Phosphorylation of nucleoside diphosphate kinase at the active site studied by steady-state and time-resolved fluorescence

Reconstruction and Characterization of Thermally Stable and Catalytically Active Proteins Comprising an Alphabet of ~ 13 Amino Acids

While extant organisms synthesize proteins using approximately 20 kinds of genetically coded amino acids, the earliest protein synthesis system is likely to have been much simpler, utilizing a reduced set of amino acids. However, which types of building blocks were involved in primordial protein synthesis remains unclear. Herein, we reconstructed three convergent sequences of an ancestral nucleoside diphosphate kinase, each comprising a 10 amino acid "alphabet," and found that two of these variants folded into soluble and stable tertiary structures. Therefore, an alphabet consisting of 10 amino acids contains sufficient information for creating stable proteins. Furthermore, re-incorporation of a few more amino acid types into the active site of the 10 amino acid variants improved the catalytic activity, although the specific activity was not as high as that of extant proteins. Collectively, our results provide experimental support for the idea that robust protein scaffolds can be built with a subset of the current 20 amino acids that might have existed abundantly in the prebiotic environment, while the other amino acids, especially those with functional sidechains, evolved to contribute to efficient enzyme catalysis.

Comprehensive reduction of amino acid set in a protein suggests the importance of prebiotic amino acids for stable proteins

Modern organisms commonly use the same set of 20 genetically coded amino acids for protein synthesis with very few exceptions. However, earlier protein synthesis was plausibly much simpler than modern one and utilized only a limited set of amino acids. Nevertheless, few experimental tests of this issue with arbitrarily chosen amino acid sets had been reported prior to this report. Herein we comprehensively and systematically reduced the size of the amino acid set constituting an ancestral nucleoside kinase that was reconstructed in our previous study. We eventually found that two convergent sequences, each comprised of a 13-amino acid alphabet, folded into soluble, stable and catalytically active structures, even though their stabilities and activities were not as high as those of the parent protein. Notably, many but not all of the reduced-set amino acids coincide with those plausibly abundant in primitive Earth. The inconsistent amino acids appeared to be important for catalytic activity but not for stability. Therefore, our findings suggest that the prebiotically abundant amino acids were used for creating stable protein structures and other amino acids with functional side chains were recruited to achieve efficient catalysis.

The role of the C-terminus and Kpn loop in the quaternary structure stability of nucleoside diphosphate kinase from Leishmania parasites

Nucleoside diphosphate kinase (NDK) is a housekeeping enzyme that plays key roles in nucleotide recycling and homeostasis in trypanosomatids. Moreover, it is secreted by the intracellular parasite Leishmania to modulate the host response. These functions make NDK an attractive target for drug design and for studies aiming at a better understanding of the mechanisms mediating host-pathogen interactions. Here, we report the crystal structures of three mutants of the NDK from Leishmania major (LmNDK) that affects the stability of the hexameric biological assembly including P95S, Δ5Ct (lacking the last five residues) and the double mutant P100S/Δ5Ct. Although P95S and Δ5Ct variants conserve the hexameric structure of the wild-type protein, the double mutant becomes a dimer as shown by in solution studies. Free energy calculation of dimer-dimer interfaces and enzymatic assays indicate that P95S, Δ5Ct and P100S/Δ5Ct mutations progressively decrease the hexamer stability and enzyme activity. These results demonstrate that the mutated regions play a role in protein function through stabilizing the quaternary arrangement.

An iTRAQ-based proteomics approach to clarify the molecular physiology of somatic embryo development in Prince Rupprecht's larch (Larix principis-rupprechtii Mayr)

Prince Rupprecht's larch (Larix principis-rupprechtii Mayr) is a native high-value forest tree species in North China whose clonal propagation through somatic embryogenesis (SE) has the potential to rapidly capture the benefits of breeding or genetic engineering programs and to improve raw material uniformity and quality. To date, research has focused on clarifying the molecular mechanism of SE, but proteomic studies are still in the early stages. In this study, isobaric tags for relative and absolute quantitation (iTRAQ) analysis was performed on three developmental stages of SE in L. principis-rupprechtii in an attempt to identify a wide range of proteins that are regulated differentially during this process. Proteins were extracted and analyzed from the pro-embryogenic mass (PEM), globular embryo (GE), and cotyledon embryo (CE) stages of embryo development. We detected 503 proteins in total and identified 96 proteins expressed differentially during different developmental stages. The identified proteins were analyzed further to provide information about their expression patterns and functions during SE. Four clusters of proteins based on shared expression profiles were generated. Functional analysis showed that proteins involved in primary metabolism, phosphorylation, and oxidation reduction were upregulated during somatic embryo development. This work provides novel insights into the process of larch embryo development in vitro and a basis for further study of the biological process and opportunities for practical application of this knowledge.

Implementation of transportation distance for analyzing FLIM and FRET experiments

Analysis of fluorescence lifetime imaging microscopy (FLIM) and Förster resonance energy transfer (FRET) experiments in living cells is usually based on mean lifetimes computations. However, these mean lifetimes can induce misinterpretations. We propose in this work the implementation of the transportation distance for FLIM and FRET experiments in vivo. This non-fitting indicator, which is easy to compute, reflects the similarity between two distributions and can be used for pixels clustering to improve the estimation of the FRET parameters. We study the robustness and the discriminating power of this transportation distance, both theoretically and numerically. In addition, a comparison study with the largely used mean lifetime differences is performed. We finally demonstrate practically the benefits of the transportation distance over the usual mean lifetime differences for both FLIM and FRET experiments in living cells.

Cloning, Expression, and Purification of Nucleoside Diphosphate Kinase from Acinetobacter baumannii

Acinetobacter baumannii is a multidrug resistant pathogenic bacteria associated with hospital acquired infections. This bacterium possesses a variety of resistance mechanisms which makes it more difficult to control the bacterium with conventional drugs, and, so far no effective drug treatment is available against it. Nucleoside diphosphate kinase is an important enzyme, which maintains the total nucleotide triphosphate pool inside the cell by the transfer of γ -phosphate from NTPs to NDPs. The role of nucleoside diphosphate kinase (Ndk) has also been observed in pathogenesis in other organisms. However, intensive studies are needed to decipher its other putative roles in Acinetobacter baumannii. In the present study, we have successfully cloned the gene encoding Ndk and achieved overexpression in bacterial host BL-21 (DE3). The overexpressed protein is further purified by nickel-nitrilotriacetic acid (Ni-NTA) chromatography.

Selectivity of kinases on the activation of tenofovir, an anti-HIV agent

Nucleoside analogues, used in HIV-therapy, need to be phosphorylated by cellular enzymes in order to become potential substrates for HIV reverse transcriptase. After incorporation into the viral DNA chain, because of lacking of their 3'-hydroxyl groups, they stop the elongation process and lead to the death of the virus. Phosphorylation of the HIV-drug derivative, tenofovir monophosphate was tested with the recombinant mammalian nucleoside diphosphate kinase (NDPK), 3-phosphoglycerate kinase (PGK), creatine kinase (CK) and pyruvate kinase (PK). Among them, only CK was found to phosphorylate tenofovir monophosphate with a reasonable rate (about 45-fold lower than with its natural substrate, ADP), while PK exhibits even lower, but still detectable activity (about 1000-fold lower compared to the value with ADP). On the other hand, neither NDPK nor PGK has any detectable activity on tenofovir monophosphate. The absence of activity with PGK is surprising, since the drug tenofovir competitively inhibits both CK and PGK towards their nucleotide substrates, with similar inhibitory constants, K(I) of 2.9 and 4.8mM, respectively. Computer modelling (docking) of tenofovir mono- or diphosphate forms to these four kinases suggests that the requirement of large-scale domain closure for functioning (as for PGK) may largely restrict their applicability for phosphorylation/activation of pro-drugs having a structure similar to tenofovir monophosphate.

Human and viral nucleoside/nucleotide kinases involved in antiviral drug activation: structural and catalytic properties

Antiviral nucleoside and nucleotide analogs, essential for the treatment of viral infections in the absence of efficient vaccines, are prodrug forms of the active compounds that target the viral DNA polymerase or reverse transcriptase. The activation process requires several successive phosphorylation steps catalyzed by different kinases, which are present in the host cell or encoded by some of the viruses. These activation reactions often are rate-limiting steps and are thus open to improvement. We review here the structural and enzymatic properties of the enzymes that carry out the activation of analogs used in therapy against human immunodeficiency virus and against DNA viruses such as hepatitis B, herpes and poxviruses. Four major classes of drugs are considered: thymidine analogs, non-natural L-nucleosides, acyclic nucleoside analogs and acyclic nucleoside phosphonate analogs. Their efficiency as drugs depends both on the low specificity of the viral polymerase that allows their incorporation into DNA, but also on the ability of human/viral kinases to provide the activated triphosphate active forms at a high concentration at the right place. Two distinct modes of action are considered, depending on the origin of the kinase (human or viral). If the human kinases are house-keeping enzymes that belong to the metabolic salvage pathway, herpes and poxviruses encode for related enzymes. The structures, substrate specificities and catalytic properties of each of these kinases are discussed in relation to drug activation.

ATPase domain of Hsp70 exhibits intrinsic ATP-ADP exchange activity

The chaperone activity of Hsp70 in protein folding and its conformational switching are regulated through the hydrolysis of ATP and the ATP-ADP exchange cycle. It was reported that, in the presence of physiological concentrations of ATP (approximately 5 mM) and ADP (approximately 0.5 mM), Hsp70 catalyzes ATP-ADP exchange through transfer of gamma-phosphate between ATP and ADP, via an autophosphorylated intermediate, whereas it only catalyzes the hydrolysis of ATP in the absence of ADP. To clarify the functional domain of the ATP-ADP exchange activity of Hsp70, we isolated the 44-kD ATPase domain of Hsp70 after limited proteolysis with alpha-chymotrypsin (EC 3.4.21.1). The possibility of ATP-ADP exchange activity of a contaminating nucleoside diphosphate kinase (EC 2.7.4.6) was monitored throughout the experiments. The purified 44-kD ATPase domain exhibited intrinsic ATP-ADP exchange by catalyzing the transfer of gamma-phosphate between ATP and ADP with acid-stable autophosphorylation at Thr204.

Structural analysis of the activation of ribavirin analogs by NDP kinase: comparison with other ribavirin targets

Ribavirin used in therapies against hepatitis C virus (HCV) is potentially efficient against other viruses but presents a high cytotoxicity. Several ribavirin triphosphate analogs modified on the ribose moiety were synthesized and tested in vitro on the RNA polymerases of HCV, phage T7, and HIV-1 reverse transcriptase. Modified nucleotides with 2'-deoxy, 3'-deoxy, 2',3'-dideoxy, 2',3'-dideoxy-2',3'-dehydro, and 2',3'-epoxy-ribose inhibited the HCV enzyme but not the other two polymerases. They were also analyzed as substrates for nucleoside diphosphate (NDP) kinase, the enzyme responsible for the last step of the cellular activation of antiviral nucleoside analogs. An X-ray structure of NDP kinase complexed with ribavirin triphosphate was determined. It demonstrates that the analog binds as a normal substrate despite the modified base and confirms the crucial role of the 3'-hydroxyl group in the phosphorylation reaction. The 3'-hydroxyl is required for inhibition of the initiation step of RNA synthesis by HCV polymerase, and both sugar hydroxyls must be present to inhibit elongation. The 2'deoxyribavirin is the only derivative efficient in vitro against HCV polymerase and properly activated by NDP kinase.

Improving nucleoside diphosphate kinase for antiviral nucleotide analogs activation

Antiviral nucleoside analog therapies rely on their incorporation by viral DNA polymerases/reverse transcriptase leading to chain termination. The analogs (3'-deoxy-3'-azidothymidine (AZT), 2',3'-didehydro-2',3'-dideoxythymidine (d4T), and other dideoxynucleosides) are sequentially converted into triphosphate by cellular kinases of the nucleoside salvage pathway and are often poor substrates of these enzymes. Nucleoside diphosphate (NDP) kinase phosphorylates the diphosphate derivatives of the analogs with an efficiency some 10(4) lower than for its natural substrates. Kinetic and structural studies of Dictyostelium and human NDP kinases show that the sugar 3'-OH, absent from all antiviral analogs, is required for catalysis. To improve the catalytic efficiency of NDP kinase on the analogs, we engineered several mutants with a protein OH group replacing the sugar 3'-OH. The substitution of Asn-115 in Ser and Leu-55 in His results in an NDP kinase mutant with an enhanced ability to phosphorylate antiviral derivatives. Transfection of the mutant enzyme in Escherichia coli results in an increased sensitivity to AZT. An x-ray structure at 2.15-A resolution of the Dictyostelium enzyme bearing the serine substitution in complex with the R(p)-alpha-borano-triphosphate derivative of AZT shows that the enhanced activity reflects an improved geometry of binding and a favorable interaction of the 3'-azido group with the engineered serine.

Nucleotide affinity for a stable phosphorylated intermediate of nucleoside diphosphate kinase

Nucleoside diphosphate (NDP) kinase is transiently phosphorylated on a histidine of the active site during the catalytic cycle. In the presence of a nucleotide acceptor, the phosphohistidine bond is unstable and the phosphate is transferred to the acceptor in less than 1 msec. We describe the synthesis of an analog of the phosphoenzyme intermediate with an inactive mutant of NDP kinase in which the catalytic histidine is replaced by a cysteine. In two sequential disulfide exchange reactions, a thiophosphate group reacts with the thiol function of the cysteine that had previously reacted with dithionitrobenzoate (DTNB). The thiophosphoenzyme presents a 400,000-fold increased stability in the presence of NDPs compared with the phosphoenzyme. The binding of NDP is studied at the steady state and presteady state. Data were analyzed according to a bimolecular association model. For the first time, the true equilibrium dissociation constants of NDP for the analog of the phosphoenzyme are determined in the absence of phosphotransfer, allowing a better understanding of the catalytic mechanism of the enzyme.

NEMO trimerizes through its coiled-coil C-terminal domain

NEMO/IkappaB kinase (IKK) gamma is the regulatory component of the IKK complex comprising the two protein kinases, IKKalpha and IKKbeta. To investigate the self-assembly properties of NEMO and to understand further the mechanism of activation of the IKK complex, we purified wild-type and mutant NEMO expressed in Escherichia coli. In the absence of its IKK partners, recombinant NEMO (rNEMO) is a metastable functional monomer correctly folded, according to its fluorescence and far-UV CD spectra, which is binding specifically to the IKK complex. A minor fraction of rNEMO was found tightly associated with DnaK (E. coli Hsp70). We also examined the interaction of NEMO with prokaryotic and eukaryotic Hsp70, and we showed that the Hsp70-NEMO complex forms a supramolecular structure probably corresponding to an assembly intermediate. In vivo cross-linking experiments indicate that native NEMO in association with IKK is in equilibrium between a dimeric and a trimeric form. Similarly to native NEMO, a NEMO mutant deleted from its IKK binding N-terminal domain (residues 242-388) forms a stable trimeric coiled-coil, suggesting that the association of NEMO with IKK or with Hsp70 prevents incorrect interdomain pairing reactions that could lead to aggregation or to an non-native oligomeric state of rNEMO. We propose a model in which the activation of the IKK complex occurs through the trimerization of NEMO upon binding to a not yet identified upstream activator.

Mechanism of phosphoryl transfer by nucleoside diphosphate kinase pH dependence and role of the active site Lys16 and Tyr56 residues

Nucleoside diphosphate (NDP) kinase phosphorylates nucleoside diphosphates with little specificity for the base and the sugar. Although nucleotide analogues used in antiviral therapies are also metabolized to their triphosphate form by NDP kinase, their lack of the 3'-hydroxyl of the ribose, which allows them to be DNA chain terminators, severely impairs the catalytic efficiency of NDP kinase. We have analyzed the kinetics parameters of several mutant NDP kinases modified on residues (Lys16, Tyr56, Asn119) interacting with the gamma-phosphate and/or the 3'-OH of the Mg2+-ATP substrate. We compared the relative contributions of the active-site residues and the substrate 3'-OH for point mutations on Lys16, Tyr56 and Asn119. Analysis of additional data from pH profiles identify the ionization state of these residues in the enzyme active form. X-ray structure of K16A mutant NDP kinase shows no detectable rearrangement of the residues of the active site.

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.

Activation of anti-reverse transcriptase nucleotide analogs by nucleoside diphosphate kinase: improvement by alpha-boranophosphate substitution

Nucleoside activation by nucleoside diphosphate kinase and inhibition of HIV-1 reverse transcriptase were studied comparatively for a new class of nucleoside analogs with a borano (BH3-) or a thio (SH) group on the alpha-phosphate. Both the alpha-Rp-borano derivatives of AZT and d4T improved phosphorylation by NDP kinase, inhibition of reverse transcription as well as stability of alpha-borano nonophosphate derivatives in terminated viral DNA chain.

Structural basis for activation of alpha-boranophosphate nucleotide analogues targeting drug-resistant reverse transcriptase

AIDS chemotherapy is limited by inadequate intracellular concentrations of the active triphosphate form of nucleoside analogues, leading to incomplete inhibition of viral replication and the appearance of drug-resistant virus. Drug activation by nucleoside diphosphate kinase and inhibition of HIV-1 reverse transcriptase were studied comparatively. We synthesized analogues with a borano (BH(3)(-)) group on the alpha-phosphate, and found that they are substrates for both enzymes. X-ray structures of complexes with nucleotide diphosphate kinase provided a structural basis for their activation. The complex with d4T triphosphate displayed an intramolecular CH.O bond contributing to catalysis, and the R(p) diastereoisomer of thymidine alpha-boranotriphosphate bound like a normal substrate. Using alpha-(R(p))-boranophosphate derivatives of the clinically relevant compounds AZT and d4T, the presence of the alpha-borano group improved both phosphorylation by nucleotide diphosphate kinase and inhibition of reverse transcription. Moreover, repair of blocked DNA chains by pyrophosphorolysis was reduced significantly in variant reverse transcriptases bearing substitutions found in drug-resistant viruses. Thus, the alpha-borano modification of analogues targeting reverse transcriptase may be of generic value in fighting viral drug resistance.

Role of nucleoside diphosphate kinase in the activation of anti-HIV nucleoside analogs

Nucleoside analogs are currently used in antiretrovirus therapies. The best known example is AZT one of the first drug to be used for the treatment of AIDS. However, only the triphosphate derivatives of these compounds act as substrates of the viral reverse transcriptase. Since they do not enter cells, nucleoside analogs are administered and phosphorylated by cellular kinases. The last step in this phosphorylation pathway is catalyzed by nucleoside diphosphate (NDP) kinase. The incorporation of the nucleoside triphosphates into nascent viral DNA chain results in termination of the elongation process. We have performed kinetics studies of the phosphorylation reaction by NDP kinase of dideoxynucleoside diphosphates such as 2',3'-dideoxy-3'-azidothymidine diphosphate (AZT-DP) and 2',3'-dideoxy-2',3'-didehydrothymidine diphosphate (d4T-DP). We show that the catalytic efficiency is strongly decreased and, therefore, that the reaction step catalyzed by NDP kinase constitutes a bottleneck in the processing pathway of anti-HIV compounds. In addition, the affinity of the analogs in the absence of catalysis was determined using a catalytically inactive NDP kinase mutant, showing a reduction of affinity by a factor of 2 to 30, depending on the analog. The structure of NDP kinase provides a structural explanation for these results. Indeed, all nucleoside analogs acting as chain terminators must lack a 3'-OH in the nucleotide deoxyribose. Unfortunately, this same substitution is detrimental for their capacity to be phosphorylated by NDP kinase. This defines the framework for the design of new nucleoside analogs with increased efficiency in antiretroviral therapies.

The catalytic mechanism of nucleoside diphosphate kinases

Nucleoside diphosphate kinases catalyze the reversible transfer of the gamma phosphate of nucleoside triphosphates to nucleoside diphosphates. This minireview presents recent advances in understanding the reaction mechanism using steady-state and fast kinetic studies, X-ray crystallography, and site-directed mutagenesis. We also briefly discuss the physiological relevance of in vitro studies.

The enantioselectivity of enzymes involved in current antiviral therapy using nucleoside analogues: a new strategy?

This review is primarily intended for synthetic bio-organic chemists and enzymologists who are interested in new strategies in the design of virus inhibitors. It is an attempt to assess the importance of the enzymatic properties of L-nucleosides and their analogues, particularly those that are active against viruses such as human immunodeficiency virus (HIV), hepatitis B virus (HBV), herpes simplex virus (HSV), etc. Only data obtained with purified enzymes have been considered and discussed. The examined enzymes include nucleoside- or nucleotide-phosphorylating enzymes, catabolic enzymes, viral target enzymes and cellular polymerases. The enantioselectivities of these enzymes were determined from existing data and are significant only when a sufficient number of enantiomeric pairs of substrates could be examined. The reported data emphasize the weak enantioselectivities of cellular or viral nucleoside kinases and some viral DNA polymerases. Thus, cellular deoxycytidine kinase has a considerably relaxed enantioselectivity with respect to a large number of nucleosides or their analogues, and it occupies a strategic position in the intracellular activation of the compounds. Similarly, HIV-1 reverse transcriptase often has a relatively weak enantioselectivity and can be inhibited by the 5-triphosphates of a large series of L-nucleosides and analogues. In contrast, degradation enzymes, such as adenosine or cytidine deaminases, generally demonstrate strict enantioselectivities favouring D-enantiomers and are used by chemists in asymmetric syntheses. The weak enantioselectivities of some enzymes involved in nucleoside metabolism are more or less pronounced, and one enantiomer or the other is favoured depending on the substrate. This suggests that the low enantioselectivity is fortuitous and does not result from evolutionary pressure, since these enzymes do not create or modify asymmetric centres in substrates. The combined enantioselectivities of the enzymes examined in this review strongly suggest that the field of L-nucleosides and their analogues should be systematically explored in the search for new virus inhibitors.

Intrinsic nucleoside diphosphate kinase-like activity is a novel function of the 20 S proteasome

The eukaryotic 20 S proteasome is the prototype of a new family of the N-terminal nucleophil hydrolases and is composed of numerous low molecular mass subunits arranged in a stack of four rings, each containing seven different alpha- or beta-subunits. Among the beta-type subunits in the yeast proteasome, three proteolytically active ones were identified, although the functions of the other beta- and alpha-type subunits remain to be clarified. We report here that the purified 20 S proteasome exhibits intrinsic nucleoside diphosphate (NDP) kinase-like activity. The proteasome exhibited a preference for ATP and dATP as phosphate donors, and a broad specificity for NDPs, other than GDP, as phosphate acceptors, unlike conventional NDP kinase, which catalyzes the transfer of gamma-phosphate between NDPs and nucleoside triphosphates. During the transfer of gamma-phosphate, the proteasome formed acid-labile phosphohistidine as autophosphorylated intermediates, and NDP-dependent dephosphorylation of the latter then occurred. These enzymatic properties are similar to those of the molecular chaperone, Hsp70, which also exhibits intrinsic NDP kinase-like activity, instead of ATPase activity. C5 among the beta-type subunits and C8 among the alpha-type subunits were autophosphorylated during the gamma-phosphate transfer reaction and were photoaffinity labeled with 8-azido-[alpha-(32)P]ATP, suggesting that the C5 and C8 subunits of the proteasome are responsible for the NDP kinase-like activity.

Heterogeneous motions within human apohemoglobin

Conservation of the secondary and tertiary protein organization of human apohemoglobin was observed at temperatures ranging from 7 to 25 degrees C using CD spectra in the far-UV (200-250 nm) and near-UV (250-300 nm) regions. The dynamics of apohemoglobin were probed using fluorescence quenching experiments on the Trp residues and an extrinsic dye (ANS or bis-ANS) located in the heme cavities. The long decay time of the dye emission (> 10 ns) reveals the dynamics of the protein matrix averaged over the whole molecule. The short decay time of the Trp residue emission (congruent with 3 ns) probes the dynamics of their close vicinities. When the temperature rises from 10 to 20 degrees C, the average intraproteic motions throughout the whole apohemoglobin matrix are greatly accelerated, whereas the hydrophobic protein regions around the alpha14, beta15 and beta37 Trp residues appear much less animated. These dynamic differences between the behavior of the softer matrix and the packed rigid regions containing the tryptophans could be one of the requisites for apohemoglobin stability. We suspect that the highly rigid tryptophan domains in human apohemoglobin are likely to be knots.

Human nucleoside diphosphate kinase B (Nm23-H2) from melanoma cells shows altered phosphoryl transfer activity due to the S122P mutation

The Ser122 --> Pro mutation in human nucleoside diphosphate kinase (NDK)-B/Nm23-H2 was recently found in melanoma cells. In comparison to the wild-type enzyme, steady state activity of NDKS122P with ATP and TDP as substrates was slowed down 5-fold. We have utilized transient kinetic techniques to analyze phosphoryl transfer between the mutant enzyme and various pairs of nucleoside triphosphates and nucleoside diphosphates. The two half-reactions of phosphorylation and dephosphorylation of the active site histidine residue (His118) were studied separately by making use of the intrinsic fluorescence changes which occur during these reactions. All apparent second order rate constants are drastically reduced, falling 5-fold for phosphorylation and 40-200-fold for dephosphorylation. Also, the reactivity of the mutant with pyrimidine nucleotides and deoxy nucleotides is more than 100-fold reduced compared with the wild-type. Thus, the rate-limiting step of the NDK-BS122P-catalyzed reaction is phosphoryl transfer from the phospho-enzyme intermediate to the nucleoside diphosphate and not phosphoryl transfer from the nucleoside triphosphate to the enzyme as was found for the wild-type protein. This results in a pronounced shift of the equilibrium between unphosphorylated and phosphorylated enzyme. Moreover, like the Killer-of-prune mutation in Drosophila NDK and the neuroblastoma Ser120 --> Gly mutation in human NDK-A/Nm23-H1, the Ser122 --> Pro substitution in NDK-B affects the stability of the protein toward heat and urea. These significantly altered properties may be relevant to the role of the mutant enzyme in various intracellular processes.

Phosphorylation of anti-HIV nucleoside analogs by nucleoside diphosphate kinase

The reaction of NDP kinase with antiviral nucleoside triphosphates used in antiviral therapies was studied at the presteady state by fluorescence stopped-flow and compared with the steady-state parameters. The affinity of the analogs was determined by fluorescence titration of a mutated enzyme with an inserted Trp in the binding site. The lack of the 3' hydroxyl in analogs is shown to decrease the kcat more than the KD.

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).

3'-Phosphorylated nucleotides are tight binding inhibitors of nucleoside diphosphate kinase activity

Nucleoside diphosphate (NDP) kinase catalyzes the phosphorylation of ribo- and deoxyribonucleosides diphosphates into triphosphates. NDP kinase is also involved in malignant tumors and was shown to activate in vitro transcription of the c-myc oncogene by binding to its NHE sequence. The structure of the complex of NDP kinase with bound ADP shows that the nucleotide adopts a different conformation from that observed in other phosphokinases with an internal H bond between the 3'-OH and the beta-O made free by the phosphate transfer. We use intrinsic protein fluorescence to investigate the inhibitory and binding potential of nucleotide analogues phosphorylated in 3'-OH position of the ribose to both wild type and F64W mutant NDP kinase from Dictyostelium discoideum. Due to their 3'-phosphate, 5'-phosphoadenosine 3'-phosphate (PAP) and adenosine 3'-phosphate 5'-phosphosulfate (PAPS) can be regarded as structural analogues of enzyme-bound ADP. The KD of PAPS (10 microM) is three times lower than the KD of ADP. PAPS also acts as a competitive inhibitor toward natural substrates during catalysis, with a KI in agreement with binding data. The crystal structure of the binary complex between Dictyostelium NDP kinase and PAPS was solved at 2.8-A resolution. It shows a new mode of nucleotide binding at the active site with the 3'-phosphate of PAPS located near the catalytic histidine, at the same position as the gamma-phosphate in the transition state. The sulfate group is directed toward the protein surface. PAPS will be useful for the design of high affinity drugs targeted to NDP kinases.

Pre-steady state of reaction of nucleoside diphosphate kinase with anti-HIV nucleotides

The pre-steady-state reaction of Dictyostelium nucleoside diphosphate (NDP) kinase with dideoxynucleotide triphosphates (ddNTP) and AZT triphosphate was studied by quenching of protein fluorescence after manual mixing or by stopped flow. The fluorescence signal, which is correlated with the phosphorylation state of the catalytic histidine in the enzyme active site, decreases upon ddNTP addition according to a monoexponential time course. The pseudo-first order rate constant was determined for different concentrations of the various ddNTPs and was found to be saturable. The data are compatible with a two-step reaction scheme, where fast association of the enzyme with the dideoxynucleotide is followed by a rate-limiting phosphorylation step. The rate constants and dissociation equilibrium constants determined for each dideoxynucleotide were correlated with the steady-state kinetic parameters measured in the enzymatic assay in the presence of the two substrates. It is shown that ddNTPs and AZT triphosphate are poor substrates for NDP kinase with a rate of phosphate transfer of 0.02 to 3.5 s-1 and a KS of 1-5 mM. The equilibrium dissociation constants for ADP, GDP, ddADP, and ddGDP were also determined by fluorescence titration of a mutant F64W NDP kinase, where the introduction of a tryptophan at the nucleotide binding site provides a direct spectroscopic probe. The lack of the 3'-OH in ddNTP causes a 10-fold increase in KD. Contrary to "natural" NTPs, NDP kinase discriminates between various ddNTPs, with ddGTP the more efficient and ddCTP the least efficient substrate within a range of 100 in kcat values.

Role of Mg2+ in nucleoside diphosphate kinase autophosphorylation

Nucleoside diphosphate (NDP) kinase is a ubiquitous enzyme that has been described to have regulatory functions. In addition to its classical enzymatic activity, NDP kinases have been characterized as inhibitors of metastasis, as a factor stimulating gene transcription, and as a protein kinase. In this report we show some characteristics of the autophosphorylation of homogeneous NDP kinase and make a comparison with that of other proteins in crude extracts. By using labeled substrates and fluorescence quenching analysis, we prove that Mg2+ is indeed necessary for the two steps of the ping-pong reaction to take place and present evidence that NTPs or NDPs, when uncomplexed to divalent cations, may not bind the active site in a comparable way to NTP . Mg2+ and NDP . Mg2+. However, even extremely small concentrations of Mg2+ suffice for maximal autophosphorylation which is obtained with Mg2+ in the nanomolar range and 100 microM ATP using homogeneous enzyme. Moreover, lower autophosphorylation levels were observed with increasing concentrations of Mg2+. The autophosphorylation equilibrium varied from 0.19 to 1.6 upon the inclusion of 10 mM EDTA to produce low Mg2+ concentrations. Under optimal conditions (low Mg2+ concentrations and short incubation times) NDP kinase was the only protein phosphorylated in crude extracts from Candida albicans, indicating that the autophosphorylation properties of the enzyme are very singular.

The isolated H4-H5 cytoplasmic loop of Na,K-ATPase overexpressed in Escherichia coli retains its ability to bind ATP

The H4-H5 loop of the alpha-subunit of mouse brain Na,K-ATPase was expressed and isolated from Escherichia coli cells. Using fluorescence analogues of ATP, this loop was shown to retain its capability to bind ATP. Isolation of a soluble H4-H5 loop with the native ATP binding site is a crucial step for detailed studies of the molecular mechanism of ATP binding and utilisation.

Substrate specificity of human nucleoside-diphosphate kinase revealed by transient kinetic analysis

Nucleoside-diphosphate kinases (NDKs) catalyze the transfer of gamma-phosphoryl groups from NTPs via an active site histidine to NDPs using a ping-pong mechanism. We have used the change of intrinsic tryptophan fluorescence that occurs upon phosphorylation of NDK to measure the rates of phosphorylation and dephosphorylation with a range of nucleotides and nucleotide analogues. For natural nucleotides, the rates of phosphorylation and dephosphorylation were linearly dependent upon nucleotide concentration until they became too fast to measure. The second order rate constants for phosphorylation by natural NTPs varied between 0.7 and 13 x 10(6) M-1 s-1. Dephosphorylation by NDPs was 2-3-fold faster than the corresponding phosphorylation reaction, and dephosphorylation by dNDPs was 3-4-fold slower than the equivalent NDPs. In all cases, second order rate constants were highest for guanine followed by adenine and lowest for cytosine nucleotides. NDK also catalyzes the transfer of thiophosphate from adenosine 5'-O-(thiotriphosphate) (ATPgammaS) and guanosine 5'-O-(thiotriphosphate) (GTPgammaS) to NDP, but at (1)/(1000) of the equivalent phosphoryl transfer rates. In this case, the observed rate constants of phosphorylation and dephosphorylation were hyperbolically dependent on nucleotide concentration. Thiophosphorylation by ATPgammaS and GTPgammaS occurred with kmax of 2.8 and 1.35 s-1 and Kd of 145 and 36 muM respectively. For dethiophosphorylation by a range of NDPs, kmax was in the range of 5-30 s-1, whereas Kd varied between 0.16 and 3.3 mM. Guanine had the lowest Kd values, and cytosine had the highest. The data are consistent with fast reversible binding of the nucleotide followed by the rate-limiting phosphoryl transfer. Thiophosphates change only the rate of the phosphoryl transfer step, whereas both events are influenced by the base. Modification at the 2'-hydroxyl of ribose has only a small effect, while the overall rate of phosphoryl transfer is reduced 1000-fold by modification at the 3'-ribose.

Intrinsic ADP-ATP exchange activity is a novel function of the molecular chaperone, Hsp70

Hsp70 is a multifunctional molecular chaperone whose interactions with protein substrates are regulated by ATP hydrolysis and ADP-ATP exchange. We show here that, in addition to ATPase activity, purified Hsp70 free from nucleoside-diphosphate (NDP) kinase exhibits intrinsic ADP-ATP exchange activity. The rate constants for ATP hydrolysis and ATP synthesis were in a similar range at the optimum pH of 7.5-8.5 in the presence of 5 mM ATP and 0.5 mM ADP. Hsp70 exhibited a considerably strict preference for ATP as a phosphate donor, and a biased substrate specificity, unlike NDP kinase; ADP, UDP, CDP > dTDP, dCDP > GDP, dGDP. During the reaction, Hsp70 formed an acid-labile autophosphorylated intermediate, and nucleoside diphosphate-dependent dephosphorylation of the latter then occurred. These properties of Hsp70 are not identical but similar to those of NDP kinase, but are not similar to those of adenylate kinase and ATP synthase.

Coupling between catalysis and oligomeric structure in nucleoside diphosphate kinase

A dimeric Dictyostelium nucleoside diphosphate kinase has been stabilized by the double mutation P100S-N150stop which targets residues involved in the trimer interface (Karlsson, A., Mesnildrey, S., Xu, Y., Moréra, S., Janin, J., and Veron, M. (1996) J. Biol. Chem. 271, 19928-19934). The reassociation of this dimeric form into a hexamer similar to the wild-type enzyme is induced by the presence of a nucleotide substrate. Equilibrium sedimentation and gel filtration experiments, as well as enzymatic activity measurements, show that reactivation of the enzyme closely parallels its reassociation. A phosphorylatable intermediate with low activity participates in the association pathway while the dimeric form is shown totally devoid of enzymatic activity. Our results support the hypothesis that different oligomeric species of nucleoside diphosphate kinase are involved in different cellular processes where the enzymatic activity is not required.

The R1 subunit of herpes simplex virus ribonucleotide reductase is a good substrate for host cell protein kinases but is not itself a protein kinase

The N terminus of the R1 subunit of herpes simplex virus type 2 ribonucleotide reductase is believed to be a protein kinase domain mainly because the R1 protein was phosphorylated in a protein kinase assay on blot. Using Escherichia coli and adenovirus expression vectors to produce R1, we found that, whereas the reductase activity of both recombinant proteins was similar, efficient phosphorylation of R1 and casein in the presence of Mg2+ was obtained only with the R1 purified from eukaryotic cells. Phosphorylation of this R1, in solution or on blot, results mainly from the activity of casein kinase II (CKII), a co-purifying protein kinase. Labeling on blot occurs from CKII leakage off the membrane and its subsequent high affinity binding to in vivo CKII-phosphorylated R1. CKII target sites were mapped to an acidic serine-rich segment of the R1 N terminus. Improvement in purification of the R1 expressed in eukaryotic cells nearly completely abolished its phosphorylation potential. An extremely low level of phosphorylation observed in the presence of Mn2+ with the R1 produced in E. coli was probably due to an unidentified prokaryotic protein kinase. These results provide evidence that the herpes simplex virus type 2 R1 does not possess an intrinsic protein kinase activity.

Intrinsic nucleoside diphosphate kinase-like activity as a novel function of 14-3-3 proteins

14-3-3 proteins play a role in many cellular functions as molecular chaperone and adapter proteins: they bind to and modulate several proteins involved in cell proliferation and differentiation, and also function ATP-dependently in targeting of precursors to mitochondria. We show here that 14-3-3 purified from a human lymphoblastoma and also its recombinant tau isoform exhibited intrinsic nucleoside diphosphate (NDP) kinase-like activity. 14-3-3 proteins preferentially catalyzed the transfer of the gamma-phosphate group from ATP, dATP or dGTP to all nucleoside diphosphates and this transfer involved acid-labile phosphoenzyme intermediates. They also simultaneously catalyzed the reverse reaction of ATP hydrolysis. These properties of 14-3-3 are similar to those of NDP kinase, but not to those of adenylate kinase.

The in vitro DNA binding properties of NDP kinase are related to its oligomeric state

Genetic and biochemical evidences suggest that the enzymatic activity of NDP kinase is necessary but not sufficient for its biological function. While the human NDPK-B binds specifically single-strand polypyrimidines sequences, the hexameric enzyme from Dictyostelium does not. We demonstrated by electrophoretic mobility shift assay and filter binding assay that a dimeric mutant from Dictyostelium binds to an oligodesoxynucleotide while the wild-type does not. These data suggest that the differences in the DNA binding properties of several eucaryotic NDP kinases might be correlated to the differences in the stability of their hexameric structure.