Adenosine triphosphate hydrolysis in rat dental tissues

Summary The effect of EDTA-decalcification, reactivating and activating procedures on the hydrolysis of ATP was studied histochemically in developing dental tissues in the rat. The incubation media contained lead citrate at alkaline pH and lead nitrate at neutral pH, and the results with ATP as substrate were compared with those obtained with -glycerophosphate.The ion dependency of ATP hydrolysis could only be ascertained in decalcified sections. As in earlier studies on the hydrolysis of -glycerophosphate in dental tissues, this hydrolysis could readily be reactivated through preincubation of the sections in a series of 0.1 M solutions of divalent cations; Zn²⁺ being the most efficient. This treatment was now found also to give rise to an ATP hydrolysis, which occurred without the need for activating ions in the incubation medium. This ATP hydrolysis should thus be described as nonspecific and, in terms of ion dependency, as due to a metalloenzyme, i.e. alkaline phosphatase. Activating ion dependent ATP hydrolysis in the dental tissues was found in the blood vessels and in the apical part of the secretory ameloblasts. The former was activated by Mg²⁺, Ca²⁺ and Mn²⁺, and the latter by Ca²⁺ and -almost specifically—by Sr²⁺. Preincubation with Zn²⁺ always inhibited the ion dependant ATP hydrolysis in the dental tissues.     

Cytochemical localization of plasma membrane ATPase activity in plant cells

Summary The cytochemical localization of ATPase activity has been investigated in maize root cells using both lead and cerium-based capture methods. With both methods, staining at the plasma membrane was observed in all cells of the root, although the precipitate obtained with cerium was more uniform and granular than that with lead. Controls using no substrate or no magnesium, -glycerophosphate to replace ATP, vanadate or boiled tissue generally showed little or no staining. However, biochemical studies on purified plasma membrane fractions showed that ATPase activity was markedly inhibited by fixation, particularly by glutaraldehyde, and also by lead and cerium ions. Non-enzymic hydrolysis of ATP by cerium was greater than that by lead. The value and limitations of these procedures for the localization of plasma membrane H⁺-ATPase activity are summarized in relation to previous criticisms of these methods.Abbreviations DTT dithiothreitol - EDTA ethylene diaminetetraacetic acid - GP B-glycerophosphate - PCMBS p-chloromercuribenzene sulphonic acid - PMSF phenylmethylsulphonyl fluoride     

Adenosine triphosphate catabolism in homogenates of rat secretory enamel organs incubated in histochemical lead media

Summary To investigate how lead, when used as trapping agent, influences the ATP hydrolysis and to study how ATP is catalyzed in histochemical systems, homogenized secretory enamel organs were incubated in histochemical [³H]-ATP media. Aliquots from the media were taken after 3, 10, 20 and 30 min, and ATP and formed metabolites were separated by electrophoresis and radiometrically quantitated.In media lacking both lead and homogenate 2% of the ATP was spontaneously hydrolyzed during 30 min incubation at room temperature. The presence of lead caused an additional 8% hydrolysis at pH 7.2 and an additional 20% hydrolysis at pH 9.4. In the presence of homogenate, however, lead caused a net decrease of the hydrolysis of ATP as well as of ADP and AMP. This enzyme inhibition varied from around zero to some 80%, depending on pH and substrates involved.In homogenate-containing lead media, at both pH 7.2 and 9.4, ATP was rapidly hydrolyzed primarily to ADP and subsequently to AMP and adenosine and/or inosine. After 5–10 min ADP constituted the predominant substrate at both pH:s. At pH 7.2 ADP remained so for the rest of the incubation, whereas at pH 9.4 AMP was the predominant substrate at the end of the incubation. AMP was the final catabolic product in experiments at pH 7.2, and adenosine and/or inosine at pH 9.4. Inorganic phosphate was liberated almost linearly during the whole incubation period.The results indicate that histochemical studies of substrate specific ATP-ases should be performed with short incubation times and, when high specific activities are present, in large quantities of incubation media to reduce interference by ADP and AMP hydrolyzing enzymes.     

The effects of magnesium and calcium ions on phosphatase activities at alkaline pH in the molar region of newborn mice

Summary The hydrolysis of ATP, AMP and glycerophosphate (GP) at alkaline pH in mineralizing bone and teeth of young mice has been studied histochemically. The substrates were visibly hydrolyzed to the same degree in osteoblasts, cells of stratum intermedium, odontoblasts and subodontoblasts at Ca²⁺ concentrations ranging from 10 mM to 600 mM. In the ameloblasts, however, only ATP was hydrolyzed. The ATPase activities gradually decreased at increasing Mg²⁺/Ca²⁺ ratios. The AMPase and GPase activities, on the other hand, were visibly unaffected. Marked cellular staining, including the nuclei was seen with AMP and GP as substrates when only Mg²⁺ ions were added. No ATPase activity at all could be recorded in media containing Mg²⁺ but no Ca²⁺ ions. The different phosphatase activities in cells involved in hard tissue formation were identically affected by preincubations with solutions containing various concentrations of Ca²⁺ or Mg²⁺ ions. The ATPase activity in striated muscle fibres and blood vessel walls, however, was affected differently by the same procedure.The results indicate that the phosphatase activities recorded in osteoblasts, cells of stratum intermedium, odontoblasts and subodontoblasts at alkaline pH belong to one single enzyme. The results also imply that CaATP is the preferred substrate in the enzymatic hydrolysis of ATP in hard-tissue-forming cells.     

The role of nucleotide pyrophosphatase in Mullerian duct regression

Mullerian inhibiting substance (MIS), a glycoprotein from the fetal testis causing regression of the embryonic Mullerian duct, can be inhibited in vitro in the presence of Mn²⁺ by a wide range of nucleotides including GTP, NAD, ATP, AMP, and several nonhydrolyzable synthetic ATP analogs. Extracellular nucleotide pyrophosphatase (NPPase), an enzyme able to hydrolyze the wide variety of the nucleotides and analogs found to inhibit Mullerian duct regression, was studied by histochemical staining (H. Sierakowska and D. Shugar (1963) to determine if NPPase localized in or around the Mullerian duct during regression. Frozen sections of urogenital ridges from to rat fetuses (n = 77) were incubated with a-naphthyl thymidine-5′-phosphate (naphthyl TMP) and Fast Red TR. Nucleotide pyrophosphatase hydrolyzes naphthyl TMP, releasing naphthol, which then reacts with Fast Red to produce color at the enzyme site. Nucleotide hydrolysis was detected around regressing male (n = 16) Mullerian duct cells at days of gestation, but no hydrolysis was detected around female (n = 17) Mullerian duct cells at any stage. Controls (n = 24) incubated without substrate did not stain. Addition of exogenous ATP (n = 20) to the histochemical incubation medium inhibited nucleotide hydrolysis on male Mullerian ducts, suggesting that this staining is specific for pyrophosphatase activity. Results in vivo were confirmed in vitro by incubating day female rat urogenital ridges with MIS for 72 hr prior to histochemical staining. The addition of testosterone to MIS was obligatory to detect staining in vitro (n = 10). The localized NPPase activity around the regressing Mullerian duct suggests that NPPase may appear as a consequence of duct regression and may act to control the degree of membrane phosphorylation by degrading excess trinucleotides.     

The Vacuolar ATPase of Red Beet Storage Tissue: Electron Microscopic Demonstration of the “Head-and-Stalk” Structure*

Tonoplast membranes were prepared from tissue homogenates and from vacuoles isolated from beetroot storage tissue (Beta vulgaris L., ssp. conditiva) for transmission electron microscopic analysis of the structure of the beetroot vacuolar ATPase using the negative staining technique. By comparison of the specific inhibitor sensitivities of the ATPase activity, i.e. ATP hydrolysis and H⁺-pumping, the purity of the tonoplast preparations with respect to contamination with mitochondrial inner membranes was assessed to avoid confusion with mitochondrial F₁F₀-ATPase. Membranes prepared in Hepes/Tris or BTP/Mes-containing media rarely showed typical head-and-stalk structures although characteristic nitrate- and bafilomycin A₁-sensitive ATP-hydrolysis and H⁺-pumping could be measured. However, typical head-and-stalk structures were observed regularly when these buffers were replaced by K-phosphate buffer. Under these conditions, the beetroot vacuolar ATPase is characterized by a large head group with a central cleft, a thin stalk, connecting it to the membrane and by basal components projecting from the base of the stalks near the vacuolar membrane and forming a distinct layer of electron-light particles between the vacuolar membrane and the layer of non-stained head groups.     

Effects of dicyclohexylcarbodiimide (DCCD) treatment on coupled activities of vanadate-sensitive ATPase from plasma membrane of maize roots

The presence of dicyclohexylcarbodiimide (DCCD) inhibited the activities of vanadate-sensitive H⁺ -ATPase in both native and reconstituted plasma membrane of maize (Zea mays L. cv. WF9 × Mo 17) roots. Concentration dependence of DCCD inhibition on adenosine triphosphate (ATP) hydrolysis of native plasma membrane vesicles suggested that the molar ratio of effective DCCD binding to ATPase was close to 1. The DCCD inhibition of ATP hydrolysis could be slightly reduced by the addition of ATP, Mg:ATP, adenosine monophosphate (AMP), Mg:AMP and adenosine diphosphate (ADP). More hydrophilic derivatives of DCCD such as l-ethyl-N^?-3-trimethyl ammonium carbodiimide (EDAC) or 1-ethyl-3-3-dimethyl-aminopropyl carbodiimide (EDC) gave no inhibition, indicating that the effective DCCD binding site was located in a hydrophobic region of the protein. The proton transport activity of reconstituted plasma membrane at a temperature below 20°C or above 25°C was much sensitive to DCCD treatment. Build-up of the proton gradient was analyzed according to a kinetic model, which showed that proton leakage across de-energized reconstituted plasma membranes was not affected by DCCD, but was sensitive to the method employed to quench ATP hydrolysis. Reconstituted plasma membrane vesicles treated with DCCD exhibited a differential inhibition of the coupled H⁺-transport and ATP hydrolysis. The presence of 50 μM DCCD nearly abolished transport but inhibited less than 50% of ATP hydrolysis. The above results suggest that the link between proton transport and vanadate-sensitive ATP hydrolysis is indirect in nature.     

A continuous culture study of an ATPase-negative mutant of Escherichia coli

For anaerobic glucose-limited chemostat cultures of Escherichia coli a value of 8.5 was found for Y _ATP ^max . For anaerobic glucose- or ammoniumlimited chemostat cultures of the ATPase-negative mutant M2-6 of E. coli Y _ATP ^max values of 17.6 and 20.0 were found, respectively. From these data it can be concluded that in the wild type during anaerobic growth 51–58% of the total ATP production is used for energetization of the membrane. Using the Y _ATP values obtained in the anaerobic experiments a P/O ratio of 1.46 could be calculated for aerobic experiments with the wild type. It is concluded that from the energy obtained by respiration in wild type E. coli about 60% is used for membrane energetization and only about 40% for the actual formation of ATP. No dramatic difference in the maintenance requirement for ATP or glucose has been observed between glucose- and ammonium-limited chemostat cultures of the mutant. The large difference in maintenance requirement observed for such cultures of the wild type is therefore supposed to be made possible by ATP hydrolysis by the ATPase.     

Adenosine triphosphate hydrolysis in rat dental tissues. A histochemical study of ion dependencies.

The effect of EDTA-decalcification, reactivating and activating procedures on the hydrolysis of ATP was studied histochemically in developing dental tissues in the rat. The incubation media contained lead citrate at alkaline pH and lead nitrate at neutral pH, and the results with ATP as substrate were compared with those obtained with beta-glycerophosphate. The ion dependency of ATP hydrolysis could only be ascertained in decalcified sections. As in earlier studies on the hydrolysis of beta-glycerophosphate in dental tissues, this hydrolysis could readily be reactivated through preincubation of the sections in a series of 0.1 M solutions of divalent cations; Zn2+ being the most efficient. This treatment was now found also to give rise to an ATP hydrolysis, which occurred without the need for activating ions in the incubation medium. This ATP hydrolysis should thus be described as nonspecific and, in terms of ion dependency, as due to a metalloenzyme, i.e. alkaline phosphatase. Activating ion dependent ATP hydrolysis in the dental tissues was found in the blood vessels and in the apical part of the secretory ameloblasts. The former was activated by Mg2+, Ca2+ and Mn2+, and the latter by Ca2+ and--almost specifically--by Sr2+. Preincubation with Zn2+ always inhibited the ion dependant ATP hydrolysis in the dental tissues.     

Adenylate cyclase cytochemistry: a methodological evaluation

Synopsis A cytochemical method for the demonstration of adenylate cyclase activity has been evaluated. Enzyme activity in the epithelium of the Müllerian part of the vaginal anlage in neonatal, oestradiol-treated mice has been studied under different experimental conditions. The effects of fixation, incubation conditions and post-fixation have been studied. Variations in the amount of impurities and acid content of the glutaraldehyde do not seem to influence the enzyme activity. High Pb²⁺ ion concentration seems to promote unspecific staining. Under standard conditions [2 mM Pb (NO₃)₂, pH 7.2, and incubation temperature 30°C], neither non-enzymatic nor nonsubstrate-dependent lead trapping in the tissue could be observed. The possible contribution of other enzymes utilizing ATP and AMP-P(NH)P as the formation precipitate, has been evaluated. Both ATP and AMP-P(NH)P have been used as substrates in this study. Provided the appropriate control experiments are performed, this cytochemical method is reliable for demonstration of adenylate cyclase activity.     

Control of membrane potential and excitability ofChara cells with ATP and Mg2+

Summmary Electric characteristics of internodalChara australis cells, from which the tonoplast had been removed by vacuolar perfusion with media containing EGTA, were studied in relation to intracellular concentrations of ATP and Mg²⁺ using the ordinary microelectrode method and the open-vacuole method developed by Tazawa, Kikuyama and Nakagawa (1975.Plant Cell Physiol. 16:611). The concentration of ATP was decreased by introducing hexokinase and glucose into the cell and that of Mg²⁺ by introducing EDTA or CyDTA. The membrane potential decrease and the membrane resistance increase were both significant when the ATP or Mg²⁺ concentration was decreased. An ATP-dependent membrane potential was also found in other species of Characeae,Nitella axillaris andN. pulchella. Excitability of the membrane was also completely lost by reducing the ATP or Mg²⁺ concentration. Both membrane potential and excitability were recovered by introducing ATP or Mg²⁺ into ATP- or Mg²⁺-depleted cells.The time course of membrane potential recovery was followed by the open-vacuole method. Recovery began as soon as intracellular perfusion with medium containing ATP and Mg²⁺ was started. Reversible transition of the membrane potential between polarized and pepolarized levels by controlling the intracellular concentration of ATP or Mg²⁺ could be repeated many times by the open-vacuole method, when the excitability was suppressed by addition of Pb²⁺ to the external medium.The ineffectiveness of an ATP analog, AMP-PNP, and the synergism of ATP and Mg²⁺ in maintaining the membrane potential and excitability strongly suggest that ATP act via its hydrolysis by Mg²⁺-activated ATPase. The passive nature of the membrane, as judged from responses of the membrane potential to changes of the external K⁺ concentration, was not altered by lowering the ATP concentration in the cell. The mechanism of membrane potential generation dependent on ATP is discussed on the basic of an electrogenic ion pump. Involvement of the membrane potential generated by the ion pump in the action potential is also discussed.     

Effects of nucleotide analogs on ATP hydrolysis by P-type ATPases. Comparison between the canine kidney (Na++ K+) ATPase and maize root H+-ATPase

The mechanism by which chemical energy is converted into an electrochemical gradient by P-type ATPase is not completely understood. The effects of ATP analogs on the canine kidney (Na⁺+ K⁺) ATPase were compared to effects of the same analogs on the maize (Zea mays L. cv. W7551) root H⁺-ATPase in order to identify probes for the ATP binding site of the maize root enzyme and to determine potential similarities of ATP hydrolysis mechanisms in these two enzymes. Six compounds able to modify the ATP binding site covalently were compared. These compounds could be classed into three distinct groups based on activity. The first group had little or no effect on catalytic activity of either enzyme and included 7-chloro-4-nitrobenz-2-oxa-1.3-diazole. The second group, which included azido adenine analogs. fluorescein isothiocyanate and 5′-p-fluorosulfonylbenzoyladenine, were inhibitors of ATP hydrolysis by both enzymes. However, the sensitivity of the (Na⁺+ K⁺) ATPase to inhibition was much greater than that exhibited by the maize root enzyme. The third group, which included periodate treated nucleotide derivatives and 2′,3′-o-(4-benzoylbenzoyl)adenosine triphosphate. inhibited both enzymes similarly. This initial screening of these covalent modifiers indicated that 2′,3′-o-(4-benzoylbenzoyl)adenosine triphosphate was the optimal covalent modifier of the ATP binding site of the maize root enzyme. Certain reagents were much more effective against the (Na⁺+ K⁺) ATPase than the maize root enzyme, possibly indicating differences in the ATP binding and hydrolysis pathway for these two enzymes. Two ATP analogs that are not covalent modifiers were also tested: the trinitrophenyl derivatives of adenine nucleotides were better than 5′-adenylylimidodiphosphate for use as an ATP binding probe.     

A study of sodium release in the course of ATP hydrolysis by membrane ATPase

Summary With the aid of sodium-sensitive glass electrodes, changes in sodium ion activity were studied in the course of subsequent additions of components required for ATP hydrolysis provided by Na⁺–K⁺-dependent membrane ATPase. Membrane ATPase was obtained from guinea pig kidney cortex. In the presence of ATP, Mg⁺⁺ and Na⁺ in media, the addition of K⁺ caused an increase in Na⁺ activity. The omission of ATP or its substitution by ADP as well as the addition of Ca⁺⁺ to the media eliminated the above-mentioned increase of Na⁺ activity. Quabain did not affect Na⁺ release caused by the addition of K⁺, although it significantly inhibited ATPase activity of the preparation. The data obtained were considered to be a direct indication of ion exchange during the course of membrane ATPase reaction. This ion-exchange stage of the reaction is not inhibited by ouabain. The ratio of sodium ions released per one inorganic phosphate formed in the course of the reaction was found to be much higher than that established for transporting membranes of intact cells. A possible cause of this difference is discussed.     

Backbone NMR resonance assignments of the nucleotide binding domain of the ABC multidrug transporter LmrA from Lactococcus lactis in its ADP-bound state

LmrA from Lactococcus lactis is a multidrug transporter and a member of the ATP binding cassette (ABC) transporter family. ABC transporters consist of a transmembrane domain (TMD) and a nucleotide binding domain (NBD). The NBD contains the highly conserved signature motifs of this transporter superfamily. In the case of LmrA, the TMD and the NBD are expressed as a single polypeptide. LmrA catalyzes the extrusion of hydrophobic compounds including antibiotics from the cell membrane at the expense of ATP hydrolysis. ATP binds to the NBD, where binding and hydrolysis induce conformational changes that lead to the extrusion of the substrate via the TMD. Here, we report the ¹H, ¹³C and ¹⁵N backbone chemical shift assignments of the isolated 263 amino acid containing NBD of LmrA in its ADP bound state.     

Characterisation of a Ca2+-dependent ATP hydrolysis associated with the vacuolar membrane of wheat roots

Microsomal fractions from wheat tissues exhibit a higher level of ATP hydrolytic activity in the presence of Ca²⁺ than Mg²⁺. Here we characterise the Ca²⁺-dependent activity from roots of Triticum aestivum lev. Troy) and investigate its possible function. Ca²⁺-dependent ATP hydrolysis in the microsomal fraction occurs over a wide pH range with two slight optima at pH 5.5 and 7.5. At these pHs the activity co-migrates with the major peak of nitrate-inhibited Mg²⁺. Cl-ATPase on continuous sucrose gradients indicating that it is associated with the vacuolar membrane. Ca²⁺-dependent ATP hydrolysis can be distinguished from an inhibitory effect of Ca²⁺ on the plasma membrane K⁺, Mg²⁺-ATPase following microsomal membrane separation using aqueous polymer two phase partitioning. The Ca²⁺-dependent activity is stimulated by free Ca²⁺ with a K_m of 8.1 μM in the absence of Mg²⁺ ([CaATP] = 0.8 mM). Vacuoiar membrane vacuolar preparations contain a higher Ca²⁺-dependent than Mg²⁺-dependent ATP hydrolysis, although the two activities are not directly additive. The nucleotide specificity of the divalent ion-dependent activities in vacuolar membrane-enriched fractions was low. hydrolysis of CTP and UTP being greater than ATP hydrolysis with both Ca²⁺ and Mg²⁺ The Ca²⁺-dependent activity did discriminate against dinucleotides, and mononucleotides. and failed to hydrolyse phosphatase substrates. Despite low nucleotide specificity the Mg²⁺-dependent activity functioned as a bafilomycin sensitive H⁺-pump in vacuolar membrane vesicles. Ca²⁺-dependent ATP hydrolysis was not inhibited by the V-, P-, or F-type ATPase inhibitors bafilomycin. vanadate and azide, respectively. nor by the phosphatase inhibitor molybdate, but was inhibited 20% at pH 7.5 by K⁺. Possible functions of Ca²⁺-dependent hydrolysis as a H⁺-pump or a Ca²⁺-pump was investigated using vacuolar membrane vesicles. No H⁺ or Ca²⁺ translocating activity was observed under conditions when the Ca²⁺-dependent ATP hydrolysis was active.     

Ca-stimulated, Mg-independent ATP hydrolysis and the high affinity Ca-pumping ATPase. Two different activities in rat kidney basolateral membranes

The Mg²⁺-dependency of Ca²⁺-induced ATP hydrolysis is studied in basolateral plasma membrane vesicles from rat kidney cortex in the presence of CDTA and EGTA as Mg²⁺- and Ca²⁺-buffering ligands. ATP hydrolysis is strongly stimulated by Mg²⁺ with a K_m of 13 μ M in the absence or presence of 1 μ M free Ca²⁺. At free Mg²⁺ concentrations of 1 μ M and lower, ATP hydrolysis is Mg²⁺ -independent, but is strongly stimulated by submicromolar Ca²⁺ concentrations K_m = 0.25 μM, V_max = 24 μmol P_i/h per mg protein). The Ca²⁺-stimulated ATP hydrolysis strongly decreases at higher Mg²⁺ concentrations. The Ca²⁺-stimulated Mg²⁺-independent ATP hydrolysis is not affected by calmodulin or trifluoperazine and shows no specificity for ATP over ADP, ITP and GTP. In contrast, at high Mg²⁺ concentrations calmodulin and trifluoperazine affect the high affinity Ca²⁺-ATPase activity significantly and ATP is the preferred substrate. Control studies on ATP-dependent Ca²⁺-pumping in renal basolaterals and on Ca²⁺-ATPase in erythrocyte ghosts suggest that the Ca²⁺-pumping enzyme requires Mg²⁺. In contrast, a role of the Ca²⁺-stimulated Mg²⁺-independent ATP hydrolysis in active Ca²⁺ transport across basolateral membranes is rather unlikely.     

Inhibitory Effects of Adenine Nucleotides on Brain Mitochondrial Permeability Transition

The adenine nucleotides ADP and ATP are probably the most important endogenous inhibitors of the mitochondrial permeability transition (MPT). We studied the inhibitory effects of adenine nucleotides on brain MPT by measuring mitochondrial swelling and Ca²⁺ and cytochrome c release. We observed that in the presence of either ADP or ATP, at 250 μM, brain mitochondria accumulated more than 1 μmol Ca²⁺ × mg protein⁻¹. ADP or ATP also prevented Ca²⁺-induced mitochondrial swelling and cytochrome c release. Interestingly, ATP lost most of its inhibitory effects on MPT when the experiments were carried out in the presence of ATP-regenerating systems. These results indicate that MPT inhibition observed in the presence of added ATP could be mainly due to hydrolysis of ATP to ADP. From mitochondrial swelling measurements, half-maximal inhibitory values (K _i) of 4.5 and 98 μM were obtained for ADP and ATP, respectively. In addition, a delayed mitochondrial swelling sensitive to higher ADP concentrations was observed. Mitochondrial anoxia/reoxygenation did not interfere with the inhibitory effect of ADP on Ca²⁺-induced MPT, but oxidative phosphorylation markedly decreased this effect. We conclude that ADP is a potent inhibitor of brain MPT whereas ATP is a weaker inhibitor of this phenomenon. Our results suggest that ADP can have an important protective role against MPT-mediated tissue damage under conditions of brain ischemia and hypoglycemia.     

Inhibition of the Ecto-ATPdiphosphohydrolase of Schistosoma mansoni by Thapsigargin

ATPdiphosphohydrolases (ATPDases) are ubiquitous enzymes capable ofhydrolyzing nucleoside di- and triphosphates. Although a number ofpossible physiological roles have been proposed for ATPDases, detailedstudies on structure-function relationships have generally been hamperedby the lack of specific inhibitors of these enzymes. We have previouslycharacterized a Ca²⁺-activated ATPDase on the external surface ofthe tegument of Schistosoma mansoni, the etiologic agent of humanschistosomiasis. In the present work, we have examined the effectsof thapsigargin, a sesquiterpene lactone known as a high affinityinhibitor of sarco-endoplasmic reticulum calcium transport (SERCA)ATPase, on ATPDase activity. Whereas other lactones tested had littleor no inhibitory action, thapsigargin inhibited ATP hydrolysis by theATPDase (K _i20 M). Interestingly, hydrolysis of ADP was notinhibited by thapsigargin. The lack of inhibition of ATPase activityby orthovanadate, a specific inhibitor of P-type ATPases, and theinhibition of the Mg²⁺-stimulated ATP hydrolysis by thapsigarginruled out the possibility that the observed inhibition of the ATPDaseby thapsigargin could be due to the presence of contaminating SERCAATPases in our preparation. Kinetic analysis indicated that a singleactive site in the ATPDase is responsible for hydrolysis of both ATPand ADP. Thapsigargin caused changes in both V _max and K _m for ATP,indicating a mixed type of inhibition. Inhibition by thapsigarginwas little or not affected by changes in free Ca²⁺ or Mg²⁺concentrations. These results suggest that interaction of thapsigarginwith the S. mansoni ATPDase prevents binding of ATP or its hydrolysisat the active site, while ADP can still undergo catalysis.     

Control of mitochondrial respiration in the heart in vivo

The role of the hydrolysis products of adenosine triphosphate (ATP), adenosine diphosphate (ADP) and inorganic phosphate (Pi), in the control of myocardial respiration was evaluated in vivo using ³¹P NMR. These studies were conducted to evaluate whether increases in the ATP hydrolysis products can be detected through the cardiac cycle or during increases in cardiac work. ³¹P NMR data acquisitions gated to various portions of the cardiac cycle (50 msec time resolution) revealed that cytosolic ATP, ADP and Pi did not change over the course of the cardiac cycle. These metabolites were also monitored during steady-state increases in cardiac work in conjunction with measurements of coronary blood flow and oxygen consumption. No changes were observed during 2 to 3 fold increases in myocardial oxygen consumption induced by various methods. These results demonstrate that the cytosolic ATP, ADP, and Pi concentrations remain relatively constant throughout the cardiac cycle and during physiological increases in cardiac work and oxygen consumption. Furthermore, it is shown that ADP and Pi cannot be solely responsible for the regulation of cardiac respiration in vivo based on the in vitro Km values of these compounds for oxidative phosphorylation. It is concluded that other mechanisms, working in concert with the simple kinetic feedback of ATP hydrolysis products, must be present in the cytosol to provide control of myocardial respiration in vivo.     

Microwave irradiation decreases ATP,increases free [Mg2+], and alters in vivo intracellular reactions in rat brain

Rapid inactivation of metabolism is essential for accurately determining the concentrations of metabolic intermediates in the in vivo state. We compared a broad spectrum of energetic intermediate metabolites and neurotransmitters in brains obtained by microwave irradiation to those obtained by freeze blowing, the most rapid method of extracting and freezing rat brain. The concentrations of many intermediates, cytosolic free NAD(P)⁺/NAD(P)H ratios, as well as neurotransmitters were not affected by the microwave procedure. However, the brain concentrations of ATP were about 30% lower, whereas those of ADP, AMP, and GDP were higher in the microwave‐irradiated compared with the freeze‐blown brains. In addition, the hydrolysis of approximately 1 μmol/g of ATP, a major in vivo Mg²⁺‐binding site, was related to approximately five‐fold increase in free [Mg²⁺] (0.53 ± 0.07 mM in freeze blown vs. 2.91 mM ± 0.48 mM in microwaved brains), as determined from the ratio [citrate]/[isocitrate]. Consequently, many intracellular properties, such as the phosphorylation potential and the ?G' of ATP hydrolysis were significantly altered in microwaved tissue. The determinations of some glycolytic and TCA cycle metabolites, the phosphorylation potential, and the ?G' of ATP hydrolysis do not represent the in vivo state when using microwave‐fixed brain tissue.