Regulation of human placental deoxyguanosine kinase by nucleotides

The activity of deoxyguanosine kinase purified from human placenta was regulated by various nucleotides. dTTP, an activator, only increased the Vmax value of the enzyme. The feedback inhibition by dGTP, dGDP and dGMP were competitive with respect to deoxyguanosine. Both the activation by dTTP and the inhibition by dGTP were reversible.     

dGTP-dependent processivity and possible template switching of euplotes telomerase.

We have measured the processivity of telomeric DNA extension by Euplotes aediculatus telomerase at various concentrations of the nucleotide substrates dGTP and dTTP. The maximum processivity (approximately 3 repeats) was observed at approximately 100 microM of each dNTP. Processivity decreased as the dNTP concentrations were reduced and, surprisingly, as the concentration of dGTP was increased. Also, the characteristic banding pattern generated by telomerase extension of DNA primers shifted in response to changes in dGTP concentration. One pattern with 8 nt periodicity was predominant at dGTP concentrations </=16 microM, while at >/= 250 microM an 8 nt repeat pattern out-of-phase with the first was observed; at intermediate concentrations the two patterns coexisted. We propose that two different segments of the RNA subunit can serve as the template for repeat synthesis; nt 42-49 at low dGTP concentrations and nt 36-43 at high dGTP concentrations. An alternative model for the low dGTP pattern involves an internal pause site but no pause at the end of the template and is, therefore, considered less likely. Because the effects of dGTP on processivity and banding pattern appear to be distinct from nucleotide binding in the polymerase active site, we propose a second dGTP binding site involved in template selection and processivity.     

Characterization of a nucleotide kinase encoded by bacteriophage t7

Gene 1.7 protein is the only known nucleotide kinase encoded by bacteriophage T7. The enzyme phosphorylates dTMP and dGMP to dTDP and dGDP, respectively, in the presence of a phosphate donor. The phosphate donors are dTTP, dGTP, and ribo-GTP as well as the thymidine and guanosine triphosphate analogs ddTTP, ddGTP, and dITP. The nucleotide kinase is found in solution as a 256-kDa complex consisting of ～12 monomers of the gene 1.7 protein. The two molecular weight forms co-purify as a complex, but each form has nearly identical kinase activity. Although gene 1.7 protein does not require a metal ion for its kinase activity, the presence of Mg(2+) in the reaction mixture results in either inhibition or stimulation of the rate of kinase reactions depending on the substrates used. Both the dTMP and dGMP kinase reactions are reversible. Neither dTDP nor dGDP is a phosphate acceptor of nucleoside triphosphate donors. Gene 1.7 protein exhibits two different equilibrium patterns toward deoxyguanosine and thymidine substrates. The K(m) of 4.4 × 10(-4) m obtained with dTTP for dTMP kinase is ～3-fold higher than that obtained with dGTP for dGMP kinase (1.3 × 10(-4) m), indicating that a higher concentration of dTTP is required to saturate the enzyme. Inhibition studies indicate a competitive relationship between dGDP and both dGTP, dGMP, whereas dTDP appears to have a mixed type of inhibition of dTMP kinase. Studies suggest two functions of dTTP, as a phosphate donor and a positive effector of the dTMP kinase reaction.     

Deoxyguanosine kinase from human placenta

Deoxyguanosine kinase (ATP:deoxyguanosine 5'-phosphotransferase) has been purified up to a specific activity of 10.3 nmol/min per mg protein from human placenta. The enzyme appears to have a molecular weight of 58 000 from the results of Sephadex G-75 gel filtration. The enzyme catalyzed phosphorylation of deoxyguanosine and deoxyadenosine, but deoxycytidine was not phosphorylated. An apparent Km value for deoxyguanosine was 2.5 micro M. When ATP was used as a phosphate donor, the pH optimum was at pH 6.0, but the optimum was shifted to pH 6.8 by the addition of dTTP. At physiological pH, the activity was stimulated 3-4-fold by dTTP. dTTP was also an effective phosphate donor, but using dTTP as a phosphate donor, a broad pH optimum of 7.0 was observed. Two Km values of 0.13 and 2.2 mM were obtained for both MgATP2- and MgdTTP2-. The activity was strongly inhibited by dGTP and dGDP; 50% inhibition by 1.0 micro M dGTP and 2.1 micro M dGDP, respectively. The enzyme required the presence o Mg2+ or Mn2+.     

Oligomerization status directs overall activity regulation of the Escherichia coli class Ia ribonucleotide reductase

Ribonucleotide reductase (RNR) is a key enzyme for the synthesis of the four DNA building blocks. Class Ia RNRs contain two subunits, denoted R1 (alpha) and R2 (beta). These enzymes are regulated via two nucleotide-binding allosteric sites on the R1 subunit, termed the specificity and overall activity sites. The specificity site binds ATP, dATP, dTTP, or dGTP and determines the substrate to be reduced, whereas the overall activity site binds dATP (inhibitor) or ATP. By using gas-phase electrophoretic mobility macromolecule analysis and enzyme assays, we found that the Escherichia coli class Ia RNR formed an inhibited alpha(4)beta(4) complex in the presence of dATP and an active alpha(2)beta(2) complex in the presence of ATP (main substrate: CDP), dTTP (substrate: GDP) or dGTP (substrate: ADP). The R1-R2 interaction was 30-50 times stronger in the alpha(4)beta(4) complex than in the alpha(2)beta(2) complex, which was in equilibrium with free alpha(2) and beta(2) subunits. Studies of a known E. coli R1 mutant (H59A) showed that deficient dATP inhibition correlated with reduced ability to form alpha(4)beta(4) complexes. ATP could also induce the formation of a generally inhibited alpha(4)beta(4) complex in the E. coli RNR but only when used in combination with high concentrations of the specificity site effectors, dTTP/dGTP. Both allosteric sites are therefore important for alpha(4)beta(4) formation and overall activity regulation. The E. coli RNR differs from the mammalian enzyme, which is stimulated by ATP also in combination with dGTP/dTTP and forms active and inactive alpha(6)beta(2) complexes.     

Analysis of inhibitors of bacteriophage T4 DNA polymerase.

Bacteriophage T4 DNA polymerase was inhibited by butylphenyl nucleotides, aphidicolin and pyrophosphate analogs, but with lower sensitivities than other members of the B family DNA polymerases. The nucleotides N2-(p-n-butylphenyl)dGTP (BuPdGTP) and 2-(p-n-butylanilino)dATP (BuAdATP) inhibited T4 DNA polymerase with competitive Ki values of 0.82 and 0.54 microM with respect to dGTP and dATP, respectively. The same compounds were more potent inhibitors in truncated assays lacking the competitor dNTP, displaying apparent Ki values of 0.001 and 0.0016 microM, respectively. BuPdGTP was a substrate for T4 DNA polymerase, and the resulting 3'-BuPdG-primer:template was bound strongly by the enzyme. Each of the non-substrate derivatives, BuPdGDP and BuPdGMPCH2PP, inhibited T4 DNA polymerase with similar potencies in both the truncated and variable competitor assays. These results indicate that BuPdGTP inhibits T4 DNA polymerase by distinct mechanisms depending upon the assay conditions. Reversible competitive inhibition predominates in the presence of dGTP, and incorporation in the absence of dGTP leads to potent inhibition by the modified primer:template. The implications of these findings for the use of these inhibitors in the study of B family DNA polymerases is discussed.     

The mode of inhibitory action by pyridoxal 5-phosphate on DNA polymerase-alpha and -beta.

The kinetics of the inhibition of DNA polymerases-alpha and -beta from sea urchin embryos by pyridoxal 5-phosphate were studied. The inhibition of DNA polymerase-alpha activity by pyridoxal 5-phosphate was competitive with activated DNA but noncompetitive with each deoxynucleoside triphosphate. With poly(dC)-oligo(dG)12-18 as a template-primer, however, the inhibition of DNA polymerase-alpha was competitive with dGTP but noncompetitive with the template-primer. These results suggest that DNA polymerase-alpha interacts with activated DNA and poly(dC)-oligo(dG)12-18 in different ways. The inhibition of DNA polymerase-beta by pyridoxal 5-phosphate was competitive with deoxynucleoside triphosphate using activated DNA as a template-primer and noncompetitive with activated DNA. Using poly(rA)-oligo(dT)12-18 as a template-primer, DNA polymerase-beta activity yielded sigmoid curves against both dTTP and the template-primer concentrations and was inhibited by pyridoxal 5-phosphate noncompetitively with respect to both dTTP and the template-primer. These results indicate that the inhibitory mode of DNA polymerase-alpha by pyridoxal 5-phosphate is different from that of DNA polymerase-beta.     

Potentiation of the anti-HIV activity of zalcitabine and lamivudine by a CTP synthase inhibitor, 3-deazauridine

Low levels of the CTP synthase inhibitor 3-deazauridine (3-DU) strongly potentiated the anti-HIV-1 activity of the 5'-triphosphates of the cytidine-based analogues [-]2'-deoxy-3'-thiacytidine (3TC; lamivudine) and 2',3'-dideoxycytidine (ddC). The potentiation was associated with a 3-DU-induced decrease in dCTP pool size; no changes were seen in cellular pool sizes of dATP, dGTP or dTTP.     

Interaction of yeast polypeptide chain elongation factor-3 (EF-3) with different nucleotides

ATPase and GTPase activities of EF-3 were similarly inhibited by various nucleotides including CTP, UTP and four dNTP's. The low specificity of EF-3 was in remarkable contrast with the high specificity of EF-1 alpha and EF-2 directed only to quanine nucleotides. The pH-activity and salt concentration-activity profiles as well as the above inhibition experiments coincidently supported that the same active site functions for ATPase and GTPase of EF-3. The stimulation of poly(Phe) synthesis was not observed with AMPPNP in place of ATP. The stimulation required ATP hydrolysis, probably catalyzed by ATPase of EF-3. Reflecting the low specificity of the ATPase, UTP, dTTP, dATP and dGTP stimulated the poly(Phe) synthesis. EF-3 appears to drive yeast elongation cycle using the energy from ATP hydrolysis by its ATPase without serving for GTP regeneration.     

Development of bioluminescent pyrophosphate assay using pyruvate phosphate dikinase and its application to single-nucleotide polymorphism analysis

DNA analysis is an important technology with respect to diagnosis of infectious disease and tailored medication. In this study, we developed a novel bioluminescent assay for pyrophosphate, and it was applied to single-nucleotide polymorphism (SNP) analysis using one-base extension reaction. The principle of this method is as follows. A specific primer within each aliquot possessing a short 3′ end of the base of interest was hybridized to the single-stranded DNA template. Subsequently, (exo-)Klenow DNA polymerase and one of either α-thio-dATP, dTTP, dGTP, or dCTP were added and incubated for 1 min. Pyrophosphate released by DNA polymerase is converted to ATP by pyruvate phosphate dikinase (PPDK), and the concentration of ATP is determined using the firefly luciferase reaction. This method, which does not require expensive equipment, can be used to rapidly monitor one point mutation in the gene.     

The mechanism of inhibition and "reversal" of mitogen-induced lymphocyte activation in a model of adenosine deaminase deficiency

The biochemical mechanism of lymphocyte dysfunction with adenosine deaminase deficiency has been investigated using cultured phytohemagglutinin stimulated normal peripheral blood lymphocytes and the adenosine deaminase (ADA) inhibitor 2'-deoxycoformycin. The addition of deoxyadenosine to ADA-inhibited (but not to uninhibited) cells generated increased dATP pools (up to 50-fold greater than controls) and depressed the mitogen response. dATP Accumulation was accompanied by depletion of the other three deoxynucleoside triphosphate (dNTP) pools (dTTP, dCTP, and dGTP). Suppression of the mitogen response could be prevented ("reversed") to 90% of control levels by the addition of deoxynucleoside precursors for the depleted dNTPs at the initiation of mitogen stimulation. "Reversal" restored the dTTP and possibly the dGTP pools. Thus the mechanism of toxicity in this model appears to be inhibition of ribonucleotide reductase by massive accumulation of dATP, resulting in starvation for the other three deoxyribonucleoside triphosphates. "Reversibility" of this toxicity by providing sources for the missing three deoxynucleoside triphosphates argues for ribonucleotide reductase inhibition rather than other mechanisms of deoxyadenosine toxicity in this model.