cDNA-derived sequence of UMP-CMP kinase from Dictyostelium discoideum and expression of the enzyme in Escherichia coli

Regulation of carbamoylphosphate synthesis in Escherichia coli: an amazing metabolite at the crossroad of arginine and pyrimidine biosynthesis

In all organisms, carbamoylphosphate (CP) is a precursor common to the synthesis of arginine and pyrimidines. In Escherichia coli and most other Gram-negative bacteria, CP is produced by a single enzyme, carbamoylphosphate synthase (CPSase), encoded by the carAB operon. This particular situation poses a question of basic physiological interest: what are the metabolic controls coordinating the synthesis and distribution of this high-energy substance in view of the needs of both pathways? The study of the mechanisms has revealed unexpected moonlighting gene regulatory activities of enzymes and functional links between mechanisms as diverse as gene regulation and site-specific DNA recombination. At the level of enzyme production, various regulatory mechanisms were found to cooperate in a particularly intricate transcriptional control of a pair of tandem promoters. Transcription initiation is modulated by an interplay of several allosteric DNA-binding transcription factors using effector molecules from three different pathways (arginine, pyrimidines, purines), nucleoid-associated factors (NAPs), trigger enzymes (enzymes with a second unlinked gene regulatory function), DNA remodeling (bending and wrapping), UTP-dependent reiterative transcription initiation, and stringent control by the alarmone ppGpp. At the enzyme level, CPSase activity is tightly controlled by allosteric effectors originating from different pathways: an inhibitor (UMP) and two activators (ornithine and IMP) that antagonize the inhibitory effect of UMP. Furthermore, it is worth noticing that all reaction intermediates in the production of CP are extremely reactive and unstable, and protected by tunneling through a 96 Å long internal channel.

UMP kinase activity is involved in proper chloroplast development in rice

Isolation of leaf-color mutants is important in understanding the mechanisms of chloroplast biogenesis and development. In this study, we identified and characterized a rice (Oryza sativa) mutant, yellow leaf 2 (yl2), exhibiting pale yellow leaves with a few longitudinal white stripes at the early seedling stage then gradually turning yellow. Genetic analyses revealed that YL2 encodes a thylakoid membrane-localized protein with significant sequence similarity to UMP kinase proteins in prokaryotes and eukaryotes. Prokaryotic UMP kinase activity was subsequently confirmed, with YL2 deficiency causing a significant reduction in chlorophyll accumulation and photochemical efficiency. Moreover, YL2 is also light dependent and preferentially expressed in green tissues. Chloroplast development was abnormal in the yl2 mutant, possibly due to reduced accumulation of thylakoid membranes and a lack of normal stroma lamellae. 2D Blue-Native SDS-PAGE and immunoblot analyses revealed a reduction in several subunits of photosynthetic complexes, in particular, the AtpB subunit of ATP synthase, while mRNA levels of corresponding genes were unchanged or increased compared with the wild type. In addition, we observed a significant decrease (ca. 36.3%) in cpATPase activity in the yl2 mutant compared with the wild type. Taken together, our results suggest that UMP kinase activity plays an essential role in chloroplast development and regulating cpATPase biogenesis in rice.

Molecular Docking Evaluation of (E)-5-arylidene-2-thioxothiazolidin-4-one Derivatives as Selective Bacterial Adenylate Kinase Inhibitors

Multi-drug resistant microorganism infections with emerging problems that require not only a prevention strategy, but also the development of new inhibitory compounds. Six previously synthesized 5-arylidene-2-thioxothiazolidin-4-one derivatives 1a–f, were screened for inhibitory activity on adenylate kinases of different origins by molecular docking. The compounds 1c and 1d were the most efficient inhibitors of bacterial and some archean adenylate kinases. Hydrogen bond interactions were observed with the residues belonging to the ATP binding site. Moreover human adenylate kinases are poor targets, suggesting that this selectivity offers promising prospectives for refining the structure of our compounds.

The influence of proline isomerization and off-pathway intermediates on the folding mechanism of eukaryotic UMP/CMP Kinase

The globular 22-kDa protein UMP/CMP from Dictyostelium discoideum (UmpK) belongs to the family of nucleoside monophosphate (NMP) kinases. These enzymes not only show high sequence and structure similarities but also share the alpha/beta-fold, a very common protein topology. We investigated the protein folding mechanism of UmpK as a representative for this ubiquitous enzyme class. Equilibrium stability towards urea and the unfolding and refolding kinetics were studied by means of fluorescence and far-UV CD spectroscopy. Although the unfolding can be described by a two-state process, folding kinetics are rather complex with four refolding phases that can be resolved and an additional burst phase. Moreover, two of these phases exhibit a pronounced rollover in the refolding limb that cannot be explained by aggregation. Whilst secondary structure formation is not observed in the burst phase reaction, folding to the native structure is strongly influenced by the slowest phase, since 30% of the alpha-helical CD signal is restored therein. This process can be assigned to proline isomerization and is strongly accelerated by the Escherichia coli peptidyl-prolyl isomerase trigger factor. The analysis of our single-mixing and double-mixing experiments suggests the occurrence of an off-pathway intermediate and an unproductive collapsed structure, which appear to be rate limiting for the folding of UmpK.

Structural and functional consequences of single amino acid substitutions in the pyrimidine base binding pocket of Escherichia coli CMP kinase

Bacterial CMP kinases are specific for CMP and dCMP, whereas the related eukaryotic NMP kinase phosphorylates CMP and UMP with similar efficiency. To explain these differences in structural terms, we investigated the contribution of four key amino acids interacting with the pyrimidine ring of CMP (Ser36, Asp132, Arg110 and Arg188) to the stability, catalysis and substrate specificity of Escherichia coli CMP kinase. In contrast to eukaryotic UMP/CMP kinases, which interact with the nucleobase via one or two water molecules, bacterial CMP kinase has a narrower NMP-binding pocket and a hydrogen-bonding network involving the pyrimidine moiety specific for the cytosine nucleobase. The side chains of Arg110 and Ser36 cannot establish hydrogen bonds with UMP, and their substitution by hydrophobic amino acids simultaneously affects the K(m) of CMP/dCMP and the k(cat) value. Substitution of Ser for Asp132 results in a moderate decrease in stability without significant changes in K(m) value for CMP and dCMP. Replacement of Arg188 with Met does not affect enzyme stability but dramatically decreases the k(cat)/K(m) ratio compared with wild-type enzyme. This effect might be explained by opening of the enzyme/nucleotide complex, so that the sugar no longer interacts with Asp185. The reaction rate for different modified CMP kinases with ATP as a variable substrate indicated that none of changes induced by these amino acid substitutions was 'propagated' to the ATP subsite. This 'modular' behavior of E. coli CMP kinase is unique in comparison with other NMP kinases.

A modular minimal cell model: purine and pyrimidine transport and metabolism

A more complete understanding of the relationship of cell physiology to genomic structure is desirable. Because of the intrinsic complexity of biological organisms, only the simplest cells will allow complete definition of all components and their interactions. The theoretical and experimental construction of a minimal cell has been suggested as a tool to develop such an understanding. Our ultimate goal is to convert a "coarse-grain" lumped parameter computer model of Escherichia coli into a genetically and chemically detailed model of a "minimal cell." The base E. coli model has been converted into a generalized model of a heterotrophic bacterium. This coarse-grain minimal cell model is functionally complete, with growth rate, composition, division, and changes in cell morphology as natural outputs from dynamic simulations where only the initial composition of the cell and of the medium are specified. A coarse-grain model uses pseudochemical species (or modules) that are aggregates of distinct chemical species that share similar chemistry and metabolic dynamics. This model provides a framework in which these modules can be "delumped" into chemical and genetic descriptions while maintaining connectivity to all other functional elements. Here we demonstrate that a detailed description of nucleotide precursors transport and metabolism is successfully integrated into the whole-cell model. This nucleotide submodel requires fewer (12) genes than other theoretical predictions in minimal cells. The demonstration of modularity suggests the possibility of developing modules in parallel and recombining them into a fully functional chemically and genetically detailed model of a prokaryote cell.

Evolution and classification of P-loop kinases and related proteins

Sequences and structures of all P-loop-fold proteins were compared with the aim of reconstructing the principal events in the evolution of P-loop-containing kinases. It is shown that kinases and some related proteins comprise a monophyletic assemblage within the P-loop NTPase fold. An evolutionary classification of these proteins was developed using standard phylogenetic methods, analysis of shared sequence and structural signatures, and similarity-based clustering. This analysis resulted in the identification of approximately 40 distinct protein families within the P-loop kinase class. Most of these enzymes phosphorylate nucleosides and nucleotides, as well as sugars, coenzyme precursors, adenosine 5'-phosphosulfate and polynucleotides. In addition, the class includes sulfotransferases, amide bond ligases, pyrimidine and dihydrofolate reductases, and several other families of enzymes that have acquired new catalytic capabilities distinct from the ancestral kinase reaction. Our reconstruction of the early history of the P-loop NTPase fold includes the initial split into the common ancestor of the kinase and the GTPase classes, and the common ancestor of ATPases. This was followed by the divergence of the kinases, which primarily phosphorylated nucleoside monophosphates (NMP), but could have had broader specificity. We provide evidence for the presence of at least two to four distinct P-loop kinases, including distinct forms specific for dNMP and rNMP, and related enzymes in the last universal common ancestor of all extant life forms. Subsequent evolution of kinases seems to have been dominated by the emergence of new bacterial and, to a lesser extent, archaeal families. Some of these enzymes retained their kinase activity but evolved new substrate specificities, whereas others acquired new activities, such as sulfate transfer and reduction. Eukaryotes appear to have acquired most of their kinases via horizontal gene transfer from Bacteria, partly from the mitochondrial and chloroplast endosymbionts and partly at later stages of evolution. A distinct superfamily of kinases, which we designated DxTN after its sequence signature, appears to have evolved in selfish replicons, such as bacteriophages, and was subsequently widely recruited by eukaryotes for multiple functions related to nucleic acid processing and general metabolism. In the course of this analysis, several previously undetected groups of predicted kinases were identified, including widespread archaeo-eukaryotic and archaeal families. The results could serve as a framework for systematic experimental characterization of new biochemical and biological functions of kinases.

Reaction of human UMP-CMP kinase with natural and analog substrates

UMP-CMP kinase catalyses an important step in the phosphorylation of UTP, CTP and dCTP. It is also involved in the necessary phosphorylation by cellular kinases of nucleoside analogs used in antiviral therapies. The reactivity of human UMP-CMP kinase towards natural substrates and nucleotide analogs was reexamined. The expression of the recombinant enzyme and conditions for stability of the enzyme were improved. Substrate inhibition was observed for UMP and CMP at concentrations higher than 0.2 mm, but not for dCMP. The antiviral analog l-3TCMP was found to be an efficient substrate phosphorylated into l-3TCDP by human UMP-CMP kinase. However, in the reverse reaction, the enzyme did not catalyse the addition of the third phosphate to l-3TCDP, which was rather an inhibitor. By molecular modelling, l-3TCMP was built in the active site of the enzyme from Dictyostelium. Human UMP-CMP kinase has a relaxed enantiospecificity for the nucleoside monophosphate acceptor site, but it is restricted to d-nucleotides at the donor site.

Purification and characterization of the deoxynucleoside monophosphate kinase of bacteriophage T5

Deoxynucleoside monophosphate kinase (dNMP kinase) of bacteriophage T5 (EC 2.7.4.13) was purified to apparent homogeneity from phage-infected Escherichia coli cells. Electrophoresis in sodium dodecyl sulfate-polyacrylamide gel showed that the enzyme has a molecular mass of about 29 kDa. The molecular mass of dNMP kinase estimated by analytical equilibrium ultracentrifugation turned out to be 29.14 +/- 3.03 kDa. These data suggest that the enzyme exists in solution as a monomer. The isoelectric point of dNMP kinase was found to be 4.2. The N-terminal amino acid sequence, comprising 21 amino acids, was determined to be VLVGLHGEAGSGKDGVAKLII. A comparison of this amino acid sequence and those of known enzymes with a similar function suggests the presence of a nucleotide-binding site in the sequenced region.

Cellular phosphorylation of 2',3'-dideoxyadenosine-5'-monophosphate, a key intermediate in the activation of the antiviral agent DDI, in human peripheral blood mononuclear cells

2',3'-dideoxyadenosine 5-monophosphate (ddAMP), is a key intermediate in the metabolism of the antiviral agent 2',3'-dideoxyinosine (ddI) to its active triphosphate derivative, 2',3'-dideoxyadenosine-5'-triphosphate (ddATP). The potential role of adenylate kinase in the phosphorylation of ddAMP was studied in human peripheral blood mononuclear cells (PBMC) and a human T cell line, CEMss. Subcellular distribution, sulfhydryl inhibitor, and substrate specificity studies support the hypothesis that the mitochondrial adenylate kinase (AK2) is a major route of cellular activation of these compounds in human lymphocytes.

Phosphorylation of deoxycytidine analog monophosphates by UMP-CMP kinase: molecular characterization of the human enzyme

Phosphorylation of deoxycytidine analogs by cellular enzymes is a prerequisite for the activity of these compounds. We have investigated the kinetic parameters for the phosphorylation of 1-beta-D-arabinofuranosylcytosine (araC) and 2', 2'-difluorodeoxycytidine (dFdC) to their diphosphate forms catalyzed by human UMP-CMP kinase. We cloned the cDNA of this enzyme to enable characterization of the recombinant protein, determine its expression in different tissues, and determine the chromosome location of the gene. We showed that the recombinant UMP-CMP kinase phosphorylated CMP, dCMP, and UMP with highest efficiency and dUMP, AMP, and dAMP with lower efficiency. The monophosphates of araC and dFdC were shown to be phosphorylated with similar efficiency as dCMP and CMP. We further showed, in a combined enzymatic assay, that human deoxycytidine kinase and UMP-CMP kinase together phosphorylated araC, dFdC, and 2',3'-dideoxycytidine to their diphosphate forms. Northern blot analysis showed that the UMP-CMP kinase mRNA was ubiquitously present in human tissues as a 3.9-kb transcript with highest levels in pancreas, skeletal muscle, and liver. The human UMP-CMP kinase gene was localized to chromosome 1p34.1-1p33 by radiation hybrid analysis. We further expressed the UMP-CMP kinase as a fusion protein to the green fluorescent protein in Chinese hamster ovary cells, and showed that the fusion protein was located in the cytosol and nucleus.

Nucleoside monophosphate kinases: structure, mechanism, and substrate specificity

The catalytic mechanisms of adenylate kinase, guanylate kinase, uridylate kinase, and cytidylate kinase are reviewed in terms of kinetic and structural information that has been obtained in recent years. All four kinases share a highly related tertiary structure, characterized by a central five-stranded parallel beta-sheet with helices on both sides, as well as the three regions designated as the CORE, NMPbind, and LID domains. The catalytic mechanism continues to be refined to higher levels of resolution by iterative structure-function studies, and the strengths and limitations of site-directed mutagenesis are well illustrated in the case of adenylate kinase. The identity and roles of active site residues now appear to be resolved, and this review describes how specific site substitutions with unnatural amino acid side-chains have proven to be a major advance. Likewise, there is mounting evidence that phosphoryl transfer occurs by an associative transition state, based on (a) the stereochemical course of phosphoryl transfer, (b) geometric considerations, (c) examination of likely electronic distributions, (d) the orientation of the phosphoryl acceptor relative to the phosphoryl being transferred, (e) the most likely role of magnesium ion, (f) the lack of restricted access of solvent water, and (g) the results of oxygen-18 kinetic isotope. effect experiments.

Structures of escherichia coli CMP kinase alone and in complex with CDP: a new fold of the nucleoside monophosphate binding domain and insights into cytosine nucleotide specificity

BACKGROUND

. Nucleoside monophosphate kinases (NMP kinases) catalyze the reversible transfer of a phosphoryl group from a nucleoside triphosphate to a nucleoside monophosphate. Among them, cytidine monophosphate kinase from Escherichia coli has a striking particularity: it is specific for CMP, whereas in eukaryotes a unique UMP/CMP kinase phosphorylates both CMP and UMP with similar efficiency.

RESULTS

. The crystal structure of the CMP kinase apoenzyme from E. coli was solved by single isomorphous replacement and refined at 1.75 A resolution. The structure of the enzyme in complex with CDP was determined at 2.0 A resolution. Like other NMP kinases, the protein contains a central parallel beta sheet, the strands of which are connected by alpha helices. The enzyme differs from other NMP kinases in the presence of a 40-residue insert situated in the NMP-binding (NMPbind) domain. This insert contains two domains: one comprising a three-stranded antiparallel beta sheet, the other comprising two alpha helices.

CONCLUSIONS

. Two features of the CMP kinase from E. coli have no equivalent in other NMP kinases of known structure. Firstly, the large NMPbind insert undergoes a CDP-induced rearrangement: its beta-sheet domain moves away from the substrate, whereas its helical domain comes closer to it in a motion likely to improve the protection of the active site. Secondly, residues involved in CDP recognition are conserved in CMP kinases and have no counterpart in other NMP kinases. The structures presented here are the first of a new family of NMP kinases specific for CMP.

Site-specific mutations of conserved residues in the phosphate-binding loop of the Arabidopsis UMP/CMP kinase alter ATP and UMP binding

All eukaryotic UMP/CMP kinases contain a glycine-rich sequence GGPG(S/A)GK at the N-terminus. This sequence is homologous to the conserved sequence GXXGXGK found in other ATP-binding proteins. To study the role of this conserved sequence in Arabidopsis UMP/CMP kinase, five conserved residues were mutated by site-directed mutagenesis to generate seven mutant enzymes: G21A, G22A, G24A, G26A, K27R, K27M, and K27E. The G21A and G26A mutants were degraded during the purification phase and were thus unable to be purified. Kinetic studies on the other mutants, when compared to studies on the wild-type enzyme, revealed that this sequence is important for ATP binding and enzyme catalysis. All mutants had a decreased kcat/KATPm value. The G22A and G24A mutants had about half of the kcat value of wildtype and 3.9-fold and 3.3-fold increases in KATPm values, respectively. The kcat/KATPm values in the K27M and K27E mutants were changed significantly and decreased by 1000-fold and 2600-fold, respectively. The removal of the terminal positive charge of Lys27 in the K27M and K27E mutants resulted in 20% of the kcat value of wildtype. However, both mutants had a remarkable increase in KATPm value by 241-fold and 552-fold, respectively. Therefore, the positive charge of Lys27 plays an important role on both ATP binding and enzyme catalysis. Interestingly, the results also showed that the mutations that affected ATP binding also had an effect on UMP binding.

pyrH-encoded UMP-kinase directly participates in pyrimidine-specific modulation of promoter activity in Escherichia coli

The carAB operon of the enterics Escherichia coli K-12 and Salmonella typhimurium LT2, encoding the sole carbamoylphosphate synthetase (CPSase) of these organisms, is transcribed from two promoters in tandem, carP1 upstream and carP2 downstream, repressed respectively by pyrimidines and arginine. We present evidence that the pyrH gene product (the hexameric UMP-kinase) directly participates in the pyrimidine-specific control of carP1 activity. Indeed, we have isolated in E. coli a particular type of pyrH mutation (pyrH41) that retains a quasi-normal UMP-kinase activity, but yet is impaired in the pyrimidine-specific repression of the P1 promoter of the carAB operon of E. coli and of S. typhimurium. Moreover, the pyrimidine-dependent inhibition of in vivo Dam methylase modification of adenine -106 upstream of the carP1 promoter is altered in this pyrH mutant. The recessive pyrH41 allele bears a single C-G to A-T transversion that converts alanine 94 into glutamic acid (A94E). Although overexpression of pyrH41 results in UMP-kinase levels far above that of a wild-type strain, pyrimidine-specific repression of the carAB operon is not restored under these conditions. Similarly, overexpression of the UMP-CMP-kinase gene of Dictyostelium discoideum in the pyrH41 mutant does not restore pyrimidine-mediated control of carP1 promoter activity, in spite of the elevated UMP-kinase activity measured in such transformants. These results indicate that besides its catalytic function in the de novo pyrimidine biosynthesis, E. coli UMP-kinase fulfils an additional, but previously unrecognized role in the regulation of the carAB operon. UMP-kinase might function as the real sensor of the internal pyrimidine nucleotide pool and act in concert with the integration host factor (IHF) and aminopeptidase A (PepA alias CarP and XerB) in the elaboration of the complex nucleoprotein structure required for pyrimidine-specific repression of carP1 promoter activity.

Cloning, sequence analysis and expression of the basidiomycete Lentinus edodes gene uck1, encoding UMP-CMP kinase, the homologue of Saccharomyces cerevisae URA6 gene

Sequence analysis of the downstream region of the basidiomycete Lentinus edodes priB gene encoding a protein with a 'Zn(II)2Cys6 zinc cluster' DNA-binding motif (Endo, H., Kajiwara, S., Tunoka, O., Shishido, K., 1994. A novel cDNA, priBc, encoding a protein with a Zn(II)2Cys6 zinc cluster DNA-binding motif, derived from the basidiomycete Lentinus edodes. Gene 139, 117-121) suggested the presence of a Saccharomyces cerevisiae URA6 gene homologue encoding UMP kinase. We isolated a corresponding cDNA from a mature fruiting-body cDNA library of L. edodes. The nucleotide sequence of this was determined and compared with that of the genomic DNA, revealing that the URA6 gene homologue encodes 227 amino acids (aa) and is interrupted by four small introns. The deduced aa sequence showed an overall identity of 51.1% to that of the S. cerevisiae URA6 gene product. The URA6 homologue protein produced in Escherichia coli using the glutathione S-transferase gene fusion system was found to catalyze the phosphoryl transfer from ATP to UMP and CMP efficiently and also to AMP and dCMP with lower efficiencies. Thus, the URA6 gene homologue was designated uck1 and its product UMP-CMP kinase. Northern-blot analysis showed that the uck1 is actively transcribed in the gill tissue of mature fruiting bodies of L. edodes, implying that uck1 may play a role during the formation of basidiospores occurs in the gill tissue.

Cloning, expression in Escherichia coli, and characterization of Arabidopsis thaliana UMP/CMP kinase

A cDNA encoding the Arabidopsis thaliana uridine 5'-monophosphate (UMP)/cytidine 5'-monophosphate (CMP) kinase was isolated by complementation of a Saccharomyces cerevisiae ura6 mutant. The deduced amino acid sequence of the plant UMP/CMP kinase has 50% identity with other eukaryotic UMP/CMP kinase proteins. The cDNA was subcloned into pGEX-4T-3 and expressed as a glutathione S-transferase fusion protein in Escherichia coli. Following proteolytic digestion, the plant UMP/CMP kinase was purified and analyzed for its structural and kinetic properties. The mass, N-terminal sequence, and total amino acid composition agreed with the sequence and composition predicted from the cDNA sequence. Kinetic analysis revealed that the UMP/CMP kinase preferentially uses ATP (Michaelis constant [Km] = 29 microM when UMP is the other substrate and Km = 292 microM when CMP is the other substrate) as a phosphate donor. However, both UMP (Km = 153 microM) and CMP (Km = 266 microM) were equally acceptable as the phosphate acceptor. The optimal pH for the enzyme is 6.5. P1, P5-di(adenosine-5') pentaphosphate was found to be a competitive inhibitor of both ATP and UMP.

Cloning and heterologous expression of Entamoeba histolytica adenylate kinase and uridylate/cytidylate kinase

We have isolated two cDNA clones encoding Entamoeba histolytica nucleotide kinases, EhAK and EhUK, expressed them in E. coli and performed functional studies of the recombinant enzymes. Nucleotide sequence analysis showed that EhAK and EhUK genes exhibited the features characteristic of E. histolytica genes, such as transcripts with relatively short 5' and 3' untranslated flanking regions containing the conserved E. histolytica transcription promoter elements located 5' to the initiation codon and a polyadenylation signal in the 3' UTR, a distinctive codon usage bias for A or T in the third position and an AT bias greater than 75% in the flanking regions of the transcripts. At the protein level, both enzymes belong to the short variant nucleoside monophosphate (NMP) kinases, which lack a 29amino acid LID region present in the long variant isoenzymes. EhAK was 30-38% identical to the members of the adenylate kinase (AK) family while EhUK was more similar (48-49% identity) to UMP/CMP kinases. Both enzymes used ATP as preferred phosphate-group donor but each one exhibited strict specificity for the acceptor NMP, EhAK for AMP and EhUK for the pyrimidine nucleoside monophosphates UMP and CMP. Biochemical characterization of the enzymes and phylogenetic reconstruction showed that EhUK is an authentic and well conserved member of the UMP/CMP kinase group while EhAK is the most divergent member known of the AK1 isoenzymes.

Structural and catalytic properties of CMP kinase from Bacillus subtilis: a comparative analysis with the homologous enzyme from Escherichia coli

CMP kinases from Bacillus subtilis and from Escherichia coli are encoded by the cmk gene (formerly known as jofC in B. subtilis and as mssA in E. coli). Similar in their primary structure (43% identity and 67% similarity in amino acid sequence), the two proteins exhibit significant differences in nucleotide binding and catalysis. ATP, dATP, and GTP are equally effective as phosphate donors with E. coli CMP kinase whereas GTP is a poor substrate with B. subtilis CMP kinase. While CMP and dCMP are the best phosphate acceptors of both CMP kinases, the specific activity with these substrates and ATP as donor are 7- to 10-fold higher in the E. coli enzyme; the relative Vm values with UMP and CMP are 0.1 for the B. subtilis CMP kinase and 0.01 for the E. coli enzyme. CMP increased the affinity of E. coli CMP kinase for ATP or for the fluorescent analog 3'-anthraniloyl dATP by one order of magnitude but had no effect on the B. subtilis enzyme. The differences in the catalytic properties of B. subtilis and E. coli CMP kinases might be reflected in the structure of the two proteins as inferred from infrared spectroscopy. Whereas the spectrum of B. subtilis CMP kinase is dominated by a band at 1633 cm-1 (representing beta type structures), the spectrum of the E. coli enzyme is dominated by two bands at 1653 and 1642 cm-1 associated with alpha-helical and unordered structures, respectively. CMP induced similar spectral changes in both proteins with a rearrangement of some of the beta-structures. ATP increases the denaturation temperature of B. subtilis CMP kinase by 9.3 degrees C, whereas in the case of the E. coli enzyme, binding of ATP has only a minor effect.

Cloning and characterization of the gene encoding Halobacterium halobium adenylate kinase

The gene (AK) encoding adenylate kinase (AK) of Halobacterium halobium was cloned. AK consisted of 648 bp and coded for 216 amino acids (aa). S1 mapping and primer extension experiments indicated that the transcription start point (tsp) was located immediately upstream from the start codon. The TAT-like promoter sequence was found at a position 20-24 bp upstream from tsp. The most striking property of the enzyme was a putative Zn finger-like structure with four cysteines. It might contribute to the structural stability of the molecule in high-salt conditions. Phylogenetic analysis indicated two lineages of the AK family, the short and long types which diverged a long time ago, possibly before the separation of prokaryotes and eukaryotes. Although the H. halobium AK belongs to the long-type AK lineage, it is located in an intermediary position between the two lineages of the phylogenetic tree, indicating early divergence of the gene along the long-type lineage.

Crystal structure of the complex of UMP/CMP kinase from Dictyostelium discoideum and the bisubstrate inhibitor P1-(5'-adenosyl) P5-(5'-uridyl) pentaphosphate (UP5A) and Mg2+ at 2.2 A: implications for water-mediated specificity

The three-dimensional structure of the UMP/CMP kinase (UK) from the slime mold Dictyostelium discoideum complexed with the specific and asymmetric bisubstrate inhibitor P1-(5'-adenosyl) P5-(5'-uridyl) pentaphosphate (UP5A) has been determined at a resolution of 2.2 A. The structure of the enzyme, which has up to 41% sequence homology with known adenylate kinases (AK), represents a closed conformation with the flexible monophosphate binding domain (NMP site) being closed over the uridyl moiety of the dinucleotide. Two water molecules were found within hydrogen-bonding distance to the uracil base. The key residue for the positioning and stabilization of those water molecules appears to be asparagine 97, a residue that is highly specific for AK-homologous UMP kinases, but is almost invariably a glutamine in adenylate kinases. Other residues in this region are highly conserved among AK-related NMP kinases. The catalytic Mg2+ ion is coordinated with octahedral geometry to four water molecules and two oxygens of the phosphate chain of UP5A but has no direct interactions with the protein. The comparison of the geometry of the UKdicty.UP5A.Mg2+ complex with the previously reported structure of the UKyeast.ADP.ADP complex [Müller-Dieckmann & Schulz (1994) J. Mol. Biol. 236, 361-367] suggests that UP5A in our structure mimics an ADP.Mg.UDP biproduct inhibitor rather than an ATP. MG.UMP bisubstrate inhibitor.

Structural properties of UMP-kinase from Escherichia coli: modulation of protein solubility by pH and UTP

UMP-kinase from Escherichia coli, unlike the analogous enzyme from eukaryotic organisms, is an oligomeric protein subjected to complex regulatory mechanisms in which UTP and GTP act as allosteric effectors. While the enzyme has an unusually low solubility at neutral pH (< or = 0.1 mg of protein/ mL), its solubility increases markedly above pH 8 and below pH 4. Furthermore, the solubility of the bacterial UMP-kinase at neutral pH is greatly enhanced in the presence of Mg-free UTP. Thermal denaturation experiments have demonstrated that UTP also increases the stability of the protein. Fourier-transform infrared spectroscopy and circular dichroism show that the secondary structure of the protein is the same at neutral and at alkaline pH. These data indicate that variations in enzyme solubility must be related to subtle changes in the tertiary and/or quaternary structure which modulate the exposure of hydrophobic surfaces in the protein molecule. A variant of UMP-kinase, obtained by site-directed mutagenesis (Asp159Asn), which is similar to the wild-type enzyme in its stability and kinetic properties, has a much increased water solubility (> 5 mg protein/mL) even at neutral pH. This suggests that salt bridges may be involved in the equilibrium between the soluble and aggregated forms of the wild-type enzyme, and that conformational changes induced upon binding of UTP increase the protein solubility by disrupting these salt bridges.

Ancient divergence of long and short isoforms of adenylate kinase: molecular evolution of the nucleoside monophosphate kinase family

Adenylate kinases (AK) from vertebrates are separated into three isoforms, AK1, AK2 and AK3, based on structure, subcellular localization and substrate specificity. AK1 is the short type with the amino acid sequence being 27 residues shorter than sequences of the long types, AK2 and AK3. A phylogenetic tree prepared for the AK isozymes and other members of the nucleoside monophosphate (NMP) kinase family shows that the divergence of long and short types occurred first and then differentiation in subcellular localization or substrate specificity took place. The first step involved a drastic change in the three-dimensional structure of the LID domain. The second step was caused mainly by smaller changes in amino acid sequences.

CMP kinase from Escherichia coli is structurally related to other nucleoside monophosphate kinases

CMP kinase from Escherichia coli is a monomeric protein of 225 amino acid residues. The protein exhibits little overall sequence similarities with other known NMP kinases. However, residues involved in binding of substrates and/or in catalysis were found conserved, and sequence comparison suggested conservation of the global fold found in adenylate kinases or in several CMP/UMP kinases. The enzyme was purified to homogeneity, crystallized, and analyzed for its structural and catalytic properties. The crystals belong to the hexagonal space group P6(3), have unit cell parameters a = b = 82.3 A and c = 60.7 A, and diffract x-rays to a 1.9 A resolution. The bacterial enzyme exhibits a fluorescence emission spectrum with maximum at 328 nm upon excitation at 295 nm, which suggests that the single tryptophan residue (Trp30) is located in a hydrophobic environment. Substrate specificity studies showed that CMP kinase from E. coli is active with ATP, dATP, or GTP as donors and with CMP, dCMP, and arabinofuranosyl-CMP as acceptors. This is in contrast with CMP/UMP kinase from Dictyostelium discoideum, an enzyme active on CMP or UMP but much less active on the corresponding deoxynucleotides. Binding of CMP enhanced the affinity of E. coli CMP kinase for ATP or ADP, a particularity never described in this family of proteins that might explain inhibition of enzyme activity by excess of nucleoside monophosphate.

Strain-dependent occurrence of functional GTP:AMP phosphotransferase (AK3) in Saccharomyces cerevisiae

The gene for yeast GTP:AMP phosphotransferase (PAK3) was found to encode a nonfunctional protein in 10 laboratory strains and one brewers' strain. The protein product showed high similarity to vertebrate AK3 and was located exclusively in the mitochondrial matrix. The deduced amino acid sequence revealed a protein that was shorter at the carboxyl terminus than all other known adenylate kinases. Introduction of a +1 frameshift into the 3'-terminal region of the gene extended homology of the deduced amino acid sequence to other members of the adenylate kinase family including vertebrate AK3. Frameshift mutations obtained after in vitro and in vivo mutagenesis were capable of complementing the adk1 temperature-conditional deficiency in Escherichia coli, indicating that the frameshift led to the expression of a protein that could phosphorylate AMP. Some yeasts, however, including strain D273-10B, two wine yeasts, and two more distantly related yeast genera, harbored an active allele, named AKY3, which contained a +1 frameshift close to the carboxyl terminus as compared with the laboratory strains. The encoded protein exhibited GTP:AMP and ITP:AMP phosphotransferase activities but did not accept ATP as phosphate donor. Although single copy in the haploid genome, disruption of the AKY3 allele displayed no phenotype, excluding the possibility that laboratory and brewers' strains had collected second site suppressors. It must be concluded that yeast mitochondria can completely dispense with GTP:AMP phosphotransferase activity.

Escherichia coli UMP-kinase, a member of the aspartokinase family, is a hexamer regulated by guanine nucleotides and UTP

The pyrH gene, encoding UMP-kinase from Escherichia coli, was cloned using as a genetic probe the property of the carAB operon to be controlled for its expression by the concentration of cytoplasmic UTP. The open reading frame of the pyrH gene of 723 bp was found to be identical to that of the smbA gene [Yamanaka, K., et al. (1992) J. Bacteriol. 174, 7517-7526], previously described as being involved in chromosome partitioning in E. coli. The bacterial UMP-kinase did not display significant sequence similarity to known nucleoside monophosphate kinases. On the contrary, it exhibited similarity with three families of enzymes including aspartokinases, glutamate kinases, and Pseudomonas aeruginosa carbamate kinase. UMP-kinase overproduced in E. coli was purified to homogeneity and analyzed for its structural and catalytic properties. The protein consists of six identical subunits, each of 240 amino acid residues (the N-terminal methionine residue is missing in the expressed protein). Upon excitation at 295 nm, the bacterial enzyme exhibits a fluorescence emission spectrum with maximum at 332 nm which indicates that the single tryptophan residue of the protein (Trp119) is located in a hydrophobic environment. Like other enzymes involved in the de novo synthesis of pyrimidine nucleotides, UMP-kinase of E. coli is subject to regulation by nucleotides: GTP is an allosteric activator, whereas UTP serves as an allosteric inhibitor. UTP and UDP, but none of the other nucleotides tested such as GTP, ATP, and UMP, enhanced the fluorescence of the protein. The sigmoidal shape of the dose-response curve indicated cooperativity in binding of UTP and UDP.(ABSTRACT TRUNCATED AT 250 WORDS)

Crystallization and preliminary X-ray analysis of UMP/CMP-kinase from Dictyostelium discoideum with the specific bisubstrate inhibitor P1-(adenosine 5')-P5-(uridine 5')-pentaphosphate (UP5A)

UMP/CMP-kinase (UK) from the slime mold Dictyostelium discoideum has been purified to high homogeneity and co-crystallized with the bisubstrate inhibitor P1-(adenosine 5')-P5-(uridine 5')-pentaphosphate (UP5A). UP5A binds to UK with a dissociation constant (Kd) of 3 +/- 0.5 nM at 25 degrees C and pH 7.5. This is some 50-fold tighter than the binding of P1,P5-(diadenosine 5')-pentaphosphate (AP5A, Kd = 160 +/- 15 nM). AP5A is a bisubstrate inhibitor that is specific for adenylate kinase. The crystals have the symmetry of the tetragonal space group P4(1)2(1)2 or its enantiomorph P4(3)2(1)2. The unit cell dimensions are a = b = 78.5 A and c = 101.4 A. The crystals diffract to a Bragg spacing of 2.1 A.

Primary structure of the hydrogenosomal adenylate kinase of Trichomonas vaginalis and its phylogenetic relationships

Hydrogenosomal adenylate kinase of the amitochondriate protist, Trichomonas vaginalis, has been purified and the sequence of its 39 amino-terminal residues established. Based on this sequence and a conserved internal region of the enzyme, a probe was obtained by DNA polymerase chain reaction and used to isolate a genomic DNA clone containing the gene of this enzyme. This gene exists probably as a single copy in T. vaginalis and is not interrupted by introns. The open reading frame obtained codes for a large type adenylate kinase with a mature molecular mass of 24.5 kDa. The T. vaginalis enzyme is homologous with adenylate kinases of other eukaryotes and eubacteria. Strongly conserved parts and residues of the molecule are conserved also in this enzyme. Phylogenetic trees obtained with various methods placed the T. vaginalis adenylate kinase close to the point where the different subfamilies of this enzyme branch from each other, indicating that the T. vaginalis enzyme has no close relationship to any of these subfamilies and that it separated early from other adenylate kinases. The conceptual translation predicts the existence of an amino-terminal nonapeptide absent from the protein purified from hydrogenosomes, similar to the processed amino-terminal extensions of other hydrogenosomal proteins. These extensions have been considered as putative targeting and import signals.

Primary structure of maize chloroplast adenylate kinase

This paper describes the sequence of adenylate kinase (Mg-ATP+AMP<-->Mg-ADP+ADP) from maize chloroplasts. This light-inducible enzyme is important for efficient CO2 fixation in the C4 cycle, by removing and recycling AMP produced in the reversible pyruvate phosphate dikinase reaction. The complete sequence was determined by analyzing peptides from cleavages with trypsin, AspN protease and CNBr and subcleavage of a major CNBr peptide with chymotrypsin. N-terminal Edman degradation and carboxypeptidase digestion established the terminal residues. Electrospray mass spectrometry confirmed the final sequence of 222 residues (M(r) = 24867) including one cysteine and one tryptophan. The sequence shows this enzyme to be a long-variant-type adenylate kinase, the nearest relatives being adenylate kinases from Enterobacteriaceae. Alignment of the sequence with the adenylate kinase from Escherichia coli reveals 44% identical residues. Since the E. coli structure has been published recently at 0.19-nm resolution with the inhibitor adenosine(5')pentaphospho(5')adenosine (Ap5A) [Müller, C. W. & Schulz, G. E. (1992) J. Mol. Biol. 224, 159-177], catalytically essential residues could be compared and were found to be mostly conserved. Surprisingly, in the nucleotide-binding Gly-rich loop Gly-Xaa-Pro-Gly-Xaa-Gly-Lys the middle Gly is replaced by Ala. This is, however, compensated by an Ile-->Val exchange in the nearest spatial neighborhood. A Thr-->Ala exchange explains the unusual tolerance of the enzyme for pyrimidine nucleotides in the acceptor site.

Human dTMP kinase: gene expression and enzymatic activity coinciding with cell cycle progression and cell growth

dTMP kinase (E.C.2.7.4.9.) catalyzes the phosphorylation of dTMP to the corresponding diphosphate. This enzyme is essential for DNA synthesis in vivo and is an important intermediate enzyme in the pathway of many pyrimidine analog drugs. In this report, we describe the isolation of the human dTMP kinase gene by functional complementation of a Saccharomyces cerevisiae cell cycle mutant, cdc8. The cDNA sequence revealed an open reading frame that encodes a protein with the molecular weight of 23,806. The deduced protein sequence was compared to known dTMP kinase sequences from different organisms. Although functionally complementary and structurally conserved, expressed human dTMP kinase in yeast shows little enzymatic activity. In contrast, active human dTMP kinase can be expressed from the gene cloned into the baculovirus expression system, as evidenced by increased enzymatic activity by four- to five-fold. Unlike yeast dTMP kinase, human dTMP kinase does not contain a cysteine residue after the conserved glycine-rich loop, but its enzymatic activity is still affected by the sulfhydryl inhibitor, 5,5'-dithio-bis(2-nitrobenzoic acid) (DTNB). The levels of dTMP kinase mRNA and its enzymatic activity fluctuate during the cell cycle, peaking at the S phase. Thus, like Saccharomyces cerevisiae CDC8 (encoding dTMP kinase), the human homolog mRNA and enzymatic activity are also cell cycle regulated. We have also examined four neuroblastoma cell lines for dTMP kinase mRNA levels and its kinase activities, which appear to vary according to cell growth rate. Our results suggest that the expression of the dTMP kinase gene and its activity coincide with various stages of cell growth. The identification of the human dTMP kinase gene and expression of its product in the baculovirus expression system should facilitate study of the mechanism of gene regulation and its role in pyrimidine metabolism.

Site-directed mutagenesis of AMP-binding residues in adenylate kinase. Alteration of substrate specificity

Adenylate kinase is highly specific for AMP as phosphoryl acceptor. We have found that the replacement of Thr39 by Ala in the chicken muscle enzyme, alone or together with the replacement of Leu66 by Ile, caused remarkable increases in CMP and UMP activities with a concomitant decrease in AMP activity; therefore, the resulting mutant enzymes show CMP and UMP activities/AMP activity ratios much higher than the wild-type enzyme. The mutant enzyme in which Ala is substituted for Thr39 has a Vmax value for CMP comparable to that of CMP-UMP kinase.

The adenylate kinase family in yeast: identification of URA6 as a multicopy suppressor of deficiency in major AMP kinase

The gene URA6 encoding uridylate kinase (UK) from Saccharomyces cerevisiae was isolated as a multicopy suppressor of the respiratory-deficient phenotype of an S. cerevisiae mutant defective in the gene AKY2 encoding AMP kinase (AK). The URA6 gene also restored temperature resistance to two different temperature-sensitive mutations in the gene encoding Escherichia coli AK. By contrast, the gene encoding UK of Dictyostelium discoideum on a multicopy yeast shuttle plasmid, expressed under control of the constitutive yeast AKY2 promoter, failed to complement the deficiency in yeast, although such transformants expressed high UK activity. We show that yeast UK exerts significant AK activity which is responsible for the complementation and is absent in the analogous enzyme from D. discoideum. Since UK also significantly phosphorylates CMP (but not GMP), it must be considered an unspecific short-form nucleoside monophosphate kinase. Wild-type mitochondria lack UK activity, but import AKY2. Since multicopy transformation with URA6 heals the Pet- phenotype of AKY2 disruption mutants, the presence of AKY2 in the mitochondrial intermembrane space is not required to maintain respiratory competence. However, furnishing UK with the bipartite intermembrane space-targeting presequence of cytochrome c1 improves the growth rates of AKY2 mutants with nonfermentable substrates, suggesting that AK activity in mitochondria is helpful, though not essential for oxidative growth.

Functional and structural conservation of Schizosaccharomyces pombe dTMP kinase gene

We describe the isolation and identification of the Schizosaccharomyces pombe dTMP kinase gene by the complementation of a Saccharomyces cerevisiae cell cycle mutant cell, cdc8. The isolated cDNA contains an open reading frame which can encode a protein with the molecular weight of 24,151. The deduced protein sequence is highly conserved among known dTMP kinase sequences from different organisms. The isolated gene should facilitate our study of its enzymatic activity, as well as nucleotide metabolism and cell cycle regulation in this organism.