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.     

Cloning, characterisation and crystallisation of a diadenosine 5',5"'-P(1),P(4)-tetraphosphate pyrophosphohydrolase from Caenorhabditis elegans.

Asymmetrically cleaving diadenosine 5',5"'-P(1),P(4)-tetraphosphate (Ap4A) hydrolase activity has been detected in extracts of adult Caenorhabditis elegans and the corresponding cDNA amplified and expressed in Escherichia coli. As expected, sequence analysis shows the enzyme to be a member of the Nudix hydrolase family. The purified recombinant enzyme behaves as a typical animal Ap4A hydrolase. It hydrolyses Ap4A with a K(m) of 7 microM and k(cat) of 27 s(-1) producing AMP and ATP as products. It is also active towards other adenosine and diadenosine polyphosphates with four or more phosphate groups, but not diadenosine triphosphate, always generating ATP as one of the products. It is inhibited non-competitively by fluoride (K(i)=25 microM) and competitively by adenosine 5'-tetraphosphate with Ap4A as substrate (K(i)=10 nM). Crystals of diffraction quality with the morphology of rectangular plates were readily obtained and preliminary data collected. These crystals diffract to a minimum d-spacing of 2 A and belong to either space group C222 or C222(1). Phylogenetic analysis of known and putative Ap4A hydrolases of the Nudix family suggests that they fall into two groups comprising plant and Proteobacterial enzymes on the one hand and animal and archaeal enzymes on the other. Complete structural determination of the C. elegans Ap4A hydrolase will help determine the basis of this grouping.     

Diadenosine tetraphosphate hydrolase from mouse liver. Purification to homogeneity and partial characterization

An enzyme hydrolyzing diadenosine 5',5"'P1, P4-tetraphosphate (Ap4A) to AMP and ATP has been purified to apparent homogeneity from mouse liver cell extracts. The isolation procedure comprised ammonium sulfate precipitation, chromatography on Sephadex G-75. DEAE-cellulose, blue Sepharose and AMP-Sepharose. The enzyme is a single polypeptide chain with a native Mr = 64,000 with a Km of 1.66 microM and Vmax of 1.25 mumol/min. AMP, ADP, Ap4, GTP, Gp4, Ap3A, Ap5A, Gp3G, and Gp5G are noncompetitive inhibitors of the Ap4A hydrolase activity, whereas Gp4G inhibits Ap4A hydrolysis competitively with a Ki of 6 microM. Theophylline, caffeine, and isobutylmethylxanthine do not or only slightly inhibit Ap4A hydrolysis. Mitogenic factors have no effect on the enzymatic activity of Ap4A hydrolase, excluding that a direct influence of internalized mitogens on Ap4A degradation could be responsible for mitogen-dependent fluctuation of intracellular Ap4A pool sizes.     

Selective degradation of 2'-adenylated diadenosine tri- and tetraphosphates, Ap(3)A and Ap(4)A, by two specific human dinucleoside polyphosphate hydrolases

It is known that the interferon-inducible 2',5'-oligoadenylate synthetase can catalyze the 2'-adenylation of various diadenosine polyphosphates. However, catabolism of those 2'-adenylated compounds has not been investigated so far. This study shows that the mono- and bis-adenylated (or mono- and bis-deoxyadenylated) diadenosine triphosphates are not substrates of the human Fhit (fragile histidine triad) protein, which acts as a typical dinucleoside triphosphate hydrolase (EC 3.6.1.29). In contrast, the diadenosine tetraphosphate counterparts are substrates for the human (asymmetrical) Ap(4)A hydrolase (EC 3.6.1.17). The relative rates of the hydrolysis of 0.15 mM AppppA, (2'-pdA)AppppA, and (2'-pdA)AppppA(2"'-pdA) catalyzed by the latter enzyme were determined as 100:232:38, respectively. The asymmetrical substrate was hydrolyzed to ATP + (2'-pdA)AMP (80%) and to (2'-pdA)ATP + AMP (20%). The human Fhit protein, for which Ap(4)A is a poor substrate, did not degrade the 2'-adenylated diadenosine tetraphosphates either. The preference of the interferon-inducible 2'-5' oligoadenylate synthetase to use Ap(3)A over Ap(4)A as a primer for 2'-adenylation and the difference in the recognition of the 2'-adenylated diadenosine triphosphates versus the 2'-adenylated diadenosine tetraphosphates by the dinucleoside polyphosphate hydrolases described here provide a mechanism by which the ratio of the 2'-adenylated forms of the signalling molecules, Ap(3)A and Ap(4)A, could be regulated in vivo.     

Diadenosine tetraphosphate activates cytosol 5'-nucleotidase

The rate of hydrolysis of IMP (0.5 mM) by cytosol 5'-nucleotidase from Artemia embryos was increased up to 7-fold by concentrations of around 10 microM diadenosine tetraphosphate (Ap4A). Half maximal activation of the enzyme was accomplished with 5 microM Ap4A. The Km (S 0.5) values of the nucleotidase for IMP, GMP, AMP, XMP and CMP decreased about 10 fold in the presence of 10 microM Ap4A. Maximum velocity of the enzyme was not affected by Ap4A. ATP had been previously described as an activator of the enzyme. However, comparatively with Ap4A, concentrations of ATP two orders of magnitude higher are needed to elicit similar effects on the enzyme. Preliminary results indicate that Ap4A is also an activator of the cytosol 5'-nucleotidase from rat liver.     

Catabolism of bis(5'-nucleosidyl) oligophosphates in Escherichia coli: metal requirements and substrate specificity of homogeneous diadenosine-5',5'-P1,P4-tetraphosphate pyrophosphohydrolase

Diadenosine-5',5'-P1,P4-tetraphosphate pyrophosphohydrolase (diadenosinetetraphosphatase) from Escherichia coli strain EM20031 has been purified 5000-fold from 4 kg of wet cells. It produces 2.4 mg of homogeneous enzyme with a yield of 3.1%. The enzyme activity in the reaction of ADP production from Ap4A is 250 s-1 [37 degrees C, 50 mM tris(hydroxymethyl)aminomethane, pH 7.8, 50 microM Ap4A, 0.5 microM ethylenediaminetetraacetic acid (EDTA), and 50 microM CoCl2]. The enzyme is a single polypeptide chain of Mr 33K, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis and high-performance gel permeation chromatography. Dinucleoside polyphosphates are substrates provided they contain more than two phosphates (Ap4A, Ap4G, Ap4C, Gp4G, Ap3A, Ap3G, Ap3C, Gp3G, Gp3C, Ap5A, Ap6A, and dAp4dA are substrates; Ap2A, NAD, and NADP are not). Among the products, a nucleoside diphosphate is always formed. ATP, GTP, CTP, UTP, dATP, dGTP, dCTP, and dTTP are not substrates; Ap4 is. Addition of Co2+ (50 microM) to the reaction buffer containing 0.5 microM EDTA strongly stimulates Ap4A hydrolysis (stimulation 2500-fold). With 50 microM MnCl2, the stimulation is 900-fold. Ca2+, Fe2+, and Mg2+ have no effect. The Km for Ap4A is 22 microM with Co2+ and 12 microM with Mn2+. The added metals have similar effects on the hydrolysis of Ap3A into ADP + AMP. However, in the latter case, the stimulation by Co2+ is small, and the maximum stimulation brought by Mn2+ is 9 times that brought by Co2+. Exposure of the enzyme to Zn2+ (5 microM), prior to the assay or within the reaction mixture containing Co2+, causes a marked inhibition of Ap4A hydrolysis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Schizosaccharomyces pombe Aps1, a diadenosine 5',5' "-P1, P6-hexaphosphate hydrolase that is a member of the nudix (MutT) family of hydrolases: cloning of the gene and characterization of the purified enzyme

The fission yeast Schizosaccharomyces pombe contains a gene on chromosome I that encodes a hypothetical nudix hydrolase, YA9E. The gene, designated aps1, has been cloned and the protein has been purified from Escherichia coli with a yield of 10 mg of Aps1/L of culture. Aps1, composed of 210 amino acids with a calculated molecular mass of 23 724 Da, behaves as a monomer with a sedimentation coefficient of 1.92 S as determined by analytical ultracentrifugation. The effective hydrodynamic radius is about 29 A as determined by both analytical ultracentrifugation and gel-filtration chromatography. Aps1, whose expression was detected in S. pombe by Western blotting, is an enzyme that catalyzes the hydrolysis of dinucleoside oligophosphates, with Ap6A and Ap5A being the preferred substrates. The major reaction products are ADP and p4A from Ap6A and ADP and ATP from Ap5A. Values of Km for Ap6A and Ap5A are 19 microM and 22 microM, respectively, and the corresponding values of kcat are 2.0 s-1 and 1.7 s-1, respectively. The enzyme has limited activity on Ap4A and negligible activity on Ap3A, ADP-ribose, and NADH. Aps1 catalyzes the hydrolysis of mononucleotides with decreasing activity in order from p5A to AMP. Optimal activity with Ap6A as substrate is observed at pH 7.6 and in the presence of 0.1-1 mM MnCl2. Aps1 is the first nudix hydrolase isolated from S. pombe, and it is the first enzyme identified with this specific substrate specificity and reaction products.     

Inhibition of carbamyl phosphate synthetase by P1, P5-di(adenosine 5')-pentaphosphate: evidence for two ATP binding sites.

Studies on the effect of a series of alpha, omega-diadenosine 5'-polyphosphate (ApnA; n = 2 to 6) on carbamyl phosphate synthetase showed that only Ap5A is an effective inhibitor. Ap5A also inhibits two partial reactions catalyzed by the enzyme: bicarbonate-dependent ATPase and ATP synthesis from carbamyl phosphate and ADP. The data indicate that Ap5A binds to the enzyme sites that interact with ATP. Of a variety of ATP-utilizing enzymes (kinases, hydrolases, synthetases), only adenylate kinase (Leinhard, G. E., and Secemski, I. I. (1973) J. Biol. Chem. 248, 1121--1123) and carbamyl phosphate synthetase are inhibited by Ap5A. The present findings provide strong evidence that carbamyl phosphate synthetase has two separate binding sites for ATP in which the gamma-phosphate moeities of ATP are bound in close proximity to the bicarbonate binding site of the enzyme.     

In vivo levels of diadenosine tetraphosphate and adenosine tetraphospho-guanosine in Physarum polycephalum during the cell cycle and oxidative stress.

Cellular levels of diadenosine tetraphosphate (Ap4A) and adenosine tetraphospho-guanosine (Ap4G) were specifically measured during the cell cycle of Physarum polycephalum by a high-pressure liquid chromatographic method. Ap4A was also measured indirectly by a coupled phosphodiesterase-luciferase assay. No cell cycle-specific changes in either Ap4A or Ap4G were detected in experiments involving different methods of assay, different strains of P. polycephalum, or different methods of fixation of macroplasmodia. Our results on Ap4A are in contrast with those reported previously (C. Weinmann-Dorsch, G. Pierron, R. Wick, H. Sauer, and F. Grummt, Exp. Cell Res. 155:171-177, 1984). Weinmann-Dorsch et al. reported an 8- to 30-fold increase in Ap4A in early S phase in P. polycephalum, as measured by the phosphodiesterase-luciferase assay. We also measured levels of Ap4A, Ap4G, and ATP in macroplasmodia treated with 0.1 mM dinitrophenol. Ap4A and Ap4G transiently increased three- to sevenfold after 1 h and then decreased concomitantly with an 80% decrease in the level of ATP after 2 h in the presence of dinitrophenol. These results do not support the hypothesis that Ap4A is a positive pleiotypic activator that modulates DNA replication, but they are consistent with the hypothesis proposed for procaryotes that Ap4A and Ap4G are signal nucleotides or alarmones of oxidative stress (B.R. Bochner, P.C. Lee, S.W. Wilson, C.W. Cutler, and B.N. Ames, Cell 37:225-232, 1984).     

Identification and partial characterization of an adenosine(5'')tetraphospho(5'')adenosine hydrolase on intact bovine aortic endothelial cells.

The biologically active dinucleotides adenosine(5')tetraphospho(5')adenosine (Ap4A) and adenosine(5')-triphospho(5')adenosine (Ap3A), which are both releasable into the circulation from storage pools in thrombocytes, are catabolized by intact bovine aortic endothelial cells. 1. Compared with extracellular ATP and ADP, which are very rapidly hydrolysed, the degradation of Ap4A and Ap3A by endothelial ectohydrolases is relatively slow, resulting in a much longer half-life on the endothelial surface of the blood vessel. The products of hydrolysis are further degraded and finally taken up as adenosine. 2. Ap4A hydrolase has high affinity for its substrate (Km 10 microM). 3. ATP as well as AMP transiently accumulates in the extracellular fluid, suggesting an asymmetric split of Ap4A by the ectoenzyme. 4. Mg2+ or Mn2+ at millimolar concentration are needed for maximal activity; Zn2+ and Ca2+ are inhibitory. 5. The hydrolysis of Ap4A is retarded by other nucleotides, such as ATP and Ap3A, which are released from platelets simultaneously with Ap4A.     

Catabolism of Ap4A and Ap3A in whole blood. The dinucleotides are long-lived signal molecules in the blood ending up as intracellular ATP in the erythrocytes

Adenosine(5')tetraphospho(5')adenosine (Ap4A) and adenosine(5')triphospho(5')adenosine (Ap3A) are stored in large amounts in human platelets. After activation of the platelets both dinucleotides are released into the extracellular milieu where they play a role in the modulation of platelet aggregation and also in the regulation of the vasotone. It has recently been shown that the dinucleotides are degraded by enzymes present in the plasma [Lüthje, J. & Ogilvie, A. (1987) Eur. J. Biochem. 169, 385-388]. The further metabolism as well as the role of blood cells has not been established. The dinucleotides were first degraded by plasma phosphodiesterases yielding ATP (ADP) plus AMP as products which were then metabolized to adenosine and inosine. The nucleosides did not accumulate but were very rapidly salvaged by erythrocytes yielding intracellular ATP as the main product. Although lysates of platelets, leucocytes and red blood cells contained large amounts of Ap3A-degrading and Ap4A-degrading activities, these activities were not detectable in suspensions of intact cells suggesting the lack of dinucleotide-hydrolyzing ectoenzymes. Compared to ATP, which is rapidly degraded by ectoenzymes present on blood cells, the half-life of Ap4A was two to three times longer. Since the dinucleotides are secreted together with ADP and ATP from the platelets, we tested the influence of ATP on the rate of degradation of Ap4A. ATP at concentrations present during platelet aggregation strongly inhibited the degradation of Ap4A in whole blood. It is suggested that in vivo the dinucleotides are protected from degradation immediately after their release. They may thus survive for rather long times and may act as signals even at sites far away from the platelet aggregate.     

Three diadenosine 5',5'-P1,P4-tetraphosphate hydrolytic enzymes from Physarum polycephalum with differential effects by calcium: a specific dinucleoside polyphosphate pyrophosphohydrolase, a nucleotide pyrophosphatase, and a phosphodiesterase

Two new enzymes that hydrolyze diadenosine tetraphosphate (Ap4A) have been isolated from the acellular slime mold Physarum polycephalum. Both enzymes are different from the Physarum Ap4A symmetrical pyrophosphohydrolase previously described on the basis of their substrate specificities, reaction products, molecular weights, and divalent cation requirements. One enzyme is a nucleotide pyrophosphatase that asymmetrically hydrolyzes Ap4A to AMP and ATP. This enzyme hydrolyzes several mono- and dinucleotides with the corresponding nucleotide monophosphate as one of the products. The percentage hydrolysis of NAD+, Ap4A, and Ap4G, each at 10 microM, was 100, 56, and 51, respectively. A divalent cation is required for activity, with Ca2+ yielding 20-30 times greater activity than Mg2+ or Mn2+. Values of Km for Ap4A and Vmax are similar to the corresponding values for Ap4A symmetrical pyrophosphohydrolase. The second enzyme is a phosphodiesterase I with broad substrate reactivity. This enzyme also asymmetrically hydrolyzes Ap4A, but it does not hydrolyze NAD+. Activity of the phosphodiesterase I is stimulated by divalent cations, with Ca2+ being 50-60 times more stimulatory than Mg2+ or Mn2+. The apparent molecular weights of the nucleotide pyrophosphatase and phosphodiesterase are 184,000 and 45,000, respectively. In contrast, the Ap4A pyrophosphohydrolase hydrolyzes Ap4A to ADP, is inhibited by Ca2+ and other divalent cations, and has an apparent molecular weight of 26,000 as previously reported.     

Purification and molecular characterization of a novel diadenosine 5′,5′′′-P1,P4-tetraphosphate phosphorylase from Mycobacterium tuberculosis H37Rv

In this study, Rv2613c, a protein that is encoded by the open reading frame Rv2613c in Mycobacterium tuberculosis H37Rv, was expressed, purified, and characterized for the first time. The amino acid sequence of Rv2613c contained a histidine triad (HIT) motif consisting of H-phi-H-phi-H-phi-phi, where phi is a hydrophobic amino acid. This motif has been reported to be the characteristic feature of several diadenosine 5′,5′′′-P¹,P⁴-tetraphosphate (Ap4A) hydrolases that catalyze Ap4A to adenosine 5′-triphosphate (ATP) and adenosine monophosphate (AMP) or 2 adenosine 5′-diphosphate (ADP). However, enzymatic activity analyses for Rv2613c revealed that Ap4A was converted to ATP and ADP, but not AMP, indicating that Rv2613c has Ap4A phosphorylase activity rather than Ap4A hydrolase activity. The Ap4A phosphorylase activity has been reported for proteins containing a characteristic H-X-H-X-Q-phi-phi motif. However, no such motif was found in Rv2613c. In addition, the amino acid sequence of Rv2613c was significantly shorter compared to other proteins with Ap4A phosphorylase activity, indicating that the primary structure of Rv2613c differs from those of previously reported Ap4A phosphorylases. Kinetic analysis revealed that the K_m values for Ap4A and phosphate were 0.10 and 0.94 mM, respectively. Some enzymatic properties of Rv2613c, such as optimum pH and temperature, and bivalent metal ion requirement, were similar to those of previously reported yeast Ap4A phosphorylases. Unlike yeast Ap4A phosphorylases, Rv2613c did not catalyze the reverse phosphorolysis reaction. Taken together, it is suggested that Rv2613c is a unique protein, which has Ap4A phosphorylase activity with an HIT motif.     

Structure and substrate-binding mechanism of human Ap4A hydrolase

Asymmetric diadenosine 5',5'-P(1),P(4)-tetraphosphate (Ap(4)A) hydrolases play a major role in maintaining homeostasis by cleaving the metabolite diadenosine tetraphosphate (Ap(4)A) back into ATP and AMP. The NMR solution structures of the 17-kDa human asymmetric Ap(4)A hydrolase have been solved in both the presence and absence of the product ATP. The adenine moiety of the nucleotide predominantly binds in a ring stacking arrangement equivalent to that observed in the x-ray structure of the homologue from Caenorhabditis elegans. The binding site is, however, markedly divergent to that observed in the plant/pathogenic bacteria class of enzymes, opening avenues for the exploration of specific therapeutics. Binding of ATP induces substantial conformational and dynamic changes that were not observed in the C. elegans structure. In contrast to the C. elegans homologue, important side chains that play a major role in substrate binding do not have to reorient to accommodate the ligand. This may have important implications in the mechanism of substrate recognition in this class of enzymes.     

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.     

Diadenosine Tetraphosphate Is Co-Released with ATP and Catecholamines from Bovine Adrenal Medulla

Secretion of adenosine(5')tetraphospho(5')adenosine (Ap4A) and ATP from perfused bovine adrenal glands stimulated with acetylcholine or elevated potassium levels was measured and compared with that of catecholamines. We have found a close correlation between the release of Ap4A and catecholamines elicited with all the secretagogues used in the presence of either Ca2+ or Ba2+, suggesting co-release of both constituents from the chromaffin granules. By contrast, ATP secretion, as measured with luciferase, showed a significantly different time course regardless of the secretagogue used. ATP secretion consistently decreased after 1-2 min of stimulation at a time when Ap4A and catecholamine secretions were still increasing. Measures of degradation of injected [3H]ATP to the gland during stimulation showed little difference in the level of uptake or decomposition of ATP throughout the pulse. However, a reexamination of ATP secretion by monitoring its products of degradation (AMP, adenosine, and inosine) by HPLC techniques showed that Ap4A, ATP, and catecholamines are indeed secreted in parallel from the perfused adrenal gland.     

The IalA invasion gene of Bartonella bacilliformis encodes a (de)nucleoside polyphosphate hydrolase of the MutT motif family and has homologs in other invasive bacteria

The product of the ialA invasion gene of Bartonella bacilliformis has been expressed as a thioredoxin fusion protein. It is a (di)nucleoside polyphosphate hydrolase of the MutT motif protein family with strong sequence similarity to plant diadenosine tetraphosphate hydrolases. It hydrolyses nucleoside and dinucleoside polyphosphates with four or more phosphate groups, always producing an NTP as one product. Diadenosine tetraphosphate (Ap4A) is the preferred substrate with a Km of 10 microM and a kcat of 3.0 s-1. It is inhibited by Ca2+ and F- (Ki = 30 microM). Hydrolysis of Ap4A in H218O yielded [18O]AMP as the only labelled product. In terms of sequence, reaction mechanism and properties, IalA is very similar to eukaryotic Ap4A hydrolases and unlike previously described bacterial Ap4A hydrolases. Homologs are present in the genomes of other invasive pathogens. They may function to reduce stress-induced dinucleotide levels during invasion and so enhance pathogen survival.     

P1,P4-Di(adenosine-5')tetraphosphate inhibits phosphorylation of immunoglobulin G by Rous sarcoma virus pp60src

Di(adenosine-5')oligophosphate nucleotides of general structure ApnA (n = 2-6) inhibited phosphorylation of immunoglobulin G from tumor-bearing rabbits (TBR IgG) by pp60src protein kinase purified from Rous sarcoma virus-transformed rat tumor cells. Ap4A, a nucleotide associated with eukaryotic cell proliferation, was one of the most effective inhibitors in the series, causing 50% inhibition of TBR IgG phosphorylation at 15 microM. Ap4A inhibited pp60src-dependent phosphorylation of TBR IgG in solution and immunoprecipitates, as well as the phosphorylation of tubulin, microtubule-associated proteins, and vinculin. Under similar assay conditions, Ap4A did not inhibit phosphorylation of histone H2b by cAMP- or cGMP-dependent protein kinases. Ap4A appears to interact noncovalently with the enzyme, because removal of pp60src by immunoprecipitation from solutions containing Ap4A restored activity to uninhibited levels. A 100-fold increase in ATP (4-400 nM) caused a 13-fold increase in the 50% inhibitory concentration of Ap4A (2.5-33 microM), consistent with the interpretation that Ap4A competes for an ATP-binding site on the pp60src molecule. The simplest explanation of these results is that Ap4A binds to the phosphodonor site for ATP.     

Acyl-CoA synthetase catalyzes the synthesis of diadenosine hexaphosphate (Ap6A).

The synthesis of diadenosine hexaphosphate (Ap6A), a potent vasoconstrictor, is catalyzed by acyl-CoA synthetase from Pseudomonas fragi. In a first step AMP is transferred from ATP to tetrapolyphosphate (P4) originating adenosine pentaphosphate (p5A) which, subsequently, is the acceptor of another AMP moiety from ATP generating diadenosine hexaphosphate (Ap6A). Diadenosine pentaphosphate (Ap5A) and diadenosine tetraphosphate (Ap4A) were also synthesized in the course of the reaction. In view of the variety of biological effects described for these compounds the potential capacity of synthesis of diadenosine polyphosphates by the mammalian acyl-CoA synthetases may be relevant.     

Identification of peptides from the adenine binding domains of ATP and AMP in adenylate kinase: isolation of photoaffinity-labeled peptides by metal chelate chromatography.

Photoaffinity labeling with azidoadenine nucleotides was used to identify peptides from the ATP and AMP binding domains on chicken muscle adenylate kinase. Competition binding studies and enzyme assays showed that the 8-azido analogues of Ap4A and ATP modified only the MgATP2- site of adenylate kinase, whereas the 2-azido analogue of ADP modified the enzyme at both the ATP and AMP sites. The positions of the two nucleotide binding sites on the enzyme were deduced by isolating and sequencing the modified peptides. Photolabeled peptides were isolated by a new procedure that used metal chelate chromatography to affinity purify the photolabeled peptides prior to final purification by reverse-phase HPLC. The sequences of the peptides that were photolabeled with the 8-azido analogues corresponded to residues K28-L44, T153-K166, and T125-E135 of the chicken muscle enzyme. The residues that were present in both tryptic- and Staphylococcus aureus V-8 protease-generated versions of these peptides were assigned to the ATP binding domain on the basis of selective photoaffinity labeling with the 8-azidoadenine analogues. These peptides and an additional peptide corresponding to positions I110-K123 were photolabeled with 2-N3ADP. Since I110-K123 was photolabeled by 2-N3ADP but not by 8-N3Ap4A, it was assigned to the AMP binding domain.