A plant proton-pumping inorganic pyrophosphatase functionally complements the vacuolar ATPase transport activity and confers bafilomycin resistance in yeast

V-ATPases (vacuolar H+-ATPases) are a specific class of multi-subunit pumps that play an essential role in the generation of proton gradients across eukaryotic endomembranes. Another simpler proton pump that co-localizes with the V-ATPase occurs in plants and many protists: the single-subunit H+-PPase [H+-translocating PPase (inorganic pyrophosphatase)]. Little is known about the relative contribution of these two proteins to the acidification of intracellular compartments. In the present study, we show that the expression of a chimaeric derivative of the Arabidopsis thaliana H+-PPase AVP1, which is preferentially targeted to internal membranes of yeast, alleviates the phenotypes associated with V-ATPase deficiency. Phenotypic complementation was achieved both with a yeast strain with its V-ATPase specifically inhibited by bafilomycin A1 and with a vma1-null mutant lacking a catalytic V-ATPase subunit. Cell staining with vital fluorescent dyes showed that AVP1 recovered vacuole acidification and normalized the endocytic pathway of the vma mutant. Biochemical and immunochemical studies further demonstrated that a significant fraction of heterologous H+-PPase is located at the vacuolar membrane. These results raise the question of the occurrence of distinct proton pumps in certain single-membrane organelles, such as plant vacuoles, by proving yeast V-ATPase activity dispensability and the capability of H+-PPase to generate, by itself, physiologically suitable internal pH gradients. Also, they suggest new ways of engineering macrolide drug tolerance and outline an experimental system for testing alternative roles for fungal and animal V-ATPases, other than the mere acidification of subcellular organelles.     

Heterogeneity of the vacuolar pyrophosphatase protein fromChenopodium rubrum

Activities of the tonoplast ATPase (V-ATPase EC 3.6.1.3) and PPase (V-PPase EC 3.6.1.1) provide the proton gradient driving the accumulation of various metabolites, organic and inorganic ions in the plant vacuole. We used anion exchange chromatography, liquid-phase isoelectric focusing (IEF), and continuous-elution native polyacrylamide gel electrophoresis (preparative PAGE) to enrich the V-PPase from solubilized tonoplast proteins from suspension cultured cells of Chenopodium rubrum L.The fractions were identified by their enzymatic activity, sensitivity towards the specific PPase inhibitor aminomethylenediphosphonate, apparent molecular weight, and immunological reactivity with an antibody raised against mung bean V-PPase. All these different methods used for the separation of solubilized tonoplast proteins revealed the existence of two physically separable V-PPase proteins exhibiting substrate specific enzymatic activity and 66 kDa apparent molecular weight after sodium dodecyl sulfate(SDS)-PAGE. The isoelectric points of the active V-PPase forms were 5.05 and 5.48 (V-ATPase 6.1). On the basis of the observation of high recoveries of enzymatic activity after different preparations we suggest that the V-PPase proteins separated may represent physiologically occurring forms of the enzyme which cannot be distinguished by SDS-PAGE and Western blot.     

Vacuolar proton-pumping pyrophosphatase in Beta vulgaris shows vectorial activation by potassium.

Previous work with membrane vesicles has demonstrated an absolute dependence on K+ for proton translocation by the inorganic pyrophosphatase (H(+)-PPase: EC 3.6.1.1) from the vacuolar membrane (tonoplast) of higher plants. Using intact vacuoles from sugar beet (Beta vulgaris) storage tissue, we have monitored PP1-dependent currents by patch clamp in 'whole vacuole' mode. Serial K+ substitutions were made at both tonoplast faces. The results show that K+ activation occurs only at the cytosolic face.     

The polyphosphate bodies of Chlamydomonas reinhardtii possess a proton-pumping pyrophosphatase and are similar to acidocalcisomes

Acidocalcisomes are acidic calcium storage compartments described initially in trypanosomatid and apicomplexan parasites. In this work, we describe organelles with properties similar to acidocalcisomes in the green alga Chlamydomonas reinhardtii. Nigericin and NH(4)Cl released (45)Ca(2+) from preloaded permeabilized cells, suggesting the incorporation of a significant amount of this cation into an acidic compartment. X-ray microanalysis of the electron-dense vacuoles or polyphosphate bodies of C. reinhardtii showed large amounts of phosphorus, magnesium, calcium, and zinc. Immunofluorescence microscopy, using antisera raised against a peptide sequence of the vacuolar type proton pyrophosphatase (H(+)-PPase) of Arabidopsis thaliana which is conserved in the C. reinhardtii enzyme, indicated localization in the plasma membrane, in intracellular vacuoles, and the contractile vacuole where it colocalized with the vacuolar proton ATPase (V-H(+)-ATPase). Purification of the electron-dense vacuoles using iodixanol density gradients indicated a preferential localization of the H(+)-PPase and the V-H(+)-ATPase activities in addition to high concentrations of PP(i) and short and long chain polyphosphate, but lack of markers for mitochondria and chloroplasts. In isolated electron-dense vacuoles, PP(i)-driven proton translocation was stimulated by potassium ions and inhibited by the PP(i) analog aminomethylenediphosphonate. Potassium fluoride, imidodiphosphate, N,N'-dicyclohexylcarbodiimide, and N-ethylmaleimide also inhibited PP(i) hydrolysis in the isolated organelles in a dose-dependent manner. These results indicate that the electron-dense vacuoles of C. reinhardtii are very similar to acidocalcisomes with regard to their chemical composition and the presence of proton pumps. Polyphosphate was also localized to the contractile vacuole by 4',6-diamidino-2-phenylindole staining, suggesting, with the immunochemical data, a link between these organelles and the acidocalcisomes.     

Creating drought- and salt-tolerant cotton by overexpressing a vacuolar pyrophosphatase gene

Increased expression of an Arabidopsis vacuolar pyrophosphatase gene, AVP1, leads to increased drought and salt tolerance in transgenic plants, which has been demonstrated in laboratory and field conditions. The molecular mechanism of AVP1-mediated drought resistance is likely due to increased proton pump activity of the vacuolar pyrophosphatase, which generates a higher proton electrochemical gradient across the vacuolar membrane, leading to lower water potential in the plant vacuole and higher secondary transporter activities that prevent ion accumulation to toxic levels in the cytoplasm. Additionally, overexpression of AVP1 appears to stimulate auxin polar transport, which in turn stimulates root development. The larger root system allows AVP1-overexpressing plants to absorb water more efficiently under drought and saline conditions, resulting in stress tolerance and increased yields. Multi-year field-trial data indicate that overexpression of AVP1 in cotton leads to at least 20% more fiber yield than wild-type control plants in dry-land conditions, which highlights the potential use of AVP1 in improving drought tolerance in crops in arid and semiarid areas of the world.Key words: drought tolerance, proton pump, salt tolerance, transgenic cotton, vacuolar membraneDrought and salinity are major environmental factors that limit agricultural productivity in most parts of the world.¹ Climate change will likely make many places worse in terms of water availability and soil salinization,² which will have negative impacts on food production in world agriculture. Yet, the demand for more food will continue to rise because of the growing world population that may reach 9 billon people by 2050.³ Therefore, the primary challenge we face during this century is the production of more food under the constraints of limited water and fertilizer on marginal soils.Many genes that respond to abiotic stresses have been identified in the model plant Arabidopsis,⁴ and some of them were shown to play important roles in protecting plants under abiotic stress conditions.⁵ The Arabidopsis vacuolar pyrophosphatase gene AVP1 appears to be one of the most promising genes that may be used to improve drought- and salt-tolerance in crops.⁶ Roberto Gaxiola''s group first demonstrated that overexpression of AVP1 could lead to significantly improved drought- and salt-tolerance in transgenic Arabidopsis plants.⁷ Later when this gene was introduced into tomato⁸ and rice,⁹ similar tolerance phenotypes were observed. Overexpression of AVP1 in cotton, not only improved drought- and salt-tolerance in greenhouse conditions, but also increased fiber yield in dryland field conditions.⁶ AVP1-expressing cotton plants produced larger root systems and bigger shoot biomass than controls when grown under hydroponic conditions in the presence of up to 200 mM NaCl.⁶ In the greenhouse, AVP1-expressing cotton plants also produced more root and shoot biomass than controls when grown under saline conditions or reduced irrigation.⁶ The increased yield by AVP1-expressing cotton plants is due to more bolls produced, which in turn is due to larger shoot system that AVP1-expressing cotton plants develop under saline or drought conditions.⁶The larger root systems of AVP1-expressing cotton plants under saline and water-deficit conditions allow transgenic plants access to more of the soil profile and available soil water resulting in increased biomass production and yield. Li et al. showed that the larger root systems of AVP1-overexpressing Arabidopsis is caused by increased auxin polar transport in the root, which stimulates root development in AVP1-overexpressing Arabidopsis plants.¹⁰ Furthermore, a recent comparative study of transgenic Arabidopsis lines that produce enlarged leaves showed that auxin levels were increased by 50% in AVP1-overexpressing plants.¹¹ To test if altered auxin level is responsible for the observed larger root systems in AVP1-expressing cotton plants, we germinated wild-type and AVP1-expressing cotton plants in the absence or presence of the auxin polar transport inhibitor Naphthylphthalamic acid (NPA). Both wild-type and AVP1-expressing cotton plants developed robust lateral root systems in the absence of NPA (Fig. 1A). The presence of 50 µM NPA resulted in nearly complete inhibition of lateral root development in wild-type plants, while lateral root development in AVP1-expressing plants was reduced, it was significantly greater than wild-type (Fig. 1B). These data indicate that AVP1-overexpression could overcome the inhibitory effects of NPA on root development in AVP1-expressing cotton plants, suggesting that either increased auxin transport or higher auxin concentration in the root systems of AVP1-expressing cotton plants is responsible for the observed larger root systems, and eventually for the increased boll numbers and fiber yields under dryland field conditions.Open in a separate windowFigure 1Root development of wild-type and AVP1-expressing cotton plants in the absence and presence of auxin transport inhibitor NPA. (A) Phenotype of cotton roots after 10 days of growth in the absence of NPA. WT, Wild-type; 1, 5, 9, three independent AVP1-overexpressing cotton lines. (B) Phenotype of cotton roots after 10 days of growth in the presence of 50 µm NPA.Many genes that may play important roles under water-deficit conditions have been tested in laboratory conditions,^4,5 but very few have been tested vigorously in field conditions. A bacterial cold shock protein gene was shown to improve drought tolerance in maize based on multi-year and multi-place field trial experiments,¹² and it appears that this gene will likely gain approval for commercial release and become the first genetically engineered product that demonstrates improved drought tolerance in a major crop in the U.S. Another example of increased drought tolerance supported by multiple field trial experiments is through downregulation of farnesylation in transgenic canola plants.¹³ Downregulation of farnesyltransferase by antisense or RNAi techniques in transgenic canola leads to increased sensitivity to abscisic acid, consequently resulting in smaller guard cell aperture under drought conditions. These transgenic canola plants lose less water through transpiration and are more drought resistant. Data from more than 5 years of field studies in Canada consistently proved that this approach can indeed increase drought tolerance in transgenic canola. Our study with AVP1-expressing cotton over the last several years in field conditions is another example that genetic engineering approach can be an efficient tool in generating drought-tolerant crops. AVP1-expressing cotton plants can establish a larger shoot mass in dryland conditions (Fig. 2), which results in increased boll numbers and fiber production. Our approach is likely applicable to other major crops as well.Open in a separate windowFigure 2Wild-type and AVP1-expressing cotton plants grown in the dryland field condition. Plants were planted in the middle of may 2009 and the picture was taken in the middle of July 2009 at the USDA experimental Farm in Lubbock, Texas.     

Dimeric structure of H-translocating pyrophosphatase from pumpkin vacuolar membranes

Vacuolar membrane H⁺-translocating pyrophosphatase (H⁺-PPase) was purified from pumpkin seedlings. Its enzymatic properties including molecular size of constituting polypeptide (75 kDa) were very similar to those of mung bean H⁺-PPase [(1989) J. Biol. Chem. 264, 20068–20073]. The native, functional molecular size of the pumpkin H⁺-PPase was estimated to be 135–139 kDa from gel permeation HPLC of the purified enzyme in the presence of detergent and from radiation inactivation of the enzyme in vacuolar membranes. It is concluded that native, functional pumpkin H⁺-PPase, and also probably H⁺-PPases from other plants, is a dimer of 75 kDa subunits.     

A vacuolar ATPase and pyrophosphatase in Acetabularia acetabulum.

Vacuole-rich fractions were isolated from Acetabularia acetabulum by Ficoll step gradient centrifugation. The tonoplast-rich vesicles showed ATP-dependent and pyrophosphate-dependent H(+)-transport activities. ATP-dependent H(+)-transport and ATPase activity were both inhibited by the addition of a specific inhibitor of vacuolar ATPase, bafilomycin B1. A 66 kDa polypeptide present in the preparation cross-reacted with the anti-IgG fractions against the alpha and beta subunits of Halobacterium halobium ATPase and with the antibody against the A subunit (68 kDa subunit) of mung bean vacuolar ATPase. A 56 kDa polypeptide present in the vacuole preparation showed cross-reactivity with the antibody against the B subunit (57 kDa) of mung bean vacuolar ATPase but not with the anti-beta subunit of H. halobium ATPase. A 73 kDa polypeptide cross-reacted with the antibody against inorganic pyrophosphatase of mung bean vacuoles. These results suggest that vacuolar membrane of A. acetabulum equipped energy transducing systems similar to those found in other plant vacuoles.     

Heterogeneity of the vacuolar pyrophosphatase protein fromChenopodium rubrum

Summary Activities of the tonoplast ATPase (V-ATPase EC 3.6.1.3) and PPase (V-PPase EC 3.6.1.1) provide the proton gradient driving the accumulation of various metabolites, organic and inorganic ions in the plant vacuole. We used anion exchange chromatography, liquid-phase isoelectric focusing (IEF), and continuous-elution native polyacrylamide gel electrophoresis (preparative PAGE) to enrich the V-PPase from solubilized tonoplast proteins from suspension cultured cells ofChenopodium rubrum L.The fractions were identified by their enzymatic activity, sensitivity towards the specific PPase inhibitor aminomethylenediphosphonate, apparent molecular weight, and immunological reactivity with an antibody raised against mung bean V-PPase. All these different methods used for the separation of solubilized tonoplast proteins revealed the existence of two physically separable V-PPase proteins exhibiting substrate specific enzymatic activity and 66 kDa apparent molecular weight after sodium dodecyl sulfate(SDS)-PAGE. The isoelectric points of the active V-PPase forms were 5.05 and 5.48 (V-ATPase 6.1). On the basis of the observation of high recoveries of enzymatic activity after different preparations we suggest that the V-PPase proteins separated may represent physiologically occurring forms of the enzyme which cannot be distinguished by SDS-PAGE and Western blot.     

Purification and properties of vacuolar membrane proton-translocating inorganic pyrophosphatase from mung bean

Inorganic pyrophosphatase was purified from the vacuolar membrane of mung bean hypocotyl tissue by solubilization with lysophosphatidylcholine and QAE-Toyopearl chromatography. The molecular mass on sodium dodecyl sulfate-polyacrylamide gel electrophoresis was 73,000 daltons. Among the amino-terminal first 30 amino acids are 25 nonpolar hydrophobic residues. For maximum activity, the purified pyrophosphatase required 1 mM Mg2+ and 50 mM K+. The enzyme reaction was stimulated by exogenous phospholipid in the presence of detergent. Excess pyrophosphate as well as excess magnesium inhibited the pyrophosphatase. The enzyme reaction was strongly inhibited by ATP, GTP, and CTP at 2 mM, and the inhibition was reversed by increasing the Mg2+ concentration. An antibody preparation raised in a rabbit against the purified enzyme inhibited both the reactions of pyrophosphate hydrolysis of the purified preparation and the pyrophosphate-dependent H+ translocation in the tonoplast vesicles. N,N'-Dicyclohexylcarbodiimide became bound to the purified pyrophosphatase and inhibited the reaction of pyrophosphate hydrolysis. It is concluded that the 73-kDa protein in vacuolar membrane functions as an H+-translocating inorganic pyrophosphatase.     

Reconstitution of transport function of vacuolar H(+)-translocating inorganic pyrophosphatase.

A procedure for reconstitution of the transport function of the vacuolar H(+)-translocating inorganic pyrophosphatase (H(+)-PPase; EC 3.6.1.1) prepared from etiolated hypocotyls of Vigna radiata (mung bean) is described. The method entails sequential extraction of isolated vacuolar membrane (tonoplast) vesicles with deoxycholate and CHAPS (3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate), combination of CHAPS-solubilized protein with phospholipid-cholesterol mixtures, dialysis, and glycerol density gradient centrifugation. The final proteoliposome preparation is 9-fold enriched for PPase activity and active in pyrophosphate (PPi)-energized electrogenic H(+)-translocation. Since both PPi hydrolysis and PPi-dependent H(+)-translocation by the proteoliposomes are indistinguishable from the corresponding activities of native tonoplast vesicles, the functional integrity of the H(+)-PPase appears to be conserved during solubilization and reconstitution. The high transport capacity and amenability of the reconstituted enzyme to both radiometric membrane filtration and fluorimetric H(+)-translocation assays, on the other hand, demonstrate its applicability to a broad range of transport studies. SDS-polyacrylamide gel electrophoresis of the proteoliposomes reveals selective enrichment of the M(r) 66,000, substrate-binding subunit of the H(+)-PPase and two additional polypeptides of M(r) 21,000 and 20,000. Although the M(r) 21,000 and 20,000 polypeptides have not been described previously, all attempts to reconstitute H(+)-PPase lacking these components were unsuccessful. It is therefore tentatively proposed that the M(r) 21,000 and 20,000 polypeptides, as well as the M(r) 66,000 subunit, are required for the productive reconstitution of PPi-dependent H(+)-translocation.     

Cloning and expression of vacuolar proton-pumping ATPase subunits in the follicular epithelium of the bullfrog endolymphatic sac

In an investigation aimed at clarifying the mechanism of crystal dissolution of the calcium carbonate lattice in otoconia (the mineral particles embedded in the otolithic membrane) of the endolymphatic sac (ELS) of the bullfrog, cDNAs encoding the A- and E-subunits of bullfrog vacuolar proton-pumping ATPase (V-ATPase) were cloned and sequenced. The cDNA of the A-subunit consisted of an 11-bp 5'-untranslated region (UTR), a 1,854-bp open reading frame (ORF) encoding a protein comprising 617 amino acids with a calculated molecular mass of 68,168 Da, and a 248-bp 3'-UTR followed by a poly(A) tail. The cDNA of the E-subunit consisted of a 72-bp 5'-UTR, a 681-bp ORF encoding a protein of 226 amino acids with a calculated molecular mass of 26,020 Da, and a 799-bp 3'-UTR followed by a poly(A) tail. Western blot and immunofluorescence analyses using specific anti-peptide antisera against the V-ATPase A- and E-subunits revealed that these subunits were present in the ELS, urinary bladder, skin, testes, and kidneys. In the ELS, positive cells were scattered in the follicular epithelium which, as revealed by electron microscopy, corresponds to the location of mitochondria-rich cells. These findings suggest that V-ATPase, including the A- and E-subunits, exists in mitochondria-rich cells of the ELS, which might be involved in dissolution of the calcium carbonate crystals in the lumen of the ELS.     

Partial characterization of H-translocating inorganic pyrophosphatase from 3 citrus varieties differing in vacuolar pH

Vacuolar pyrophosphatase (V-PPase) from juice cells of 3 citrus varieties (differing in their vacuolar pH) were partially characterized using purified tonoplast vesicles. Total V-PPase activity was highest in vesicle samples from sweet limes with vacuolar pH of 5.0, while samples from acid limes (with lowest vacuolar pH of 2.0) had the minimal total V-PPase activity. Samples from 'Valencia' orange had intermediate V-PPase levels. When assayed at equal V-PPase activity (measured as Pi production), V-PPase was not able to generate a pH gradient (ΔpH) in vesicles from acid lime, despite its capacity to form a ΔpH in the presence of ATP. Vesicles from sweet lime and 'Valencia' orange were able to form similar ΔpHs in the presence of PPi and ATP supplied together or separately. Antibodies raised against a peptide corresponding to the catalytic site of mung bean V-PPase reacted with samples from all varieties, coinciding with their capacity to hydrolyze PPi. However, antibodies raised against the entire V-PPase polypeptide from mung bean recognized V-PPase from sweet lime and 'Valencia' orange, but did not recognize acid lime samples even at elevated protein concentrations. The structural differences highlighted by antibody recognition, substrate affinity and proton-pumping reactions of V-PPase presented here may reflect evolutionary adaptations related to its reduced function under in vivo conditions and are in agreement with our understanding of acid, sugar accumulation and vacuolar pH changes during the development and maturation of citrus fruits.     

Common identity of substrate binding subunit of vacuolar h-translocating inorganic pyrophosphatase of higher plant cells

There have been conflicting reports in the literature concerning the polypeptide composition of the vacuolar H⁺-translocating inorganic pyrophosphatase (tonoplast H⁺-PPase) of plant cells. The major subunit(s) of the enzyme have been attributed to polypeptides of relative molecular weight (M_r) 64,500 (Beta vulgaris), 67,000 (Beta vulgaris), 73,000 (Vigna radiata), and 37,000 to 45,000 (Zea mays). Here, we reconcile these differences to show, through the combined application of independent purification, affinity-labeling, sequencing, and immunological procedures, that the major polypeptide associated with the H⁺-PPase from all of these organisms, and Arabidopsis thaliana, corresponds to the same moiety. The principal polypeptide components of the H⁺-PPase purified from Beta and Vigna by independent procedures have similar apparent subunit masses when subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) under identical conditions (M_r(Beta) = 64,500; M_r(Vigna) = 66,000) and exhibit identical kinetics of irreversible inhibition and ligand-modified labeling by [¹⁴C]-N-ethylmaleimide. Similarly, the M_r 64,500 and 67,000 polypeptides isolated from Beta by independent methods (cf. C.J. Britten, J.C. Turner, P.A. Rea [1989] FEBS Lett 256: 200-206 versus V. Sarafian and R.J. Poole [1989] Plant Physiol 91: 34-38) are indistinguishable: the two polypeptides comigrate when electrophoresed under the same conditions and yield tryptic fragments with identical overlapping sequences. Because both the N-terminal sequence of the M_r 66,000 subunit of the H⁺-PPase isolated from Vigna and the direct sequence data from Beta align precisely with the deduced amino acid sequence of cDNAs encoding the H⁺-PPase of Arabidopsis, all three enzymes are inferred to be highly conserved structurally. Accordingly, immunoblots of membranes prepared from Arabidopsis, Beta, Vigna, and Zea, probed with antibody affinity purified against the magnesium inorganic pyrophosphate-binding, M_r 66,000 polypeptide of Vigna, reveal a single immunoreactive band at M_r 64,500 to 67,000 in all four preparations. The M_r 66,000 polypeptide of Zea membranes is, however, prone to proteolysis during membrane fractionation and selective aggregation during sample denaturation for SDS-PAGE. The anomalous M_r 37,000 to 45,000 subunit pattern previously ascribed to the H⁺-PPase from Zea (A. Chanson and P.E. Pilet [1989] Plant Physiol 90: 934-938) is attributed to loss of the M_r 66,000 subunit and the appearance of polypeptide fragments of M_r 44,700 and 39,000 through the combined effects of sample aggregation before SDS-PAGE and proteolysis, respectively. It is, therefore, concluded that the substrate-binding subunit of the tonoplast H⁺-PPase has a common identity in all four organisms.     

Evidence for the role of vacuolar soluble pyrophosphatase and inorganic polyphosphate in Trypanosoma cruzi persistence

Trypanosoma cruzi infection leads to development of a chronic disease but the mechanisms that the parasite utilizes to establish a persistent infection despite activation of a potent immune response by the host are currently unknown. Unusual characteristics of T. cruzi are that it possesses cellular levels of pyrophosphate (PP_i) at least 10 times higher than those of ATP and molar levels of inorganic polyphosphate (polyP) within acidocalcisomes. We characterized an inorganic soluble EF‐hand containing pyrophosphatase from T. cruzi (TcVSP) that, depending on the pH and cofactors, can hydrolyse either pyrophosphate (PP_i) or polyphosphate (polyP). The enzyme is localized to both acidocalcisomes and cytosol. Overexpression of TcVSP (TcVSP‐OE) resulted in a significant decrease in cytosolic PP_i, and short and long‐chain polyP levels. Additionally, the TcVSP‐OE parasites showed a significant growth defect in fibroblasts, less responsiveness to hyperosmotic stress, and reduced persistence in tissues of mice, suggesting that PP_i and polyP are essential for the parasite to resist the stressful conditions in the host and to maintain a persistent infection.     

Oxygen exchange reactions catalyzed by vacuolar H-translocating pyrophosphatase Evidence for reversible formation of enzyme-bound pyrophosphate

Vacuolar membrane-derived vesicles isolated from Vigna radiata catalyze oxygen exchange between medium phosphate and water. On the basis of the inhibitor sensitivity and cation requirements of the exchange activity, it is almost exclusively attributable to the vacuolar H⁺-pyrophosphatase (V-PPase). The invariance of the partition coefficient and the results of kinetic modeling indicate that exchange proceeds via a single reaction pathway and results from the reversal of enzyme-bound pyrophosphate synthesis. Comparison of the exchange reactions catalyzed by V-PPase and soluble PPases suggests that the two classes of enzyme mediate P_i---HOH exchange by the same mechanism and that the intrinsic reversibility of the V-PPase is no greater than that of soluble PPases.     

Diethylpyrocarbonate inhibition of vacuolar H+-pyrophosphatase possibly involves a histidine residue

Vacuolar proton pumping pyrophosphatase (H⁺-PPase; EC 3.6.1.1) plays a pivotal role in electrogenic translocation of protons from cytosol to the vacuolar lumen at the expense of PP_i hydrolysis. A histidine-specific modifier, diethylpyrocarbonate (DEPC), could substantially inhibit enzymic activity and H⁺-translocation of vacuolar H⁺-PPase in a concentration-dependent manner. Absorbance of vacuolar H⁺-PPase at 240 nm was increased upon incubation with DEPC, demonstrating that an N-carbethoxyhistidine moiety was probably formed. On the other hand, hydroxylamine, a reagent that can deacylate N-carbethoxyhistidine, could reverse the absorption change at 240 nm and partially restore PP_i hydrolysis activity as well. The pK _a of modified residues of the enzyme was determined to be 6.4, a value close to that of histidine. Thus, we speculate that inhibition of vacuolar H⁺-PPase by DEPC possibly could be attributed to the modification of histidyl residues on the enzyme. Furthermore, inhibition of vacuolar H⁺-PPase by DEPC follows pseudo-first-order rate kinetics. A reaction order of 0.85 was calculated from a double logarithmic plot of the apparent reaction constant against DEPC concentration, suggesting that the modification of one single histidine residue on the enzyme suffices to inhibit vacuolar H⁺-PPase. Inhibition of vacuolar H⁺-PPase by DEPC changes V _max but not K _m values. Moreover, DEPC inhibition of vacuolar H⁺-PPase could be substantially protected against by its physiological substrate, Mg²⁺-PP_i. These results indicated that DEPC specifically competes with the substrate at the active site and the DEPC-labeled histidine residue might locate in or near the catalytic domain of the enzyme. Besides, pretreatment of the enzyme with N-ethylmaleimide decreased the degree of subsequent labeling of H⁺-PPase by DEPC. Taken together, we suggest that vacuolar H⁺-PPase likely contains a substrate-protectable histidine residue contributing to the inhibition of its activity by DEPC, and this histidine residue may located in a domain sensitive to the modification of Cys-629 by NEM.     

Heat of PPi hydrolysis varies depending on the enzyme used. Yeast and corn vacuolar pyrophosphatase

With yeast-soluble inorganic pyrophosphatase, the heat released during PP(i) hydrolysis was -6.3 kcal/mol regardless of the KCl concentration in the medium. With the membrane-bound pyrophosphatase of corn vacuoles, the heat released varies between -23.5 and -7.5 kcal/mol depending on the KCl concentration in the medium and whether or not a H(+) gradient is formed across the vacuole membranes. The data support the proposal that enzymes are able to handle the energy derived from phosphate compound hydrolysis in such a way as to determine the parcel that is used for work and the fraction that is converted into heat.     

Osteoclast activation: Potent inhibition by the bisphosphonate alendronate through a nonresorptive mechanism

Alendronate, an aminobisphosphonate used in the treatment of osteoporosis, is a potent inhibitor of bone resorption. Its mechanism of action is unknown. Because it localizes to bone surfaces, we compared the sensitivity of components of the resorptive process to incubation on alendronate-coated bone surfaces. We found that bone resorption by osteoclasts isolated from neonatal rat bone was unaffected by alendronate (10^-4 M). Osteoclast production in bone marrow cultures, as assessed by the production of calcitonin-receptor positive cells, was observed even at 10^-4 M, but bone resorption in these cultures was almost completely abolished by 10^-6 M alendronate. The greater sensitivity of osteoclast activation to inhibition by alendronate that these results suggest was supported by similar inhibition of osteoblast-mediated activation of osteoclasts from neonatal rat bone. Thus, activation of osteoclasts by osteoblastic/stromal cells is apparently the most sensitive component of the pathway whereby bone resorption is affected. Moreover, the ability of alendronate to suppress osteoclastic activation does not depend on resorption-mediated release of alendronate from bone surfaces. This ability extends the range of cell types and processes that might be affected by alendronate, beyond those in the immediate vicinity of resorbing cells, to include any cell that comes into contact with alendronate-coated bone surfaces. J. Cell. Physiol. 172:79–86, 1997. © 1997 Wiley-Liss, Inc.