Zinc enzymology is, compared to some other current areas of metallobiochemistry, a maturing field, but in addition to further developments of structure-function relationships it has also provided a number of surprising new results and ideas in the last few years. In fact, the number of studies makes it impossible to provide a comprehensive review of the recent literature on zinc enzymology here, and the authors therefore focus on those zinc enzymes for which structure-function relationships are possible on the basis of structural and biochemical data. This means that, with a few exceptions, only zinc enzymes for which NMR or crystal structures are available are included here. Another seemingly simple, yet experimentally sometimes complex issue concerns the choice of which metalloenzyme is a zinc enzyme. Since there is in principle no difference in chemical catalysis by low-affinity compared to high-affinity metal sites, some of these enzymes are also included in this article, especially if they are or have been discussed as zinc enzymes, or are active with zinc. 552 refs.

Recent Advances in Zinc Enzymology

Ecto-nucleotidases play a pivotal role in purinergic signal transmission. They hydrolyze extracellular nucleotides and thus can control their availability at purinergic P2 receptors. They generate extracellular nucleosides for cellular reuptake and salvage via nucleoside transporters of the plasma membrane. The extracellular adenosine formed acts as an agonist of purinergic P1 receptors. They also can produce and hydrolyze extracellular inorganic pyrophosphate that is of major relevance in the control of bone mineralization. This review discusses and compares four major groups of ecto-nucleotidases: the ecto-nucleoside triphosphate diphosphohydrolases, ecto-5′-nucleotidase, ecto-nucleotide pyrophosphatase/phosphodiesterases, and alkaline phosphatases. Only recently and based on crystal structures, detailed information regarding the spatial structures and catalytic mechanisms has become available for members of these four ecto-nucleotidase families. This permits detailed predictions of their catalytic mechanisms and a comparison between the individual enzyme groups. The review focuses on the principal biochemical, cell biological, catalytic, and structural properties of the enzymes and provides brief reference to tissue distribution, and physiological and pathophysiological functions.

/pdf/cellular-function-and-molecular-structure-of-ecto-3htlo76yqi.pdf

Cellular function and molecular structure of ecto-nucleotidases

Allosteric Supramolecular Receptors and Catalysts

A revised mechanism for the alkaline phosphatase reaction involving three metal ions.

Hypophosphatasia, a rare inherited disorder characterized by defective bone mineralization, is highly variable in its clinical expression. The disease is due to various mutations in the tissue-non-specific alkaline phosphatase ( TNSALP ) gene. We report here the use of clinical data, site-directed mutagenesis and computer-assisted modelling to propose a classification of 32 TNSALP gene mutations found in 23 European patients, 17 affected with lethal hypophosphatasia and six with non-lethal hypophosphatasia. Transfection studies of the missense mutations found in non-lethal hypophosphatasia showed that six of them allowed significant residual in vitro enzymatic activity, suggesting that these mutations corresponded to moderate alleles. Each of the six patients with non-lethal hypophosphatasia carried at least one of these alleles. The three-dimensional model study showed that moderate mutations were not found in the active site, and that most of the severe missense mutations were localized in crucial domains such as the active site, the vicinity of the active site and homodimer interface. Some mutations appeared to be organized in clusters on the surface of the molecule that may represent possible candidates for regions interacting with the C-terminal end involved in glycosylphosphatidylinositol (GPI) attachment or with other dimers to form tetramers. Finally, our results show a good correlation between clinical forms of the disease, mutagenesis experiments and the three-dimensional structure study, and allowed us to clearly distinguish moderate alleles from severe alleles. They also confirm that the extremely high phenotypic heterogeneity observed in patients with hypophosphatasia was due mainly to variable residual enzymatic activities allowed by missense mutations found in the human TNSALP gene.

/pdf/correlations-of-genotype-and-phenotype-in-hypophosphatasia-3hib36dbga.pdf

Correlations of Genotype and Phenotype in Hypophosphatasia

Mutations at positions 153 and 328 in Escherichia coli alkaline phosphatase provide insight towards the structure and function of mammalian and yeast alkaline phosphatases.

Site-specific mutagenesis was used to explore the roles of the side chains of residues Lys-328 and Asp-153 in Escherichia coli alkaline phosphatase. The D153H enzyme exhibits a 3.5-fold decrease in activity at pH 8.0 compared to that of the wild-type enzyme, while a double mutant D153H/K328H exhibits a 16-fold decrease in activity under these conditions. However, the Km values for both enzymes, employing the substrate p-nitrophenyl phosphate, are lower than the value for the wild-type enzyme. The Ki for phosphate, which is pH- and Mg(2+)-dependent, is decreased for the D153H enzyme and increased for the D153H/K328H enzyme. Relative to the wild-type enzyme, both mutant enzymes bind Mg2+ more weakly and undergo a time-dependent activation induced by Mg2+. The half-time of the activation process is independent of the Mg2+ concentration, indicating that the activation most probably involves a conformational change. The pH versus activity profiles of both enzymes are altered relative to that of the wild-type enzyme and exhibit greatly enhanced activity, relative to that of the wild-type enzyme, at high pH values. The pre-steady-state kinetics for the D153H and D153H/K328H enzymes exhibit a transient burst of product formation at pH 8.0, under conditions at which the wild-type enzyme exhibits no transient burst, indicating that at pH 8.0 the hydrolysis of the covalent enzyme-phosphate complex is rate-determining and not the release of phosphate from the noncovalent enzyme-phosphate complex as is observed for the wild-type enzyme. Therefore, these mutations are directly influencing catalysis.(ABSTRACT TRUNCATED AT 250 WORDS)

Magnesium in the active site of Escherichia coli alkaline phosphatase is important for both structural stabilization and catalysis

Conversion of a magnesium binding site into a zinc binding site by a single amino acid substitution in Escherichia coli alkaline phosphatase.

Summary

Mammalian alkaline phosphatases are 20-30-fold more active than the corresponding bacterial enzymes even though their amino acid sequences are 25–30% absolutely conserved. In the active-site region there are two noticeable differences between the sequences of the bacterial and mammalian enzymes, in the Escherichia coli enzyme positions 153 and 328 are Asp and Lys, respectively, but in the mammalian enzymes His is observed at both of these positions. Site-specific mutagenesis, genetic and X-ray crystallographic data, which will be summarized here, suggest that the His substitutions at positions 153 and 328 are primarily responsible for the differences in properties between the bacterial and mammalian alkaline phosphatases.

https://onlinelibrary.wiley.com/doi/pdf/10.1111/j.1365-2958.1994.tb01024.x

Why are mammalian alkaline phosphatases much more active than bacterial alkaline phosphatases

Kinetic and structural consequences of replacing the aspartate bridge by asparagine in the catalytic metal triad of Escherichia coli alkaline phosphatase.

Jennifer E. Murphy

Papers

Mutations at positions 153 and 328 in Escherichia coli alkaline phosphatase provide insight towards the structure and function of mammalian and yeast alkaline phosphatases.

Magnesium in the active site of Escherichia coli alkaline phosphatase is important for both structural stabilization and catalysis

Conversion of a magnesium binding site into a zinc binding site by a single amino acid substitution in Escherichia coli alkaline phosphatase.

Why are mammalian alkaline phosphatases much more active than bacterial alkaline phosphatases

Kinetic and structural consequences of replacing the aspartate bridge by asparagine in the catalytic metal triad of Escherichia coli alkaline phosphatase.