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Query: EC:3.1.3.1 (
alkaline phosphatase
)
47,916
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Differential scanning calorimetry has been employed to monitor structural alterations induced in the dimeric enzyme
alkaline phosphatase
on binding of Cd(II) (to the metal-free apoenzyme) and phosphate (Pi) (to the Cd(II) enzyme). Cd(II) addition to the apoenzyme at pH 6.5 results in an increased transition temperature, suggesting a stabilizing effect of the bound metal ion. Two distinct structural forms of the protein are detected as discrete calorimetric transitions (Tm = 69-84 degrees C; 87-94 degrees C, respectively). Distribution of the enzyme between these forms is found to depend on the exogenous Cd(II) concentration and the protocol of Cd(II) addition. These results indicate that conversion between the conformational forms is a slow process which appears to require specific levels of metal ion site occupancy. These studies, in which the exogenous Cd(II) concentration was varied from 10(-5) M to 10(-3) M suggest a structural basis for previously observed hysteretic phenomena observed on Cd(II) binding to the enzyme. Even at a minimum stoichiometry of Cd(II) (2 eq/mol of dimer) a single equivalent of Pi is sufficient to accelerate assumption of a stabilized form of the protein (Tm = 90 degrees C). This is followed by a slow structural change paralleling the time course of formation of the functional 2 Cd(II) phosphoryl enzyme which displays two calorimetric transitions (Tm = 65 degrees C, 88 degrees C). The low temperature transition does not appear if Pi is initially present at millimolar concentrations and is abolished on addition of Pi at concentrations in excess of 0.1 mM. These observations suggest the presence of a second, distinct Pi binding site on the 2 Cd(II) phosphoryl enzyme. This is supported by the changes observed in the 31P
NMR
chemical shift of Pi added to comparable enzyme samples. These data, including assessment of the effect of the presence of Mg(II), are discussed in terms of the mechanism of metal ion association to the enzyme and rearrangement of bound metal ions induced by Pi binding.
...
PMID:Differential scanning calorimetry of Cd(II) alkaline phosphatases. 636 47
Methods have been developed for the addition of different metal ion species to the three distinct pairs of metal sites (A, B, and C) found in the dimer of apoalkaline phosphatase. This allows the preparation of hybrid alkaline phosphatases in which A and B sites of each monomer contain two different species of metal ion or the A and B sites of one monomer contain the same species of metal ion, while the adjacent monomer contains a second species. The following hybrids have been characterized in detail: (Zn(II)ACd(II)B)2
alkaline phosphatase
, (Zn(II)AMg(II)B)2
alkaline phosphatase
, (Cd(II)AZn(II)B)2
alkaline phosphatase
, and (Zn(II)AZn(II]B)(Cd(II)ACd(II)B)
alkaline phosphatase
. 31P and, where appropriate, 113Cd
NMR
have been used to monitor the behavior of the covalent (E-P) and noncovalent (E X P) phosphointermediates and of the A and B metal ions. From the pH dependencies of the E-P in equilibrium E X P in equilibrium E + Pi equilibria, it is clear that A site metal is the dominant influence in dephosphorylation of E-P and may have a coordinated water molecule, which ionizes to ZnOH- at a low pH providing the nucleophile for dephosphorylation. A site metal also serves to coordinate phosphate in the E X P complex. B site metal has a much smaller effect on dephosphorylation rates, although it does dramatically alter the Pi dissociation rate, which is the rate-limiting step for the native enzyme at alkaline pH, and is probably important in neutralizing the charge on the phosphoseryl residue, thus potentiating the nucleophilic attack of the OH- bound at A site. Phosphate dissociation is slowed markedly by replacement of B site zinc by cadmium. There is clear evidence for long range effects of subunit-subunit interactions, since metal ion and phosphate binding at one active center alters the environments of A and B site metal ions and phosphoserine at the other active site.
...
PMID:Zn(II)-113Cd(II) and Zn(II)-Mg(II) hybrids of alkaline phosphatase. 31P and 113Cd NMR. 637 Sep 97
Chloride binding to
alkaline phosphatase
from Escherichia coli has been monitored by 35Cl
NMR
for the native zinc enzyme and by 113Cd
NMR
for two Cd(II)-substituted species, phosphorylated Cd(II)6
alkaline phosphatase
and unphosphorylated Cd(II)2
alkaline phosphatase
. Of the three metal binding sites per enzyme monomer, A, B, and C, only the
NMR
signal of 113Cd(II) at the A sites shows sensitivity to the presence of Cl-, suggesting that Cl- coordination occurs at the A site metal ion. From the differences in the chemical shift changes produced in the A site 113Cd resonance for the covalent (E-P) form of the enzyme versus the noncovalent (E . P) form of the enzyme, it is concluded that the A site metal ion can assume a five-coordinate form. The E-P form of the enzyme has three histidyl nitrogens as ligands from the protein to the A site metal ion plus either two water molecules or two Cl- ions as additional monodentate ligands. In the E . P form, there is a phosphate oxygen as a monodentate ligand and either a water molecule or a Cl- ion as the additional monodentate ligand. The shifts of the 113Cd
NMR
signals of the unphosphorylated Cd(II)2 enzyme induced by Cl- are very similar to those induced in the E-P derivative of the same enzyme, supporting the conclusion that the phosphoseryl residue is not directly coordinated to any of the metal ions. Specific broadening of the 35Cl resonance from bulk Cl- is induced by Zn(II)4
alkaline phosphatase
, while Zn(II)2
alkaline phosphatase
is even more effective, suggesting an influence by occupancy of the B site on the interaction of monodentate ligands at the A site. A reduction in this quadrupolar broadening is observed upon phosphate binding at pH values where E . P is formed, but not at pH values where E-P is the major species, confirming a specific interaction of Cl- at the A site, the site to which phosphate is bound in E . P, but not in E-P. For the zinc enzyme, a significant decrease in phosphate binding affinity can be shown to occur at pH 8 where one monomer has a higher affinity than the other.
...
PMID:Chloride binding to alkaline phosphatase. 113Cd and 35Cl NMR. 638 93
Proteoglycans isolated from the Swarm rat chondrosarcoma were shown to contain 35 mol of phosphate/mol of proteoglycan. While 20% of this phosphate was released by digestion with dilute alkali in the presence of sodium borohydride and is presumably of the phosphoserine/phosphothreonine type, 78% of the phosphate copurified with the peptide-free chondroitin sulfate chains. When chondroitin sulfate chains purified by ethanol precipitation or Sephacryl S200 column chromatography were digested with chondroitinase AC and the digests chromatographed on Bio-Gel P-4, the phosphate co-migrated with a carbohydrate fragment that contained 2 glucuronic acid (one as delta 4,5-unsaturated sugar), 1-galactosamine, 2-galactose, and 1-phosphate residue/xylitol. A second fragment of similar composition but lacking phosphate was also recovered in a ratio of about 3 to 1 relative to the phosphorylated fragment. The phosphate in the chondroitin sulfate linkage region fragment had the
alkaline phosphatase
sensitivity as well as 31P
NMR
spectra of a monophosphate esterified to a secondary sugar alcohol. The phosphate was localized on the C-2 of the chain initiating xylose since these residues as xylitol showed a delayed release during acid hydrolysis and the xylitol was recovered intact after periodate oxidation. In the chondrosarcoma, 2-phosphoxylose appears to be a normal synthetic product since [32P]phosphate was readily incorporated into the proteoglycan and the incorporated isotope had similar biochemical properties as the unlabeled phosphate.
...
PMID:Phosphorylation of chondroitin sulfate in proteoglycans from the swarm rat chondrosarcoma. 642 Apr 13
Alkaline phosphatase from Escherichia coli contains three metal binding sites (A, B, and C) located at sites forming a triangle with sides of 4, 5, and 7 A (Wyckoff, H.W., Handschumacher, M., Murthy, K., and Sowadski, J.M. (1983) Adv. Enzymol. 55, 453). When all three sites are occupied by Cd(II) the enzyme has a very low turnover; at least 10(3) slower than the native Zn(II) enzyme. The slow turnover number has made the Cd(II) enzyme useful in
NMR
studies of the mechanism of
alkaline phosphatase
. The binding of arsenate to two forms of Cd(II)
alkaline phosphatase
(Cd(II)2alkaline phosphatase and Cd(II)6alkaline phosphatase) has been studied by 113Cd
NMR
. Cd(II)2alkaline phosphatase, pH 6.3, binds arsenate at only one monomer of the dimeric enzyme and causes migration of Cd(II) from the A site of one monomer to the B site of the arsenylated monomer. This same migration has previously been observed to accompany metal ion-dependent phosphate binding, but is much more rapid in the case of arsenate. The acceleration of migration induced by arsenate supports the conclusion based on the phosphate data that the substrate anion binds to the A site metal ion of one monomer prior to migration and that only the metal ion at A site is required for phosphorylation (arsenylation) of serine 102. The 113Cd chemical shifts of A and B site metal ions are very sensitive to the form of the bound arsenate, i.e. covalent (E-As) or noncovalent (E X As) complex. Like the analogous phosphate derivatives, the change of chemical shift of A site (to which phosphate is coordinated in the E X P complex) is much greater than that of the B site metal ion, when the arsenate shifts between the two intermediates, suggesting that arsenate is also coordinated to A site in the E X As intermediate. The chemical shifts of A and B site 113Cd(II) ions are considerably different in the arsenate and phosphate derivatives, while the C site 113Cd(II) ions have nearly identical chemical shifts. Thus the substrate appears to interact closely with both A and B sites, while C site appears relatively unimportant in phosphomonoester hydrolysis. The analogous behavior of arsenate and phosphate at the active center as evaluated by 113Cd
NMR
supports the validity of using the heavier arsenate derivative in x-ray diffraction studies.
...
PMID:113Cd NMR. Arsenate binding to Cd(II) alkaline phosphatase. 642 81
The "activation factor" for phosphofructokinase was shown by chemical analysis, by synthesis, and by 13C
NMR
spectroscopy to be beta-D-fructose-2,6-P2. This compound was prepared from D-fructose-1,2-cyclic 6-P2 by alkaline hydrolysis. D-Fructose-1,2-cyclic 6-P2 is ineffective in activating phosphofructokinase while synthetic D-fructose-2,6-P2 has the same specific activity toward phosphofructokinase as the "activation factor" isolated from rat liver, and it exhibits the same characteristics on paper and ion exchange chromatography. Acid treatment of both the synthetic and the natural product destroys the biological activity and yields 1 mol each of fructose-6-P and Pi;
alkaline phosphatase
treatment of the compound followed with acid hydrolysis yields fructose. The natural abundance 13C
NMR
spectra of the synthetically prepared and purified D-fructose-1,2-cyclic 6-P2 and D-fructose-2,6-P2 have been obtained and all resonances have been assigned. The spectra also show that both samples contain predominantly one anomer and the 13C chemical shifts and 31P-13C coupling constants are consistent only with the beta-anomer.
...
PMID:The structure of "activation factor" for phosphofructokinase. 645 27
We have measured the phosphorylation of the subunits of
alkaline phosphatase
in the steady state with several substrates and at several pH values. Our results vary from 80% phosphorylation of both subunits at pH7 to only 9% at pH 10. There is no evidence of anticooperativity. With the measurement of kcat, we are able to evaluate rate constants in a minimal scheme. The results show that the main rate influencing steps ar chemical dephosphorylation and dissociation of phosphate. The predominates at pH 7.0 but declines in importance as the pH is raised. Our rate constants for dissociation of phosphate are in agreement with recent
NMR
studies.
...
PMID:Phosphorylated intermediate of alkaline phosphatase. 699 1
Carbon-13 nuclear magnetic resonance (13C
NMR
) of Escherichia coli
alkaline phosphatase
labeled biosynthetically with beta,beta-[gamma-13C]dideuteriohistidine has been used to determine the number and identity of the histidine residues that participate in metal ion coordination at the three classes of binding sites in this dimeric Zn2+ metalloenzyme. Detailed 13C
NMR
titrations of the apoenzyme with 113Cd2+ and Mg2+, in conjunction with parallel 13 Cd
NMR
measurements [Otvos, J.D., & Armitage, I.M. (1980) Biochemistry (third of three papers in this issue)], permitted the assignment of four histidine residues as ligands to the "catalytic", or A site, metal ions, two coordinated via their N pi imidazole nitrogens and two via N pi. In addition, a fifth histidyl ligand, coordinated through N pi, was shown to be located at the "structural", or B, sites on the dimer. The "regulatory", or C, sites do not contain histidyl metal ligands. Unambiguous identification of the three histidines coordinated to metal ion via N pi was provided by the observation of resolved 113Cd-13C spin-spin coupling (3J = 12-19 Hz) in their gamma-carbon resonances. Once assigned, the 13C resonances of the five histidyl metal ligands were used to monitor the relative affinities of the A, B, and C sites for Cd2+ and Zn2+. At pH 6.3, Cd2+ was found to bind to the A sites at least 10 times tighter than to the B or C sites, which have roughly equal affinities. In marked contrast, Zn2+ was found to have similar affinities for the A and B sites at both pH 6.3 and 8.0. The affinity of the C sites for Zn2+ and Mg2+ was shown to be at least an order of magnitude lower. The binding constants of all three sites for Cd2+ and Zn2+ are greater than 10(5) M-1. Evidence is also presented that suggests that the A, B, and C sites may be located in close proximity to one another in the monomers.
...
PMID:Characterization of the properties of the multiple metal binding sites in alkaline phosphatase by carbon-13 nuclear magnetic resonance. 699 14
Cadmium-113 nuclear magnetic resonance (113Cd
NMR
) has been used to probe the binding characteristics of 113Cd2+ to the three classes of metal binding sites in Escherichia coli
alkaline phosphatase
to help elucidate the molecular origin of the metal ion dependent "half-sites" reactivity exhibited by this dimeric Zn2+ metalloenzyme [Otvos, J.D., Armitage, I.M., Chlebowski, J.F., & Coleman, J.E. (1979) J. Biol. Chem. 254, 4707-4713]. In the absence of phosphate, the first two 113Cd2+ ions added to the apodimer give rise to a single 113Cd resonance (169 ppm), indicating selective binding to the pair of symmetrically disposed A sites. Resonances arising from additional 113Cd2+ bound to the B and C sites cannot be observed; B- and/or C-site occupation also renders the A-site 113Cd resonance undetectable. Both these observations have been attributed to severe chemical exchange broadening in the A-, B-, and C-site 113Cd signals induced by an unknown modulation process(es). Interestingly, covalent phosphorylation of the active-site serine residues abolishes this exchange modulation, allowing three separate resonances to be detected and assigned to 113Cd2+ located at each of the three classes of metal binding sites in the enzyme. By varying the metal composition of the phosphorylated enzyme, we have characterized the correlations that exist between the chemical shifts ana intensities of these 113Cd resonances and the metal occupancies of the A, B, and C sites in the individual subunits. This information has allowed us to conclude that the half-sites phosphorylation of the Cd2 2+ enzyme is accompanied by a slow migration of half the Cd2+ originally located at the A sites to the B sites on the phosphorylated subunits. The driving force for this metal redistribution, which at equilibrium leaves half the subnits devoid of metal ion and thereby incapable of binding phosphate, is apparently the dramatic stabilization of the complex of Cd2+ with the B sites, which was demonstrated to occur in those subunits that become phosphorylated. From the kinetics of both phosphorylation and metal redistribution in Cd2 2+ enzyme, we suggest that population of the A and B sites in a subunit, rather than the A site alone, constitutes the minimum requirement for induction of catalytic function in
alkaline phosphatase
. The spin relaxation properties of the enzyme-bound 113Cd2+ ions are also briefly discussed.
...
PMID:Determination by cadmium-113 nuclear magnetic resonance of the structural basis for metal ion dependent anticooperativity in alkaline phosphatase. 699 15
Carboxypeptidase Y, a vacuolar enzyme from Saccharomyces cerevisiae, was digested with endo-beta-N-acetyl-D-glucosaminidase H to release the four oligosaccharide chains that are linked to asparagine in the glycoprotein. The oligosaccharides were fractionated into a neutral and acidic component, and the latter proved to phosphorylated. From its gel filtration pattern, the neutral fraction was shown to be a mixture of at least four homologs, the smallest of which had a proton
NMR
spectrum almost identical to that given by an IgM oligosaccharide with eight mannoses and one N-acetylglucosamine [Cohen, R. E. & Ballou, C. E. (1980) Biochemistry 19, 4345--4358]. The yeast oligosaccharide has one additional mannose unit in an alpha 1 leads to 3 or alpha 1 leads to 6 linkage, whereas the larger homologs appear to have two, three, and four more mannose units. One phosphorylated oligosaccharides with a mannose/phosphate ratio of 12.5 was reduced with NaB3H4 and then subjected to mild acid hydrolysis. This released mannose and mannobiose that were glycosidically linked to the phosphate group, whereas complete acid hydrolysis yielded D-mannose 6-phosphate. The recovered oligosaccharide phosphomonoester, which contained 11 or 12 mannose units, was digested exhaustively with alpha-mannosidase, and the product of this reaction was treated with
alkaline phosphatase
, which yielded radioactive Man3GlcNAcH2. These results suggest that the mannosidase-resistant phosphorylated oligosaccharide has the structure Man leads to P leads to 6 alpha Man leads to alpha Man leads to 6 beta Man leads to 4GlcNAcH2, in which some of the phosphate groups are substituted with mannobiose instead of mannose. A second phosphorylated oligosaccharide with a mannose/phosphate ratio of 6.5 probably contains two phosphodiester groups, but its structure has not been investigated in detail.
...
PMID:Carbohydrate chains on yeast carboxypeptidase Y are phosphorylated. 701 28
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