Fluoride-inhibited calcium ATPase of sarcoplasmic reticulum. Magnesium and fluoride stoichiometry

Role of nucleotides in stabilization of the phospholamban/cardiac Ca²⁺ pump inhibitory complex examined with use of metal fluorides

Phospholamban (PLB) inhibits the activity of the cardiac calcium pump SERCA2a. We previously showed that PLB with engineered Cys residues only cross-linked with the Ca(2+) -free E2 intermediate of SERCA2a. Formation of E2•PLB prevents Ca(2+) binding at the high-affinity Ca(2+) binding sites, blocking the enzyme kinetic cycle. Here we further studied the synergistic action of PLB and ATP on E2 in terms of prevention of formation of the phosphorylated E2P-like states stabilized by metal fluorides. SERCA2a was co-expressed in insect cell microsomes with PLB mutants of normal or super-inhibitory strength, with cross-linkable mutations at either the cytosolic side (N30C) or the luminal side (V49C) of PLB. For normal-strength PLB mutants, in the absence of nucleotide, metal fluorides totally inhibited both SERCA2a enzyme activity and cross-linking of PLB to SERCA2a at both sites, suggesting that PLB dissociates from SERCA2a in the E2P-like states. However, under the same conditions, super-inhibitory PLB mutants prevented total enzyme inhibition by metal fluorides. Further, the cross-linking of super-inhibitory PLB to SERCA2a was only partially inhibited by metal fluorides, but was drastically restored upon sequential addition of ATP. These results revealed the equilibrium between E2•PLB, E2•ATP, or E2•ATP•PLB states and E2P-like states, suggesting that the synergistic binding of ATP and PLB to SERCA is very strong, sufficient to prevent formation of E2 phosphoenzymes, even when stabilized by metal fluorides.

Metal Fluoride Inhibition of a P-type H+ Pump: STABILIZATION OF THE PHOSPHOENZYME INTERMEDIATE CONTRIBUTES TO POST-TRANSLATIONAL PUMP ACTIVATION

The plasma membrane H(+)-ATPase is a P-type ATPase responsible for establishing electrochemical gradients across the plasma membrane in fungi and plants. This essential proton pump exists in two activity states: an autoinhibited basal state with a low turnover rate and a low H(+)/ATP coupling ratio and an activated state in which ATP hydrolysis is tightly coupled to proton transport. Here we characterize metal fluorides as inhibitors of the fungal enzyme in both states. In contrast to findings for other P-type ATPases, inhibition of the plasma membrane H(+)-ATPase by metal fluorides was partly reversible, and the stability of the inhibition varied with the activation state. Thus, the stability of the ATPase inhibitor complex decreased significantly when the pump transitioned from the activated to the basal state, particularly when using beryllium fluoride, which mimics the bound phosphate in the E2P conformational state. Taken together, our results indicate that the phosphate bond of the phosphoenzyme intermediate of H(+)-ATPases is labile in the basal state, which may provide an explanation for the low H(+)/ATP coupling ratio of these pumps in the basal state.

Fluoroquinolones influence the intracellular calcium handling in individuals susceptible to malignant hyperthermia

INTRODUCTION

The mechanisms of fluoroquinolone-induced myotoxicity are unknown but an involvement of intracellular calcium handling is suspected. An in vitro contracture test used to investigate cellular processes in malignant hyperthermia (MH) can be applied to study the effects of fluoroquinolones.

METHODS

With approval of the local ethics committee, muscle biopsies of 18 MH susceptible (MHS) and 12 MHS non-susceptible (MHN) pigs were performed. Individual bundles were mounted on an isometric force transducer, preloaded, and electrically stimulated. After equilibration they were exposed to ciprofloxacin or levofloxacin. The measured baseline tension was analyzed (Wilcoxon test: P < 0.05).

RESULTS

There were no differences in weight, length, or predrug tension between the groups. Both levofloxacin an ciprofloxacin induced significant contractures in MHS muscle bundles but not in MHN.

CONCLUSIONS

Fluoroquinolones appear to have a pathological influence on intracellular calcium handling. A pre-existing impairment of the calcium homeostasis, however, seems to be necessary for this behavior.

Lumenal gating mechanism revealed in calcium pump crystal structures with phosphate analogues

P-type ion transporting ATPases are ATP-powered ion pumps that establish ion concentration gradients across biological membranes. Transfer of bound cations to the lumenal or extracellular side occurs while the ATPase is phosphorylated. Here we report at 2.3 A resolution the structure of the calcium-ATPase of skeletal muscle sarcoplasmic reticulum, a representative P-type ATPase that is crystallized in the absence of Ca2+ but in the presence of magnesium fluoride, a stable phosphate analogue. This and other crystal structures determined previously provide atomic models for all four principal states in the reaction cycle. These structures show that the three cytoplasmic domains rearrange to move six out of ten transmembrane helices, thereby changing the affinity of the Ca2+-binding sites and the gating of the ion pathway. Release of ADP triggers the opening of the lumenal gate and release of phosphate its closure, effected mainly through movement of the A-domain, the actuator of transmembrane gates.

Distinct natures of beryllium fluoride-bound, aluminum fluoride-bound, and magnesium fluoride-bound stable analogues of an ADP-insensitive phosphoenzyme intermediate of sarcoplasmic reticulum Ca2+-ATPase: changes in catalytic and transport sites during phosphoenzyme hydrolysis

The structural natures of stable analogues for the ADP-insensitive phosphoenzyme (E2P) of Ca(2+)-ATPase formed in sarcoplasmic reticulum vesicles, i.e. the enzymes with bound beryllium fluoride (BeF.E2), bound aluminum fluoride (AlF.E2), and bound magnesium fluoride (MgF.E2), were explored and compared with those of actual E2P formed from P(i) without Ca(2+). Changes in trinitrophenyl-AMP fluorescence revealed that the catalytic site is strongly hydrophobic in BeF.E2 as in E2P but hydrophilic in MgF.E2 and AlF.E2; yet, the three cytoplasmic domains are compactly organized in these states. Thapsigargin, which was shown in the crystal structure to fix the transmembrane helices and, thus, the postulated Ca(2+) release pathway to lumen in a closed state, largely reduced the tryptophan fluorescence in BeF.E2 as in E2P, but only very slightly (hence, the release pathway is likely closed without thapsigargin) in MgF.E2 and AlF.E2 as in dephosphorylated enzyme. Consistently, the completely suppressed Ca(2+)-ATPase activity in BeF-treated vesicles was rapidly restored in the presence of ionophore A23187 but not in its absence by incubation with Ca(2+) (over several millimolar concentrations) at pH 6, and, therefore, lumenal Ca(2+) is accessible to reactivate the enzyme. In contrast, no or only very slow restoration was observed with vesicles treated with MgF and AlF even with A23187. BeF.E2 thus has the features very similar to those characteristic of the E2P ground state, although AlF.E2 and MgF.E2 most likely mimic the transition or product state for the E2P hydrolysis, during which the hydrophobic nature around the phosphorylation site is lost and the Ca(2+) release pathway is closed. The change in hydrophobic nature is probably associated with the change in phosphate geometry from the covalently bound tetrahedral ground state (BeF(3)(-)) to trigonal bipyramidal transition state (AlF(3) or AlF(4)(-)) and further to tetrahedral product state (MgF(4)(2-)), and such change likely rearranges transmembrane helices to prevent access and leakage of lumenal Ca(2+).

Correlation between uncoupled ATP hydrolysis and heat production by the sarcoplasmic reticulum Ca2+-ATPase: coupling effect of fluoride

The sarcoplasmic reticulum Ca(2+)-ATPase transports Ca(2+) using the chemical energy derived from ATP hydrolysis. Part of the chemical energy is used to translocate Ca(2+) through the membrane (work) and part is dissipated as heat. The amount of heat produced during catalysis increases after formation of the Ca(2+) gradient across the vesicle membrane. In the absence of gradient (leaky vesicles) the amount of heat produced/mol of ATP cleaved is half of that measured in the presence of the gradient. After formation of the gradient, part of the ATPase activity is not coupled to Ca(2+) transport. We now show that NaF can impair the uncoupled ATPase activity with discrete effect on the ATPase activity coupled to Ca(2+) transport. For the control vesicles not treated with NaF, after formation of the gradient only 20% of the ATP cleaved is coupled to Ca(2+) transport, and the caloric yield of the total ATPase activity (coupled plus uncoupled) is 22.8 kcal released/mol of ATP cleaved. In contrast, the vesicles treated with NaF consume only the ATP needed to maintain the gradient, and the caloric yield of ATP hydrolysis is 3.1 kcal/mol of ATP. The slow ATPase activity measured in vesicles treated with NaF has the same Ca(2+) dependence as the control vesicles. This demonstrates unambiguously that the uncoupled activity is an actual pathway of the Ca(2+)-ATPase rather than a contaminating phosphatase. We conclude that when ATP hydrolysis occurs without coupled biological work most of the chemical energy is dissipated as heat. Thus, uncoupled ATPase activity appears to be the mechanistic feature underlying the ability of the Ca(2+)-ATPase to modulated heat production.

Fluoride-induced depletion of polyphosphoinositides in rat brain cortical slices: a rationale for the inhibitory effects on phospholipase C

Fluoride, which is used commonly as a pharmacological tool to activate phosphoinositide-phospholipase C coupled to the heterotrymeric Gq/11 proteins, inhibited the phosphorylation of phosphatidylinositol (PtdIns) to polyphosphoinositides (PtdIns4P and PtdIns4,5P2) in membranes from rat brain cortex. Fluoride enhanced basal production of 3H-inositol phosphates in membranes prepared from brain cortical slices that had been prelabeled with [3H]inositol, but inhibited the stimulation elicited by carbachol in the presence of GTPgammaS. However in both cases fluoride depleted [3H]PtdIns4P content by 95%. The inhibitory effects of fluoride on the release of 3H-inositol phosphates in slices were not apparent in a pulse [3H]inositol-labeling strategy, but became dramatic in a continuous labeling protocol, particularly at long incubation times. Prelabeling slices with [3H]inositol in the presence of fluoride precluded polyphosphoinositide labeling, and eliminated phospholipase C responsiveness to carbachol under normal or depolarizing conditions, and to the calcium ionophore ionomycin. The lack of response of 3H-polyphosphoinositide-depleted slices to phospholipase C stimuli was not due to fluoride poisoning, unaccessibility of the [3H]inositol label to phospholipase C or desensitization of Gq/11, as the effect of carbachol and GTPgammaS was restored, in the presence of ATP, in membranes prepared from slices that had been labeled in the presence of fluoride. In conclusion, our data show that fluoride, at a concentration similar to that used to stimulate directly Gq/11-coupled phospholipase C, effectively blocks the synthesis of phospholipase C substrates from PtdIns.

Inhibition of the hepatitis C virus helicase-associated ATPase activity by the combination of ADP, NaF, MgCl2, and poly(rU). Two ADP binding sites on the enzyme-nucleic acid complex

Hepatitis C virus (HCV) helicase has an intrinsic ATPase activity and a nucleic acid (poly(rU))-stimulated ATPase activity. The poly(rU)-stimulated ATPase activity was inhibited by F- in a time-dependent manner during ATP hydrolysis. Inhibition was the result of trapping an enzyme-bound ADP-poly(rU) ternary complex generated during the catalytic cycle and was not the result of generating enzyme-free ADP that subsequently inhibited the enzyme. However, catalysis was not required for efficient inhibition by F-. The stimulated and the intrinsic ATPase activities were also inhibited by treatment of the enzyme with F-, ADP, and poly(rU). The inhibited enzyme slowly recovered (t1/2 = 23 min) ATPase activity after a 2000-fold dilution into assay buffer. The onset of inhibition by 500 microM ADP and 15 mM F- in the absence of nucleic acid was very slow (t1/2 > 40 min). However, the sequence of addition of poly(rU) to a diluted solution of ADP/NaF-treated enzyme had a profound effect on the extent of inhibition. If the ADP/NaF-treated enzyme was diluted into an assay that lacked poly(rU) and the assay was subsequently initiated with poly(rU), the treated enzyme was not inhibited. Alternatively, if the treated enzyme was diluted into an assay containing poly(rU), the enzyme was inhibited. ATP protected the enzyme from inhibition by ADP/NaF. The stoichiometry between ADP and enzyme monomer in the inhibited enzyme complex was 2, as determined from titration of the ATPase activity ([ADP]/[E] = 2.2) and from the number of radiolabeled ADP bound to the inhibited enzyme ([ADP]/[E] = 1.7) in the presence of excess NaF, MgCl2, and poly(rU). The Hill coefficient for titration of ATPase activity with F- (n = 2.8) or MgCl2 (n = 2.1) in the presence of excess ADP and poly(rU) suggested that multiple F- and Mg2+ were involved in forming the inhibited enzyme complex. The stoichiometry between (dU)18, a defined oligomeric nucleic acid substituting for poly(rU), and enzyme monomer in the inhibited enzyme complex was estimated to be 1 ([(dU)18/[E] = 1.2) from titration of the ATPase activity in the presence of excess ADP, MgCl2, and NaF.

Reaction of 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole with the (Ca2+ + Mg2+)- ATPase protein of sarcoplasmic reticulum at low temperature

Modification of the (Ca2+ + Mg2+)-ATPase protein of rabbit skeletal sarcoplasmic reticulum (SR) with 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole, NBD-Cl, at 4 degrees C for 5 min caused a 63% loss of the Ca(2+)-dependent ATPase activity when 1 mol of the adenine analog was incorporated per 10(5) g of protein. At 25 degrees C, above the lipid phase transition, the extent of labeling was 3-fold higher although the Ca(2+)-ATPase activity was inhibited to the same extent. MgATP protected the ATPase activity at 4 degrees C and 25 degrees C but there was little change in the extent of labeling at 4 degrees C suggesting that changes in the fluidity of the lipid moiety made different sites on the ATPase protein accessible to the reagent. At 4 degrees C, addition of sodium deoxycholate enhanced the inactivation (6% ATPase activity remained) but the labeling of the SR-ATPase protein did not increase significantly. Incubation with MgATP prior to solubilization with deoxycholate resulted in the protection of the Ca(2+)-ATPase activity and only a small decrease in the labeling occurred. At 25 degrees C, a similar pattern was found with deoxycholate but the loss of ATPase activity was less dramatic and the extent of labeling by NBD-Cl was greater than that at 4 degrees C. MgATP induced changes in the conformation of the ATPase protein protecting essential cysteine residues while shifting the reaction of NBD-Cl with the ATPase protein to non-essential sites in the absence or presence of deoxycholate. An analysis of tryptic digests of the NBD-ATPase protein showed that MgATP shifted the labeling from the A2 subfragment to the A1 subfragment in the absence of deoxycholate and from the A1 subfragment to the A2 subfragment in the presence of deoxycholate. The reagent, NBD-Cl, can distinguish between different temperature dependent conformational states of the ATPase protein.

Stoichiometry of tight binding of magnesium and fluoride to phosphorylation and high-affinity binding of ATP, vanadate, and calcium in the sarcoplasmic reticulum Ca(2+)-ATPase

We previously showed that, when the purified Ca(2+)-ATPase from sarcoplasmic reticulum (SR) is treated with fluoride (F-) in the presence of Mg2+, a complete inactivation of the enzyme is induced by tight binding of approximately 2 mol of Mg2+ and 4 mol of F- to the catalytic site per mole of phosphorylation site [Kubota, T., Daiho, T., & Kanazawa, T. (1993) Biochim. Biophys. Acta 1163, 131-143]. Contradictorily, on the basis of the postulated content of the Ca(2+)-ATPase in F(-)-treated SR vesicles, Coll and Murphy [(1992) J. Biol. Chem. 267, 21584-21587] suggested that each inactivated enzyme contains one tightly-bound Mg2+ and two tightly-bound F-. The present study has been made to resolve this conflict. The contents of phosphorylation site, high-affinity ATP-binding site, high-affinity vanadate-binding site, and high-affinity Ca(2+)-binding site in the SR vesicles used were 3.33 +/- 0.06, 3.54 +/- 0.12, 3.34 +/- 0.04, and 6.98 +/- 0.16 nmol/mg, respectively. When the vesicles were incubated with F- in the presence of Mg2+, the Ca(2+)-ATPase was inactivated progressively. After removal of unbound Mg2+ and F- by gel filtration, tightly-bound Mg2+ and F- were determined by use of an atomic absorption spectrophotometer and a F(-)-selective electrode. A linear relationship existed between the extent of the enzyme inactivation and the contents of the tightly-bound ligands. The contents of tightly-bound Mg2+ and F- in the fully inactivated vesicles were 6.65 and 12.6 nmol/mg, respectively. The same stoichiometry was obtained with another preparation of SR vesicles.(ABSTRACT TRUNCATED AT 250 WORDS)