Role of phosphate on the ADP-induced hysteretic inhibition of mitochondrial adenosine 5'-triphosphatase. Effects of the natural protein inhibitor

Preincubation of F1-ATPase with ADP and Mg2+ leads to ADP binding at regulatory site inducing a hysteretic inhibition of ATP hydrolysis, i.e., an inhibition that slowly develops after Mg-ATP addition (Di Pietro, A., Penin, F., Godinot, C. and Gautheron, D.C. (1980) Biochemistry 19, 5671-5678). It is shown here that inorganic phosphate (Pi) together with ADP during preincubation abolishes the time-dependence of the inhibition after the addition of the substrate Mg-ATP. This preincubation in the presence of both Pi and ADP slowly leads to a conformation of the enzyme immediately inhibited after the addition of the substrate Mg-ATP. The Pi effect is half-maximal at 35 microM and pH 6.6, whereas a limited effect is induced at pH 8.0. The preincubation of F1-ATPase with Pi and ADP must last long enough (t1/2 = 5 min). The effects can be correlated to the amount of Pi bound to the enzyme, 1 mol Pi per mol (apparent KD of 33 microM) at saturation. Pi neither modifies the ADP binding nor the final level of the concomitant inhibition. When Pi is not present in the preincubation, the final stable rate of ADP-induced hysteretic inhibition is always reached when a near-constant amount of Pi has been generated during Mg-ATP hydrolysis. Kinetic experiments indicate that preincubation with ADP and Pi decreases both Vmax and Km which would favor a conformational change of the enzyme. Taking into account the Pi effects, a more precise model of hysteretic inhibition is proposed. The natural protein inhibitor IF1 efficiently prevents the binding of Pi produced by ATP hydrolysis indicating that the hysteretic inhibition and the IF1-dependent inhibition obey different mechanisms.     

Characteristics of the combination of inhibitory Mg2+ and azide with the F1 ATPase from chloroplasts.

The interactions between ADP, Mg2+, and azide that result in the inhibition of the chloroplast F1 ATPase (CF1) have been explored further. The binding of the inhibitory Mg2+ with low Kd is shown to occur only when tightly bound ADP is present at a catalytic site. Either the tightly bound ADP forms part of the Mg(2+)-binding site or it induces conformational changes creating the high-affinity site for inhibitory Mg2+. Kinetic studies show that CF1 forms two catalytically inactive complexes with Mg2+. The first complex results from Mg2+ binding with a Kd for Mg2+ dissociation of about 10-15 microM, followed by a slow conversion to a complex with a Kd of about 4 microM. The rate-limiting step of the CF1 inactivation by Mg2+ is the initial Mg2+ binding. When medium Mg2+ is chelated with EDTA, the two complexes dissociate with half-times of about 1 and 7 min, respectively. Azide enhances the extent of Mg(2+)-dependent inactivation by increasing the affinity of the enzyme for Mg2+ 3-4 times and prevents the reactivation of both complexes of CF1 with ADP and Mg2+. This results from decreasing the rate of Mg2+ release; neither the rate of Mg2+ binding to CF1 nor the rate of isomerization of the first inactive complex to the more stable form is affected by azide. This suggests that the tight-binding site for the inhibitory azide requires prior binding of both ADP and Mg2+.     

Insight into the bind-lock mechanism of the yeast mitochondrial ATP synthase inhibitory peptide

The mechanism of yeast mitochondrial F1-ATPase inhibition by its regulatory peptide IF1 was investigated with the noncatalytic sites frozen by pyrophosphate pretreatment that mimics filling by ATP. This allowed for confirmation of the mismatch between catalytic site occupancy and IF1 binding rate without the kinetic restriction due to slow ATP binding to the noncatalytic sites. These data strengthen the previously proposed two-step mechanism, where IF1 loose binding is determined by the catalytic state and IF1 locking is turnover-dependent and competes with IF1 release (Corvest, V., Sigalat, C., Venard, R., Falson, P., Mueller, D. M., and Haraux, F. (2005) J. Biol. Chem. 280, 9927-9936). They also demonstrate that noncatalytic sites, which slightly modulate IF1 access to the enzyme, play a minor role in its binding. It is also shown that loose binding of IF1 to MgADP-loaded F1-ATPase is very slow and that IF1 binding to ATP-hydrolyzing F1-ATPase decreases nucleotide binding severely in the micromolar range and moderately in the submillimolar range. Taken together, these observations suggest an outline of the total inhibition process. During the first catalytic cycle, IF1 loosely binds to a catalytic site with newly bound ATP and is locked when ATP is hydrolyzed at a second site. During the second cycle, blocking of ATP hydrolysis by IF1 inhibits ATP from becoming entrapped on the third site and, at high ATP concentrations, also inhibits ADP release from the second site. This model also provides a clue for understanding why IF1 does not bind ATP synthase during ATP synthesis.     

Pre-steady-state kinetics of beef heart mitochondrial ATPase

The pre-steady-state kinetics of beef heart mitochondrial ATPase (F1) were examined. F1 was found to exhibit hysteretic behavior when hydrolyzing ATP. The hysteretic property was expressed as an activation process which occurred when the enzyme was mixed with its substrate, MgATP. Many catalytic turnovers were required before the activation was complete. The lag in hydrolysis increased hyperbolically as the concentration of enzyme increased. Passage of F1 through Sephadex G25 eliminated the activation process. Several kinetically distinct possibilities for explaining these data, including multiple nucleotide dissociations, enzyme conformational changes, and regulatory site interactions, are discussed. The enzyme was apparently able to recognize nucleotide in a noncatalytic manner, as evidenced by the fact that F1 preincubated with ADP in the absence of substrate achieved partial activation (smaller lag times) before being introduced to substrate. ADP is also a time-dependent inhibitor, exhibiting a slow hysteretic inhibition in addition to immediate competitive inhibition.     

Azide as a probe of co-operative interactions in the mitochondrial F1-ATPase

(1) The hydrolytic activity of the isolated mitochondrial ATPase (F1) is strongly inhibited by azide. However, at very low ATP concentration (1 microM or less), no inhibition by azide is observed. (2) The azide-insensitive ATPase activity represents a high-affinity, low-capacity mode of turnover of F1. This is identified with the low Km, low Vmax component seen in steady-state kinetic studies in the absence of azide. (3) The azide-insensitive ATPase activity shows simple Michaelis-Menten kinetics, with Km = 3.2 microM, and Vmax = 1.1 mumol/min per mg (6 s-1). It is unaffected by anions such as sulphite, or by increasing pH in the range 7 to 8, both of which stimulate the maximal activity of F1. (4) Both the azide-insensitive and azide-sensitive components of F1-ATPase activity are equally inhibited by labelling the enzyme with 7-chloro-4-nitrobenzofurazan, by binding the natural inhibitor protein, or by cold denaturation of the enzyme. (5) It is concluded that azide-insensitive ATP hydrolysis represents catalysis by F1 involving a single catalytic site, and that azide acts by abolishing intersubunit cooperativity between the three catalytic sites of F1. Azide-sensitivity is thus a useful probe for events which affect the active site of F1 directly.     

Metal interactions with beef heart mitochondrial ATPase

Atomic absorption and electron paramagnetic resonance spectroscopy were used to study the metal binding sites of beef heart mitochondrial ATPase (F1). Quantitative and qualitative properties of these sites are described. Two different separation techniques were able to distinguish two very tight sites from one tight (easily exchangeable) metal binding site on F1. Of these sites, two are specific for magnesium while one can be substituted with Mn2+, Co2+, or Zn2+. When MgAMP-PNP was incubated with F1, a fourth metal was bound to the enzyme. The carboxyl group modified by dicyclohexylcarbodiimide is shown not to be involved in binding of any of the tightly bound metals. Qualitative properties of the metal binding sites using the Mn2+-enzyme complex as a probe were ascertained using EPR at pH 6.8 and 8.0. CrATP and Mn2+ appear to bind to different metal sites on F1. The possible role of the metals in regulation of catalysis, and their relation to nucleotide binding is discussed.     

The inhibition of caeruloplasmin by azide

1. The inhibition of the oxidase activity of caeruloplasmin by azide was investigated at 25 degrees and 7.5 degrees . 2. The inhibition is reversible on dilution or Sephadex treatment, indicating a caeruloplasmin-azide complex. 3. The enzyme is protected against azide inhibition by chloride, acetate or EDTA, the last-named acting not by chelation but by a non-specific effect similar to that of acetate. 4. Lineweaver-Burk plots with different concentrations of azide are parallel. This may occur either when the enzyme-substrate complex or when a subsequent intermediate structure of the enzyme forms the inhibited complex. 5. At 7.5 degrees inhibition may be shown not to occur until after the initial reaction of enzyme with substrate. 6. At 7.5 degrees , the inhibition is of the mutual-depletion type, inhibitory concentrations of azide being comparable with the concentration of caeruloplasmin. It is shown that the binding of a single azide group completely inhibits a caeruloplasmin molecule. 7. An arrangement of the four valence-changing copper atoms of caeruloplasmin is proposed in which they are so close together in the cuprous form that reoxidation may occur by the simultaneous transfer of four electrons from the copper atoms to a single oxygen molecule.     

Tightly bound adenosine diphosphate, which inhibits the activity of mitochondrial F1-ATPase, is located at the catalytic site of the enzyme

The binding of one ADP molecule at the catalytic site of the nucleotide depleted F1-ATPase results in a decrease in the initial rate of ATP hydrolysis. The addition of an equimolar amount of ATP to the nucleotide depleted F1-ATPase leads to the same effect, but, in this case, inhibition is time dependent. The half-time of this process is about 30 s, and the inhibition is correlated with Pi dissociation from the F1-ATPase catalytic site (uni-site catalysis). The F1-ATPase-ADP complex formed under uni-site catalysis conditions can be reactivated in two ways: (i) slow ATP-dependent ADP release from the catalytic site (tau 1/2 20 s) or (ii) binding of Pi in addition to MgADP and the formation of the triple F1-ATPase-MgADP-Pi complex. GTP and GDP are also capable of binding to the catalytic site, however, without changes in the kinetic properties of the F1-ATPase. It is proposed that ATP-dependent dissociation of the F1-ATPase-GDP complex occurs more rapidly, than that of the F1-ATPase-ADP complex.     

Measurements of electron spin resonance with the pyruvate dehydrogenase complex from Escherichia coli. Studies on the allosteric binding site of acetyl-coenzyme A

Binding of the feedback inhibitor acetyl-coenzyme A to the pyruvate dehydrogenase complex from Escherichia coli was studied by electron spin resonance spectroscopy with the spin-labelled acetyl-CoA analogue 3-carboxy-2,2,5,5-tetramethylpyrrolidine-1-oxyl-CoA-thioester. The spin-labelled compound binds to the pyruvate dehydrogenase component of the enzyme complex and this binding can be reversed by acetyl-CoA, while CoA has no effect. AMP and fructose 1,6-bisphosphate, which are both activators of the pyruvate dehydrogenase complex, exhibit a partial competition with the spin-labelled acetyl-CoA analogue and it could be shown that both activators act essentially by reversion of the feedback inhibition of acetyl-CoA. The binding site for these activators seems to overlap with the acetyl-CoA binding site, possibly by a common phosphate attachment point. No competition for binding to the feedback inhibition site exists with pyruvate, thiamine diphosphate, magnesium ions and with the fluorescent chromophore 8-anilino-1-naphthalene sulfonic acid. Thus, the feedback inhibition site proves to be a true allosteric regulatory site, which appears to be completely separate from the catalytic site on the pyruvate dehydrogenase component. The spin-labelled acetyl-CoA analogue binds also to the product binding site of acetyl-CoA on the dihydrolipoamide acetyltransferase component of the pyruvate dehydrogenase complex. Two binding sites per polypeptide chain with identical affinities on this enzyme component were found and the binding of the analogue can be inhibited by acetyl-CoA as well as by CoA.     

Nickel(II) transport in human blood serum. Studies of nickel(II) binding to human albumin and to native-sequence peptide, and ternary-complex formation with l-histidine

1. The initial rapid phase of ATP hydrolysis by bovine heart submitochondrial particles or by soluble F1-ATPase is insensitive to anion activation (sulphite) or inhibition (azide). 2. The second slow phase of ATP hydrolysis is hyperbolically inhibited by azide (Ki approximately 10(-5) M); the inosine triphosphatase activity of submitochondrial particles or F1-ATPase is insensitive to azide or sulphite. 3. The rate of interconversion between rapid azide-insensitive and slow azide-sensitive phases of ATP hydrolysis does not depend on azide concentration, but strongly depends on ATP concentration. 4. Sulphite prevents the interconversion of the rapid initial phase of the reaction into the slower second phase, and also prevents and slowly reverses the inhibition by azide. 5. The presence of sulphite in the mixture when ADP reacts with ATPase of submitochondrial particles changes the pattern of the following activation process. 6. Azide blocks the activation of ATP-inhibited ATPase of submitochondrial particles by phosphoenolpyruvate and pyruvate kinase. 7. The results obtained suggest that the inhibiting effect of azide on mitochondrial ATPase is due to stabilization of inactive E*.ADP complex formed during ATP hydrolysis; the activation of ATPase by sulphite is also realized through the equilibrium between intermediate active E.ADP complex and inactive E*.ADP complex.     

Mechanism of allosteric regulation of the Ca,Mg-ATPase of sarcoplasmic reticulum: studies with 5'-adenylyl methylenediphosphate

Four mechanisms for the allosteric regulation of the calcium and magnesium ion activated adenosinetriphosphatase (Ca,Mg-ATPase) of sarcoplasmic reticulum were examined. Negative cooperativity in substrate binding was not supported by 3H-labeled 5'-adenylyl methylenediphosphate (AMPPCP) binding, which was best fit by a single class of sites. Although calcium had no effect on the absence of cooperativity, it did increase the affinity of the enzyme for AMPPCP. Allosteric regulation via an effector site for AMPPCP or ATP on the same ATPase chain was eliminated by the stoichiometry of ATP and AMPPCP binding, 1 mol of site per mole of enzyme. The possibility that AMPPCP acts at an effector site was eliminated by showing that it competitively inhibits the rate of phosphoenzyme formation. Allosteric regulation of kinetics via site-site interaction in an oligomer was eliminated by showing that the inhibition of ATPase activity by fluorescein isothiocyanate is linearly dependent upon its incorporation into the sarcoplasmic reticulum. The fourth mechanism considered was stimulation of ATPase activity by the binding of ATP or AMPPCP at the active site after departure of ADP but before the departure of inorganic phosphate. This hypothesis was supported by site stoichiometry and by the observation that AMPPCP or ATP stimulates v/EP, the rate of ATP hydrolysis for a given level of phosphoenzyme. Computer simulation of this branched monomeric model could duplicate all experimental observations made with AMPPCP and ATP as allosteric regulators. The condition that the affinity of ATP binding to the enzyme be reduced when it is phosphorylated, which is required by the computer model, was confirmed experimentally.     

Analysis of the metal-induced conformational change in myosin with a monoclonal antibody to light chain two

A monoclonal antibody capable of detecting a conformational change in myosin light chain two (LC2) was characterized in detail. The antibody was shown to bind only to myosin LC2 when tested against fast skeletal myosin (chicken pectoralis muscle). With cardiac or slow muscle myosins, the antibody exclusively recognized their first light chains (LC1). Staining of myofibrils by the monoclonal antibody could be observed only after their irreversible denaturation by acetone or ethanol, or after incubation of the myofibrils in divalent metal chelators. This latter effect was shown to be fully reversible. The metal effect was independent of ionic strength although the affinity of the antibody for myosin was depressed at high salt concentrations. Similar metal effects were detected in the binding of antibody to cardiac or slow myosins. Neither the metal nor the ionic strength-related inhibition of antibody binding were detected with denatured myosin. The antibody binding site overlaps one of the alpha-chymotryptic sites in LC2 protected by divalent metals. Electron microscopic observations of myosin-antibody complexes demonstrated that the antibody binding site is located near the head-rod junction of myosin. Since the binding site of this monoclonal antibody has been mapped by recombinant DNA methods to the junction of the first alpha-helical domain with the calcium binding site of LC2, the location of the calcium binding site must also be located near the head-tail junction of myosin. A model for conformational changes at the myosin head-tail junction is proposed to account for the metal-induced blockage of antibody binding and the inhibition of alpha-chymotryptic digestion of LC2.     

Alteration of apparent negative cooperativity of ATPase activity by alpha-subunit glutamine 173 mutation in yeast mitochondrial F1. Correlation with impaired nucleotide interaction at a regulatory site.

The first described alpha-subunit mutation of yeast mitochondrial F1 has been recently identified as a single Gln173----Leu substitution in a strongly conserved sequence (Falson, P., Maffey, L., Conrath, K., and Boutry, M. (1991) J. Biol. Chem. 266, 287-293). This mutation is shown here to greatly modify the biphasic pattern of ATPase activity as a function of pH: (i) the shoulder observed at acidic pH is significantly increased; (ii) the main peak, at alkaline pH, is markedly lowered; (iii) the optimal pH is shifted from 8.8 to 7.7. The mutation lowers both apparent negative cooperativity and sensitivity to azide inhibition which concomitantly increase when the assay pH decreases. Azide partial inhibition produces apparent negative cooperativity which can be further abolished by bicarbonate. The mutation increases both activation energies determined from biphasic Arrhenius plots. The mutation decreases the inactivation rate by 5'-p-fluorosulfonylbenzoyladenosine and abolishes the protection by nucleotide binding at the adenine-specific regulatory site. On the contrary, it does not modify the reactivity of 5'-p-fluorosulfonylbenzoylguanosine at the less-selective catalytic site. In addition, partial inactivation by 5'-p-fluorosulfonylbenzoyladenosine, as opposed to 5'-p-fluorosulfonylbenzoylguanosine, produces apparent negative cooperativity under conditions where unmodified-enzyme kinetics are noncooperative. The results show that alpha-Gln173 participates in nucleotide interaction at a regulatory site which controls the negative cooperativity of F1-ATPase activity.     

Active/Inactive state transitions of the chloroplast F1 ATPase are induced by a slow binding and release of Mg2+. Relationship to catalysis and control of F1 ATPases

Mg2+ is known to be a potent inhibitor of F1 ATPases from various sources. Such inhibition requires the presence of a tightly bound ADP at a catalytic site. Results with the spinach chloroplast F1 ATPase (CF1) show that the time delays of up to 1 min or more in the induction or the relief of the inhibition are best explained by a slow binding and slow release of Mg2+ rather than by slow enzyme conformational changes. CF1 is known to have multiple Mg2+ binding sites with Kd values in the micromolar range. The inhibitory Mg2+ and ADP can bind independently to CF1. When Mg2+ and ATP are added to the uninhibited enzyme, a relatively fast rate of hydrolysis attained soon after the addition is followed by a much slower steady-state rate. The inhibited steady-state rate results from a slowly attained equilibrium of binding of medium Mg2+. The Kd for the binding of the inhibitory Mg2+ is in the range of 1-8 microM, in the presence or absence of added ATP, as based on the extent of rate inhibition induced by Mg2+. Assessments from 18O exchange experiments show that the binding of Mg2+ is accompanied by a relatively rapid change to an enzyme form that is incapable of hydrolyzing MgATP. When ATP is added to the Mg2+- and ADP-inhibited enzyme, the resulting reactivation can be explained by MgATP binding to an alternate catalytic site which results in a displacement of the tightly bound ADP after a slow release of Mg2+. Both an increase in temperature (to 50 degrees C) and the presence of activating anions such as bicarbonate or sulfite reduce the extent of the Mg2+ inhibition markedly. The activating anions may bind to CF1 in place of Pi near the ADP. Whether the inhibitory Mg2+ binds at catalytic or noncatalytic nucleotide binding sites or at another location is not known. The Mg2(+)- and ADP-induced inhibition appears to be a general property of F1 ATPases, which show considerable differences in affinity for ADP, Mg2+, and Pi. These differences may reflect physiological control functions.     

Effects of azide on the S2 state EPR signals from Photosystem II

The anion azide, N₃ ^-, has been previously found to be an inhibitor of oxygen evolution by Photosystem II (PS II) of higher plants. With respect to chloride activation, azide acts primarily as a competitive inhibitor but uncompetitive inhibition also occurs [Haddy A, Hatchell JA, Kimel RA and Thomas R (1999) Biochemistry 38: 6104–6110]. In this study, the effects of azide on PS II-enriched thylakoid membranes were characterized by electron paramagnetic resonance (EPR) spectroscopy. Azide showed two distinguishable effects on the S₂ state EPR signals. In the presence of chloride, which prevented competitive binding, azide suppressed the formation of the multiline and g = 4.1 signals concurrently, indicating that the normal S₂ state was not reached. Signal suppression showed an azide concentration dependence that correlated with the fraction of PS II centers calculated to bind azide at the uncompetitive site, based on the previously determined inhibition constant. No evidence was found for an effect of azide on the Fe(II)Q_A ^- signals at the concentrations used. This result is consistent with placement of the uncompetitive site on the donor side of PS II as suggested in the previous study. In chloride-depleted PS II-enriched membranes azide and fluoride showed similar effects on the S₂ state EPR signals, including a notable increase and narrowing of the g = 4.1 signal. Comparable effects of other anions have been described previously and apparently take place through the chloride-competitive site. The two azide binding sites described here correlate with the results of other studies of Lewis base inhibitors.This revised version was published online in October 2005 with corrections to the Cover Date.     

Adenine nucleotide-binding sites on mitochondrial F1-ATPase: studies of the inactive complex formed upon binding ADP at a catalytic site.

ADP-induced inhibition of mitochondrial F1-ATPase has been studied. It is shown that in the presence of magnesium and the absence of light, the photoaffinity ADP analog, 2-azido-ADP, induces a reversible inhibition of native F1 that is indistinguishable from that obtained with ADP. Photolysis of the inactive complex results in the predominant labeling of a catalytic-site peptide identified previously (Cross et al., 1987, Proc. Natl. Acad. Sci. USA 84, 5715-5719). Dissociation of the inactive complex formed between F1 and ADP is biphasic with a rapid azide-insensitive phase followed by a slow azide-sensitive phase (k approximately 3 x 10(-3) s-1). It is also shown that incubation of the ADP-inhibited enzyme with EDTA or phosphate does not result in release or migration of ADP from the catalytic site. However, it does convert the complex to a form that reactivates in the presence of 100 microM ATP at a rate too rapid to observe using manual mixing.     

Restoring proper radical generation by azide binding to the iron site of the E238A mutant R2 protein of ribonucleotide reductase from Escherichia coli

The enzyme activity of Escherichia coli ribonucleotide reductase requires the presence of a stable tyrosyl free radical and diiron center in its smaller R2 component. The iron/radical site is formed in a reconstitution reaction between ferrous iron and molecular oxygen in the protein. The reaction is known to proceed via a paramagnetic intermediate X, formally a Fe(III)-Fe(IV) state. We have used 9.6 GHz and 285 GHz EPR to investigate intermediates in the reconstitution reaction in the iron ligand mutant R2 E238A with or without azide, formate, or acetate present. Paramagnetic intermediates, i.e. a long-living X-like intermediate and a transient tyrosyl radical, were observed only with azide and under none of the other conditions. A crystal structure of the mutant protein R2 E238A/Y122F with a diferrous iron site complexed with azide was determined. Azide was found to be a bridging ligand and the absent Glu-238 ligand was compensated for by azide and an extra coordination from Glu-204. A general scheme for the reconstitution reaction is presented based on EPR and structure results. This indicates that tyrosyl radical generation requires a specific ligand coordination with 4-coordinate Fe1 and 6-coordinate Fe2 after oxygen binding to the diferrous site.     

Interaction of anions with the active site of carboxypeptidase A

Studies of azide inhibition of peptide hydrolysis catalyzed by cobalt(II) carboxypeptidase A identify two anion binding sites. Azide binding to the first site (KI = 35 mM) inhibits peptide hydrolysis in a partial competitive mode while binding at the second site (KI = 1.5 M) results in competitive inhibition. The cobalt electronic absorption spectrum is insensitive to azide binding at the first site but shows marked changes upon azide binding to the second site. Thus, azide elicits a spectral change with new lambda max (epsilon M) values of 590 (330) and 540 nm (190) and a KD of 1.4 M, equal to the second kinetic KI value for the cobalt enzyme, indicating that anion binding at the weaker site involves an interaction with the active-site metal. Remarkably, in the presence of the C-terminal products of peptide or ester hydrolysis or carboxylate inhibitor analogues, anion (e.g., azide, cyanate, and thiocyanate) binding is strongly synergistic; thus, KD for azide decreases to 4 mM in the presence of L-phenylalanine. These ternary complexes have characteristic absorption, CD, MCD, and EPR spectra. The absorption spectra of azide/carboxylate inhibitor ternary complexes with Co(II)CPD display a near-UV band between 305 and 310 nm with epsilon M values around 900-1250 M-1 cm-1. The lambda max values are close to the those of the charge-transfer band of an aquo Co(II)-azide complex (310 nm), consistent with the presence of a metal azide bond in the enzyme complex.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fluoride is a slow, tight-binding inhibitor of the calcium ATPase of sarcoplasmic reticulum.

Addition of sodium fluoride in the millimolar concentration range to a solution containing the sarcoplasmic reticulum CaATPase undergoing turnover in its vesicular or nonionic detergent-solubilized forms produced a slow (time range of minutes) complete loss of enzymatic activity. In the presence of magnesium and the absence of calcium, similar results were obtained under nonturnover conditions. Time courses were adequately fit by a function corresponding to a monophasic transformation with a pseudo first order rate constant kobs. In the absence of Mg2+ (EDTA present) no inhibition developed; kobs depended hyperbolically on the Mg2+ concentration with the half maximal effect occurring near 4 mM. The fluoride concentration dependence of kobs showed no evidence of approaching saturation (highest [F-] used was 40 mM) and corresponded to a rate law which was approximately second-order with respect to fluoride. A number of ligands known to bind to the CaATPase were found to decrease kobs. Calcium prevented onset of fluoride inhibition with a midpoint in the micromolar range, implying an effect due to binding at the high affinity transport sites. ATP also protected with a midpoint in the micromolar range, consistent with an effect caused by active site binding of the nucleotide; protection was only partial, suggesting the ATPase can bind fluoride and ATP simultaneously. Prevention of fluoride inhibition by Pi occurred with a [Pi]1/2 of 12 mM at pH 6.5, a concentration similar to that which produces active site phosphorylation. Finally, protection by orthovanadate was found to be competitive and have a midpoint of 5 microM. These results point to an effect exerted at or near the phosphorylation site. The value of kobs increased from essentially zero above pH 8 to a plateau below pH 6; the transition had a midpoint near pH 7.2. Inhibition persisted after removal (with EGTA present) of unbound fluoride by dialysis. Reversal of fluoride inhibition was very slow, with a t1/2 of 16 h at 37 degrees C. These results suggest that fluoride behaves like a slow, tight-binding inhibitor of the ATPase and that the resulting complex is a stable transition (or intermediate) state analog. Plausible molecular bases for our results are that fluoride acts at the phosphorylation site as an analog of Pi or of hydroxide, which may be considered a substrate in the normal hydrolysis of the phosphorylated enzyme. A role for aluminum was ruled out after finding that the addition of EGTA to 10 mM or aluminum sulfate to 0.2 mM or deferoxamine to 0.5 mM produced no significant change in kobs.     

Band-3 protein function in human erythrocytes: effect of oxygenation-deoxygenation

Sulfate transport by band-3 protein in adult human erythrocytes was shown to be modulated by oxygen pressure. In particular, a higher transport activity was measured under high oxygen pressure than at low one (0.0242+/-0.0073 vs. 0.0074+/-0.0010 min(-1)). Other factors, such as magnesium ions and orthovanadate, which can indirectly affect the binding properties of the cytoplasmic domain of band 3 (cdb3), influence significantly the anion exchanger activity. No effect of oxygen pressure on sulfate transport was found in chicken erythrocytes, which may be related to their lacking the cdb3 binding site. These findings are fully consistent with a molecular mechanism where the oxygen-linked transition of hemoglobin (T-->R) could play a key role in the regulation of anion exchanger activity.