled SR did show the characteristic changes in FITC fluorescence on addition of Ca2+ or vanadate, indicating that the preparation was competent for E1----E2 transitions. Therefore the absence of changes in the c.d. spectra implies that the E1----E2 transition in the Ca2+-ATPase does not involve a major net rearrangement of the polypeptide backbone conformation.