Nucleotide sequence of the alkaline phosphatase gene of Escherichia coli

The nucleotide sequence of the alkaline phosphatase (APase) gene (phoA) of Escherichia coli strain 294 has been determined. Pre-APase has a total of 471 amino acids (aa) including a signal sequence of 21 aa. The derived aa sequence differs from that obtained by protein sequencing by the presence of aspartic acid instead of asparagine at positions 16 and 36, and glutamic acid instead of glutamine at position 197. Two open reading frames (ORF1 and ORF2) located downstream from phoA or upstream from proC have been found. ORF1 encodes a putative presecretory protein of 106 aa with a signal sequence of 21 or 22 aa. If this protein is actually produced, it may be one of the smallest periplasmic proteins in E. coli.     

Mutations that alter the signal sequence of alkaline phosphatase in Escherichia coli.

A phoA-lacZ gene fusion was used to isolate mutants altered in the alkaline phosphatase signal sequence. This was done by selecting Lac+ mutants from a phoA-lacZ fusion strain that produces a membrane-bound hybrid protein and is unable to grow on lactose. Two such mutant derivatives were characterized. The mutations lie within the phoA portion of the fused gene and cause internalization of the hybrid protein. When the mutations were genetically recombined into an otherwise wild-type phoA gene, they interfered with export of alkaline phosphatase to the periplasm. The mutant alkaline phosphatase protein was found instead in the cytoplasm in precursor form. DNA sequence analysis demonstrated that both mutations lead to amino acid alterations in the signal sequence of alkaline phosphatase.     

Studies on alkaline phosphatase. Transientstate and steady-state kinetics of Escherichia coli alkaline phosphatase

1. Reduction of a 19s immunoglobulin M with 3mm-mercaptoethanol or 0.05-0.5mm-dithiothreitol followed by alkylation gave sedimentation patterns indicating products compatible with structures consisting of one, two, three, four and five 7s sub-units. This supports the concept of a five-sub-unit structure for immunoglobulin M. 2. Reduction with 0.125mm-dithiothreitol or 20mm-cysteine produced 7s sub-units that could not be dissociated into chains in m-propionic acid. 3. By labelling (with iodo[2-(14)C]acetic acid) the thiol groups liberated during reduction with 0.125mm-dithiothreitol, it was possible to identify the tryptic peptides involved in the disulphide bridges that link the 7s sub-units together (inter-sub-unit bridges). 4. By further reducing and labelling (with iodo[2-(14)C]acetic acid) the 7s sub-units produced by 0.125mm-dithiothreitol, it was possible to identify tryptic peptides derived from intra-sub-unit bridges. 5. Sub-units produced by reduction with 20mm-cysteine proved to be unsuitable for distinguishing between inter-sub-unit bridges and intra-sub-unit bridges. 6. The possible arrangement of the interchain disulphide bridges was deduced.     

Proteolytic modification of Escherichia coli alkaline phosphatase

Proteolytic modification of the native alkaline phosphatase dimer is restricted to sites in the amino-terminal portion of the sequence. Complementing previous studies of the product of trypsin cleavage at the R-11, A-12 bond (Roberts, C. H., and Chlebowski, J. F. (1984) J. Biol. Chem. 259, 729-733; Roberts, C. H., and Chlebowski, J. F. (1984) J. Biol. Chem. 260, 7557-7561) circular dichroic spectroscopy indicates that cleavage at this site results in a rearrangement of secondary structure and change in tertiary structure as monitored in the far and near UV regions, respectively. Under more vigorous reaction conditions, trypsin cleaves at the R-35, D-36 bond. The deletion of an additional 24 residues yields a species whose functional and structural properties are similar to the initial product of trypsin cleavage. Treatment of the enzyme with Protease V-8 results in cleavage at the E-9, N-10 bond. In contrast to the products of trypsin treatment, this truncated enzyme is similar to the native enzyme. These results indicate that the residues at the N-10 and R-11 positions play a unique role in maintaining the structural integrity and catalytic potency of the enzyme although this locus is distant from the enzyme active centers. These observations are discussed in terms of the three-dimensional structure of the enzyme.     

Hybrids of chemical derivatives of Escherichia coli alkaline phosphatase.

The activities of hybrid dimers of alkaline phosphatase containing two chemically modified subunits have been investigated. One hybrid species was prepared by dissociation and reconstitution of a mixture of two variants produced by chemical modification of the native enzyme with succinic anhydride and tetranitromethane, respectively. The succinyl-nitrotyrosyl hybrid was separated from the other members of the hybrid set by DEAE-Sephadex chromatography and then converted to a succinyl-aminotyrosyl hybrid by reduction of the modified tyrosine residues with sodium dithionite. A comparison of the activities of these two hybrids with the activities of the succinyl, nitrotyrosyl and aminotyrosyl derivatives has shown that either the subunits of alkaline phosphatase function independently or if the subunits turnover alternately in a reciprocating mechanism, then the intrinsic activity of each subunit must be strongly dependent on its partner subunit.     

Escherichia coli alkaline phosphatase. Relaxation spectra of ligand binding

The temperature-jump technique was used to study the binding equilibrium between the Escherichia coli alkaline phosphatase dimer and 2-hydroxy-5-nitrobenzyl phosphonate in 0.1m-tris buffer, pH8.0. Three partially discrete relaxations were observed, two of which could be related to the bimolecular associations of ligand with different conformations of the enzyme and the third to the interconversion of these states. Relaxation spectra were also used to analyse the changes in the mechanism of ligand binding to alkaline phosphatase caused by increase in ionic strength. The relaxation spectrum observed after the addition of P(i) to the equilibrium mixture of phosphonate and enzyme was also studied. Difference spectroscopy indicated that both of these ligands were bound to the alkaline phosphatase dimer at the same time. These results are related to the catalytic mechanism of this enzyme, with particular reference to the role of two identical subunits in a dimeric enzyme that exhibits only one active site functioning in catalysis at any given time.     

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.     

Metal ion-induced conformational changes in Escherichia coli alkaline phosphatase.

Ultraviolet difference spectra are produced by the binding of divalent metal ions to metal-free alkaline phosphatase (EC 3.1.3.1). The interaction of the apoprotein with Zn2+, Mn2+, Co2+ and Cd2+, which induce the tight binding of one phosphate ion per dimer, give distinctly different ultraviolet spectra changes from Ni2+ and Hg2+ which do not induce phosphate binding. Spectrophotometric titrations at alkaline pH of various metallo-enzymes reveal a smaller number of ionizable tyrosines and a greater stability towards alkaline denaturation in the Zn2+- and Mn2+-enzymes than in the Ni2+-, Hg2+- and apoenzymes. The Zn2+- and Mn2+-enzymes have CD spectra in the region of the aromatic transitions that are different from the CD spectra of the Ni2+-, Hg2+- and apoenzymes. Modifications of arginines with 2,3-butanedione show that a smaller number of arginine residues are modified in the Zn2+-enzyme than in the Hg2+-enzyme. The presented data indicate that alkaline phosphatase from Escherichia coli must have a well-defined conformation in order to bind phosphate. Some metal ions (i.e. Zn2+, Co2+, Mn2+ and Cd2+), when interacting with the apoenzyme, alter the conformation of the protein molecule in such a way that it is able to interact with substrate molecules, while other metal ions (i.e. Ni2+ and Hg2+) are incapable of inducing the appropriate conformational change of the apoenzyme. These findings suggest an important structural function of the first two tightly bound metal ions in enzyme.     

Molecular asymmetry in alkaline phosphatase of Escherichia coli

Thermal inactivation of alkaline phosphatase of Escherichia coli has been studied at different temperatures (45 to 70 degrees C) and pHs (7.5, 9.0, and 10.0) for the commercial, buffer-dialyzed (pH 9.0) and EDTA-dialyzed (pH 9.0) enzymes. In each case, the inactivation exhibits biphasic kinetics consistent with the rate equation, (formula; see text) where A0 and A are activities at time zero and t, and k1 and k2 are first-order rate constants for the fast and slow phase, respectively. Values of k1 and k2 change independently with temperature, pH, and pretreatment (dialysis) of the enzyme. Time course of inactivation of the enzyme with excess EDTA and effect of Zn2+ ion concentration on the activity of EDTA-dialyzed enzyme have been investigated. The data suggest that the dimeric enzyme protein has two types of catalytic sites which have equal catalytic efficiency (or specific activity) but differ in several other properties. Structural implications of these results have been discussed.     

Zinc and magnesium content of alkaline phosphatase from Escherichia coli.

Since alkaline phosphatase from Escherichia coli was first reported to contain 2.1 g-atoms of zinc and 0.8 g-aton of magnesium per molecular weight 80,000 (Plocke, D.J., Levinthal, D., and Vallee, B. L. (1962), Biochemistry 1, 373-378), the procedures for isolation and purification of the enzyme, as well as values for the protein molecular weight, specific absorptivity, and maximal activity, have changed repeatedly. Such variations have resulted in uncertainties concerning the molar metal content of this phosphatase. The present paper reviews the initial and recent results of metal analyses of alkaline phosphatase preparations in this laboratory and compares them with those obtained elsewhere, while simultaneously identifying some of the factors which have affected reports on the metal content of this enzyme. A purification procedure is described eliminating the features of all methods known to alter the metal content of phosphatase. In addition, the three isozymic forms, as well as preparations from four E. coli strains commonly employed for phosphatase isolation, were analyzed and compared.