Assay of diadenosine tetraphosphate hydrolytic enzymes by boronate chromatography

A new procedure was described for assay of diadenosine tetraphosphate (Ap4A) hydrolases based on boronate chromatography. Potential reaction products, AMP, ADP, and ATP, of the hydrolysis of Ap4A were separated from residual substrate by chromatography on a boronate-derivatized cation-exchange resin, Bio-Rex 70. Separation was achieved by changing the concentrations of ethanol and ammonium acetate in the elution buffers. Picomole masses of products were detectable, blank dpm values were less than 0.5% of the total dpm, and auxiliary enzymes were not required. The procedure was specifically described for Ap4A pyrophosphohydrolase from Physarum polycephalum. The assay is generally applicable for dinucleoside polyphosphate hydrolases which hydrolyze other substrates such as Ap3A, Ap5A, Ap6A, and Gp4G. Dinucleotide polyphosphates are readily purified by chromatography on this boronate resin in a volatile buffer. Tes, Tricine, and Tris buffers significantly interfered with the chromatography of ATP.     

Accumulation of dinucleoside polyphosphates in Saccharomyces cerevisiae under stress conditions. High levels are associated with cell death

Adenosine tetraphosphonucleosides (Ap4X) were measured in Saccharomyces cerevisiae by a coupled phosphodiesterase-luciferase assay. After exposure of the cells to cadmium or to hyperthermic treatment (46 degrees C) a marked increase of the cellular pool from 0.08 microM (base level) to 4 microM or higher was observed. The accumulation of Ap4X to high levels is associated with irreversible processes leading to cell death.     

T4 RNA ligase catalyzes the synthesis of dinucleoside polyphosphates.

T4 RNA ligase has been shown to synthesize nucleoside and dinucleoside 5'-polyphosphates by displacement of the AMP from the E-AMP complex with polyphosphates and nucleoside diphosphates and triphosphates. Displacement of the AMP by tripolyphosphate (P3) was concentration dependent, as measured by SDS/PAGE. When the enzyme was incubated in the presence of 0.02 mm [alpha-32P] ATP, synthesis of labeled Ap4A was observed: ATP was acting as both donor (Km, microm) and acceptor (Km, mm) of AMP from the enzyme. Whereas, as previously known, ATP or dATP (but not other nucleotides) were able to form the E-AMP complex, the specificity of a compound to be acceptor of AMP from the E-AMP complex was very broad, and with Km values between 1 and 2 mm. In the presence of a low concentration (0.02 mm) of [alpha-32P] ATP (enough to form the E-AMP complex, but only marginally enough to form Ap4A) and 4 mm of the indicated nucleotides or P3, the relative rate of synthesis of the following radioactive (di)nucleotides was observed: Ap4X (from XTP, 100); Ap4dG (from dGTP, 74); Ap4G (from GTP, 49); Ap4dC (from dCTP, 23); Ap4C (from CTP, 9); Ap3A (from ADP, 5); Ap4ddA, (from ddATP, 1); p4A (from P3, 200). The enzyme also synthesized efficiently Ap3A in the presence of 1 mm ATP and 2 mm ADP. The following T4 RNA ligase donors were inhibitors of the synthesis of Ap4G: pCp > pAp > pA2'p.     

Isolation and characterization of a dinucleoside triphosphatase from Saccharomyces cerevisiae.

An enzyme able to cleave dinucleoside triphosphates has been purified 3,750-fold from Saccharomyces cerevisiae. Contrary to the enzymes previously shown to catabolize Ap4A in yeast, this enzyme is a hydrolase rather than a phosphorylase. The dinucleoside triphosphatase molecular ratio estimated by gel filtration is 55,000. Dinucleoside triphosphatase activity is strongly stimulated by the presence of divalent cations. Mn2+ displays the strongest stimulating effect, followed by Mg2+, Co2+, Cd2+, and Ca2+. The Km value for Ap3A is 5.4 microM (50 mM Tris-HCl [pH 7.8], 5 mM MgCl2, and 0.1 mM EDTA; 37 degrees C). Dinucleoside polyphosphates are substrates of this enzyme, provided that they contain more than two phosphates and that at least one of the two bases is a purine (Ap3A, Ap3G, Ap3C, Gp3G, Gp3C, m7Gp3A, m7Gp3G, Ap4A, Ap4G, Ap4C, Ap4U, Gp4G, and Ap5A are substrates; AMP, ADP, ATP, Ap2A, and Cp4U are not). Among the products, a nucleoside monophosphate is always formed. The specificity of cleavage of methylated dinucleoside triphosphates and the molecular weight of dinucleoside triphosphatase indicate that this enzyme is different from the mRNA decapping enzyme previously characterized (A. Stevens, Mol. Cell. Biol. 8:2005-2010, 1988).     

Yeast diadenosine 5',5'-P1,P4-tetraphosphate alpha,beta-phosphorylase behaves as a dinucleoside tetraphosphate synthetase

The diadenosine 5',5'-P1,P4-tetraphosphate alpha,beta-phosphorylase (Ap4A phosphorylase), recently observed in yeast [Guaranowski, A., & Blanquet, S. (1985) J. Biol. Chem. 260, 3542-3547], is shown to be capable of catalyzing the synthesis of Ap4A from ATP + ADP, i.e., the reverse reaction of the phosphorolysis of Ap4A. The synthesis of Ap4A markedly depends on the presence of a divalent cation (Ca2+, Mn2+, or Mg2+). In vitro, the equilibrium constant K = ([Ap4A][Pi])/[(ATP][ADP]) is very sensitive to pH. Ap4A synthesis is favored at low pH, in agreement with the consumption of one to two protons when ATP + ADP are converted into Ap4A and phosphate. Optimal activity is found at pH 5.9. At pH 7.0 and in the presence of Ca2+, the Vm for Ap4A synthesis is 7.4 s-1 (37 degrees C). Ap4A phosphorylase is, therefore, a valuable candidate for the production of Ap4A in vivo. Ap4A phosphorylase is also capable of producing various Np4N' molecules from NTP and N'DP. The NTP site is specific for purine ribonucleotides (N = A, G), whereas the N'DP site has a broader specificity (N' = A, C, G, U, dA). This finding suggests that the Gp4N' nucleotides, as well as the Ap4N' ones, could occur in yeast cells.     

Changes in diadenosine tetraphosphate levels in Physarum polycephalum with different oxygen concentrations.

Cellular levels of diadenosine tetraphosphate (Ap4A) were measured, by a specific high-pressure liquid chromatography method, in microplasmodia of Physarum polycephalum subjected to different degrees of hypoxia, hyperoxia, and treatment with H2O2. Ap4A levels increased three- to sevenfold under anaerobic conditions, and the microplasmodia remained viable after such treatment. Elevated levels of Ap4A returned to the basal level within 5 to 10 min upon reoxygenation of the microplasmodia. The increases in Ap4A levels were larger in stationary-phase or starved microplasmodia than in fed, log-phase microplasmodia. The maximal increase measured in log-phase microplasmodia was twofold. No significant changes in Ap4A levels occurred in microplasmodia subjected to mild hypoxia, hyperoxia, or treatment with 1 mM H2O2. These results indicate that in P. polycephalum, Ap4A may function in the metabolic response to anaerobic conditions rather than in the response to oxidative stress.     

Overexpressed pp60c-src can induce focus formation without complete transformation of NIH 3T3 cells.

NIH 3T3 cells were transfected with plasmids containing Moloney murine leukemia virus long terminal repeats and either chicken c-src or v-src genes. In contrast with the effects observed after transfection with plasmids containing c-src and avian retrovirus or simian virus 40 promoter-enhancers (H. Hanafusa, H. Iba, T. Takeya, and F. R. Cross, p. 1-8, in G. F. Vande Woude, A. J. Levine, W. C. Topp, and J. D. Watson, ed., Cancer Cells, vol. 2, 1984; H. Iba, T. Takeya, F. R. Cross, T. Hanafusa, and H. Hanafusa, Proc. Natl. Acad. Sci. U.S.A. 81:4424-4428, 1984; R. C. Parker, R. Swanstrom, H. E. Varmus, and J. M. Bishop, p. 19-26, in G. F. Vande Woude et al., ed., Cancer Cells, vol. 2, 1984; R. C. Parker, H. E. Varmus, and J. M. Bishop, Cell 37:131-139, 1984; D. Shalloway, P. M. Coussens, and P. Yaciuk, p. 9-17, in G. F. Vande Woude et al., ed., Cancer Cells, vol. 2, 1984; D. Shalloway, P. M. Coussens, and P. Yaciuk, Proc. Natl. Acad. Sci. U.S.A. 81:7071-7075; and K. C. Wilhelmsen, W. G. Tarpley, and H. M. Temin, p. 303-308, in G. F. Vande Woude et al., ed., Cancer Cells, vol. 2, 1984), we found that both types of Moloney murine leukemia virus long terminal repeat-src expression plasmids induced focus formation, although c-src induced only 1% as many foci as v-src. The focus-selected c-src overexpressed cells had altered morphology and limited growth in soft agarose but were not tumorigenic in vivo. Cleveland digests, comparative in vitro kinase assays, secondary transfections, and immunoprecipitations indicated that focus formation was caused by rare transfection events that resulted in very high-level pp60c-src expression rather than by mutations of the transfected c-src genes. These results suggest that pp60v-src induced transformation is not a completely spurious activity which is unrelated to the function of pp60c-src but that it represents a perturbation of already existent molecular control processes involving pp60c-src.     

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.     

Thermostable Pyrococcus furiosus DNA ligase catalyzes the synthesis of (di)nucleoside polyphosphates

DNA ligase from the hyperthermophilic marine archaeon Pyrococcus furiosus (Pfu DNA ligase) synthesizes adenosine 5'-tetraphosphate (p4A) and dinucleoside polyphosphates by displacement of the adenosine 5'-monophosphate (AMP) from the Pfu DNA ligase-AMP (E-AMP) complex with tripolyphosphate (P3), nucleoside triphosphates (NTP), or nucleoside diphosphates (NDP). The experiments were performed in the presence of 1-2 microM [alpha-32P]ATP and millimolar concentrations of NTP or NDP. Relative rates of synthesis (%) of the following adenosine(5')tetraphospho(5')nucleosides (Ap4N) were observed: Ap4guanosine (Ap4G) (from GTP, 100); Ap4deoxythymidine (Ap4dT) (from dTTP, 95); Ap4xanthosine (Ap4X) (from XTP, 94); Ap4deoxycytidine (Ap4dC) (from dCTP, 64); Ap4cytidine (Ap4C) (from CTP, 60); Ap4deoxyguanosine (Ap4dG) (from dGTP, 58); Ap4uridine (Ap4U) (from UTP, <3). The relative rate of synthesis (%) of adenosine(5')triphospho(5')nucleosides (Ap3N) were: Ap3guanosine (Ap3G) (from GDP, 100); Ap3xanthosine (Ap3X) (from XDP, 110); Ap3cytidine (Ap3C) (from CDP, 42); Ap3adenosine (Ap3A) (from ADP, <1). In general, the rate of synthesis of Ap4N was double that of the corresponding Ap3N. The enzyme presented optimum activity at a pH value of 7.2-7.5, in the presence of 4 mM Mg2+, and at 70 degrees C. The apparent Km values for ATP and GTP in the synthesis of Ap4G were about 0.001 and 0.4mM, respectively, lower values than those described for other DNA or RNA ligases. Pfu DNA ligase is used in the ligase chain reaction (LCR) and some of the reactions here reported [in particular the synthesis of Ap4adenosine (Ap4A)] could take place during the course of that reaction.     

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.     

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)     

Rad50S alleles of the Mre11 complex: questions answered and questions raised

We find that Rad50S mutations in yeast and mammals exhibit constitutive PIKK (PI3-kinase like kinase)-dependent signaling [T. Usui, H. Ogawa, J.H. Petrini, A DNA damage response pathway controlled by Tel1 and the Mre11 complex. Mol. Cell 7 (2001) 1255-1266.; M. Morales, J.W. Theunissen, C.F. Kim, R. Kitagawa, M.B. Kastan, J.H. Petrini, The Rad50S allele promotes ATM-dependent DNA damage responses and suppresses ATM deficiency: implications for the Mre11 complex as a DNA damage sensor. Genes Dev. 19 (2005) 3043-4354.]. The signaling depends on Mre11 complex functions, consistent with its role as a DNA damage sensor. Rad50S is distinct from hypomorphic mutations of Mre11 and Nbs1 in mammals [M. Morales, J.W. Theunissen, C.F. Kim, R. Kitagawa, M.B. Kastan, J.H. Petrini, The Rad50S allele promotes ATM-dependent DNA damage responses and suppresses ATM deficiency: implications for the Mre11 complex as a DNA damage sensor. Genes Dev. 19 (2005) 3043-3054.; J.P. Carney, R.S. Maser, H. Olivares, E.M. Davis, Le M. Beau, J.R. Yates, III, L. Hays, W.F. Morgan, J.H. Petrini, The hMre11/hRad50 protein complex and Nijmegen breakage syndrome: linkage of double-strand break repair to the cellular DNA damage response. Cell 93 (1998) 477-486.; G.S. Stewart, R.S. Maser, T. Stankovic, D.A. Bressan, M.I. Kaplan, N.G. Jaspers, A. Raams, P.J. Byrd, J.H. Petrini, A.M. Taylor, The DNA double-strand break repair gene hMRE11 is mutated in individuals with an ataxia-telangiectasia-like disorder. Cell 99 (1999) 577-587.; B.R. Williams, O.K. Mirzoeva, W.F. Morgan, J. Lin, W. Dunnick, J.H. Petrini, A murine model of nijmegen breakage syndrome. Curr. Biol. 12 (2002) 648-653.; J.W. Theunissen, M.I. Kaplan, P.A. Hunt, B.R. Williams, D.O. Ferguson, F.W. Alt, J.H. Petrini, Checkpoint failure and chromosomal instability without lymphomagenesis in Mre11(ATLD1/ATLD1) mice. Mol. Cell 12 (2003) 1511-1523.] and the Mre11 complex deficiency in yeast [T. Usui, H. Ogawa, J.H. Petrini, A DNA damage response pathway controlled by Tel1 and the Mre11 complex. Mol. Cell 7 (2001) 1255-1266.; D'D. Amours, S.P. Jackson, The yeast Xrs2 complex functions in S phase checkpoint regulation. Genes Dev. 15 (2001) 2238-49. ; M. Grenon, C. Gilbert, N.F. Lowndes, Checkpoint activation in response to double-strand breaks requires the Mre11/Rad50/Xrs2 complex. Nat. Cell Biol. 3 (2001) 844-847. ] where the signaling is compromised. Herein, we describe evidence for chronic signaling by Rad50S and discuss possible mechanisms.     

Studies on pig liver mevalonate-5-diphosphate decarboxylase

A procedure in which three sequential enzymes of cholesterol biosynthesis, mevalonate kinase (ATP: (R)-mevalonate 5-phosphotransferase, EC 2.7.1.36), phosphomevalonate kinase (ATP: (R)-5-phosphomevalonate phosphotransferase, EC 2.7.4.2) and mevalonate-5-diphosphate decarboxylase (ATP: (R)-5-diphosphomevalonate carboxy-lyase (dehydrating), EC 4.1.1.33), from pig liver, could be purified in the one operation is described. Mevalonate kinase and phosphomevalonate kinase were utilized for the enzymic synthesis of mevalonate 5-diphosphate (both 1-14C-labelled and unlabelled), the substrate for mevalonate-5-diphosphate decarboxylase, using excess free ATP4-. A radioactive assay for the enzyme, based on the release of 14CO2 from [1-14C]mevalonate-5-diphosphate, was developed. The assay allowed reassessment of the metal and nucleotide specificity of the decarboxylase. ATP could be partially replaced by GTP and ITP, but no activity was observed with CTP, UTP or TTP. Apparent activation of the enzyme by ATP4- was observed as found for mevalonate kinase (C.S. Lee and W.J. O'Sullivan (1983) Biochim. Biophys. Acta 747, 215-224) and phosphomevalonate kinase (C.S. Lee and W.J. O'Sullivan (1985) Biochim. Biophys. Acta 839, 83-89). The presence of 1 mM excess free ATP4-, above that complexed as the substrate MgATP2-, decreased the Km for MgATP2- from 0.45 mM to 0.15 mM. MgADP- was shown to act as a competitive inhibitor with respect to MgATP2-.     

In human and rat lung membranes [35S]GTPgammaS binding is a tool for pharmacological characterization of G protein-coupled dinucleotide receptors.

The P2Y receptor family is activated by extracellular nucleotides such as ATP and UTP. P2Y receptors regulate physiological functions in numerous cell types. In lung, the P2Y2 receptor subtype plays a role in controlling Cl- and fluid transport. Besides ATP or UTP, also diadenosine tetraphosphate (Ap4A), a stable nucleotide, seems to be of physiological importance. In membrane preparations from human and rat lung we applied several diadenosine polyphosphates to investigate whether they act as agonists for G protein-coupled receptors. We assessed this by determining the stimulation of [35S]GTPgammaS binding. Stimulation of [35S]GTPgammaS binding to G proteins has already been successfully applied to elucidate agonist binding to various G protein-coupled receptors. Ap(n)A (n = 2 to 6) enhanced [35S]GTPgammaS binding similarly in human and rat lung membranes, an indication of the existence of G protein-coupled receptor binding sites specific for diadenosine polyphosphates. Moreover, in both human and rat lung membranes comparable pharmacological properties were found for a diadenosine polyphosphate ([3H]Ap4A) binding site. The affinity for Ap2A, Ap3A, Ap4A, Ap5A, and Ap6A was also comparable. 8-Diazido-Ap4A and ATP were less potent, whereas the pyrimidine nucleotide UTP showed hardly any affinity. Thus, we present evidence that different diadenosine polyphosphates bind to a common G protein-coupled receptor binding site in membranes derived either from human or rat lung.     

High diadenosine tetraphosphate (Ap4A) level in germ cells and embryos of sea urchin and Xenopus and its effect on DNA synthesis

Ap4A levels in sperms, eggs and different developmental stages of sea urchin (Psammechinus miliaris) and (Xenopus laevis) were determined by a method based on ATP measurement with luciferin/luciferase after splitting diadenosine 5',5'-P1,P4-tetraphosphate (Ap4A) into ATP and AMP. Appreciable storage pools of Ap4A were found in unfertilized eggs of Psammechinus and Xenopus as well as in sea urchin sperms. The actual Ap4A concentration of 28 microM in sperm represents the highest Ap4A level so far observed in eukaryotic cells. Upon fertilization an instant onset of de novo synthesis of Ap4A was demonstrated. Ap4A levels during early embryogenesis of P. miliaris and X. laevis (2.5-4 microM) are higher than those in exponentially growing mammalian culture cells and mammalian fetuses. Microinjection of Ap4A into unfertilized eggs of Psammechinus miliaris caused a 3-7 fold increase of DNA synthesis in comparison with mock-injected eggs.     

Decay of thermal resistance following acute heating is independent of the G1- to S-phase transition

The phenomena of heat-induced G1 delay and thermal resistance were compared in synchronous populations of CHO cells. Mildly toxic induction doses of 5 min (Single cell survival, (SCS) = 0.90 +/- 0.06) and 10 min (SCS = 0.69 +/- 0.12) at 45 degrees C resulted in G1 delays of 4.3 and 11.3 h, respectively. Thermal resistance was tested (30 min, 45 degrees C) for up to 32-92 h following the induction dose. Thermal resistance did not start to decay prior to 26 h following the induction dose. These data confirm reports by R. R. Read, M. H. Fox, and J. S. Bedford [Radiat. Res. 98, 491-505 (1984)] and G. L. Rice, J. W. Gray, P. N. Dean, and W. C. Dewey [Cancer Res. 44, 2368-2376 (1984)] that acutely heated G1 populations of CHO cells progress into S phase without a concurrent loss of thermal resistance, using 45 degrees C induction doses even less toxic than used by other workers.     

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.     

A paradoxical increase of a metabolite upon increased expression of its catabolic enzyme: the case of diadenosine tetraphosphate (Ap4A) and Ap4A phosphorylase I in Saccharomyces cerevisiae.

The APA1 gene in Saccharomyces cerevisiae encodes Ap4A phosphorylase I, the catabolic enzyme for diadenosine 5',5"'-P1,P4-tetraphosphate (Ap4A). APA1 has been inserted into a multicopy plasmid and into a centromeric plasmid with a GAL1 promoter. Enhanced expression of APA1 via the plasmids resulted in 10- and 90-fold increases in Ap4A phosphorylase activity, respectively, as assayed in vitro. However, the intracellular concentration of Ap4A exhibited increases of 2- and 15-fold, respectively, from the two different plasmids. Intracellular Ap4A increased 3- to 20-fold during growth on galactose of a transformant with APA1 under the control of the GAL1 promoter. Intracellular adenosine 5'-P1-tetraphospho-P4-5"'-guanosine (Ap4G) and diguanosine 5',5"'-P1,P4-tetraphosphate (Gp4G) also increased in the transformant under these conditions. The chromosomal locus of APA1 has been disrupted in a haploid strain. The Ap4A phosphorylase activity decreased by 80% and the intracellular Ap4A concentration increased by a factor of five in the null mutant. These results with the null mutant agree with previous results reported by Plateau et al. (P. Plateau, M. Fromant, J.-M. Schmitter, J.-M. Buhler, and S. Blancquet, J. Bacteriol. 171:6437-6445, 1989). The paradoxical increase in Ap4A upon enhanced expression of APA1 indicates that the metabolic consequences of altered gene expression may be more complex than indicated solely by assay of enzymatic activity of the gene product.     

Distribution of acetylated alpha-tubulin in Physarum polycephalum

The expression and cytological distribution of acetylated alpha-tubulin was investigated in Physarum polycephalum. A monoclonal antibody specific for acetylated alpha-tubulin, 6-11B-1 (Piperno, G., and M. T. Fuller, 1985, J. Cell Biol., 101:2085-2094), was used to screen for this protein during three different stages of the Physarum life cycle--the amoeba, the flagellate, and the plasmodium. Western blots of two-dimensional gels of amoebal and flagellate proteins reveal that this antibody recognizes the alpha 3 tubulin isotype, which was previously shown to be formed by posttranslational modification (Green, L. L., and W. F. Dove, 1984, Mol. Cell. Biol., 4:1706-1711). Double-label immunofluorescence demonstrates that, in the flagellate, acetylated alpha-tubulin is localized in the flagella and flagellar cone. Similar experiments with amoebae interestingly reveal that only within the microtubule organizing center (MTOC) are there detectable amounts of acetylated alpha-tubulin. In contrast, the plasmodial stage gives no evidence for acetylated alpha-tubulin by Western blotting or by immunofluorescence.     

Book Review

B iotechnology: A T extbook OF I ndustrial M icrobiology (1984). W. Crueger & A. Crueger.
I ntroduction TO M odern M ycology 2nd edition B asic M icrobiology Volume 7 (1984). J. W. Deacon.
L aboratory A nimal M edicine (1984). Edited by J. G. Fox, B. J. Cohen & F. M. Loew.
B acterial V accines (1984). Edited by R. Germanier.
M onoclonal A ntibodies: P rinciples AND P ractice P roduction AND A pplication IN C ell B iology , B iochemistry AND I mmunology (1983) J. W. Goding.
A dvances IN B iotechnological P rocesses Volume 3 (1984). Edited by A. Mizrahi & A. L. van Wezel.
C urrent D evelopment IN B iological N itrogen F ixation (1984). Edited by N. S. Subba Roa.