Studies on some specific Ap4A-degrading enzymes with the use of various methylene analogues of P1P4-bis-(5',5'''-adenosyl) tetraphosphate

Novel diadenosine polyphosphate analogs with oxymethylene bridges replacing oxygen in the polyphosphate chain: potential substrates and/or inhibitors of Ap4A hydrolases

Dinucleoside polyphosphates (Np(n)N's; where N and N' are nucleosides and n = 3-6 phosphate residues) are naturally occurring compounds that may act as signaling molecules. One of the most successful approaches to understand their biological functions has been through the use of Np(n)N' analogs. Here, we present the results of studies using novel diadenosine polyphosphate analogs, with an oxymethylene group replacing one or two bridging oxygen(s) in the polyphosphate chain. These have been tested as potential substrates and/or inhibitors of the symmetrically acting Ap(4)A hydrolase [bis(5'-nucleosyl)-tetraphosphatase (symmetrical); EC 3.6.1.41] from E. coli and of two asymmetrically acting Ap(4)A hydrolases [bis(5'-nucleosyl)-tetraphosphatase (asymmetrical); EC 3.6.1.17] from humans and narrow-leaved lupin. The six chemically synthesized analogs were: ApCH(2)OpOCH(2)pA (1), ApOCH(2)pCH(2)OpA (2), ApOpCH(2)OpOpA (3), ApCH(2)OpOpOCH(2)pA (4), ApOCH(2)pOpCH(2)OpA (5) and ApOpOCH(2)pCH(2)OpOpA (6). The eukaryotic asymmetrical Ap(4)A hydrolases degrade two compounds, 3 and 5, as anticipated in their design. Analog 3 was cleaved to AMP (pA) and beta,gamma-methyleneoxy-ATP (pOCH(2)pOpA), whereas hydrolysis of analog 5 gave two molecules of alpha,beta-oxymethylene ADP (pCH(2)OpA). The relative rates of hydrolysis of these analogs were estimated. Some of the novel nucleotides were moderately good inhibitors of the asymmetrical hydrolases, having K(i) values within the range of the K(m) for Ap(4)A. By contrast, none of the six analogs were good substrates or inhibitors of the bacterial symmetrical Ap(4)A hydrolase.

Hint1 is a haplo-insufficient tumor suppressor in mice

The HINT1 protein, a member of the histidine triad (HIT) family, is highly conserved in diverse species and ubiquitously expressed in mammalian tissues. However, its precise function in mammalian cells is not known. As a result of its structural similarity to the tumor-suppressor protein FHIT, we used homozygous-deleted Hint1 mice to study its role in tumorigenesis. We discovered that after 2 to 3 years of age the spontaneous tumor incidence in Hint1 -/- mice was significantly greater than that in wild-type Hint1 +/+ mice (P < 0.05). Using a well-established mouse model of 7,12-dimethylbenz[a]anthracene (DMBA)-induced mammary carcinogenesis we found a marked and significant (P < 0.05) increase in the incidence of mammary and ovarian tumors in both, Hint1 -/- and +/- mice versus +/+ mice. The Hint1 -/- and +/- mice had similar tumor incidence and similar tumor histologies. Therefore, deletion of Hint1 in mice enhances both spontaneous tumor development and susceptibility to tumor induction by DMBA. In addition, since the Hint1 +/- tumors retained expression of the unmutated wild-type allele, Hint1 is haplo-insufficient with respect to tumor suppression in this model system.

Regulation of dinucleoside polyphosphate pools by the YgdP and ApaH hydrolases is essential for the ability of Salmonella enterica serovar typhimurium to invade cultured mammalian cells

The ygdP and apaH genes of Salmonella enterica serovar Typhimurium (S. Typhimurium) encode two unrelated dinucleoside polyphosphate (NpnN) hydrolases. For example, YgdP cleaves diadenosine tetraphosphate (Ap4A) producing AMP and ATP, while ApaH cleaves Ap4A producing 2ADP. Disruption of ygdP, apaH individually, and disruption of both genes together reduced intracellular invasion of human HEp-2 epithelial cells by S. Typhimurium by 9-, 250-, and 3000-fold, respectively. Adhesion of the mutants was also greatly reduced compared with the wild type. Invasive capacity of both single mutants was restored by transcomplementation with the ygdP gene, suggesting that loss of invasion was due to increased intracellular NpnN. The normal level of 3 microM adenylated NpnN (ApnN) was increased 1.5-, 3.5-, and 10-fold in the ygdP, apaH and double mutants, respectively. Expression of the putative ptsP virulence gene downstream of ygdP was not affected in the ygdP mutant. Analysis of 19 metabolic enzyme activities and the ability to use a range of carbohydrate carbon sources revealed a number of differences between the mutants and wild type. The increase in intracellular NpnN in the mutants appears to cause changes in gene expression that limit the ability of S. Typhimurium to adhere to and invade mammalian cells.

Adenosine-5'-O-phosphorylated and adenosine-5'-O-phosphorothioylated polyols as strong inhibitors of (symmetrical) and (asymmetrical) dinucleoside tetraphosphatases

Dinucleoside 5',5"'- P (1), P ( n )-polyphosphates, and particularly the diadenosine compounds, have been implicated in extracellular purinergic signalling and in various intracellular processes, including DNA metabolism, tumour suppression and stress responses. If permitted to accumulate, they may also be toxic. One approach to understanding their function is through the various specific degradative enzymes that regulate their levels. Eight adenosine-5'- O -phosphorylated polyols (derivatives of glycerol, erythritol and pentaerythritol) and 11 adenosine-5'- O -phosphorothioylated polyols (derivatives of glycerol, erythritol, pentaerythritol, butanediol and pentanediol) have been tested as inhibitors of specific diadenosine tetraphosphate (Ap(4)A) hydrolases. Of these two groups of novel nucleotides, the adenosine-5'- O -phosphorothioylated polyols were generally stronger inhibitors than their adenosine-5'- O -phosphorylated counterparts. 1,4-Di(adenosine-5'- O -phosphorothio) erythritol appeared to be the strongest inhibitor of ( asymmetrical ) Ap(4)A hydrolases (EC 3.6.1.17) from both lupin and human, with K (i) values of 0.15 microM and 1.5 microM respectively. Of eight adenosine-5'- O -phosphorylated polyols, 1,4-di(adenosine-5'- O -phospho) erythritol was the only compound that inhibited the lupin enzyme. Two derivatives of pentaerythritol, di(adenosine-5'- O -phosphorothio)-di(phosphorothio) pentaerythritol and tri(adenosine-5'- O -phosphorothio)-phosphorothio-pentaerythritol, proved to be the strongest inhibitors of the prokaryotic ( symmetrical ) Ap(4)A hydrolase (EC 3.6.1.41) so far reported. The estimated K (i) values were 0.04 microM and 0.08 microM respectively. All of these inhibitors were competitive with respect to Ap(4)A. These new selectively acting Ap(4)A analogues should prove to be valuable tools for further studies of Ap(4)A function and of the enzymes involved in its metabolism.

The crystal structure of diadenosine tetraphosphate hydrolase from Caenorhabditis elegans in free and binary complex forms

The crystal structure of C. elegans Ap(4)A hydrolase has been determined for the free enzyme and a binary complex at 2.0 A and 1.8 A, respectively. Ap(4)A hydrolase has a key role in regulating the intracellular Ap(4)A levels and hence potentially the cellular response to metabolic stress and/or differentiation and apoptosis via the Ap(3)A/Ap(4)A ratio. The structures reveal that the enzyme has the mixed alpha/beta fold of the Nudix family and also show how the enzyme binds and locates its substrate with respect to the catalytic machinery of the Nudix motif. These results suggest how the enzyme can catalyze the hydrolysis of a range of related dinucleoside tetraphosphate, but not triphosphate, compounds through precise orientation of key elements of the substrate.

The structure of Ap(4)A hydrolase complexed with ATP-MgF(x) reveals the basis of substrate binding

Ap(4)A hydrolases are Nudix enzymes that regulate intracellular dinucleoside polyphosphate concentrations, implicating them in a range of biological events, including heat shock and metabolic stress. We have demonstrated that ATP x MgF(x) can be used to mimic substrates in the binding site of Ap(4)A hydrolase from Lupinus angustifolius and that, unlike previous substrate analogs, it is in slow exchange with the enzyme. The three-dimensional structure of the enzyme complexed with ATP x MgF(x) was solved and shows significant conformational changes. The substrate binding site of L. angustifolius Ap(4)A hydrolase differs markedly from the two previously published Nudix enzymes, ADP-ribose pyrophosphatase and MutT, despite their common fold and the conservation of active site residues. The majority of residues involved in substrate binding are conserved in asymmetrical Ap(4)A hydrolases from pathogenic bacteria, but are absent in their human counterparts, suggesting that it might be possible to generate compounds that target bacterial, but not human, Ap(4)A hydrolases.

Modified dinucleoside tetraphosphonates, new potential inhibitors of HIV reverse transcriptase

New gamma-substituted analogues of dNTP were synthesized and their enzymatic stability and antiviral properties were evaluated.

Specific and nonspecific enzymes involved in the catabolism of mononucleoside and dinucleoside polyphosphates

This review concerns enzymes that can degrade nucleoside 5'-tetra- and pentaphosphates (p(4)N and p(5)N) and those that can degrade various dinucleoside polyphosphates (Np(3-6)N'). Most of these enzymes are hydrolases, and they occur in all types of organisms. Certain fungi and protozoa also possess specific Np(n)N' phosphorylases. Specific p(4)N hydrolases have been demonstrated in mammals and in plants. In yeast, p(4)N and p(5)N are hydrolyzed by exopolyphosphatases. Among other hydrolases that can degrade these minor mononucleotides are phosphatases, apyrase, and (asymmetrical) Np(4)N' hydrolase, as well as the nonspecific adenylate deaminase. Np(n)N's are good substrates for Type I phosphodiesterases and nucleotide pyrophosphatases, and diadenosine polyphosphates are easily deaminated to diinosine polyphosphates by nonspecific adenylate deaminases. Specific Np(3)N' hydrolases occur in both prokaryotes and eukaryotes. Interestingly, the human fragile histidine triad (Fhit) tumor suppressor protein appears to be a typical Np(3)N' hydrolase. Among the specific Np(4)N' hydrolases are asymmetrically cleaving ones, which are typical of higher eukaryotes, and symmetrically cleaving enzymes found in Physarum polycephalum and in many bacteria. An enzyme that hydrolyzes both diadenosine tetraphosphate and diadenosine triphosphate has been found in the fission yeast Schizosaccharomyces pombe. Its amino acid sequence is similar to that of the human Fhit/Np(3)N' hydrolase. Very recently, a typical (asymmetrical) Np(4)N' hydrolase has been demonstrated for the first time in a bacterium-the pathogenic Bartonella bacilliformis. Another novelty is the discovery of diadenosine 5', 5"'-P(1),P 6-hexaphosphate hydrolases in budding and fission yeasts and in mammalian cells. These enzymes and the (asymmetrical) Np(4)N' hydrolases have the amino acid motif typical of the MutT (or Nudix hydrolase) family. In contrast, the Schizosaccharomyces pombe Ap(4)A/Ap(3)A hydrolase, the human Fhit protein, and the yeast Np(n)N' phosphorylases belong to a superfamily GAFH, which includes the histidine triad proteins.

Metal requirements of a diadenosine pyrophosphatase from Bartonella bacilliformis: magnetic resonance and kinetic studies of the role of Mn2+

Recombinant IalA protein from Bartonella bacilliformis is a monomeric adenosine 5'-tetraphospho-5'-adenosine (Ap4A) pyrophosphatase of 170 amino acids that catalyzes the hydrolysis of Ap4A, Ap5A, and Ap6A by attack at the delta-phosphorus, with the departure of ATP as the leaving group [Cartwright et al. (1999) Biochem. Biophys. Res. Commun. 256, 474-479]. When various divalent cations were tested over a 300-fold concentration range, Mg2+, Mn2+, and Zn2+ ions were found to activate the enzyme, while Ca2+ did not. Sigmoidal activation curves were observed with Mn2+ and Mg2+ with Hill coefficients of 3.0 and 1.6 and K0.5 values of 0.9 and 5.3 mM, respectively. The substrate M2+ x Ap4A showed hyperbolic kinetics with Km values of 0.34 mM for both Mn2+ x Ap4A and Mg2+ x Ap4A. Direct Mn2+ binding studies by electron paramagnetic resonance (EPR) and by the enhancement of the longitudinal relaxation rate of water protons revealed two Mn2+ binding sites per molecule of Ap4A pyrophosphatase with dissociation constants of 1.1 mM, comparable to the kinetically determined K0.5 value of Mn2+. The enhancement factor of the longitudinal relaxation rate of water protons due to bound Mn2+ (epsilon b) decreased with increasing site occupancy from a value of 12.9 with one site occupied to 3.3 when both are occupied, indicating site-site interaction between the two enzyme-bound Mn2+ ions. Assuming the decrease in epsilon(b) to result from cross-relaxation between the two bound Mn2+ ions yields an estimated distance of 5.9 +/- 0.4 A between them. The substrate Ap4A binds one Mn2+ (Kd = 0.43 mM) with an epsilon b value of 2.6, consistent with the molecular weight of the Mn2+ x Ap4A complex. Mg2+ binding studies, in competition with Mn2+, reveal two Mg2+ binding sites on the enzyme with Kd values of 8.6 mM and one Mg2+ binding site on Ap4A with a Kd of 3.9 mM, values that are comparable to the K0.5 for Mg2+. Hence, with both Mn2+ and Mg2+, a total of three metal binding sites were found-two on the enzyme and one on the substrate-with dissociation constants comparable to the kinetically determined K0.5 values, suggesting a role in catalysis for three bound divalent cations. Ca2+ does not activate Ap4A pyrophosphatase but inhibits the Mn2+-activated enzyme competitively with a Ki = 1.9 +/- 1.3 mM. Ca2+ binding studies, in competition with Mn2+, revealed two sites on the enzyme with dissociation constants (4.3 +/- 1.3 mM) and one on Ap4A with a dissociation constant of 2.1 mM. These values are similar to its Ki suggesting that inhibition by Ca2+ results from the complete displacement of Mn2+ from the active site. Unlike the homologous MutT pyrophosphohydrolase, which requires only one enzyme-bound divalent cation in an E x M2+ x NTP x M2+ complex for catalytic activity, Ap4A pyrophosphatase requires two enzyme-bound divalent cations that function in an active E x (M2+)2 x Ap4A x M2+ complex.

Characterization of the HeLa cell DNA polymerase alpha-associated Ap4A binding protein by photoaffinity labeling

The ubiquitous dinucleotide diadenosine tetraphosphate (Ap4A) has been proposed to be involved in DNA replication and cell proliferation, DNA repair, platelet aggregation, and vascular tonus. A protein binding to Ap4A is associated with a multiprotein form of DNA polymerase alpha (pol alpha 2) in HeLa cells. We have purified the pol alpha-associated Ap4A binding protein to homogeneity. The Ap4A binding protein is resolved into two polypeptides of 45 and 22 kDa, designated as A1 and A2, respectively. We have utilized [alpha-32P]8-N3-Ap4A to label the purified binding protein, and by cross-linking the photoaffinity label we have determined that Ap4A binds to the A1 subunit. No binding to the ligand is observed with the A2 subunit. Photoaffinity labeling is saturated with approximately 0.4 microM photolabel, with a half-maximal binding at 0.15 microM. The labeling is UV-dependent and is competed by both 8-N3-Ap4A and Ap4A. Photoaffinity labeling is not affected in the presence of dATP and dGTP and is reduced only in the presence of excess of ATP indicating the specificity of the protein for Ap4A. Of the diadenosine polyphosphates, Ap4A and Ap5A competed for binding, while Ap2A and Ap3A did not compete for binding. Further, the presence of at least one adenosine may be necessary since Ap4G competes but Gp4G does not compete for binding to the protein. Various methylene bisphosphonate and thiophosphate analogs of Ap4A were tested to see their effect on photoaffinity labeling with 8-N3-Ap4A. Significant differences were observed among the various analogs in their ability to prevent the photoaffinity labeling of the ligand to the binding protein.

The bis(adenosin-N6-yl)alkanes, a family of potential dinucleoside-polyphosphate analogue precursors. Cytotoxicity, adenosine-receptor binding and metabolism

A series of bis(adenosin-N6-yl)alkanes, in which two adenosine residues are linked via their N6 positions by alkyl bridges comprising between 2 and 14 methylene units, were synthesized as potential precursors to dinucleoside-polyphosphate analogues. These compounds were moderately cytotoxic to mammalian cells, the toxicity increasing with the length of the alkyl chain. For example, the dose of bis(adenosin-N6-yl)dodecane, A[CH2]12A, leading to 50% inhibition of cell growth (ID50) for BHK fibroblasts, Walker 256 carcinoma cells and S-49 T-lymphoma cells were 90 +/- 8, 100 +/- 5 and 23 +/- 4 microM respectively. A significant amount of A[CH2]12A bound to serum albumin in the growth media; thus the ID50 for S-49 cells grown in serum-free medium was 9 +/- 2 microM. The corresponding bis-cytidine analogues were much less toxic; however the presence of a second adenosine moeity/molecule had little significant effect on cell growth when compared to N6-alkyladenosines. Toxicity to S-49 cells was unaffected by the nucleoside-transporter inhibitor nitrobenzylthioinosine and was even higher (ID50 = 5 +/- 0.5 microM) towards nucleoside-transport-deficient AE-1 cells, showing that the analogues could pass freely through the plasma membrane. Interaction with A1 adenosine receptors was shown by displacement of [3H]N6-R-phenylisopropyladenosine (Kd = 6 nM) from rat adipocyte membranes, with Ki values of 45, 65, 85 and 390 nM for the compounds containing 12, 8, 6 and 4 methylene units, respectively. Affinity for human platelet membrane A2 adenosine receptors was about 100-fold less, however the compounds were weak A2 agonists, producing up to a threefold increase in intracellular cyclic AMP in WI-38/VA-13 cells. Thus, these compounds behave, not surprisingly, as adenosine analogues. In addition, A[CH2]12A was metabolized in vitro and intracellularly by adenosine kinase (Ki = 70 nM) and adenylate kinase to yield a number of phosphorylated derivatives with the potential to act as diadenosine polyphosphate analogues. One of these, the bismonophosphate, was recognized by and inhibited adenylate kinase more effectively than adenosine(5')tetraphospho(5')adenosine (Ap4A, Ki = 3 microM).

P alpha-chiral phosphorothioate analogues of bis(5'-adenosyl)tetraphosphate (Ap4A); their enzymatic synthesis and degradation

Synthesis of Sp and Rp diastereomers of Ap4A alpha S has been characterized in two enzymatic systems, the lysyl-tRNA synthetase from Escherichia coli and the Ap4A alpha, beta-phosphorylase from Saccharomyces cerevisiae. The synthetase was able to use both (Sp)ATP alpha S and (Rp)ATP alpha S as acceptors of adenylate thus yielding corresponding monothioanalogues of Ap4A,(Sp) Ap4A alpha S and (Rp)Ap4A alpha S. No dithiophosphate analogue was formed. Relative synthetase velocities of the formation of Ap4A,(Sp) Ap4A alpha S and (Rp)Ap4A alpha S were 1:0.38:0.15, and the computed Km values for (Sp)ATP alpha S and (Rp)ATP alpha S were 0.48 and 1.34 mM, respectively. The yeast Ap4A phosphorylase synthesized (Sp)Ap4A alpha S and (Rp)Ap4A alpha S using adenosine 5'-phosphosulfate (APS) as source of adenylate. The adenylate was accepted by corresponding thioanalogues of ATP. In that system, relative velocities of Ap4A, (Sp)Ap4A alpha S and (Rp)Ap4A alpha S formation were 1:0.15:0.60. The two isomeric phosphorothioate analogues of Ap4A were tested as substrates for the following specific Ap4A-degrading enzymes: (asymmetrical) Ap4A hydrolase (EC 3.6.1.17) from yellow lupin (Lupinus luteus) seeds hydrolyzed each of the analogues to AMP and the corresponding isomer of ATP alpha S; (symmetrical) Ap4A hydrolase (EC 3.6.1.41) from E. coli produced ADP and the corresponding diastereomer of ADP alpha S; and Ap4A phosphorylase (EC 2.7.7.53) from S. cerevisiae cleaved the Rp isomer only at the unmodified end yielding ADP and (Rp)ATP alpha S whereas the Sp isomer was degraded non-specifically yielding a mixture of ADP, (Sp)ADP alpha S, ATP and (Sp)ATP alpha S. For all the Ap4A-degrading enzymes, the Rp isomer of Ap4A alpha S appeared to be a better substrate than its Sp counterpart; stereoselectivity of the three enzymes for the Ap4A alpha S diastereomers is 51, 6 and 2.5, respectively. Basic kinetic parameters of the degradation reactions are presented and structural requirements of the Ap4A-metabolizing enzymes with respect to the potential substrates modified at the Ap4A-P alpha are discussed.