113Cd nuclear magnetic resonance of Cd(II) alkaline phosphatases

Part-of-the-sites binding and reactivity in the homooligomeric enzymes - facts and artifacts

For a number of enzymes composed of several subunits with the same amino acid sequence, it was documented, or suggested, that binding of a ligand, or catalysis, is carried out by a single subunit. This phenomenon may be the result of a pre-existent asymmetry of subunits or a limiting case of the negative cooperativity, and is sometimes called "half-of-the-sites binding (or reactivity)" for dimers and could be called "part-of-the-sites binding (or reactivity)" for higher oligomers. In this article, we discuss molecular mechanisms that may result in "part-of-the-sites binding (and reactivity)", offer possible explanations why it may have a beneficial role in enzyme function, and point to experimental problems in documenting this behaviour. We describe some cases, for which such a mechanism was first reported and later disproved. We also give several examples of enzymes, for which this mechanism seems to be well documented, and profitable. A majority of enzymes identified in this study as half-of-the-sites binding (or reactive) use it in the flip-flop version, in which "half-of-the-sites" refers to a particular moment in time. In general, the various variants of the mechanism seems to be employed often by oligomeric enzymes for allosteric regulation to enhance the efficiency of enzymatic reactions in many key metabolic pathways.

A histidine-rich Pseudomonas metallothionein with a disordered tail displays higher binding capacity for cadmium than zinc

The NMR solution structure of a Pseudomonas metallothionein reveals a different binding capacity for Zn^II and Cd^II ions that results in two novel metal-cluster topologies. Replacement of a non-coordinating residue by histidine decreases the kinetic lability of the cluster. All three structures reported show an identical protein fold.

Identification of rare slipknots in proteins and their implications for stability and folding

Among the thousands of known three-dimensional protein folds, only a few have been found whose backbones are in knotted configurations. The rarity of knotted proteins has important implications for how natural proteins reach their natively folded states. Proteins with such unusual features offer unique opportunities for studying the relationships between structure, folding, and stability. Here we report the identification of a unique slipknot feature in the fold of a well-known thermostable protein, alkaline phosphatase. A slipknot is created when a knot is formed by part of a protein chain, after which the backbone doubles back so that the entire structure becomes unknotted in a mathematical sense. Slipknots are therefore not detected by computational tests that look for knots in complete protein structures. A computational survey looking specifically for slipknots in the Protein Data Bank reveals a few other instances in addition to alkaline phosphatase. Unexpected similarities are noted among some of the proteins identified. In addition, two transmembrane proteins are found to contain slipknots. Finally, mutagenesis experiments on alkaline phosphatase are used to probe the contribution the slipknot feature makes to thermal stability. The trends and conserved features observed in these proteins provide new insights into mechanisms of protein folding and stability.

Dimer asymmetry and the catalytic cycle of alkaline phosphatase fromEscherichia coli

Although alkaline phosphatase (APase) from Escherichia coli crystallizes as a symmetric dimer, it displays deviations from Michaelis-Menten kinetics, supported by a model describing a dimeric enzyme with unequal subunits [Orhanović S., Pavela-Vrancic M. and Flogel-Mrsić M. (1994) Acta. Pharm.44, 87-95]. The possibility, that the observed asymmetry could be attributed to negative cooperativity in Mg2+ binding, has been examined. The influence of the metal ion content on the catalytic properties of APase from E. coli has been examined by kinetic analyses. An activation study has indicated that Mg2+ enhances APase activity by a mechanism that involves interactions between subunits. The observed deviations from Michaelis-Menten kinetics are independent of saturation with Zn2+ or Mg2+ ions, suggesting that asymmetry is an intrinsic property of the dimeric enzyme. In accordance with the experimental data, a model describing the mechanism of substrate hydrolysis by APase has been proposed. The release of the product is enhanced by a conformational change generating a subunit with lower affinity for both the substrate and the product. In the course of the catalytic cycle the conformation of the subunits alternates between two states in order to enable substrate binding and product release. APase displays higher activity in the presence of Mg2+, as binding of Mg2+ increases the rate of conformational change. A conformationally controlled and Mg2+-assisted dissociation of the reaction product (Pi) could serve as a kinetic switch preventing loss of Pi into the environment.

The mechanism of the alkaline phosphatase reaction: insights from NMR, crystallography and site-specific mutagenesis

The proposed double in-line displacement mechanism of Escherichia coli alkaline phosphatase (AP) involving two-metal ion catalysis is based on NMR spectroscopic and X-ray crystallographic studies. This mechanism is further supported by the X-ray crystal structures of the covalent phospho-enzyme intermediate of the H331Q mutant AP and of the transition state complex between the wild-type enzyme and vanadate, a transition state analog. Kinetic and structural studies on several genetically engineered versions of AP illustrate the overall importance of the active site's metal geometry, hydrogen bonding network and electrostatic potential in the catalytic mechanism.

Open sandwich ELISA with V(H)-/V(L)-alkaline phosphatase fusion proteins

The Sandwich ELISA is a widely used technique to measure antigen concentration. Recently, a novel ELISA based on the interchain interaction of separated V(H) and V(L) chains from a single antibody variable region (Fv) was proposed (Open Sandwich ELISA). Since it employs a single antibody recognizing one epitope, the assay requires, in essence, only one cycle of incubation and washing steps. To demonstrate this directly, we have constructed a recombinant gene fusion encoding the V(H) chain of an anti-hen egg lysozyme (HEL) antibody HyHEL-10 and Escherichia coli alkaline phosphatase (V(H)-PhoA). The same type of gene fusion using V(L) chain instead of V(H) chain (V(L)-PhoA) was also constructed and the proteins were obtained with an E. coli expression/secretion system. Open Sandwich ELISAs were performed using microtiter plates with immobilized V(L) or V(H) fragment, and V(H)-PhoA or V(L)-PhoA, respectively, as the detection reagent which was simultaneously added to each well with samples. As a result, HEL concentrations in the samples were determined after one round of incubation and washing steps, with a signal generated in a direct relationship to the concentration of HEL added to the reaction mixture. The minimum detectable HEL concentration was approximately 10 ng/ml, which was almost equal to the value previously obtained with plate-immobilized V(L) and V(H) fragment displayed on M13 phage. When the active-site mutant V(H)-PhoA(D101S) was employed instead of V(H)-PhoA and reacted at an optimum pH of 10, a significant enhancement in signal was attained.

Proline isomerization is unlikely to be the cause of slow annealing and reactivation during the folding of alkaline phosphatase

The in vitro folding of Escherichia coli alkaline phosphatase (AP) from the guanidine hydrochloride (GdnHCl) denatured state is characterized by a significant slow phase in the post activational recovery of native protein lability (probed by the susceptibility to GdnHCl denaturation and occurring on the time scale of days) as well as a slow phase in the recovery of activity (on the time scale of minutes). Slow folding events have often been attributed to cis-trans isomerizations of X-Pro peptide bonds, a plausible explanation for AP, which contains 21 prolines per subunit. To investigate the role of proline isomerization in the two measures of refolding mentioned above, we have performed "double-jump" GdnHCl denaturation/renaturation experiments, with a third jump, where the rate of unfolding of refolded protein upon exposure to denaturant was added to assess the rate of change of lability. Our measurements of the time evolution of both the lability and the reactivation of refolded AP as a function of denaturation time show that proline isomerization is unlikely to be the cause of either of these slow events in the refolding of AP. The conclusions are further confirmed by the absence of proline isomerization effects when AP is refolded in the presence of human and periplasmic E. coli peptidyl-prolyl isomerase.

Thermal and pH stabilities of alkaline phosphatase from bovine intestinal mucosa: a FTIR study

The inactivation of alkaline phosphatase (AP) from bovine intestinal mucosa caused by lowering the p2H from 10.4 to 5.4 or by increasing the temperature from 25 degrees C to 70 degrees C were not followed by significant FTIR changes, indicating that the native conformation of AP was preserved under these conditions. Further decrease of p2H from 5.4 to 3.4 leaded to small infrared spectral changes of AP in the amide I' and amide II regions that were similar to the infrared spectral changes of AP induced by raising the temperature from 70 degrees C to 80 degrees C. The increase of temperature from 70 degrees C to 80 degrees C promoted the formation of intermolecular beta-sheets at the expense of some alpha-helix structures as evidenced by the appearance of the 1684 cm-1 and 1620 cm-1 component bands and the disappearance of the 1651-1657 cm-1 component band. This conformational change was followed by a sharp increase of the 2H/H exchange rate. CD spectra confirmed the FTIR results and were very sensitive to the variation of alpha-helix content while FTIR spectra were more receptive to the changes of beta-sheet structures.

Kinetics and crystal structure of a mutant Escherichia coli alkaline phosphatase (Asp-369-->Asn): a mechanism involving one zinc per active site

Using site-directed mutagenesis, an aspartate side chain involved in binding metal ions in the active site of Escherichia coli alkaline phosphatase (Asp-369) was replaced, alternately, by asparagine (D369N) and by alanine (D369A). The purified mutant enzymes showed reduced turnover rates (kcat) and increased Michaelis constants (Km). The kcat for the D369A enzyme was 5,000-fold lower than the value for the wild-type enzyme. The D369N enzyme required Zn2+ in millimolar concentrations to become fully active; even under these conditions the kcat measured for hydrolysis of p-nitrophenol phosphate was 2 orders of magnitude lower than for the wild-type enzyme. Thus the kcat/Km ratios showed that catalysis is 50 times less efficient when the carboxylate side chain of Asp-369 is replaced by the corresponding amide; and activity is reduced to near nonenzymic levels when the carboxylate is replaced by a methyl group. The crystal structure of D369N, solved to 2.5 A resolution with an R-factor of 0.189, showed vacancies at 2 of the 3 metal binding sites. On the basis of the kinetic results and the refined X-ray coordinates, a reaction mechanism is proposed for phosphate ester hydrolysis by the D369N enzyme involving only 1 metal with the possible assistance of a histidine side chain.

Nonoxidative cadmium-dependent dimerization of Cd7-metallothionein from rabbit liver

The effect of free Cd(II) ions on monomeric Cd7-metallothionein-2 (MT) from rabbit liver has been studied. Slow, concentration-dependent dimerization of this protein was observed by gel filtration chromatographic studies. The dimeric MT form, isolated by gel filtration, contains approximately two additional and more weakly bound Cd(II) ions per monomer. The incubation of MT dimers with complexing agents EDTA and 2-mercaptoethanol leads to the dissociation of dimers to monomers. The results of circular dichroism (CD) and electronic absorption studies indicate that the slow dimerization process is preceded by an initial rapid Cd-induced rearrangement of the monomeric Cd7-MT structure. The 113Cd NMR spectrum of the MT dimer revealed only four 113Cd resonances at chemical shift positions similar to those observed for the Cd4 cluster of the well-characterized monomeric 113Cd7-MT. This result suggests that on dimer formation major structural changes occur in the original three-metal cluster domain of Cd7-MT.

Reaction mechanism of alkaline phosphatase based on crystal structures. Two-metal ion catalysis

Alkaline phosphatase (AP) is a widely distributed non-specific phosphomonoesterase that functions through formation of a covalent phosphoseryl intermediate (E-P). The enzyme also catalyzes phosphoryl transfer reaction to various alcohols. Escherichia coli AP is a homodimer with 449 residues per monomer. It is a metalloenzyme with two Zn2+ and one Mg2+ at each active site. The crystal structure of native E. coli AP complexed with inorganic phosphate (Pi), which is a strong competitive inhibitor as well as a substrate for the reverse reaction, has been refined at 2.0 A resolution. Some parts of the molecular have been retraced, starting from the previous 2.8 A study. The active site has been modified substantially and is described in this paper. The changes in the active site region suggest the need to reinterpret earlier spectral data, and suggestions are made. Also presented are the structures of the Cd-substituted enzyme complexed with inorganic phosphate at 2.5 A resolution, and the phosphate-free native enzyme at 2.8 A resolution. At pH 7.5, where the X-ray data were collected, the Cd-substituted enzyme is predominantly the covalent phosphoenzyme (E-P) while the native Zn/Mg enzyme exists in predominantly noncovalent (E.P) form. Implication of these results for the catalytic mechanism of the enzyme is discussed. APs from other sources are believed to function in a similar manner.

p10 single-stranded nucleic acid binding protein from murine leukemia virus binds metal ions via the peptide sequence Cys26-X2-Cys29-X4-His34-X4-Cys39

The RNA binding protein of 56 residues encoded by the extreme 3' region of the gag gene of Rauscher murine leukemia virus (MuLV) has been chemically synthesized by a solid-phase synthesis approach. Since the peptide contains a Cys26-X2-Cys29-X4-His34-X2-Cys39 sequence that is shared by all retroviral gag polyproteins which has been proposed to be a metal binding region, it was of considerable interest to examine the metal binding properties of the complete p10 protein. As postulated, p10 binds the metal ions Cd(II), Co(II), and Zn(II). The Co(II) protein shows a set of d-d absorption bands typical of a tetrahedral Co(II) complex at 695 (epsilon = 565 M-1 cm-1), 642 (epsilon = 655 M-1 cm-1), and 615 nm (epsilon = 510 M-1 cm-1) and two intense bands at 349 (epsilon = 2460 M-1 cm-1) and 314 nm (epsilon = 4240 M-1 cm-1) typical of Co(II)----(-)S- charge transfer. The ultraviolet absorption spectrum also indicates Cd(II) binding by the appearance of a Cd(II)----(-)S- charge-transfer band at 255 nm. The 113Cd NMR spectrum of 113Cd(II)-p10 reveals one signal at delta = 648 ppm. This chemical shift correlates well with that predicted for ligation of 113Cd(II) to three -S- from the three Cys residues of p10. The chemical shift of 113Cd(II)-p10 changes by only 4 ppm upon binding of d(pA)6, indicating that the chelate complex is little changed by oligonucleotide binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Tryptophan phosphorescence as a monitor of the structural role of metal ions in alkaline phosphatase

The phosphorescence properties of Trp109 in alkaline phosphatase from Escherichia coli have been utilized to probe the conformation of the polypeptide following the removal of metal ions, reconstitution with Zn2+ and Cd2+ and phosphorylation. The complete removal of metal ions induces a drastic loosening of the protein structure that extends to the inner core of the macromolecule. While binding of a single metal ion/subunit (A-site occupancy) restores the holoconformer, practically no structuring effect is observed upon B-site occupancy by the second incoming metal ion. An exception to this rule occurs at alkaline pH and when the adjacent subunit in the dimer is metal-free. Under these circumstances a conformation of the subunit more compact than that of the fully saturated dimer manifests some degree of communication across the subunit interface. The binding of more than two metal ions/monomer generally destabilizes the protein, the effect being more pronounced at acid pH. Finally, the binding of inorganic phosphate restores the native-like configuration abolishing any destabilization induced by excess metal ions and acid pH. If the negative cooperativity towards metal binding to A sites in doubly metalated forms at pH 8 is in substantial agreement with 113Cd-NMR data, the equivalence in conformation between Zn2+- and Cd2+-reconstituted alkaline phosphatase emphasizes that no serious structural changes are introduced by the metal replacement.

NMR studies of ion binding in biological systems

Biological systems must have evolved in an interplay between a great many organic and inorganic compounds. As a result a considerable number of elements - estimates range between 25 and 30 - are essential for higher life forms such as animals and man (Underwood, 1977; Williams, 1983, 1984).

Refined structure of alkaline phosphatase from Escherichia coli at 2.8 A resolution

The structure of alkaline phosphatase from Escherichia coli has been determined to 2.8 A resolution. The multiple isomorphous replacement electron density map of the dimer at 3.4 A was substantially improved by molecular symmetry averaging and solvent flattening. From these maps, polypeptide chains of the dimer were built using the published amino acid sequence. Stereochemically restrained least-squares refinement of this model against native data, starting with 3.4 A data and extending in steps to 2.8 A resolution, proceeded to a final overall crystallographic R factor of 0.256. Alkaline phosphatase-phosphomonoester hydrolase (EC 3.1.3.1) is a metalloenzyme that forms an isologous dimer with two reactive centers 32 A apart. The topology of the polypeptide fold of the subunit is of the alpha/beta class of proteins. Despite the similarities in the overall alpha/beta fold with other proteins, alkaline phosphatase does not have a characteristic binding cleft formed at the carboxyl end of the parallel sheet, but rather an active pocket that contains a cluster of three functional metal sites located off the plane of the central ten-stranded sheet. This active pocket is located near the carboxyl ends of four strands and the amino end of the antiparallel strand, between the plane of the sheet and two helices on the same side. Alkaline phosphatase is a non-specific phosphomonoesterase that hydrolyzes small phosphomonoesters as well as the phosphate termini of DNA. The accessibility calculations based on the refined co-ordinates of the enzyme show that the active pocket barely accommodates inorganic phosphate. Thus, the alcoholic or phenolic portion of the substrate would have to be exposed on the surface of the enzyme. Two metal sites, M1 and M2, 3.9 A apart, are occupied by zinc. The third site, M3, 5 A from site M2 and 7 A from site M1, is occupied by magnesium or, in the absence of magnesium, by zinc. As with other zinc-containing enzymes, histidine residues are ligands to zinc site M1 (three) and to zinc site M2 (one). Ligand assignment and metal preference indicate that the crystallographically found metal sites M1, M2 and M3 correspond to the spectroscopically deduced metal sites A, B and C, respectively. Arsenate, a product analog and enzyme inhibitor, binds between Ser102 and zinc sites M1 and M2. The position of the guanidinium group of Arg 166 is within hydrogen-bonding distance from the arsenate site.(ABSTRACT TRUNCATED AT 400 WORDS)

Yeast inorganic pyrophosphatase. A model for active-site structure based on 113Cd2+ and 31P NMR studies

Equilibrium dialysis and 113Cd2+ NMR studies in the presence of inorganic phosphate (Pi) provide clear evidence for the existence of four well-defined Cd2+ sites per yeast inorganic pyrophosphatase subunit. Parallel 31P NMR studies demonstrate the existence of two binding sites per subunit for Pi and provide strong confirmatory evidence for a small amount of enzyme-bound inorganic pyrophosphate in equilibrium with enzyme-bound Pi. Such inorganic pyrophosphate formation was demonstrated by chemical analysis earlier [Welsh, K.M., Armitage, I.M., & Cooperman, B.S. (1983) Biochemistry 22, 1046-1054]. In this same earlier paper, we provided evidence for inner-sphere contact between enzyme-bound Cd2+ and Pi bound in the higher affinity of the two Pi sites. We now present heteronuclear decoupling evidence that one to three different Cd2+ ions make such contact. The divalent metal ion cofactor conferring the highest activity on inorganic pyrophosphatase is Mg2+, and we present evidence from competition experiments that such inner-sphere contact is also likely for the Mg2+-enzyme. On the other hand, these experiments also show that some metal ion binding sites on the enzyme bind Mg2+ and not Cd2+, and some bind Cd2+ and not Mg2+. These results are considered along with others obtained recently in proposing an active-site structure for inorganic pyrophosphatase.

Crystallographic observations of the metal ion triple in the active site region of alkaline phosphatase

Diffraction analysis reveals three metal ion binding sites, M1, M2 and M3, in each of two symmetric active centers 32 A apart in alkaline phosphatase from Escherichia coli with intermediate distances within the center of 4, 5 and 7 A for M1-M2, M2-M3 and M1-M3, respectively. A fourth site, M4, has been reported 25 A away. Arsenate, a product analog, binds adjacent to M1 and M2. The active serine residue, 102, which is phosphorylated during normal enzymatic turnover, is also adjacent to M1 and M2 and arginine 166 is adjacent to the arsenate. The implication with respect to the mechanism is that M1, M2 and Arg 166 neutralize and redistribute charges within the phosphate group, activate the serine hydroxyl, and stabilize transition states during bond formation and breakage. Three sites, A, B and C, have been deduced from solution studies and defined specifically on the basis of nuclear magnetic resonance data, binding studies and activity data. The evidence suggests correspondence of A to M1, B to M2, and C to M3. Strong antagonism between binding at M1 and M2 is evidenced crystallographically by a pseudo-saturation, which is relieved by phosphate binding. Local destabilization of the protein, particularly residues 323 through 333, is produced by removal of metals from the crystal.