Synthesis of diadenosine 5',5'-P1,P4-tetraphosphate (AppppA) from adenosine 5'-phosphosulfate and adenosine 5'-triphosphate catalyzed by yeast AppppA phosphorylase

A novel way of enzymatic synthesis of diadenosine 5',5"'-P1,P4-tetraphosphate (AppppA), which does not involve aminoacyl-tRNA synthetases, has been discovered. Yeast AppppA alpha, beta-phosphorylase catalyzes irreversible conversion of adenosine 5'-phosphosulfate (APS) and ATP into AppppA according to the equation APS + ATP----AppppA + sulfate. In this reaction, the enzyme exhibits a broad pH optimum (between 6 and 8) and requires Mn2+, Mg2+, or Ca2+ ions for activity, with Mn2+ being twice as effective as Mg2+ or Ca2+ at optimal concentration (0.5 mM). The Km values computed for APS and ATP are 80 microM and 700 microM, respectively. The rate constant for the AppppA synthesis is 3 s-1 (pH 8.0, 30 degrees C, 0.5 mM MgCl2). Some ATP analogues like ppppA, GTP, adenosine 5'-(alpha, beta-methylenetriphosphate), and adenosine 5'-(beta, gamma-methylenetriphosphate), but not dATP, UTP, or CTP, are also substrates for AppppA phosphorylase and accept adenylate from APS with the formation of AppppA, AppppG, Appp(CH2)pA, and App(CH2)ppA, respectively. Functional versatility of yeast AppppA phosphorylase may provide a link between metabolism of AppppA on one hand and metabolism of APS and phosphate on the other and raises the possibility of participation of AppppA in regulation of metabolism of APS and/or inorganic phosphate in yeast.     

Effects of diadenosine 5',5'-P1, P4-tetraphosphate and of adenosine 5'-triphosphate on the higher order structure of calf thymus DNA

The effective length and the hard core radius were calculated by scaled particle theory for high molecular weight calf thymus DNA in the presence of varying concentrations of diadenosine 5',5'-P1, P4-tetraphosphate and of adenosine 5'-triphosphate in aqueous millimolar NaCl. DNA became slightly more flexible in the presence of diadenosine 5',5'-P1, P4-tetraphosphate at concentrations of 10(-9)-10(-7) M. DNA was denatured in the presence of 5 X 10(-5) M adenosine triphosphate.     

Metabolism of adenylylated nucleotides in Clostridium acetobutylicum.

In response to the stresses imposed by temperature upshift or addition of butanol, Clostridium acetobutylicum cultures accumulated diadenosine-5',5'-P1,P4-tetraphosphate (Ap4A) and adenosine 5'-P1,P4-tetraphospho-5'-guanosine (Ap4G) to high levels. The two adenylylated nucleotides were also accumulated in batch culture in the absence of imposed stresses when the clostridia switched from the acidogenic phase of growth to the solventogenic phase. Most of the adenylylated nucleotides were extracellular. The intracellular concentrations of these compounds were low throughout batch growth and in cells stressed by added butanol. In contrast to other procaryotes, these clostridia did not possess enzymes to degrade the dinucleotides, as shown with both intact cells and cell-free preparations. Our findings are consistent with the hypothesis that endogenously produced solvents are stressful to the cells, stimulating the synthesis of adenylylated nucleotides. The nucleotides accumulate extracellularly because they cannot be degraded and because the cell membranes are permeabilized by the solvents produced.     

Synthesis of dinucleoside polyphosphates catalyzed by firefly luciferase.

In the presence of ATP, luciferin (LH2), Mg2+ and pyrophosphatase, the firefly (Photinus pyralis) luciferase synthesizes diadenosine 5',5"'-P1,P4-tetraphosphate (Ap4A) through formation of the E-LH2-AMP complex and transfer of AMP to ATP. The maximum rate of the synthesis is observed at pH 5.7. The Km values for luciferin and ATP are 2-3 microM and 4 mM, respectively. The synthesis is strictly dependent upon luciferin and a divalent metal cation. Mg2+ can be substituted with Zn2+, Co2+ or Mn2+, which are about half as active as Mg2+, as well as with Ni2+, Cd2+ or Ca2+, which, at 5 mM concentration, are 12-20-fold less effective than Mg2+. ATP is the best substrate of the above reaction, but it can be substituted with adenosine 5'-tetraphosphate (p4A), dATP, and GTP, and thus the luciferase synthesizes the corresponding homo-dinucleoside polyphosphates:diadenosine 5',5"'-P1,P5-pentaphosphate (Ap5A), dideoxyadenosine 5',5"'-P1,P4-tetraphosphate (dAp4dA) and diguanosine 5',5"'-P1,P4-tetraphosphate (Gp4G). In standard reaction mixtures containing ATP and a different nucleotide (p4A, dATP, adenosine 5'-[alpha,beta-methylene]-triphosphate, (Ap[CH2]pp), (S')-adenosine-5'-[alpha-thio]triphosphate [Sp)ATP[alpha S]) and GTP], luciferase synthesizes, in addition to Ap4A, the corresponding hetero-dinucleoside polyphosphates, Ap5A, adenosine 5',5"'-P1,P4-tetraphosphodeoxyadenosine (Ap4dA), diadenosine 5',5"'-P1,P4-[alpha,beta-methylene] tetraphosphate (Ap[CH2]pppA), (Sp-diadenosine 5',5"'-P1,P4-[alpha-thio]tetraphosphate [Sp)Ap4A[alpha S]) and adenosine-5',5"'-P1,P4-tetraphosphoguanosine (Ap4G), respectively. Adenine nucleotides, with at least a 3-phosphate chain and with an intact alpha-phosphate, are the preferred substrates for the formation of the enzyme-nucleotidyl complex. Nucleotides best accepting AMP from the E-LH2-AMP complex are those which contain at least a 3-phosphate chain and an intact terminal pyrophosphate moiety. ADP or other NDP are poor adenylate acceptors as very little diadenosine 5',5"'-P1,P3-triphosphate (Ap3A) or adenosine-5',5"'-P1,P3-triphosphonucleosides (Ap3N) are formed. In the presence of NTP (excepting ATP), luciferase is able to split Ap4A, transferring the resulting adenylate to NTP, to form hetero-dinucleoside polyphosphates. In the presence of PPi, luciferase is also able to split Ap4A, yielding ATP. The cleavage of Ap4A in the presence of Pi or ADP takes place at a very low rate. The synthesis of dinucleoside polyphosphates, catalyzed by firefly luciferase, is compared with that catalyzed by aminoacyl-tRNA synthetases and Ap4A phosphorylase.     

Phosphonate analogues of diadenosine 5',5'-P1,P4-tetraphosphate as substrates or inhibitors of procaryotic and eucaryotic enzymes degrading dinucleoside tetraphosphates

The substrate specificity of procaryotic and eucaryotic AppppA-degrading enzymes was investigated with phosphonate analogues of diadenosine 5',5'-P1,P4-tetraphosphate (AppppA). App(CH2)ppA (I), App(CHBr)ppA (II), and Appp(CH2)pA (III), but not Ap(CH2)pp(CH2)pA (IV), are substrates for lupin AppppA hydrolase (EC 3.6.1.17) and phosphodiesterase I (EC 3.1.4.1). None of the four analogues is hydrolyzed by bacterial AppppA hydrolase (EC 3.6.1.41), and only analogue III is degraded by yeast AppppA phosphorylase (EC 2.7.7.53). The analogues are competitive inhibitors of all four enzymes. The affinity of analogue IV is 3-40-fold lower than that of analogues I-III for all four enzymes. Introduction of one methylene (as in I and III) [or bromomethylene (as in II)] group into AppppA results in a 3-15-fold increase of its affinity for lupin and Escherichia coli AppppA hydrolases. The same modifications only negligibly (10-30%) affect its affinity for yeast AppppA phosphorylase and decrease its affinity for lupin phosphodiesterase I about 2.5-fold. The data provide further evidence for the heterogeneity among catalytic sites of all four AppppA-degrading enzymes.     

Hydrolysis of 5',5'-tri- or tetraphosphate-mRNA 5'-cap analogs promoted by Cu2+ or Zn2+ metal ions

Kinetics of the hydrolysis of a P(1)-(7-methylguanosinyl-5') P(3)-(guanosinyl-5') triphosphate (m(7)GpppG), P(1)-(7-methylguanosinyl-5') P(4)- (guanosinyl-5') tetraphosphate (m(7)GppppG), diadenosine-5',5'-P(1),P(3)-triphosphate (ApppA), and diadenosine-5',5'-P(1),P(4)-tetraphosphate (AppppA) promoted by Cu(2+) or Zn(2+) has been investigated. Time-dependent products distributions at various metal ion concentrations have been determined by CZE and HPLC-RP. The results show that in acidic conditions, in the presence of metal ion, the predominant hydrolytic reaction is the cleavage of 5',5'-oligophosphate bridge. The 5',5'-oligophosphate bridge of the dinucleotides studied is hydrolyzed by Cu(2+) more efficiently than by Zn(2+). At the catalyst concentration of 2 mM the cleavage of the 5',5'-triphosphate bridge of m(7)GpppG was ～3.6 times faster, and that of the tetraphosphate bridge of m(7)GppppG ～2.3-fold faster in the presence of Cu(2+) compared to the Zn(2+) ion, applied as catalysts. Dependence of the rates of hydrolysis on the catalyst concentration was in some instances not linear, interpreted as evidence for participation of more than one metal ion in the transition complex.     

Replicon initiation frequency and intracellular levels of ATP, ADP, AMP and of diadenosine 5',5'-P1,P4-tetraphosphate in ehrlich ascites cells cultured aerobically and anaerobically

When Ehrlich ascites cells were cultured for 2 h under oxygen-free atmosphere, a shut-down of initiation of new replication units was observed by chain length analysis of the nascent daughter strands and by DNA fibre autoradiography. The intracellular level of ATP, ADP and AMP remained virtually normal in the anaerobized cells, while that of diadenosine 5',5'-P1,P4-tetraphosphate was found reduced by about two orders of magnitude. It is proposed that the ceasing of DNA synthesis after O2 removal is at actively controlled regulatory response of the cells in which diadenosine 5',5"'-P1,P4-tetraphosphate is probably involved.     

Hydrolysis of diadenosine polyphosphates by nucleotide pyrophosphatases/phosphodiesterases.

Diadenosine polyphosphates (ApnAs) act as extracellular signaling molecules in a broad variety of tissues. They were shown to be hydrolyzed by surface-located enzymes in an asymmetric manner, generating AMP and Apn-1 from ApnA. The molecular identity of the enzymes responsible remains unclear. We analyzed the potential of NPP1, NPP2, and NPP3, the three members of the ecto-nucleotide pyrophosphatase/phosphodiesterase family, to hydrolyze the diadenosine polyphosphates diadenosine 5',5"'-P1,P3-triphosphate (Ap3A), diadenosine 5',5"'-P1,P4-tetraphosphate (Ap4A), and diadenosine 5',5"'-P1,P5-pentaphosphate, (Ap5A), and the diguanosine polyphosphate, diguanosine 5',5"'-P1,P4-tetraphosphate (Gp4G). Each of the three enzymes hydrolyzed Ap3A, Ap4A, and Ap5A at comparable rates. Gp4G was hydrolyzed by NPP1 and NPP2 at rates similar to Ap4A, but only at half this rate by NPP3. Hydrolysis was asymmetric, involving the alpha,beta-pyrophosphate bond. ApnA hydrolysis had a very alkaline pH optimum and was inhibited by EDTA. Michaelis constant (Km) values for Ap3A were 5.1 micro m, 8.0 micro m, and 49.5 micro m for NPP1, NPP2, and NPP3, respectively. Our results suggest that NPP1, NPP2, and NPP3 are major enzyme candidates for the hydrolysis of extracellular diadenosine polyphosphates in vertebrate tissues.     

Synthesis of diadenosine 5',5'-P1,P4-tetraphosphate (AP4A) in sea urchin embryos

Sea urchin embryos were labeled with [3H]adenosine at two developmental stages (morula and prism) and the labeled acid-soluble nucleotides were fractionated successively by column chromatography with DEAE-Sephadex and DEAE-cellulose, and by thin-layer chromatography on a PEI-cellulose plate. Significant radioactivity was detected on the PEI-cellulose plate at the region of diadenosine 5',5'-P1,P4-tetraphosphate (AP4A). After treatment of this fraction with phosphodiesterase, the radioactivity was all recovered in the AMP region, while alkaline phosphatase had no effect on the AP4A fraction. The present result suggests that AP4A is actively synthesized in the sea urchin embryos.     

The Saccharomyces cerevisiae YOR163w gene encodes a diadenosine 5', 5"'-P1,P6-hexaphosphate (Ap6A) hydrolase member of the MutT motif (Nudix hydrolase) family

The YOR163w open reading frame on chromosome XV of the Saccharomyces cerevisiae genome encodes a member of the MutT motif (nudix hydrolase) family of enzymes of Mr 21,443. By cloning and expressing this gene in Escherichia coli and S. cerevisiae, we have shown the product to be a (di)adenosine polyphosphate hydrolase with a previously undescribed substrate specificity. Diadenosine 5',5"'-P1, P6-hexaphosphate is the preferred substrate, and hydrolysis in H218O shows that ADP and adenosine 5'-tetraphosphate are produced by attack at Pbeta and AMP and adenosine 5'-pentaphosphate are produced by attack at Palpha with a Km of 56 microM and kcat of 0.4 s-1. Diadenosine 5',5"'-P1,P5-pentaphosphate, adenosine 5'-pentaphosphate, and adenosine 5'-tetraphosphate are also substrates, but not diadenosine 5',5"'-P1,P4-tetraphosphate or other dinucleotides, mononucleotides, nucleotide sugars, or nucleotide alcohols. The enzyme, which was shown to be expressed in log phase yeast cells by immunoblotting, displays optimal activity at pH 6.9, 50 degrees C, and 4-10 mM Mg2+ (or 200 microM Mn2+). It has an absolute requirement for a reducing agent, such as dithiothreitol (1 mM), and is inhibited by Ca2+ with an IC50 of 3.3 mM and F- (noncompetitively) with a Ki of 80 microM. Its function may be to eliminate potentially toxic dinucleoside polyphosphates during sporulation.     

A proton magnetic resonance study of the effects of polyamine and divalent metal ions on diadenosine 5',5'-P1,P4-tetraphosphate base stacking

Complexation of putrescine, spermidine, spermine, and Mg2+ with diadenosine 5',5'-P1,P4-tetraphosphate induces an upfield shift in the signals for the H-2 and H-8 protons. The upfield shifts in H-2 indicate that cation complexation enhances intramolecular adenine stacking interactions. The resonances for H-2 and H-8 of neutral analogs of 5',5'-dinucleotides appear farther upfield relative to the appropriate monomeric models than those for the corresponding dinucleotide; reduction of intra-chain phosphate repulsion is the origin of cation induced enhancement of diadenosine 5H,5'-P1,P4-tetraphosphate base stacking.     

Mitochondrial location of rat liver dinucleoside triphosphatase

Rat liver dinucleoside triphosphatase (EC 3.6.1.29) is associated with sucrose-gradient purified mitochondria and can be extracted by freeze and thaw treatment. The proportion of mitochondrial dinucleoside triphosphatase approaches 50% of total liver enzyme. Evidence is also presented that 10% of total liver bis(5'-guanosyl)tetraphosphatase (EC 3.6.1.17) might be equally linked to mitochondria. Those data suggest that diadenosine 5',5'-P1,P3-triphosphate, diadenosine 5',5'-P1,P4-tetraphosphate, or other substrates of those enzymes, might be somehow related to mitochondria or mitochondrial function(s), although the occurrence of dinucleoside polyphosphates has not been reported in that organelle.     

ADP-ribosylation of diadenosine 5',5"-P1,P4-tetraphosphate by poly(ADP-ribose) polymerase in vitro

When the effect of diadenosine 5',5"'-P1,P4-tetraphosphate on a purified poly(ADP-ribose) polymerase reaction was examined, the compound strongly inhibited ADP-ribosylation reaction of histone, while the compound was much less inhibitory of the Mg2+-dependent automodification of this enzyme. In an attempt to study the mechanism of the inhibition, we analyzed the total reaction products, which were synthesized from NAD+ in the presence of diadenosine 5',5"'-P1,P4-tetraphosphate in a reaction mixture for ADP-ribosylation of histone, and found that a new, low molecular product was predominantly synthesized instead of ADP-ribosylated histone in the reaction. Approximately 90% of added NAD+ was converted into this low molecular product under an appropriate reaction condition. Further analysis revealed that the product was mono- and oligo(ADP-ribosyl)ated diadenosine nucleotide and that the bound oligo(ADP-ribose) is elongating at one end of the product during the reaction. Thus, the present study clearly demonstrated that diadenosine 5',5"'-P1,P4-tetraphosphate functions as an acceptor for ADP-ribose in a poly(ADP-ribose) polymerase reaction in vitro. The finding that histone H1 is required in the reaction mixture for the synthesis of this new product suggests that histone H1 and the diadenosine compound interact during this modification reaction.     

Hydrolysis of bis(5''-nucleosidyl) polyphosphates by Escherichia coli 5''-nucleotidase.

Two enzymatic activities that split diadenosine triphosphate have been reported in Escherichia coli: a specific Mg-dependent bis(5'-adenosyl) triphosphatase (EC 3.6.1.29) and the bis(5'-adenosyl) tetraphosphatase (EC 3.6.1.41). In addition to the activities of these two enzymes, a different enzyme activity that hydrolyzes dinucleoside polyphosphates is described. After purification and study of its molecular and kinetic properties, we concluded that it corresponded to the 5'-nucleotidase (EC 3.1.3.5) that has been described in E. coli. The enzyme was purified from sonic extracts and osmotic shock fluid. From sonic extracts, two isoforms were isolated by chromatography on ion-exchange Mono Q columns; they had a molecular mass of about 100 kilodaltons (kDa). From the osmotic shock fluid, a unique form of 52 kDa was recovered. Mild heating transformed the 100-kDa isoform to a 52-kDa form, with an increase in activity of about threefold. The existence of a 5'-nucleotidase inhibitor described previously, which associates with the enzyme and is not liberated in the osmotic shock fluid, may have been responsible for these results. The kinetic properties and substrate specificities of both forms (52 and 100 kDa) were almost identical. The enzyme, which is known to hydrolyze AMP and uridine-(5')-diphospho-(1)-alpha-D-glucose, but not adenosine-(5')-diphospho-(1)-alpha-D-glucose, was also able to split adenosine-(5')-diphospho-(5)-beta-D-ribose, ribose-5-phosphate, and dinucleoside polyphosphates [diadenosine 5',5'-P1,P2-diphosphate,diadenosine 5',5'-P1,P3-triphosphate, diadenosine 5',5'-P1,P4-tetraphosphate, and bis(5'-guanosyl) triphosphate]. The effects of divalent cations and pH on the rate of the reaction with different substrates were studied.     

Isothermal titration calorimetry reveals a zinc ion as an atomic switch in the diadenosine polyphosphates

Diadenosine polyphosphates (diadenosine 5',5'-P(1),P(n)-polyphosphate (Ap(n)A)) are 5'-5'-phosphate-bridged dinucleosides that have been proposed to act as signaling molecules in a variety of biological systems. Isothermal titration calorimetry was used to measure the affinities of a variety of metal cations for ATP, diadenosine 5',5'-P(1),P(3)-triphosphate (Ap(3)A), diadenosine 5',5'-P(1),P(4)-tetraphosphate (Ap(4)A), and diadenosine 5',5'-P(1),P(5)-pentaphosphate (Ap(5)A). The binding of Mg(2+), Ca(2+), and Mn(2+) to ATP is shown to take place with the beta,gamma-phosphates (primary site) and be endothermic in character. The binding of Ni(2+), Cd(2+), and Zn(2+) to ATP is found to take place at both the primary site and at a secondary site identified as N-7 of the adenine ring. Binding to this second site is exothermic in character. Generally, the binding of metal cations to diadenosine polyphosphates involves a similar primary site to ATP. No exothermic binding events are identified. Critically, the binding of Zn(2+) to diadenosine polyphosphates proves to be exceptional. This appears to involve a very high affinity association involving the N-7 atoms of both adenine rings in each Ap(n)A, as well as the more usual endothermic association with the phosphate chain. The high affinity association is also endothermic in character. A combination of NMR and CD evidence is provided in support of the calorimetry data demonstrating chemical shift changes and base stacking disruptions entirely consistent with N-7 bridging interactions. N-7 bridging interactions are entirely reversible, as demonstrated by EDTA titration. Considering the effects of Zn(2+) on a wide variety of dinucleoside polyphosphate-metabolizing enzymes, we examine the possibility of Zn(2+) acting as an atomic switch to control the biological function of the diadenosine polyphosphates.     

Synthesis of diadenosine 5',5' -P1,P4-tetraphosphate by lysyl-tRNA synthetase and a multienzyme complex of aminoacyl-tRNA synthetases from rat liver

An 18 S multienzyme complex of aminoacyl-tRNA synthetases is found to be active in the synthesis of diadenosine-5',5'-P1,P4-tetraphosphate (AppppA). Most of the activity is attributed to lysyl-tRNA synthetase in the complex. Free lysyl-tRNA synthetase dissociated from the synthetase complex is about 6-fold more active than the complex in AppppA synthesis, while their apparent Michaelis constants for ATP and lysine are similar. AMP, which reportedly activates AppppA synthesis (Hilderman, R.H. (1983) Biochemistry 22, 4353-4357), has no effect on AppppA synthesis. The higher activity of free Lys-tRNA synthetase is in part due to the higher stimulation of AppppA synthesis by Zn2+. These results suggest that association of aminoacyl-tRNA synthetases may affect AppppA synthesis.     

4-Coumarate:coenzyme A ligase has the catalytic capacity to synthesize and reuse various (di)adenosine polyphosphates

4-Coumarate:coenzyme A ligase (4CL) is known to activate cinnamic acid derivatives to their corresponding coenzyme A esters. As a new type of 4CL-catalyzed reaction, we observed the synthesis of various mono- and diadenosine polyphosphates. Both the native 4CL2 isoform from Arabidopsis (At4CL2 wild type) and the At4CL2 gain of function mutant M293P/K320L, which exhibits the capacity to use a broader range of phenolic substrates, catalyzed the synthesis of adenosine 5'-tetraphosphate (p(4)A) and adenosine 5'-pentaphosphate when incubated with MgATP(-2) and tripolyphosphate or tetrapolyphosphate (P(4)), respectively. Diadenosine 5',5',-P(1),P(4)-tetraphosphate represented the main product when the enzymes were supplied with only MgATP(2-). The At4CL2 mutant M293P/K320L was studied in more detail and was also found to catalyze the synthesis of additional dinucleoside polyphosphates such as diadenosine 5',5'-P(1),P(5)-pentaphosphate and dAp(4)dA from the appropriate substrates, p(4)A and dATP, respectively. Formation of Ap(3)A from ATP and ADP was not observed with either At4CL2 variant. In all cases analyzed, (di)adenosine polyphosphate synthesis was either strictly dependent on or strongly stimulated by the presence of a cognate cinnamic acid derivative. The At4CL2 mutant enzyme K540L carrying a point mutation in the catalytic center that is critical for adenylate intermediate formation was inactive in both p(4)A and diadenosine 5',5',-P(1),P(4)-tetraphosphate synthesis. These results indicate that the cinnamoyl-adenylate intermediate synthesized by At4CL2 not only functions as an intermediate in coenzyme A ester formation but can also act as a cocatalytic AMP-donor in (di)adenosine polyphosphate synthesis.     

Ap4A induces apoptosis in human cultured cells.

Diadenosine oligophosphates (Ap(n)A) have been proposed as intracellular and extracellular signaling molecules in animal cells. The ratio of diadenosine 5',5'-P1,P3-triphosphate to diadenosine 5',5'-P1,P4-tetraphosphate (Ap3A/Ap4A) is sensitive to the cellular status and alters when cultured cells undergo differentiation or are treated with interferons. In cells undergoing apoptosis induced by DNA topoisomerase II inhibitor VP16, the concentration of Ap3A decreases significantly while that of Ap4A increases. Here, we have examined the effects of exogenously added Ap3A and Ap4A on apoptosis and morphological differentiation. Penetration of Ap(n)A into cells was achieved by cold shock. Ap4A at 10 microM induced programmed cell death in human HL60, U937 and Jurkat cells and mouse VMRO cells and this effect appeared to require Ap4A breakdown as hydrolysis-resistant analogues of Ap4A were inactive. On its own, Ap3A induced neither apoptosis nor cell differentiation but did display strong synergism with the protein kinase C activators 12-deoxyphorbol-13-O-phenylacetate and 12-deoxyphorbol-13-O-phenylacetate-20-acetate in inducing differentiation of HL60 cells. We propose that Ap4A and Ap3A are physiological antagonists in determination of the cellular status: Ap4A induces apoptosis whereas Ap3A is a co-inductor of differentiation. In both cases, the mechanism of signal transduction remains unknown.     

Isolation, characterization, and inactivation of the APA1 gene encoding yeast diadenosine 5'',5''''''-P1,P4-tetraphosphate phosphorylase.

The gene encoding diadenosine 5',5'-P1,P4-tetraphosphate (Ap4A) phosphorylase from yeast was isolated from a lambda gt11 library. The DNA sequence of the coding region was determined, and more than 90% of the deduced amino acid sequence was confirmed by peptide sequencing. The Ap4A phosphorylase gene (APA1) is unique in the yeast genome. Disruption experiments with this gene, first, supported the conclusion that, in vivo, Ap4A phosphorylase catabolizes the Ap4N nucleotides (where N is A, C, G, or U) and second, revealed the occurrence of a second Ap4A phosphorylase activity in yeast cells. Finally, evidence is provided that the APA1 gene product is responsible for most of the ADP sulfurylase activity in yeast extracts.     

Molecular cloning of the Escherichia coli gene for diadenosine 5'',5''''''-P1,P4-tetraphosphate pyrophosphohydrolase.

A clone overproducing diadenosine tetraphosphatase (diadenosine 5', 5'-P1, P4-tetraphosphate pyrophosphohydrolase) activity was isolated from an Escherichia coli cosmid library. Localization of the DNA region responsible for stimulation of this activity was achieved by deletion mapping and subcloning in various vectors. Maxicell experiments and immunological assays demonstrated that a 3.5-kilobase-pair DNA fragment carried the structural gene apaH encoding the E. coli diadenosine tetraphosphatase. The DNA coding strand was determined by cloning this fragment in both orientations in pUC plasmids. It was also shown that the overproduction of diadenosine tetraphosphatase decreased the dinucleoside tetraphosphate concentration in E. coli by a factor of 10.