Phosphotyrosyl-specific protein phosphatase activity of a bovine skeletal acid phosphatase isoenzyme. Comparison with the phosphotyrosyl protein phosphatase activity of skeletal alkaline phosphatase

A partially purified bovine cortical bone acid phosphatase, which shared similar characteristics with a class of acid phosphatase known as tartrate-resistant acid phosphatase, was found to dephosphorylate phosphotyrosine and phosphotyrosyl proteins, with little activity toward other phosphoamino acids or phosphoseryl histones. The pH optimum was about 5.5 with p-nitrophenyl phosphate as substrate but was about 6.0 with phosphotyrosine and about 7.0 with phosphotyrosyl histones. The apparent Km values for phosphotyrosyl histones (at pH 7.0) and phosphotyrosine (at pH 5.5) were about 300 nM phosphate group and 0.6 mM, respectively, The p-nitrophenyl phosphatase, phosphotyrosine phosphatase, and phosphotyrosyl protein phosphatase activities appear to be a single protein since these activities could not be separated by Sephacryl S-200, CM-Sepharose, or cellulose phosphate chromatographies, he ratio of these activities remained relatively constant throughout the purification procedure, each of these activities exhibited similar thermal stabilities and similar sensitivities to various effectors, and phosphotyrosine and p-nitrophenyl phosphate appeared to be alternative substrates for the acid phosphatase. Skeletal alkaline phosphatase was also capable of dephosphorylating phosphotyrosyl histones at pH 7.0, but the activity of that enzyme was about 20 times greater at pH 9.0 than at pH 7.0. Furthermore, the affinity of skeletal alkaline phosphatase for phosphotyrosyl proteins was low (estimated to be 0.2-0.4 mM), and its protein phosphatase activity was not specific for phosphotyrosyl proteins, since it also dephosphorylated phosphoseryl histones. In summary, these data suggested that skeletal acid phosphatase, rather than skeletal alkaline phosphatase, may act as phosphotyrosyl protein phosphatase under physiologically relevant conditions.     

Mechanism of action of Zn2+ and Mg2+ on rat placenta alkaline phosphatase. II. Studies on membrane-bound phosphatase in tissue sections and in whole placenta.

Alkaline phosphatase (EC 3.1.3.1) bound to trophoblastic cells in rat placenta is activated by Mg2+ and inhibited by Zn2+ in the same way as is found with partially purified soluble alkaline phosphatase in the same tissue (PetitClerc, C., Delisle, M., Martel, M., Fecteau, C. & Brière, N. (1975) Can. J. Biochem. 53, 1089-1100). In studies done with tissue sections (6-10 micron), it is shown that alkaline phosphatase activity and labelling of active sites by orthophosphate are lost during incubation with ethanolamine at pH 9.0. Addition of Mg2+ causes total recovery of catalytic activity and active sites labelling. Zn2+ displaces and replaces at the Mg2+ binding sites. The affinity for both ions is similar, and dissociation of Zn2+ from the enzyme is a very slow process, even in the presence of Mg2+. The Zn2+-alkaline phosphatase and Mg2+-alkaline phosphatase, which only differ by the ion bound to an apparent modulator site, have the same catalytic activity at pH less than 7.0, but the Zn2+ species has little activity at alkaline pH. Phosphorylation of the enzyme by orthophosphate indicates that with both enzyme species phosphoryl intermediate does not accumulate at alkaline pH. These results suggest that with orthophosphate, the phosphorylation step is rate determining for both enzymes, and that Zn2+ affects this step to a much greater extent. It is proposed that Zn2+ and Mg2+ regulate alkaline phosphatase in rat placenta. The concentration of both ions in maternal serum and placenta suggest that such a mechanism could exist in vivo.     

Phosphoester specificity of purified human liver alkaline phosphatase.

Kinetic parameters for the hydrolysis of a number of physiologically important phosphoesters by purified human liver alkaline phosphatase have been determined. The enzyme was studied at pH values of 7.0 to 10.0. The affinity of the enzyme for the compounds was determined by competition experiments and by their direct employment as substrates. Phosphodiesters and phosphonates were not hydrolysed but the latter were inhibitors. Calcium and magnesium ions inhibited the hydrolysis of ATP and PP1 and evidence is presented to show that the metal complexes of these substrates are not hydrolysed by alkaline phosphatase. A calcium-stimulated ATPase activity could not be demonstrated for the purified enzyme or the enzyme in the presence of a calcium-dependent regulator protein. Nevertheless, the influence of magnesium and calcium ions on the ATPase activity of alkaline phosphatase means that precautions must be taken when assaying for Ca2+-ATPase in the presence of alkaline phosphatase. The low substrate Km values and the hydrolysis which occurs at pH 7.4 mean that the enzyme could have a significant phosphohydrolytic role. However, liver cell phosphate concentrations, if accessible to the enzyme, are sufficient to strongly inhibit this activity.     

Role of alkaline phosphatase in phosphate uptake into brush border membrane vesicles from human intestinal mucosa

In order to elucidate the physiological function of intestinal alkaline phosphatase, the characteristics of human intestinal alkaline phosphatase bound to brush border membrane vesicles were compared under optimal and physiological pHs. The Km value of this enzyme towards p-nitrophenylphosphate at the physiological pH was lower than that at the optimal pH. At the physiological pH, phosphate, arsenate and vanadate competitively inhibited the alkaline phosphatase activity, as they did at optimal pH, and the K1 values of these inhibitors at the physiological pH were also lower than those at the optimal pH. The effects of various inhibitors and antibody to human intestinal alkaline phosphatase on phosphate uptake into brush border membrane vesicles were investigated. The results indicated that phosphate uptake was affected by various inhibitors and the antibody to human intestinal alkaline phosphatase, but L-homoarginine, levamisole, and ouabain had no effect. From the above findings, it is strongly suggested that human intestinal alkaline phosphatase may function as a phosphate binding protein at low phosphate concentrations under physiological conditions.     

Dephosphorylation of phosphoproteins of human liver plasma membranes by endogenous and purified liver alkaline phosphatases

Purified alkaline phosphatase and plasma membranes from human liver were shown to dephosphorylate phosphohistones and plasma membrane phosphoproteins. The protein phosphatase activity of the liver plasma membranes was inhibited by levamisole, a specific inhibitor of alkaline phosphatase, and by phenyl phosphonate and orthovanadate, but was relatively insensitive to fluoride (50 mM). Endogenous membrane protein phosphatase activity was optimal at pH 8.0, compared to pH 7.8 for purified liver alkaline phosphatase. Plasma membranes also exhibited protein kinase activity using exogenous histone or endogenous membrane proteins (autophosphorylation) as substrates; this activity was cAMP-dependent. Autophosphorylation of plasma membrane proteins was apparently enhanced by phenyl phosphonate, levamisole, or orthovanadate. The dephosphorylation of phosphohistones by protein phosphatase 1 was not inhibited by levamisole but was inhibited by fluoride. Inhibition of endogenous protein phosphatase activity by orthovanadate during autophosphorylation of plasma membranes could be reversed by complexation of the inhibitor with (R)-(-)-epinephrine, and the dephosphorylation that followed was levamisole-sensitive. Neither plasma membranes nor purified liver alkaline phosphatase dephosphorylated glycogen phosphorylase a. These results suggest that the increased [32P]phosphate incorporation by endogenous protein kinases into the membrane proteins is due to inhibition of alkaline phosphatase and that the major protein phosphatase of these plasma membranes is alkaline phosphatase.     

Chromatofocussing and centrifugal reconstitution as tools for the separation and characterization of the Na+-cotransport systems of the brush-border membrane

Chromatofocussing was used for the separation of brush-border membrane proteins from calf kidney into 4 or 5 fractions over the pH range 4.0 to 7.4. These fractions were reconstituted into proteoliposomes by gradient centrifugation. Determination of the sodium-dependent solute uptake by proteoliposomes reconstituted from different chromatofocussed fractions showed that the sodium-D-glucose cotransport system was present in the fraction eluted between pH 5.3 and 5.8, and that the sodium-phosphate cotransport was present in fractions eluted between pH 4.6 and 5.3 and between pH 5.8 and 6.6, sodium-alanine cotransport could be detected in almost all fractions. Marker enzymes of the brush-border membrane, such as alkaline phosphatase, gamma-glutamyltransferase and aminopeptidase M etc. were also found to be eluted at pH 7.0-7.4, 4.0-4.1 and 5.6-5.8, respectively. These results suggest that chromatofocussing is a promising tool for the separation of membrane proteins and for pre-purification of the sodium-D-glucose cotransport system. It can be further concluded that the sodium-dependent phosphate transport across the brush-border membrane is not dependent upon alkaline phosphatase activity.     

Light/dark regulation of maize leaf phosphoenolpyruvate carboxylase by in vivo phosphorylation

Phosphoenolpyruvate carboxylase (PEPCase) from light- and dark-adapted maize leaves was rapidly purified in the presence of L-malate and glycerol to apparent electrophoretic homogeneity by ammonium sulfate fractionation, hydroxylapatite chromatography, and fast-protein liquid chromatography on Mono Q. The resulting preparations were totally devoid of pyruvate, orthophosphate dikinase protein based on immunoblot analysis. Throughout the purification, both forms of PEPCase retained their different enzymatic properties. The specific activity of the light enzyme was consistently about twice that of the dark form when assayed at suboptimal (but physiological) pH (pH 7.0-7.3), and the former was also less sensitive to feedback inhibition by L-malate than that from darkened leaves under various conditions. Covalently bound phosphate and high-performance liquid chromatography-based phosphoamino acid analyses showed that both forms of purified PEPCase were phosphorylated exclusively on serine residues, but the degree of phosphorylation was about 50% greater in the light enzyme. Notably, incubation of purified PEPCase in vitro with exogenous alkaline phosphatase led to an increase in malate sensitivity and a decrease in specific activity of the light form enzyme to levels observed with the dark form, which was essentially not affected by phosphatase treatment. These results with the purified enzyme from light- and dark-adapted maize leaves indicate that the light-induced changes in activity and malate sensitivity of C4 PEPCase are related, at least in part, to the degree of covalent seryl phosphorylation of the protein in vivo.     

Mechanism of action of Mg2+ and Zn2+ on rat placental alkaline phosphatase. I. Studies on the soluble Zn2+ and Mg2+ alkaline phosphatases.

Rat placental alkaline phosphatase (EC 3.1.3.1), a dimer of 135,000 daltons, is strongly activated by Mg2+. However, Zn2+ has to be present on the apoenzyme to obtain this activation. Mg2+ alone is unable to reconstitute functional active sites. Excess Zn2+ which competes for the Mg2+ site leads to a phosphatase with little catalytic activity at alkaline pH but with normal active sites at acidic pH as shown by covalent incorporation of ortho-[32P]phosphate. Two enzyme species with identical functional active sites have been reconstituted that only differ by the presence of Zn2+ or Mg2+ at the effector site. A mechanism is presented by which alkaline phosphatase activity of rat placenta would be controlled by a molecular process involving the interaction of Mg2+ and Zn2+ with the dimeric enzyme molecule.     

Extracellular pH modulates the activity of cultured human osteoblasts

The effect of medium pH on the activity of cultured human osteoblasts was investigated in this study. Osteoblasts derived from explants of human trabecular bone were grown to confluence and subcultured. The first-pass cells were incubated in Hepes-buffered media at initial pHs adjusted from 7.0 to 7.8. Osteoblast function was evaluated by measuring lactate production, alkaline phosphatase activity, proline hydroxylation, DNA content, and thymidine incorporation. Changes in medium pH were determined from media pHs recorded at the beginning and end of the final 48 h incubation period. As medium pH increased through pH 7.6, collagen synthesis, alkaline phosphatase activity, and thymidine incorporation increased. DNA content increased from pH 7.0 to 7.2, plateaued from pH 7.2 to 7.6, and increased again from pH 7.6 to 7.8. The changes in the medium pH were greatest at pHs 7.0 and 7.8, modest at pHs 7.4 and 7.6, and did not change at 7.2, suggesting that the pHs are migrating towards pH 7.2. Lactate production increased at pH 7.0 but remained constant from 7.2 to 7.8. These results suggest that in the pH range from 7.0–7.6 the activity of human osteoblasts increases with increasing pH, that this increase in activity does not require an increase in glycolytic activity, and that pH 7.2 may be the optimal pH for these cells. J. Cell. Biochem. 68:83–89, 1998. © 1998 Wiley-Liss, Inc.     

31P nuclear magnetic resonance study of alkaline phosphatase: the role of inorganic phosphate in limiting the enzyme turnover rate at alkaline pH.

31P nuclear magnetic resonance (NMR) was used to directly observe the binding of inorganic phosphate to alkaline phosphatase. Evidencq for the tight binding of 1.5-2.0 mol of inorganic phosphate per dimer of alkaline phosphatase is presented. Two distinct forms of bound phosphate are observed, one predominating above pH 7 and representing the non-covalent E-P1 complex and the other predominating below pH 5 and representing the covalent E-P1 complex. The 31P NMR line width of the E-P1 complex indicates that the dissociation of noncovalent phosphate is the rate-limiting step in the turnover of the enzyme at high pH.     

Presence and androgen control of an alkaline phosphatase in the nucleus of rat ventral prostate.

The presence of alkaline phosphatase (EC 3.1.3.1) activity has been demonstrated in nuclei of rat ventral prostate. This enzyme activity remained after washing of isolated nuclei with 0.5% Triton X-100; an acid phosphatase initially present with the nuclear fraction was removed by this treatment. The nuclear alkaline phosphatase, examined by utilizing p-nitrophenyl phosphate as substrate, had a pH optimum of 9.5-10.3, and a broad substrate specificity: p-nitrophenyl phosphate greater than phosphothreonine greater than beta-glycerophosphate greater than phosphoserine. The nuclear phosphatase was sensitive to denaturation by heat or urea treatments and was also inhibited by Pi, L-phenylalanine, homoarginine, dithiothreitol, and EDTA. The EDTA-inhibited enzyme was maximally reactivated by Zn2+, although Mg2+, or Ca2+ were also effective at somewhat higher concentrations. Orchiectomy of adult rats resulted in an increase in the nuclear alkaline phosphatase activity (2-3-fold at 24 or 48 h postorchiectomy). A decline in the protein: DNA ratio also occurred following orchiectomy, but the increase in phosphatase specific activity was evident whether expressed per unit of protein or per unit of DNA. Testosterone replacement following orchiectomy abolished the increase in nuclear phosphatase activity. The results suggest that the prostatic nuclear alkaline phosphatase may be involved in events related to inactivation of the prostate nucleus following androgen deprivation.     

Purification and characterization of neutral trehalase from the yeast ABYS1 mutant

Neutral trehalase was purified from stationary yeast ABYS1 mutant cells deficient in the vacuolar proteinases A and B and the carboxypeptidases Y and S. The purified electrophoretically homogeneous preparation of phosphorylated neutral trehalase exhibited a molecular mass of 160,000 Da on nondenaturing gel electrophoresis and of 80,000 Da on sodium dodecyl sulfate-gel electrophoresis. Maximal activity (114 mumol of trehalose min-1 x mg-1 at 37 degrees C) was observed at pH 6.8-7.0. The apparent Km for trehalose was 34.5 mM. Among seven oligosaccharides studied, the enzyme formed glucose only from trehalose. Neutral trehalase is located in the cytosol. A polyclonal rabbit antiserum raised against neutral trehalase precipitates the enzyme in the presence of protein A. The antiserum does not react with acid trehalase. Dephosphorylation by alkaline phosphatase from Escherichia coli of the active phosphorylated enzyme is accompanied by greater than or equal to 90% inactivation. Rephosphorylation by incubation with the catalytic subunit of beef heart protein kinase is accompanied by reactivation and incorporation of 0.85 mol of phosphate/mol subunit (80,000 Da). The phosphorylated amino acid residue was identified as phosphoserine.     

Rate-determining step of Escherichia coli alkaline phosphatase altered by the removal of a positive charge at the active center

Escherichia coli alkaline phosphatase catalyzes both the nonspecific hydrolysis of phosphomonoesters and a transphosphorylation reaction in which phosphate is transferred to an alcohol via a phosphoseryl intermediate. The rate-determining step for the wild-type enzyme is pH dependent. At alkaline pH, release of the product phosphate from the noncovalent enzyme-phosphate complex determines the reaction rate, whereas at acidic pH hydrolysis of the covalent enzyme-phosphate complex controls the reaction rate. When the lysine at position 328 was substituted with a cysteine (K328C), the rate-determining step at pH 8.0 of the mutant enzyme was altered so that hydrolysis of the covalent intermediate became limiting rather than phosphate release. The transphosphorylation activity of the K328C enzyme was selectively enhanced, while the hydrolysis activity was reduced compared to that of the wild-type enzyme. The ratio of the transphosphorylation to the hydrolysis activities increased 28-fold for the K328C enzyme in comparison with the wild-type enzyme. Several other mutant enzymes for which a positive charge at the active center is removed by site-specific mutagenesis share this characteristic of the K328C enzyme. These results suggest that the positive charge at position 328 is at least partially responsible for maintaining the balance between the hydrolysis and transphosphorylation activities and plays an important role in determining the rate-limiting step of E. coli alkaline phosphatase.     

Studies on (Na+ + K+)-activated ATPase. XXXVIII. A 100 000 molecular weight protein as the low-energy phosphorylated intermediate of the enzyme.

Phosphorylation of NaI-treated bovine brain cortex microsomes by inorganic phosphate in the presence of Mg2+ and ouabain has been studied at 0 degrees C (pH 7.4) and 20 degrees C (pH 7.0). Nearly maximal (90%) and half-maximal phosphorylation are achieved at 20 degrees C within 2 min with 50--155 and 5.6--17 muM 32Pi, respectively, and at 0 degrees C within 75 s with 300--600 and 33--66 muM 32Pi, respectively. Maximal phosphorylation yields 146 pmol 32P - mg-1 protein. Without ouabain (20 degrees C, pH 7.0) less than 25% of the incorporation observed in the presence of ouabain is reached. Preincubation of the native microsomes with Mg2+ and K+, in order to decompose possibly present high-energy phosphoryl-bonds prior to ouabain treatment, does not affect the maximal phosphate incorporation. This indicates that the inorganic phosphate incorporation is not due to an exchange with high-energy phosphoryl-bonds, which might have been preserved in the microsomal preparations. Phosphorylation of the native microsomes by ATP in the presence of Mg2+ and Na+ reaches 90 and 50% maximal levels within 15--30 s at 0 degrees C and pH 7.4 at concentrations of [gamma-32P]ATP of 5--32 and 0.5--3.5 muM, respectively. The maximal phosphorylation level is 149 pmol 32P-mg-1 protein, equal to that of ouabain-treated microsomes phosphorylated by inorganic phosphate. Both inorganic phosphate and ATP phosphorylate on site per active enzyme subunit of 135 000 molecular weight. From the equilibrium constants for the phosphorylation of ouabain-treated microsomes by inorganic phosphate at 0 degrees C and 20 degrees C standard free-energy changes of --5.4 and --6.8 kcal/mol, respectively, are calculated. These values yield a standard enthalpy change of 14 kcal/mol and an entropy change of 70 cal/mol - degree K. This characterizes the reaction as a process driven by an entropy change. The intermediate formed by phosphorylation with Pi has maximal stability at acidic pH, as is the case for the intermediate formed with ATP. Solubilization in sodium dodecyl sulfate stabilizes the phosphoryl-bond in the pH range of 4--7. The non-solubilized preparation has optimal stability at pH 2--4, the level of which is equal to that of detergent-solubilized intermediate. Sodium dodecyl sulfate gel electrophoresis of the microsomes at pH 3, following incorporation of 32Pi yields 11 protein bands, only one of which (mol. wt 100 000--106 000) carries the radioactive label. This protein has the same molecular weight as the protein, which is phosphorylated by ATP in the presence of Mg2+ and Na+.     

Phosphorylation and inactivation of yeast fructose-1,6-bisphosphatase by cyclic AMP-dependent protein kinase from yeast

Purified fructose-1,6-bisphosphatase from Saccharomyces cerevisiae was phosphorylated in vitro by purified yeast cAMP-dependent protein kinase. Maximal phosphorylation was accompanied by an inactivation of the enzyme by about 60%. In vitro phosphorylation caused changes in the kinetic properties of fructose-1,6-bisphosphatase: 1) the ratio R(Mg2+/Mn2+) of the enzyme activities measured at 10 mM Mg2+ and 2 mM Mn2+, respectively, decreased from 2.6 to 1.2; 2) the ratio R(pH 7/9) of the activities measured at pH 7.0 and pH 9.0, respectively, decreased from 0.62 to 0.38, indicating a shift of the pH optimum to the alkaline range. However, the affinity of the enzyme for its inhibitors fructose-2,6-bisphosphate (Fru-2,6-P2) and AMP, expressed as the concentration required for 50% inhibition, was not changed. The maximum amount of phosphate incorporated into fructose-1,6-bisphosphatase was 0.6-0.75 mol/mol of the 40-kDa subunit. Serine was identified as the phosphate-labeled amino acid. The initial rate of in vitro phosphorylation of fructose-1,6-bisphosphatase, obtained with a maximally cAMP-activated protein kinase, increased when Fru-2,6-P2 and AMP, both potent inhibitors of the enzyme, were added. As Fru-2,6-P2 and AMP did not affect the phosphorylation of histone by cAMP-dependent protein kinase, the inhibitors must bind to fructose-1,6-bisphosphatase in such a way that the enzyme becomes a better substrate for phosphorylation. Nevertheless, Fru-2,6-P2 and AMP did not increase the maximum amount of phosphate incorporated into fructose-1,6-bisphosphatase beyond that observed in the presence of cAMP alone.     

Escherichia coli alkaline phosphatase. An analysis of transient kinetics

1. The hydrolysis of 2,4-dinitrophenyl phosphate by Escherichia coli alkaline phosphatase at pH5.5 was studied by the stopped-flow technique. The rate of production of 2,4-dinitrophenol was measured both in reactions with substrate in excess of enzyme and in single turnovers with excess of enzyme over substrate. It was found that the step that determined the rate of the transient phase of this reaction was an isomerization of the enzyme occurring before substrate binding. 2. No difference was observed between the reaction after mixing a pre-equilibrium mixture of alkaline phosphatase and inorganic phosphate, with 2,4-dinitrophenyl phosphate at pH5.5 in the stopped-flow apparatus, and the control reaction in which inorganic phosphate was pre-equilibrated with the substrate. Since dephosphorylation is the rate-limiting step of the complete turnover at pH5.5, this observation suggests that alkaline phosphatase can bind two different ligands simultaneously, one at each of the active sites on the dimeric enzyme, even though only one site is catalytically active at any given time. 3. Kinetic methods are outlined for the distinction between two pathways of substrate binding, which include an isomerization either of the free enzyme or of the enzyme-substrate complex.     

Purification and characterization of an acid phosphatase that displays phosphotyrosyl-protein phosphatase activity from bovine cortical bone matrix

An acid phosphatase activity that displayed phosphotyrosyl-protein phosphatase has been purified from bovine cortical bone matrix to apparent homogeneity. The overall yield of the enzyme activity was greater than 25%, and overall purification was approximately 2000-fold with a specific activity of 8.15 mumol of p-nitrophenyl phosphate hydrolyzed per min/mg of protein at pH 5.5 and 37 degrees C. The purified enzyme was judged to be purified based on its appearance as a single protein band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (silver staining technique). The enzyme could be classified as a band 5-type tartrate-resistant acid phosphatase isoenzyme. The apparent molecular weight of this enzyme activity was determined to be 34,600 by gel filtration and 32,500 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence of reducing agent, indicating that the active enzyme is a single polypeptide chain. Kinetic evaluations revealed that the acid phosphatase activity appeared to catalyze its reaction by a pseudo Uni Bi hydrolytic two-step transfer reaction mechanism and was competitively inhibited by transition state analogs of Pi. The enzyme activity was also sensitive to reducing agents and several divalent metal ions. Substrate specificity evaluation showed that this purified bovine skeletal acid phosphatase was capable of hydrolyzing nucleotide tri- and diphosphates, phosphotyrosine, and phosphotyrosyl histones, but not nucleotide monophosphates, phosphoserine, phosphothreonine, phosphoseryl histones, or low molecular weight phosphoryl esters. Further examination of the phosphotyrosyl-protein phosphatase activity indicated that the optimal pH at a fixed substrate concentration (50 nM phosphohistones) for this activity was 7.0. Kinetic analysis of the phosphotyrosyl-protein phosphatase activity indicated that the purified enzyme had an apparent Vmax of approximately 60 nmol of [32P]phosphate hydrolyzed from [32P]phosphotyrosyl histones per min/mg of protein at pH 7.0 and an apparent Km for phosphotyrosyl proteins of approximately 450 nM phosphate group. In summary, the results of these studies represent the first purification of a skeletal acid phosphatase to apparent homogeneity. Our observation that this purified bovine bone matrix acid phosphatase was able to dephosphorylate phosphotyrosyl proteins at neutral pH is consistent with our suggestion that this enzyme may function as a phosphotyrosyl-protein phosphatase in vivo.     

Identification of nutrient-dependent changes in extracellular pH and acid phosphatase secretion in Aspergillus nidulans

The present study was designed to identify nutrient-dependent changes in extracellular pH and acid phosphatase secretion in the biA1 palC4 mutant strain of Aspergillus nidulans. The palC4 mutant was selected as lacking alkaline phosphatase, but having substantially increased acid phosphatase activity when grown on solid minimal medium under phosphate starvation, pH 6.5. Gene palC was identified as a putative member of a conserved signaling cascade involved in ambient alkaline sensing whose sole function is to promote the proteolytic activation of PacC at alkaline pH. We showed that both poor growth and conidiation of the palC4 mutant strain on solid medium, alkaline pH, were relative to its hypersensitivity to Tris (hydroxymethyl) aminomethane buffer. Also, the secretion of acid phosphatase was repressed when both the wild-type and palC4 mutant strains were grown in low-phosphate yeast extract liquid medium, pH 5.0, indicating that the secretion of this enzyme is not necessary to regenerate inorganic phosphate from the organic phosphate pool present in yeast extract.     

The mechanism of hydrolysis of beta-glycerophosphate by kidney alkaline phosphatase.

1. To identify the functional groups that are involved in the conversion of beta-glycerophosphate by alkaline phosphatase (EC 3.1.3.1) from pig kidney, the kinetics of alkaline phosphatase were investigated in the pH range 6.6-10.3 at substrate concentrations of 3 muM-30 mM. From the plots of log VH+ against pH and log VH+/KH+m against pH one functional group with pK = 7.0 and two functional groups with pK = 9.1 were identified. These groups are involved in substrate binding. Another group with pK = 8.8 was found, which in its unprotonated form catalyses substrate conversion. 2. GSH inhibits the alkaline phosphatase reversibly and non-competitively by attacking the bound Zn(II). 3. The influence of the H+ concentration on the activation by Mg2+ ions of alkaline pig kidney phosphate was investigated between pH 8.4 and 10.0. The binding of substrate and activating Mg2+ ions occurs independently at all pH values between 8.4 and 10.0. The activation mechanism is not affected by the H+ concentration. The Mg2+ ions are bound by a functional group with a pK of 10.15. 4. A scheme is proposed for the reaction between enzyme, substrate, Mg2+ and H+ and the overall rate equation is derived. 5. The mechanism of substrate binding and splitting by the functional groups of the active centre is discussed on the basis of a model. Mg2+ seems to play a role as an autosteric effector.     

Bacillus cereus phosphopentomutase is an alkaline phosphatase family member that exhibits an altered entry point into the catalytic cycle

Bacterial phosphopentomutases (PPMs) are alkaline phosphatase superfamily members that interconvert α-D-ribose 5-phosphate (ribose 5-phosphate) and α-D-ribose 1-phosphate (ribose 1-phosphate). We investigated the reaction mechanism of Bacillus cereus PPM using a combination of structural and biochemical studies. Four high resolution crystal structures of B. cereus PPM revealed the active site architecture, identified binding sites for the substrate ribose 5-phosphate and the activator α-D-glucose 1,6-bisphosphate (glucose 1,6-bisphosphate), and demonstrated that glucose 1,6-bisphosphate increased phosphorylation of the active site residue Thr-85. The phosphorylation of Thr-85 was confirmed by Western and mass spectroscopic analyses. Biochemical assays identified Mn(2+)-dependent enzyme turnover and demonstrated that glucose 1,6-bisphosphate treatment increases enzyme activity. These results suggest that protein phosphorylation activates the enzyme, which supports an intermolecular transferase mechanism. We confirmed intermolecular phosphoryl transfer using an isotope relay assay in which PPM reactions containing mixtures of ribose 5-[(18)O(3)]phosphate and [U-(13)C(5)]ribose 5-phosphate were analyzed by mass spectrometry. This intermolecular phosphoryl transfer is seemingly counter to what is anticipated from phosphomutases employing a general alkaline phosphatase reaction mechanism, which are reported to catalyze intramolecular phosphoryl transfer. However, the two mechanisms may be reconciled if substrate encounters the enzyme at a different point in the catalytic cycle.