Microtubules and nucleoside diphosphate kinase. Nucleoside diphosphate kinase binds to co-purifying contaminants rather than to microtubule proteins.

Nucleoside diphosphate (NDP) kinase has been postulated to generate GTP from the GDP bound to tubulin. The purified chick brain enzyme was studied with respect to its kinetic parameters, and the protein-protein interactions between the NDP kinase and tubulin were examined. No specific interaction is observed between the enzyme and assembled microtubules, tubulin dimers, or tubulin-microtubule-associated protein (MAP) oligomers under a variety of nucleotide conditions. The apparent association is demonstrated to result from NDP kinase binding to a co-purifying contaminant. The absence of detectable NDP kinase-tubulin interactions indicates that NDP kinase does not directly charge up tubulin-GDP.     

Nucleosidediphosphate kinase associates with rings but not with assembled microtubules

Microtubules reassembled in vitro from chick brain contain significant nucleosidediphosphate (NDP) kinase activity (EC 2.7.4.6) although the specific activity decreases with successive cycles of reassembly. However, while the recovery of microtubule protein, as a function of initial protein concentration, exhibits a critical concentration below which there is no polymerisation, the recovery of NDP kinase activity is, at low initial protein concentrations, directly proportional to the initial protein content indicating that microtubule protein and the kinase activity are independently recovered. This was confirmed by pelleting the reassembled microtubules through a sucrose cushion: the specific activity of the pelleted microtubules was reduced by approximately 90%. By contrast, when cold-dissociated microtubule protein, which is predominantly in the form of rings, is fractionated on a Biogel A 15 m column the microtubule protein and NDP kinase activity coeluted in the void volume and the specific activity remained constant throughout the ring fraction. Similarly, when microtubules were dissociated in the presence of NDP kinase the enzyme bound to the generated rings. These results suggest that NDP kinase binds preferentially to the rings compared with the microtubules, and a model is proposed to account for the presence of this enzyme in pellets of microtubule protein.     

Nm23/NDP kinases in human male germ cells: role in spermiogenesis and sperm motility?

Nucleoside diphosphate (NDP) kinases, responsible for the synthesis of nucleoside triphosphates and produced by the nm23 genes, are involved in numerous regulatory processes associated with proliferation, development, and differentiation. Their possible role in providing the GTP/ATP required for sperm function is unknown. Testis biopsies and ejaculated sperm were examined by immunohistochemical and immunofluorescence microscopy using specific antibodies raised against Nm23-H5, specifically expressed in testis germinal cells and the ubiquitous NDP kinases A to D. Nm23-H5 was present in sperm extract, together with the ubiquitous A and B NDP kinases (but not the C and D isoforms) as shown by Western blotting. Nm23-H5 was located in the flagella of spermatids and spermatozoa, adjacent to the central pair and outer doublets of axonemal microtubules. High levels of NDP kinases A and B were observed at specific locations in postmeiotic germinal cells. NDP kinase A was transiently located in round spermatid nuclei and became asymmetrically distributed in the cytoplasm at the nuclear basal pole of elongating spermatids. The distribution of NDP kinase B was reminiscent of the microtubular structure of the manchette. In ejaculated spermatozoa, the proteins presented specific locations in the head and flagella. Nm23/NDP kinase isoforms may have specific functions in the phosphotransfer network involved in spermiogenesis and flagellar movement.     

Overexpression of wild-type and mutant NDP kinase in Dictyostelium discoideum

Nucleoside diphosphate (NDP) kinase has a central role in the synthesis of (deoxy-)trinucleotides. In addition, mutations in the gene encoding NDP kinase have been shown to have important consequences for Drosophila development and mammalian tumorogenesis. We have overexpressed, in Dictyostelium discoideum, a genomic clone encoding the enzyme NDP kinase. The concomitant increase in the levels of RNA and enzyme activity identifies a 5′ non-coding genomic region of 0.9 kb as being the complete promoter region. Overexpression of wild-type NDP kinase has no effect on development. This is also true for an inactive mutant H122C that does not have a dominant inhibitor effect. Overexpression of the P105G mutant NDP kinase, which is known to be affected in its stability in vitro, only leads to a small increase in total NDP-kinase activity. Thermal and chemical denaturation experiments demonstrate the formation of hexameric hybrids between wild-type and mutant monomers.     

Activation of G-proteins by receptor-stimulated nucleoside diphosphate kinase in Dictyostelium.

Recently, interest in the enzyme nucleoside diphosphate kinase (EC2.7.4.6) has increased as a result of its possible involvement in cell proliferation and development. Since NDP kinase is one of the major sources of GTP in cells, it has been suggested that the effects of an altered NDP kinase activity on cellular processes might be the result of altered transmembrane signal transduction via guanine nucleotide-binding proteins (G-proteins). In the cellular slime mould Dictyostelium discoideum, extracellular cAMP induces an increase of phospholipase C activity via a surface cAMP receptor and G-proteins. In this paper it is demonstrated that part of the cellular NDP kinase is associated with the membrane and stimulated by cell surface cAMP receptors. The GTP produced by the action of NDP kinase is capable of activating G-proteins as monitored by altered G-protein-receptor interaction and the activation of the effector enzyme phospholipase C. Furthermore, specific monoclonal antibodies inhibit the effect of NDP kinase on G-protein activation. These results suggest that receptor-stimulated NDP kinase contributes to the mediation of hormone action by producing GTP for the activation of GTP-binding proteins.     

Purification and characterization of nucleoside diphosphate kinase from spinach leaves.

Two types of nucleoside diphosphate kinase (NDP kinase I and NDP kinase II) have been purified from spinach leaves to electrophoretic homogeneity. The enzymes were copurified with apparent [35S]GTP-gamma S-binding activities. NDP kinase I, which was not adsorbed to a hydroxyapatite column, and NDP kinase II, which was adsorbed, had molecular weights of 16,000 and 18,000, respectively, as judged by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The molecular weights determined by gel filtration were 92,000 and 110,000, respectively, suggesting that both enzymes are composed of six identical subunits. Minor differences in some amino acids between NDP kinase I and NDP kinase II were observed when both enzymes were analyzed for amino acid composition. The apparent [35S]GTP gamma S-binding activity of purified NDP kinase I and NDP kinase II was found to be due to the formation of a [35S]thiophosphorylated enzyme, which is the intermediate of the NDP kinase reaction.     

Structural and catalytic properties and homology modelling of the human nucleoside diphosphate kinase C, product of the DRnm23 gene.

The human DRnm23 gene was identified by differential screening of a cDNA library obtained from chronic myeloid leukaemia-blast crisis primary cells. The over-expression of this gene inhibits differentiation and induces the apoptosis of myeloid precursor cell lines. We overproduced in bacteria a truncated form of the encoded protein lacking the first 17 N-terminal amino acids. This truncated protein was called nucleoside diphosphate (NDP) kinase CDelta. NDP kinase CDelta had similar kinetic properties to the major human NDP kinases A and B, but was significantly more stable to denaturation by urea and heat. Analysis of denaturation by urea, using size exclusion chromatography, indicated unfolding without the dissociation of subunits, whereas renaturation occurred via a folded monomer. The stability of the protein depended primarily on subunit interactions. Homology modelling of the structure of NDP kinase CDelta, based on the crystal structure of NDP kinase B, indicated that NDP kinase CDelta had several additional stabilizing interactions. The overall structure of the two enzymes appears to be identical because NDP kinase CDelta readily formed mixed hexamers with NDP kinase A. It is possible that mixed hexamers can be observed in vivo.     

Isolation of a mRNA encoding a nucleoside diphosphate kinase from tomato that is up-regulated by wounding

A cDNA clone (TAB2) encoding a nucleoside diphosphate (NDP) kinase has been isolated from a tomato (Lycopersicon esculentum Mill. cv. Ailsa Craig) cDNA library. The clone is 590 bp long and exhibits a high degree of sequence identity with spinach NDP kinases I and II, Pisum sativum NDP kinase I, Arabidopsis thaliana NDP kinase, Drosophila melanogaster NDP kinase, Dictyostelium discoideum NDP kinase and human Nm 23-H1 and Nm23-H2. Northern analysis has revealed that the mRNA encoded by TAB2 is up-regulated in both leaf and stem tissue in response to wounding. The increase is apparent within 1 h of wounding and is not further elevated by application of ethylene. Southern blot analysis indicates that TAB2 is a member of a small gene family.     

Conversion of GDP into GTP by nucleoside diphosphate kinase on the GTP-binding proteins

A direct interaction of alpha beta gamma trimeric GTP binding proteins (G proteins; G0 and Gs) with nucleoside diphosphate kinase (NDP kinase) was investigated with homogeneously purified proteins. There was a progressive release of 32Pi from [gamma-32P]ATP when GDP-bound G0 was incubated together with NDP kinase. The Pi release induced by the interaction of G0 with NDP kinase was not accompanied by the dissociation of GDP bound to the alpha-subunit of G0. This was a sharp contrast to G protein-catalyzed GTP hydrolysis observed with GTP as the substrate; the dissociation of bound GDP was essentially required for the following binding of the substrate, GTP, to be hydrolyzed. A kinetic analysis displayed different properties for the substrate of NDP kinase between free GDP and G protein-bound GDP. NDP kinase-dependent phosphorylation of GDP on G0 was indeed demonstrated with adenosine 5'-(3-O-thio)triphosphate as the phosphate donor; there was a formation of guanosine 5'-(3-O-thio)triphosphate-bound G0 from the ATP analogue. Moreover, purified Gs was readily ADP-ribosylated by cholera toxin in the presence of NDP kinase, ATP, and an ADP-ribosylation factor, also suggesting that the nucleotide form on Gs was certainly GTP. These results indicate that NDP kinase can transfer the gamma-phosphate of ATP directly to GDP bound to G proteins and that this phosphorylation results in the activation of the signal-coupling proteins. A possible role of the new activation mechanism of G proteins is discussed in comparison with the previously characterized GDP-GTP exchange pathway by the agonist-receptor complex.     

Regulation of dynamin by nucleoside diphosphate kinase

Nucleoside diphosphate (NDP) kinase is required for multiple cellular functions, including cell growth, motility, and differentiation, and its loss is associated with pathologies including tumor metastasis. A recent study has revealed a previously unknown function for NDP kinase as positive regulator of dynamin, a GTPase essential for endocytosis. In this review we describe the evidence that NDP kinase function is essential for endocytosis and also elaborate on a mechanism for NDP kinase regulation of dynamin. Recently documented interactions between endocytosis and cell signaling have revealed new insights into potential mechanisms of cancer. In this context, we discuss the possible relevance of NDP kinase and dynamin interaction for tumor suppression.     

X-ray structure of nucleoside diphosphate kinase.

The X-ray structure of a point mutant of nucleoside diphosphate kinase (NDP kinase) from Dictyostelium discoideum has been determined to 2.2 A resolution. The enzyme is a hexamer made of identical subunits with a novel mononucleotide binding fold. Each subunit contains an alpha/beta domain with a four stranded, antiparallel beta-sheet. The topology is different from adenylate kinase, but identical to the allosteric domain of Escherichia coli ATCase regulatory subunits, which bind mononucleotides at an equivalent position. Dimer contacts between NDP kinase subunits within the hexamer are similar to those in ATCase. Trimer contacts involve a large loop of polypeptide chain that bears the site of the Pro----Ser substitution in Killer of prune (K-pn) mutants of the highly homologous Drosophila enzyme. Properties of Drosophila NDP kinase, the product of the awd developmental gene, and of the human enzyme, the product of the nm23 genes in tumorigenesis, are discussed in view of the three-dimensional structure and of possible interactions of NDP kinase with other nucleotide binding proteins.     

Interactions between Escherichia coli nucleoside-diphosphate kinase and DNA.

Nucleoside-diphosphate (NDP) kinase (NTP:nucleoside-diphosphate phosphotransferase) catalyzes the reversible transfer of gamma-phosphates from nucleoside triphosphates to nucleoside diphosphates through an invariant histidine residue. It has been reported that the high-energy phosphorylated enzyme intermediate exhibits a protein phosphotransferase activity toward the protein histidine kinases CheA and EnvZ, members of the two-component signal transduction systems in bacteria. Here we demonstrate that the apparent protein phosphotransferase activity of NDP kinase occurs only in the presence of ADP, which can mediate the phosphotransfer from the phospho-NDP kinase to the target enzymes in catalytic amounts (approximately 1 nm). These findings suggest that the protein kinase activity of NDP kinase is probably an artifact attributable to trace amounts of contaminating ADP. Additionally, we show that Escherichia coli NDP kinase, like its human homologue NM23-H2/PuF/NDP kinase B, can bind and cleave DNA. Previous in vivo functions of E. coli NDP kinase in the regulation of gene expression that have been attributed to a protein phosphotransferase activity can be explained in the context of NDP kinase-DNA interactions. The conservation of the DNA binding and DNA cleavage activities between human and bacterial NDP kinases argues strongly for the hypothesis that these activities play an essential role in NDP kinase function in vivo.     

Comparative study of recombinant rat nucleoside diphosphate kinases alpha and beta by intrinsic protein fluorescence

Nucleoside diphosphate (NDP) kinases of mammals are hexamers of two sorts of randomly associated highly homologous subunits of 152 residues each and, therefore exist in cell as NDP kinase isoforms. The catalytic properties and three-dimensional structures of the isoforms are very similar. The physiological meaning of the existence of the isoforms in cells remained unclear, but studying recombinant rat NDP kinases alpha and beta, each containing only one sort of subunits, we discovered that, in contrast to the isoenzyme beta, NDP kinase alpha is able to interact with the complex between bleached rhodopsin and G-protein transducin in retinal rod membranes at lowered pH values (Orlov et al. FEBS Lett. 389, 186-190, 1996). In order to search for possible molecular basis of such differences between these isoenzymes, a detailed comparative study of their intrinsic fluorescence properties in a large range of solvent conditions was performed in this work. The isoenzymes alpha and beta both contain the same three tryptophan (Trp78, 133, Ind 149) and four tyrosine (Tyr 52, 67, 147, and 151) residues per subunit, but exhibit pronounced differences in their fluorescence properties (both in spectral positions and shape and quantum yield values) and behave differently under pH titration. Whereas NDP kinase alpha undergoes spectral changes in the pH range 5-7 with the mid-point at 6.2, no unequivocal indication of a structural change of NDP kinase beta under pH titration from 9 to 5 was obtained. Since the pH dependencies obtained for fluorescence of isoenzyme alpha resembles the dependence of its binding to the rhodopsin-transducin complex it was suggested that the differences between the NDP kinase isoenzymes alpha and beta in the pH-induced behavior, revealed by the fluorescence spectroscopy, and the differences in their ability to interact with rhodopsin-transducin complex may have the same physical nature, that would be a physico-chemical reason of possible functional dissimilarity of NDP kinase isoforms in cell. An additional analysis of three-dimensional structure of homologous NDP kinases revealed that the source of the differences in fluorescence properties and pH-titration behavior between the isoenzymes alpha and beta may be due to the difference in their global electrostatic charges, rather than to any structural differences between them at neutral pH. The unusually high positive electrostatic potential at he deeply buried active site Tyr52 makes possible that it exists in deprotonated tyrosinate form at neutral and moderately acidic solution. Such a possibility may account for rather unusual fluorescence properties of NDP kinase alpha: (i) rather long-wavelength emission of NDP kinase alpha at ca. 340 nm at pH ca. 8 at extremely low accessibility to external quenchers and, possibly, (ii) an unusually high quantum yield value (ca. 0.42).     

Investigation of chimerical and tagged forms of recombinant rat nucleoside diphosphate kinases α and β. Interaction with rhodopsin—transducin complex and thermal stability

To elucidate the physicochemical basis of differences between the isoforms of mammalian multifunctional nucleoside diphosphate kinase (NDP), we investigated the recombinant rat homohexameric NDP kinases alpha and beta, consisting of highly homologous alpha or beta subunits of 152 residues each and differing only in variable regions V1 and V2, and their chimerical forms (NDP kinase alpha(1-130)beta(131-152) and NDP kinase beta(1-130)alpha(131-152)) and tagged derivatives (NDP kinase HA-alpha(1-130)beta(131-152), NDP kinase HA-beta(1-130)alpha(131-152), and NDP kinase HA-beta). The thermal stability of these proteins and the ability of some of them to interact with the rhodopsin-transducin (R*Gt) complex have been studied. It was found that NDP kinase alpha, NDP kinase alpha(1-130)beta(131-152), and NDP kinase HA-alpha(1-130)beta(131-152) were similar in their thermal stability (T(1/2) = 61-63 degrees C). NDP kinase beta, NDP kinase beta(1-130)alpha(131-152), NDP kinase HA-beta(1-130)alpha(131-152), and NDP kinase HA-beta were inactivated at a lower temperature (T(1/2) = 51-54 degrees C). NDP kinase HA-alpha(1-130)beta(131-152) interacted with the R*Gt complex in the same manner as NDP kinase alpha, whereas the interaction of NDP kinase HA-beta(1-130)alpha(131-152) and NDP kinase beta with the photoreceptor membranes under the same conditions was very weak. It is suggested that the variability of the region V1 is a structural basis for the multifunctionality of NDP kinase hexamers in the cell.     

Comparative Study of Recombinant Rat Nucleoside Diphosphate Kinases α and β By Intrinsic Protein Fluorescence

Abstract

Nucleoside diphosphate (NDP) kinases of mammals are hexamers of two sorts of randomly associated highly homologous subunits of 152 residues each and, therefore exist in cell as NDP kinase isoforms. The catalytic properties and three-dimensional structures of the isoforms are very similar. The physiological meaning of the existence of the isoforms in cells remained unclear, but studying recombinant rat NDP kinases a and β, each containing only one sort of subunits, we discovered that, in contrast to the isoenzyme β, NDP kinase α is able to interact with the complex between bleached rhodopsin and G-protein transducin in retinal rod membranes at lowered pH values (Orlov et al. FEBS Lett. 389, 186–190, 1996). In order to search for possible molecular basis of such differences between these isoenzymes, a detailed comparative study of their intrinsic fluorescence properties in a large range of solvent conditions was performed in this work. The isoenzymes α and β both contain the same three tryptophan (Trp78, 133, 1nd 149) and four tyrosine (Tyr 52, 67, 147, and 151) residues per subunit, but exhibit pronounced differences in their fluorescence properties (both in spectral positions and shape and quantum yield values) and behave differently under pH titration. Whereas NDP kinase a undergoes spectral changes in the pH range 5–7 with the mid-point at 6.2, no unequivocal indication of a structural change of NDP kinase β under pH titration from 9 to 5 was obtained. Since the pH dependencies obtained for fluorescence of isoenzyme α resembles the dependence of its binding to the rhodopsin-transducin complex it was suggested that the differences between the NDP kinase isoenzymes α and β in the pH-induced behavior, revealed by the fluorescence spectroscopy, and the differences in their ability to interact with rhodopsin-transducin complex may have the same physical nature, that would be a physico-chemical reason of possible functional dissimilarity of NDP kinase isoforms in cell. An additional analysis of three-dimensional structure of homologous NDP kinases revealed that the source of the differences in fluorescence properties and pH-titration behavior between the isoenzymes α and β may be due to the difference in their global electrostatic charges, rather than to any structural differences between them at neutral pH. The unusually high positive electrostatic potential at he deeply buried active site Tyr52 makes possible that it exists in deprotonated tyrosinate form at neutral and moderately acidic solution. Such a possibility may account for rather unusual fluorescence properties of NDP kinase α: (i) rather long-wavelength emission of NDP kinase a at ca. 340 nm at pH ca. 8 at extremely low accessibility to external quenchers and, possibly, (ii) an unusually high quantum yield value (ca. 0.42).     

Autophosphorylation of nucleoside diphosphate kinase from Myxococcus xanthus.

The nucleoside diphosphate kinase (NDP kinase) from Myxococcus xanthus has been purified to homogeneity and crystallized (J. Munoz-Dorado, M. Inouye, and S. Inouye, J. Biol. Chem. 265:2702-2706, 1990). In the presence of ATP, the NDP kinase was autophosphorylated. Phosphoamino acid analysis was carried out after acid and base hydrolyses of phosphorylated NDP kinase. It was found that the protein was phosphorylated not only at a histidine residue but also at a serine residue. Replacement of histidine 117 with a glutamine residue completely abolished the autophosphorylation and nucleotide-binding activity of the NDP kinase. Since histidine 117 is the only histidine residue that is conserved in all known NDP kinases so far characterized, the results suggest that the phosphohistidine intermediate is formed at this residue during the transphosphorylation reaction from nucleoside triphosphates to nucleoside diphosphates. Preliminary mutational analysis of putative ATP-binding sites is also presented.     

Differential regulation by fatty acids of protein histidine phosphorylation in rat pancreatic islets

Long-chain fatty acids (e.g. arachidonic acid) have been implicated in physiological control of insulin secretion. We previously reported histidine phosphorylation of at least two islet proteins (e.g., NDP kinase and the beta subunit of trimeric G-proteins), and suggested that such a signalling step may have regulatory roles in beta cell signal transduction, specifically at the level of G-protein activation. Since our earlier findings also indicated potential regulation by long-chain fatty acids of islet G-proteins, we undertook the current study to verify putative regulation, by fatty acids, of protein histidine phosphorylation of NDP kinase and Gbeta subunit in normal rat islets. The phosphoenzyme formation of NDP kinase was stimulated by various fatty acids in the following rank order: linoleic acid > arachidonic acid > oleic acid > palmitic acid = stearic acid = control. Furthermore, the catalytic activity of NDP kinase was stimulated by these fatty acids in the rank order of: oleic acid > arachidonic acid > linoleic acid > palmitic acid = stearic acid = control. Arachidonic acid methyl ester, an inactive analog of arachidonic acid, did not significantly affect either the phosphoenzyme formation or the catalytic activity of NDP kinase. Interestingly, arachidonic acid exerted dual effects on the histidine phosphorylation of beta subunit; it significantly stimulated the phosphorylation at 33 microM beyond which it was inhibitory. Together, these findings identify additional loci (e.g., NDP kinase and Gbeta subunit) at which unsaturated, but not saturated, fatty acids could exert their intracellular effects leading to exocytotic secretion of insulin.     

The Human Nm23/Nucleoside Diphosphate Kinases

Biochemical experiments over the past 40 years have shown that nucleoside diphosphate(NDP) kinase activity, which catalyzes phosphoryl transfer from a nucleoside triphosphate toa nucleoside diphosphate, is ubiquitously found in organisms from bacteria to human. Overthe past 10 years, eight human genes of the nm23/NDP kinase family have been discoveredthat can be separated into two groups based on analysis of their sequences. In addition tocatalysis, which may not be exhibited by all isoforms, evidence for regulatory roles has comerecently from the discovery of the genes nm23 and awd, which encode NDP kinases and areinvolved in tumor metastasis and Drosophila development, respectively. Current work showsthat the human NDP kinase genes are differentially expressed in tissues and that their productsare targeted to different subcellular locations. This suggests that Nm23/NDP kinases possessdifferent, but specific, functions within the cell, depending on their localization. The roles ofNDP kinases in metabolic pathways and nucleic acid synthesis are discussed.