A recycling assay for alkaline phosphatase applied to studies on its transport in E. coli K12

A recycling assay for alkaline phosphatase, based on its ability to hydrolyse NADP to NAD+, is presented. The product NAD+ is recycled in a coupled assay consisting of NADH regeneration and reduction of a nitroblue tetrazolium salt. This assay is 10-12 times more sensitive than the conventional assay. We demonstrate the role of energy poisons in transport of this protein into the periplasm by combining the improved detection with phase separation of the periplasmic and cytoplasmic alkaline phosphatase pools.     

Reconstitution of denatured E. coli alkaline phosphatase with E. coli ribosome.

E. coli alkaline phosphatase was denatured by physical/chemical means. In vitro reconstitution of this denatured enzyme was assisted by 70S E. coli ribosome, as shown by the recovery of its catalytic competence. Almost total recovery of activity of the totally inactivated enzyme was obtained in presence of equimolar concentration of 70S ribosome at 50 degrees C.     

3-13C-methionine-labelled E. coli alkaline phosphatase

3-13C-methionine has been biosynthetically incorporated into E. coli alkaline phosphatase using strain CW3747 which is auxotrophic for Met. 13C NMR of the dimeric native enzyme labelled at the eight methionine residues of the primary structure shows a dispersion of resonance signals permitting resolution of at least five methionine environments, none of which coincide with the chemical shift position of free methionine. At acid pH, 13C signal intensity is shifted to a chemical shift consistent with solvent exposure. However, three discrete resonances are observed, suggesting a retention of defined structure. The labelled protein thus can serve as a probe of conformational alterations of the enzyme.     

Evidence concerning a possible steady state rate equation for E. coli alkaline phosphatase

• 1.1. Steady state data was obtained for alkaline phosphatase over a wide range of experimental conditions using two substrates, four inhibitors, two modifiers and several pH, ionic strength and temperatures values.
• 2.2. The data was fitted by rational functions of degree 1:1, 2:2 and 3:3 using a non-linear regression program and then the F-test was used to assess the goodness of fit.
• 3.3. A proportion of the curves could only be fitted by 2:2 functions but many of them could be adequately fitted by 1:1 functions.
• 4.4. No statistically significant improvement in fit occurred with 3:3 functions.
• 5.5. Data was simulated using a computer program to see what sort of curves could be generated by a two sites mechanism proposed for alkaline phosphatase and this study showed that it is difficult to detect cubic terms in this rate equation.
• 6.6. It was concluded that alkaline phosphatase does not obey Michaelis-Menten kinetics. Rather, the steady state data require a mechanism of at least second degree but do not exclude a rate equation of third degree.

     

Escherichia coli alkaline phosphatase. Kinetic studies with the tetrameric enzyme

1. The stability of the tetrameric form of Escherichia coli alkaline phosphatase was examined by analytical ultracentrifugation. 2. The stopped-flow technique was used to study the hydrolysis of nitrophenyl phosphates by the alkaline phosphatase tetramer at pH7.5 and 8.3. In both cases transient product formation was observed before the steady state was attained. Both transients consisted of the liberation of 1mol of nitrophenol/2mol of enzyme subunits within the dead-time of the apparatus. The steady-state rates were identical with those observed with the dimer under the same conditions. 3. The binding of 2-hydroxy-5-nitrobenzyl phosphonate to the alkaline phosphatase tetramer was studied by the temperature-jump technique. The self-association of two dimers to form the tetramer is linked to a conformation change within the dimer. This accounts for the differences between the transient phases in the reactions of the dimer and the tetramer with substrate. 4. Addition of P_i to the alkaline phosphatase tetramer caused it to dissociate into dimers. The tetramer is unable to bind this ligand. It is suggested that the tetramer undergoes a compulsory dissociation before the completion of its first turnover with substrate. 5. On the basis of these findings a mechanism is proposed for the involvement of the alkaline phosphatase tetramer in the physiology of E. coli.     

Expression of chemically synthesized alpha-neo-endorphin gene fused to E. coli alkaline phosphatase.

An alpha-neo-endorphin (alpha NE) gene, which we previously synthesized chemically and inserted into E. coli beta-galactosidase gene of pK013 plasmid, has been excised and fused to E. coli alkaline phosphatase (APase) gene. One of the transformants was named E15/pA alpha NE1. Under the APase gene regulation, APase-alpha NE chimeric protein was expressed at 1.3 X 10(6) molecules per cell, and accounted for about 60% of total cellular proteins. The HPLC pattern of CNBr treated E15/pA alpha NE1 was very simple reflecting the high content of the chimeric protein and low numbers of methionine residues in it. A series of genes encoding APase-alpha NE chimeric proteins in which 30 to 94 C-terminal amino acid residues were replaced by (met)-alpha NE, was cloned in E. coli. Transportation of the chimeric proteins to periplasmic space was studied. All chimeric proteins were apparently processed by signal peptidase but few, if any, was transported to the periplasmic space.     

Novel synthesized colourless ligands in affinity chromatography for purification of alkaline phosphatase

Summary A 350-and a 460-fold one step purification of alkaline phosphatase from a crude calf intestine extract has been achived using two new synthesized colourless biomimetic compounds coupled to Agarose CL-4B.     

Blue dextran Sepharose chromatography of the tryptophanyl-tRNA synthetase of E. coli: a potential application for the purification of the enzyme.

E. coli tryptophanyl-tRNA synthetase can form a complex with Blue-dextran Sepharose, in the presence or in the absence of Mg++. In its absence, the complex is dissociated by either ATP or cognate tRNATrp. However, in the presence of Mg++, only tRNATrp can dissociate the complex whereas ATP has no effect. E. coli total tRNA or tRNAMet, at the same concentration, cannot displace the synthetase from the complex. It is suggested that the Blue-dextran binds to the synthetase through its tRNA binding domain. This hypothesis is supported by previous findings with polynucleotide phosphorylase showing that Blue-dextran Sepharose can be used in affinity chromatography to recognize a polynucleotide binding site of the protein. The selective elution by its cognate tRNA of Trp-tRNA synthetase bound to Blue-dextran Sepharose provides a rapid and efficient purification of the enzyme. Examples of other synthetases and nucleotidyl transferases are also discussed.     

Isolation and properties of immobilized alkaline phosphatase from E. coli

Preparations of alkaline phosphatase from E. coli, immobilized on Sepharose, with a specific activity of 40-60 U/g wet weight were obtained. The immobilized enzyme was stable up to 50 degrees C; at higher temperatures it was inactivated. At 70 degrees most of the activity was lost for 1 h. The substrate (AMP) stabilized the enzyme. In the temperature range from 30 to 40 degrees C activation of the enzyme was observed, especially pronounced in the presence of the substrate. The pH optimum of the immobilized enzyme activity (7.8-8.2) is shifted towards the acid region, as compared to the soluble enzyme (8.0-8.6). The kinetic parameters for inhibition by the reaction product were determined using the integral Michaelis-Menten equation. KmAMP was found to be higher in case of the immobilized enzyme as compared to the soluble one (5.02 X 10(-4) M and 1.85 X 10(-5) M, respectively), which seems to be associated with diffusion limitations.     

Factors affecting the zinc content of E. coli alkaline phosphatase

Through experiments with radioactively labeled EDTA, it has been shown that alkaline phosphatasc from E. coli has a high affinity for binding EDTA, requiring extensive dialysis for removal. This paper reviews the results of zinc analyses of E. coli alkaline phosphatase prepared in the presence and absence of EDTA. The presence of EDTA in most preparations of alkaline phosphatase accounts for previous overestimates of the zine content of the enzyme.With radioactively labeled EDTA, direct evidence for the binding of EDTA to the metal-free alkaline phosphatase is presented. It has been shown that the apoprotein binds two EDTA molecules rather strongly. Addition of four metal ions are necessary for reactivation of this EDTA-contaminated apoenzyme. However, when the EDTA-contaminated apoenzyme is subject for extensive dialysis and EDTA is removed, the addition of two zinc ions restores the enzyme activity completely.     

Phospholipids of E. coli and activity of alkaline phosphatase]

The effects of liposomes prepared from the E. coli lipids on the activity of soluble alkaline phosphatase and on the complementation reaction between its subunits were studied. It was shown that the liposomes nonspecifically catalyze the dimerization of the enzyme subunits without changing the dimer activity. The effects of phospholipases A2 and C on the activity of membrane-bound alkaline phosphatase were studied. An interrelationship was found between the level of hydrolysis of membrane phosphatidyl glycerol (PG) by these enzymes and the changes in the activity of membrane-bound alkaline phosphatase. It was also shown that PG is less accessible to the effects of phospholipases in the cells with derepressed biosynthesis of alkaline phosphatase. It is assumed that the membrane PG interacts with the membrane-bound alkaline phosphatase during its translocation into the periplasm.     

Hysteresis on heating and cooling of E. coli alkaline phosphatase

Measurements of [theta](222) of E. coli phosphatase on heating from 20 degrees to 90 degrees and subsequent cooling to 20 degrees shows a gradual increase in [theta](222) on heating, while cooling shows a symmetric transition centered at 45 degrees . Reheating and cooling shows the same phenomenon. Enzyme heated and cooled once is fully active. The activity of the enzyme depends on its storage conditions (buffer and pH for example), but such changes are least to some extent reversible, especially by heating in different solvents. We conclude the enzyme exists in several forms which are in slow equilibrium with each other, so that the enzyme responds slowly when heated and hence is not at equilibrium during heating/cooling experiments.     

A new direct lead technique for histochemical demonstration of alkaline phosphatase activity.

A lead method for demonstrating alkaline phosphatase is described. The method is based on direct precipitation of lead as lead phosphatase at pH 9.5, the pH optimum of the enzyme. Stable incubation medium was achieved by using tartrate, instead of maleate, as chelating for lead. The method was found to be suitable for visualization of alkaline phosphatase in different types of tissues.     

Reactivation of denatured fungal glucose 6-phosphate dehydrogenase and E. coli alkaline phosphatase with E. coli ribosome.

Fungal glucose 6-phosphate dehydrogenase and E. coli alkaline phosphatase were denatured either by physical or by chemical means. In vitro reconstitution of these denatured enzymes was assisted by 70S E. coli ribosome, as shown by the recovery of their catalytic competence. Almost total recovery of the activities of completely inactivated enzymes was obtained when 70S ribosome was present at about equimolar concentration with the enzyme molecules at 37C and 50C, respectively.     

19-F NMR studies of the binding of a fluorine-labeled phosphonate ion to E. coli alkaline phosphatase.

The interaction of a fluorinated phosphonate with Zn-2+-and Mn-2+-alkaline phosphatase as studied by 19-F NMR revealed a stoichiometry of 1:1 for the binding of the phosphonate anion to the enzyme. In the presence of two metal ions, one fluorinated phosphonate ion was found to interact strongly with the enzyme, while a different interaction was observed when the number of metal ions per enzyme exceeded two. Phosphate replaced enzyme bound phosphonate, as is shown by the 19-F NMR spectra. No direct interaction between the fluorinated phosphonate and the metal ion responsible for enzyme activity was indicated by the 19-F NMR data. This observation supports the idea of a considerable distance between metal ion and substrate binding site in Escherichia coli alkaline phosphatase.     

Insertion of a disulfide-containing neurotoxin into E. coli alkaline phosphatase: the hybrid retains both biological activities.

We have inserted a disulfide-containing snake neurotoxin into the N-terminal end of Escherichia coli alkaline phosphatase, between residues +6 and +7 of the mature enzyme. For this purpose, we have designed a cloning and expression vector which allows insertion of foreign DNA between the corresponding codons, and visual selection of the desired recombinant clones upon recovery of phosphatase activity. The hybrid protein is exported to the bacterial periplasm, the alkaline phosphatase signal peptide is correctly processed, and both domains are functionally conformed. The phosphatase domain displays catalytic activity, and the inserted toxin is able to bind to its biological target, the nicotinic acetylcholine receptor. The hybrid molecule is remarkably stable and resistant to proteolysis. Crude periplasmic extract containing the hybrid can be used as a tracer-containing reagent in competitive enzymo-immuno and enzymo-receptor assays. We propose to use the system described in this paper for fast preparation of properly folded disulfide-containing enzymatic probes.