Dinucleosidasetetraphosphatase in rat liver and Artemia salina.

A comparative study of an enzymatic activity present in Artemia salina and rat liver which specifically splits dinucleoside tetraphosphates is presented. All the purine and pyrimidine dinucleoside tetraphosphates tested, i.e. diadenosine, diguanosine, dixanthosine and diuridine tetraphosphates, were substrates of both enzymes with similar maximum velocities and Km values, (around 10 muM). The inhibition by nucleotides of the enzyme from the two sources is also similar. Particularly relevant is the strong inhibition caused by nucleoside tetraphosphates which have Ki values in the nanomolar range. The Artemia enzyme has a slightly lower molecular weight (17 500) than the liver enzyme (21 000) and is more resistant to acidic pH. Based on previous findings, the enzyme from Artemia salina was named diguanosinetetraphosphatase (EC 3.6.1.17) by the Enzyme Commission. The results presented in this paper show that the liver and Artemia enzymes are similar, and we propose to name this enzyme as dinucleosidetetraphosphatase or dinucleoside-tetraphosphate nucleotidehydrolase.     

Primer-independent abortive initiation by wheat-germ RNA polymerase B (II)

Highly purified RNA polymerase B (II) from wheat germ catalyses the formation of dinucleoside tetraphosphates from ribonucleoside triphosphates in the absence of an oligonucleotide primer or additional protein factors. The reaction requires bivalent cations such as Mn2+ or Mg2+ and proceeds linearly for several hours. It is strongly inhibited by 1 microgram/ml alpha-amanitin or 2 micrograms/ml heparin. The reaction strictly depends on the addition of a specific linear or circular DNA template, such as the plasmid pSmaF or a DNA fragment containing the gene for nopaline dehydrogenase. Bacteriophage T7 D111 DNA has almost no template activity. The start sites for dinucleotide synthesis on the template are limited. With the DNA fragment containing the gene for nopaline dehydrogenase only pppApA and pppApU are synthesised substantially whereas pppUpU is formed only in trace amounts. No significant dinucleotide synthesis is observed with other ribonucleoside triphosphates either singly or in a combination of two. The various regions of the DNA fragment differ distinctly in template activity.     

Heat shock and hydrogen peroxide responses of Escherichia coli are not changed by dinucleoside tetraphosphate hydrolase overproduction.

In Escherichia coli strains overproducing dinucleoside tetraphosphate hydrolase, the accumulation of dinucleoside tetraphosphates (AppppN, with N = A, C, G, or U) during heat shock or H2O2 treatment was reduced about 10-fold as compared with a control strain. This accumulation neither modified the pattern of the proteins induced by a temperature shift or H2O2 nor reduced the protection against oxidative damage induced by moderate H2O2 levels.     

Monothiophosphate Analogs of Dinucleoside Tetraphosphate

Abstract

Monothiophosphate analogs of dinucleoside tetraphosphates have been synthesized i n order to study their resistance towards the specific hydrolase of E. Coli.     

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.     

Structure–activity relationships of dinucleotides: Potent and selective agonists of P2Y receptors

Dinucleoside polyphosphates act as agonists on purinergic P2Y receptors to mediate a variety of cellular processes. Symmetrical, naturally occurring purine dinucleotides are found in most living cells and their actions are generally known. Unsymmetrical purine dinucleotides and all pyrimidine containing dinucleotides, however, are not as common and therefore their actions are not well understood. To carry out a thorough examination of the activities and specificities of these dinucleotides, a robust method of synthesis was developed to allow manipulation of either nucleoside of the dinucleotide as well as the phosphate chain lengths. Adenosine containing dinucleotides exhibit some level of activity on P2Y₁ while uridine containing dinucleotides have some level of agonist response on P2Y₂ and P2Y₆. The length of the linking phosphate chain determines a different specificity; diphosphates are most accurately mimicked by dinucleoside triphosphates and triphosphates most resemble dinucleoside tetraphosphates. The pharmacological activities and relative metabolic stabilities of these dinucleotides are reported with their potential therapeutic applications being discussed.     

Diadenosine 5",5"'P1,P4-tetraphosphatase in Drosophila embryos: developmental regulation and characterization

1. An enzyme has been isolated from Drosophila embryos which specifically hydrolyzes dinucleoside tetraphosphates to the corresponding nucleoside tri- and tetraphosphates, with Km values around 4 microM. 2. Nucleoside mono-, di- and triphosphates are competitive inhibitors with K1 values i the 0.01 mM range. 3. The inhibition is particularly strong by adenosine tetraphosphate (Ki = 10 nM). 4. The enzyme is maximally active at pH 7.5 and is quite stable at acid pH. 5. The enzyme requires divalent cations for activity: Co(2+) much greater than [corrected] Mn(2+) Mg(2+) x Co(2+) stimulated about 90-fold at 6 mM. 6. The specific stimulation by Co(2+) has been described before, but at lower concentrations, for the enzyme of procaryotes which splits diadenosine tetraphosphate symmetrically. Zn(2+) and Ca(2+) are inhibitors of the Drosophila enzyme. Co(2+) is also inhibitor in the presence of Mg(2+). 7. The Drosophila enzyme has essential sulphydryl group(s) and a molecular weight of 26,000. 8. Diadenosine tetraphosphatase is present in mature oocytes and increases after fertilization to reach a peak 1.5 hr later. 9. From this time to 3.5 hr the activity decreased to remain at a plateau until the end of embryogenesis. 10. The profile of activity is compatible with its involvement in the regulation of nuclear division.     

Dinucleoside tetraphosphate variations in cultured tumor cells during their cell cycle and growth

Asynchronous and synchronized cultures of A549 and HTC cells were used to detect possible, cell cycle or cell density specific variations in the intracellular pools of dinucleoside tetraphosphates (Ap4X). No important variations of the nucleotide pools were observed during cell growth. When HTC cells were released from mitotic arrest, a decrease by a factor of N3 Ap4X and ATP levels was observed when the cells entered the G1 phase. This decrease is essentially due to cell doubling. When A549 cells were released from an arrest at the G1/S boundary, the nucleotide pool size increased slightly during the G2 phase just before mitosis. This result is in agreement with both earlier data from our laboratory and the observed decrease in Ap4X pool after release from mitotic-arrested HTC cells. These results suggest that the Ap4X and ATP pools are only subjected to very small variations during the cell cycle, essentially in the G2 phase and after mitosis.     

Uridine 5'-polyphosphates (p4U and p5U) and uridine(5')polyphospho(5')nucleosides (Up(n)Ns) can be synthesized by UTP:glucose-1-phosphate uridylyltransferase from Saccharomyces cerevisiae

UTP:glucose-1-phosphate uridylyltransferase (EC 2.7.7.9) from Saccharomyces cerevisiae can transfer the uridylyl moiety from UDP-glucose onto tripolyphosphate (P(3)), tetrapolyphosphate (P(4)), nucleoside triphosphates (p(3)Ns) and nucleoside 5'-polyphosphates (p(4)Ns) forming uridine 5'-tetraphosphate (p(4)U), uridine 5'-pentaphosphate (p(5)U) and dinucleotides, such as Ap(4)U, Cp(4)U, Gp(4)U, Up(4)U, Ap(5)U and Gp(5)U. Unlike UDP-glucose, UDP-galactose was not a UMP donor and ADP was not a UMP acceptor. This is the first example of an enzyme that may be responsible for accumulation of dinucleoside tetraphosphates containing two pyrimidine nucleosides in vivo. Occurrence of such dinucleotides in S. cerevisiae and Escherichia coli has been previously reported (Coste et al., J. Biol. Chem. 262 (1987) 12096-12103).     

Identification of dinucleoside polyphosphates in adrenal glands

Dinucleoside polyphosphates have been characterised as extracellular mediators controlling numerous physiological functions like vascular tone or cell proliferation. Here we describe the isolation and identification of dinucleoside polyphosphates Ap(n)A (with n=2-3), Ap(n)G (with n=2-6) as well as Gp(n)G (with n=2-6) from adrenal glands. These dinucleoside polyphosphates are localised in granules of the adrenal glands. The dinucleoside polyphosphates diadenosine diphosphate (Ap(2)A), diadenosine triphosphate (Ap(3)A), adenosine guanosine polyphosphates (Ap(n)G) and diguanosine polyphosphates (Gp(n)G), both with phosphate group (p) numbers (n) ranging from 2 to 6, were identified by fractionating them to homogeneity by preparative size-exclusion- and affinity-chromatography as well as analytical anion-exchange and reversed-phase-chromatography from deproteinised adrenal glands and by analysis of the homogeneous dinucleoside polyphosphates containing fractions with post-source-decay (PSD) matrix-assisted laser desorption/ionisation mass spectrometry (MALDI-MS). The identity of the dinucleoside polyphosphates was confirmed by retention time comparison with authentic dinucleoside polyphosphates. Enzymatic analysis demonstrated an interconnection of the phosphate groups with the adenosines in the 5(')-positions of the riboses in all dinucleoside polyphosphates purified from adrenal glands. In conclusion, the identification of these dinucleoside polyphosphates in adrenal gland granules emphasises that these dinucleoside polyphosphates can be released from the adrenal glands upon stimulation into the circulation.     

Bis-(5''-guanosyl) tetraphosphatase in rat tissues.

The occurrence and distribution of bis-(5'-guanosyl) tetraphosphatase activity towards dinucleoside tetraphosphates between the 27 000 g supernatant and sedimented fraction were studied in liver, kidney, brain, muscle and intestinal mucosa from rat. The p1p4-bis-(5'-guanosyl) tetraphosphate-hydrolysing activities found in total homogenates were 0.77, 1.44, 0.39, 0.36 and 2.14 units (mumol/min)/g respectively. The activities found in the 27000 g-sedimented fractions were 74, 49, 11, 4 and 96% of those present in the homogenates respectively. The properties of the soluble enzymes were investigated. All of them have low Km values for p1p4-bis-(5'-guanosyl) tetraphosphate (from 2 to 50 microM), are competitively inhibited by guanosine 5'-tetraphosphate with K1 values from 10 to 160 nM, have molecular weights of about 21 000, require Mg2+ or Mn2+ and are inhibited by Ca2+. These properties show that bis-(5'-guanosyl) tetraphosphatase (EC 3.6.1.17), an enzyme previously characterized in Artemia salina and rat liver [Warner & Finamore (1965) Biochemistry 4, 1568-1575; Vallejo, Sillero & Sillero (1974) Biochim, Biophys. Acta 358, 117-125; Lobatón, Vallejo, Sillero & Sillero (1975) Eur. J. Biochem. 50, 495-501], is present in all the rat tissues examined. The inhibition of the enzyme by Ca2+ could be related to the effect of p1p4-bis-(5'-adenosyl) tetraphosphate as a trigger of DNA synthesis [Grummt, Waltl, Jantzen, Hamprecht, Huebscher & Kuenzle (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 6081-6085].     

Ion-exchange thin-layer chromatography and paper ionophoresis of dinucleoside monophosphates

The thin-layer chromatography of dinucleoside monophosphates on plates coated with DEAE-cellulose powder and on plates coated with cellulose impregnated with polyethyleneimine, together with their ionophoretic mobilities on DEAE-cellulose paper, is described. It is shown that the 2′→5′ dinucleoside monophosphates can be separated from the corresponding 3′→5′ isomers by ion-exchange thin-layer chromatography and paper ionophoresis. The method is very sensitive and can replace the commonly used enzymic hydrolysis for analyzing the nature of the phosphodiester linkage of a given dinucleoside monophosphate.     

Catabolism of bis(5'-nucleosidyl) tetraphosphates in Saccharomyces cerevisiae.

Bis(5'-adenosyl) tetraphosphate (Ap4A) phosphorylase II (P. Plateau, M. Fromant, J. M. Schmitter, J. M. Buhler, and S. Blanquet, J. Bacteriol. 171:6437-6445, 1989) was obtained in a homogeneous form through a 40,000-fold purification, starting from a Saccharomyces cerevisiae strain devoid of Ap4A phosphorylase I activity. The former enzyme behaves as a 36.8K monomer. As with Ap4A phosphorylase I, the addition of divalent cations is required for the expression of activity. Mn2+, Mg2+, and Ca2+ sustain phosphorolysis by the two enzymes, whereas Co2+ and Cd2+ stimulate only phosphorylase II activity. All bis(5'-nucleosidyl) tetraphosphates assayed (Ap4A, Ap4C, Ap4G, Ap4U, Gp4G, and Gp4U) are substrates of the two enzymes. However, Ap4A phosphorylase II shows a marked preference for A-containing substrates. The two enzymes catalyze adenosine 5'-phosphosulfate phosphorolysis or an exchange reaction between Pi and the beta-phosphate of any nucleoside diphosphate. They can also produce Ap4A at the expense of ATP and ADP. The gene (APA2) encoding Ap4A phosphorylase II was isolated and sequenced. The deduced amino acid sequence shares 60% identity with that of Ap4A phosphorylase I. Disruption of APA2 and/or APA1 shows that none of these genes is essential for the viability of Saccharomyces cerevisiae. The concentrations of all bis(5'-nucleosidyl) tetraphosphates are increased in an apa1 apa2 double mutant, as compared with the parental wild-type strain. The factor of increase is 5 to 50 times, depending on the nucleotide. This observation supports the conclusion that, in vivo, Ap4A phosphorylase II, like Ap4A phosphorylase I, participates in the catabolism rather than the synthesis of the bis(5'-nucleosidyl) tetraphosphates.     

Binding of 9-aminoacridine to deoxydinucleoside phosphates of defined sequence: Preferences and stereochemistry

The effect of sequence on the binding of 9-aminoacridine to DNA has been investigated by studying its interaction with deoxydinucleoside phosphates of different sequences using proton nuclear magnetic resonance. Quantitative binding information can be obtained by comparison of the proton chemical shift behavior of 9-aminoacridine upon addition of dinucleoside phosphate to various models for the interaction using least-squares computer fitting procedures. The simplest model that fits the data includes (1) dimerization of 9-aminoacridine and (2) a mixture of 1:1 and 2:1 (dinucleoside phosphate/9-aminoacridine) complexes. The computed parameters allow comparison of binding constants and stereochemistry for different sequences. The 1:1 complexes seem to involve interaction of the ring nitrogen with the backbone phosphate and stacking of one or both chromophores on the acridine; preference in binding is observed for alternating (purine-pyrimidine or pyrimidine-purine) over non-alternating (purine-purine) dinucleoside phosphates. The 2:1 complexes involve intercalation of the acridine between two complementary dinucleoside phosphate strands with weak sequence preferences in binding. The stereochemistry of intercalation differs between non-alternating purine-purine sequences and the alternating pyrimidine-purine or purine-pyrimidine sequences in having the 9-aminoacridine stacked with the purines of one strand rather than straddling the purines on opposite strands. The difference in stereochemistry could possibly be a determining factor in frameshift sequence specificity.     

Selective splitting of 3'-adenylated dinucleoside polyphosphates by specific enzymes degrading dinucleoside polyphosphates

Several 3'-[(32)P]adenylated dinucleoside polyphosphates (Np(n)N'p*As) were synthesized by the use of poly(A) polymerase (Sillero MAG et al., 2001, Eur J Biochem.; 268: 3605-11) and three of them, ApppA[(32)P]A or ApppAp*A, AppppAp*A and GppppGp*A, were tested as potential substrates of different dinucleoside polyphosphate degrading enzymes. Human (asymmetrical) dinucleoside tetraphosphatase (EC 3.6.1.17) acted almost randomly on both AppppAp*A, yielding approximately equal amounts of pppA + pAp*A and pA + pppAp*A, and GppppGp*, yielding pppG + pGp*A and pG + pppGp*A. Narrow-leafed lupin (Lupinus angustifolius) tetraphosphatase acted preferentially on the dinucleotide unmodified end of both AppppAp*A (yielding 90% of pppA + pAp*A and 10 % of pA + pppAp*A) and GppppGp*A (yielding 89% pppG + pGp*A and 11% of pG + pppGp*A). (Symmetrical) dinucleoside tetraphosphatase (EC 3.6.1.41) from Escherichia coli hydrolyzed AppppAp*A and GppppGp*A producing equal amounts of ppA + ppAp*A and ppG + ppGp*A, respectively, and, to a lesser extent, ApppAp*A producing pA + ppAp*A. Two dinucleoside triphosphatases (EC 3.6.1.29) (the human Fhit protein and the enzyme from yellow lupin (Lupinus luteus)) and dinucleoside tetraphosphate phosphorylase (EC 2.7.7.53) from Saccharomyces cerevisiae did not degrade the three 3'-adenylated dinucleoside polyphosphates tested.     

Large scale synthesis of dinucleoside monophosphates catalyzed by ribonuclease from Aspergillus clavatus

A gram scale enzymatic synthesis of eight, dinucleoside monophosphates (ApC, ApU, CpC, CpU, GpC, GpU, UpC, and UpU) is described. The synthesis involves a reaction between the appropriate ribonucleoside-2′,3′-cyclie phosphates and cytidine or uridine in the presence of ribonuelease from Aspergillus clavatus at 30°C. The enzyme is removed from the reaction mixture by chromatography on Bio-Gel P–4, and the dinucleoside monophosphate is further purified by chromatography on a DEAE-Sephadex A–25, column. A procedure for the large scale preparation of the ribonuclease from Aspergillus clavatus is also described.     

Synthesis and properties of dithymidine phosphate analogues containing 3''-thiothymidine.

Dithymidine-3'-S-phosphorothioate (d(TspT)) has been prepared from a 5'-O-monomethoxytritylthymidine-3'-S-phosphorothioamidite (7) by activation with 5-(p-nitrophenyl)tetrazole in the presence of 3'-O-acetylthymidine. The resulting dinucleoside phosphorothioite is readily oxidised to the corresponding 3'-S-phosphorothioate using either tetrabutylammonium (TBA) periodate or TBA oxone and has been deprotected under standard conditions to yield d(TspT). This dithymidine phosphate analogue is comparatively resistant to hydrolysis by nuclease P1, but the P-S bond is readily cleaved by aqueous solutions of either iodine or silver nitrate. Dithymidine-3'-S-phosphorodithioate (d[Tsp(s)T]) was prepared in an analogous fashion using sulphur to oxidise the intermediate dinucleoside phosphorothioite. Absolute stereochemistry has been assigned to the diastereoisomers of d[Tsp(s)T] by comparing their physical and chemical properties to those of the dinucleoside phosphorothioates.     

Dinucleoside monophosphates. I. Optical properties and conformation in solution with one base charged.

A least squares analysis of the titration properties of several dinucleoside monophosphates enables calculation of the pK's for protonation. These pK's are used to resolve the spectral properties of dinucleoside monophosphates with one base charged from the apparent spectral properties of a dinucleoside monophosphate in aqueous solution. This method is applied to dinucleoside monophosphates containing adenosine and/or cytidine. Results of CD, nmr, and CD-temperature dependence measurements are presented. The results indicate that singly protonated dimers of these nucleosides stack as do their unprotonated analogs. It is suggested that this is true for all dimers with one base charged.