Inhibition and labeling of the Ca2(+)-ATPase from sarcoplasmic reticulum by periodate oxidized ATP

Oxidized ATP protection against anthrax lethal toxin

Bacillus anthracis lethal toxin (LT) induces rapid lysis (<90 min) of murine macrophages from certain inbred strains. The mechanism for LT-induced cytolysis is currently unknown. We hypothesized that the ATP-activated macrophage P2X7 receptors implicated in nucleotide-mediated macrophage lysis could play a role in LT-mediated cytolysis and discovered that a potent P2X7 antagonist, oxidized ATP (o-ATP), protects macrophages against LT. Other P2X7 receptor antagonists, however, had no effect on LT function, while oxidized nucleotides, o-ADP, o-GTP, and o-ITP, which did not act as receptor ligands, provided protection. Cleavage of the LT substrates, the mitogen-activated protein kinases, was inhibited by o-ATP in RAW274.6 macrophages and CHO cells. We investigated the various steps in the intoxication pathway and found that binding of the protective-antigen (PA) component of LT to cells and the enzymatic proteolytic ability of the lethal factor (LF) component of LT were unaffected by o-ATP. Instead, the drug inhibited formation of the sodium dodecyl sulfate-resistant PA oligomer, which occurs in acidified endosomes, but did not prevent cell surface PA oligomerization, as evidenced by binding and translocation of LF to a protease-resistant intracellular location. We found that o-ATP also protected cells from anthrax edema toxin and diphtheria toxin, which also require an acidic environment for escape from endosomes. Confocal microscopy using pH-sensitive fluorescent dyes showed that o-ATP increased endosomal pH. Finally, BALB/cJ mice injected with o-ATP and LT were completely protected against lethality.

Oxidized ATP (oATP) attenuates proinflammatory signaling via P2 receptor-independent mechanisms

Periodate-oxidized ATP (oATP), which covalently modifies nucleotide-binding proteins, can significantly attenuate proinflammatory signaling. Although the P2X7 nucleotide receptor (P2X7R) is irreversibly antagonized by oATP, it is unclear whether anti-inflammatory actions of oATP are predominantly mediated via its actions on P2X7R. Here, we describe inhibitory effects of oATP on proinflammatory responses in three human cell types that lack expression of P2X7R: human umbilical vein endothelial cells (HUVEC), HEK293 cells, and 1321N1 astrocytes. oATP decreased by 40-70% the secretion of interleukin (IL)-8 stimulated by tumor necrosis factor-alpha (TNF-alpha) in all three cell types, by IL-1beta in HUVEC and 1321N1 cells, and by endotoxin in HUVEC. Attenuation of TNF-alpha-stimulated IL-8 secretion by oATP was similar in wild-type HEK cells or HEK cells stably expressing recombinant P2X7R. oATP also attenuated cytokine-stimulated expression of nuclear factor-kappaB-luciferase reporter genes expressed in HEK or 1321N1 cells, but did not affect the rapid downregulation of IkappaB. oATP had no effect on uridine triphosphate-induced activation of native P2Y2 receptors in HEK cells, but reduced the potency and efficacy of ADP as an agonist of native P2Y1 receptors. However, inhibition of P2Y1 receptors with the specific antagonist MRS2216 did not mimic the effects of oATP on TNF-alpha-stimulated IL-8 secretion. Although 1321N1 astrocytes lack expression of any known P2 receptor subtypes, oATP markedly inhibited ecto-ATPase activity in these cells, resulting in a significant accumulation of extracellular ATP. In summary, oATP can attenuate proinflammatory signaling by mechanisms independent of the expression or activation of known P2 receptor subtypes.

ATPase and phosphatase activities are differentially inhibited by photo-oxidation of the sarcoplasmic reticulum Ca(2+)-ATPase

We have already described that photo-oxidation of the sarcoplasmic reticulum Ca(2+)-ATPase with the halogenated dye erythrosin B produces inhibition of the ATPase activity (J.A. Mignaco et al., Biochemistry 35 (1996) 3886-3891). We now show that the Ca(2+)-dependent and Ca(2+)-independent p-nitrophenylphosphatase activities are also inhibited by this treatment. Modification of rapidly (< 10 min) oxidized residue(s) is responsible for the major loss of ATPase activity, whereas photo-inhibition of the phosphatase activities occurs more slowly (t1/2 20-30 min). Here we have focused on photo-inhibition of the Ca(2+)-independent pNPPase activity, and the counteracting effects of ATP and FITC. Following photo-oxidation, the Ca(2+)-independent pNPPase activity decreases monotonically. ATP partially protects against the inactivation of the pNPPase, whereas labeling the enzyme with FITC does not. However, the protective effect of ATP is completely abolished by the attached FITC. These data are interpreted in terms of two different sites that are susceptible to photo-oxidation and are involved in different events related to substrate hydrolysis.

Effects of photo-oxidizing analogs of fluorescein on the sarcoplasmic reticulum Ca2+-ATPase. Functional consequences for substrate hydrolysis and effects on the partial reactions of the hydrolytic cycle

Erythrosin B was used to photo-oxidize the sarcoplasmic reticulum Ca2+-ATPase. The ATPase activity is rapidly and irreversibly inhibited by photo-oxidation with erythrosin. This inhibition is protected by the presence of ATP during the photo-oxidation period. After photo-oxidation, the steady-state phosphorylation by ATP remains almost unchanged, whereas phosphorylation by inorganic phosphate is impaired. The pseudo-first order rate constants for phosphorylation by 15 microM ATP at 25 degrees C are strongly inhibited when starting from either a Ca2+-bound or a Ca2+-free enzyme form, decreasing from 145 to 23 s-1 for the Ca2+-bound form and from 50 to 18 s-1 for the Ca2+-free form. Concurrently, the rate constants for dephosphorylation are also severely inhibited, changing from a fast double exponential to a very slow single exponential decay in the reverse direction and from a moderately slow single to a very slow single exponential decay in the forward direction. Ca2+ binding data show that the phosphorylated intermediate formed by the photo-oxidized enzyme contains two occluded Ca2+, and TNP-ATP fluorescence measurements indicate that it accumulates in a E1-P.Ca2-like conformation. Protection by ADP against glutaraldehyde-induced cross-linking indicates that ADP binding to Ca2+-ATPase is not impaired by photo-oxidation nor by free erythrosin. These data support the view that an ADP-insensitive, Ca2+-bound, slowly interconverting phosphoenzyme is formed. Thus, photo-oxidation with erythrosin B leads to impairment of phosphoryl transfer reactions and related conformational changes.

Are there different water requirements in different steps of a catalytic cycle? Hydration effects at the E1 and E2 conformers of sarcoplasmic reticulum Ca(2+)-ATPase studied in organic solvents with low amounts of water

The Ca(2+)-ATPase from sarcoplasmic reticulum was transferred in an active form to a low-water system composed of toluene, phospholipids, and Triton X-100 (TPT). The Ca(2+)-ATPase activity in the TPT system with 4.0% water (by vol. was about 50% of the activity observed in all-aqueous mixtures. Phosphate formation was linear with time up to 20% of ATP hydrolysis and, as expected from an enzyme-catalysed reaction, activity was linear with protein concentration. No ATPase activity was detected in the presence of 3 mM EGTA, indicating that the enzyme retained its Ca2+ dependence in the TPT system. A hyperbolic response to ATP concentration was observed with a Km of 0.15 mM. There was no detectable ATPase activity at water concentrations below 1.5% (by vol.). With 2.0% water, activity became detectable and increased as the water content was progressively raised to 7.0% (by vol.). Higher amounts of water produced unstable emulsions. Enzyme phosphorylation by ATP and dephosphorylation took place in the TPT system. The velocities of both enzyme phosphorylation and dephosphorylation increased with increments in the water content. The enzyme could also be phosphorylated in the TPT system by inorganic phosphate. However, in comparison to ATP, phosphorylation by phosphate took place with significantly lower amounts of water. It is suggested that at low amounts of water, the enzyme is in a relatively rigid conformation and, as the water content is increased, the ATPase acquires more flexibility and, hence, the capacity to carry out catalysis at higher rates. Nevertheless, the release of conformational constraints of the catalytic site of the E2 conformer takes place at water concentrations much lower than those needed for the expression of catalytic activity by the E1 conformer.

2',3'-Dialdehyde ATP analog labels the Ca(2+)-ATPase of sarcoplasmic reticulum via the catalytic adenosine-nucleotide-binding site

The 2',3'-dialdehyde ATP analog (oATP) was synthesized and its ability to activate the Ca(2+)-ATPase of skeletal muscle sarcoplasmic reticulum via the adenosine-nucleotide-binding site was investigated. After reduction by sodium borohydride, oATP binds covalently to the catalytic adenosine-nucleotide-binding site of the enzyme, resulting in 85% loss of acetyl-phosphate-driven Ca2+ uptake and ATP-hydrolysing ability. In the absence of a reducing agent, oATP serves as a substrate for the Ca(2+)-ATPase, as indicated by Pi formation (hydrolysis) and Ca(2+)-uptake ability. oATP binding to the intact light sarcoplasmic reticulum is observed in the absence and presence of the competitive adenosine nucleotide inhibitor, fluorescein isothiocyanate with apparent affinity constants of 1.2 mM and 2.2 mM, respectively. Autoradiography of tryptic fragments from partially purified Ca(2+)-ATPase labeled with [alpha-32P]oATP or [gamma-32P]oATP locates the covalent binding site to the A1 fragment, even in the fluorescein-isothiocyanate-labeled pump protein. With high probability, a lysine residue in the tryptic A1 fragment is labeled by the ribose-modified ATP analog close to the phosphorylation site at Asp351.

Vanadate inhibition of ATP and p-nitrophenyl phosphate hydrolysis in the fragmented sarcoplasmic reticulum

The vanadate inhibition of the Ca(2+)-ATPase activity was analysed both in intact sarcoplasmic reticulum vesicles and in the presence of low concentrations of Tween 20, using ATP and p-nitrophenyl phosphate as substrates. The saturation of the internal low-affinity calcium-binding sites protects the enzyme against vanadate inhibition, because: (1) p-nitrophenyl phosphate hydrolysis is not inhibited by vanadate in intact vesicles, but inhibition developed after solubilization with detergents; (2) the vanadate inhibition of the p-nitrophenyl phosphate hydrolysis in solubilized preparations is prevented by free Ca2+ concentrations higher than 10(-3) M and vanadate competes with calcium (10(-5)-10(-3) M); and (3) the vanadate inhibition of ATP hydrolysis is decreased with an increase in vesicular Ca2+ concentration. The presence of magnesium ions is indispensable for the vanadate effect. The vanadate inhibition is non-competitive with respect to Mg-p-nitrophenyl phosphate and uncompetitive with respect to Mg-ATP. However, in the presence of dimethyl sulfoxide, which facilitates phosphorylation of the enzyme, the inhibition is converted to a competitive one with respect to a substrate. The results suggest, that in the process of enzyme operation vanadate interacts with the unliganded E form of Ca(2+)-ATPase, occupying probably an intermediate position between the E2 and E1 forms, with the formation of an E2 Van complex, that imposes the inhibition on the Ca(2+)-ATPase activity.