Purification and characterization of the gene 1.2 protein of bacteriophage T7

Gene 1.2 of bacteriophage T7, located near the primary origin of DNA replication at position 15.37 on the T7 chromosome, encodes a 10,059-dalton protein that is essential for growth on Escherichia coli optA1 strains (Saito, H., and Richardson, C. C. (1981) J. Virol. 37, 343-351). In the absence of the T7 1.2 and E. coli optA gene products, the degradation of E. coli DNA proceeds normally, and T7 DNA synthesis is initiated at the primary origin. However, T7 DNA synthesis ceases prematurely and the newly synthesized DNA is degraded; no viable phage particles are released. The gene 1.2 protein has been purified to apparent homogeneity from cells in which the cloned 1.2 gene is overexpressed. Purification of the [35S] methionine-labeled protein was followed by monitoring the radioactivity of the protein and by gel electrophoresis. The purified protein has been identified as the product of gene 1.2 on the basis of molecular weight and partial amino acid sequence. We have found that extracts of E. coli optA1 cells infected with T7 gene 1.2 mutants are defective in packaging exogenous T7 DNA when such extracts are prepared late in infection. Purified gene 1.2 protein restores packaging activity to these defective extracts, thus providing a biological assay for gene 1.2 protein. No specific enzymatic activity has been found associated with the purified gene 1.2 protein.     

Genetic analysis of gene 1.2 of bacteriophage T7: isolation of a mutant of Escherichia coli unable to support the growth of T7 gene 1.2 mutants.

The product of gene 1.2 of bacteriophage T7 is not required for the growth of T7 in wild-type Escherichia coli since deletion mutants lacking the entire gene 1.2 grow normally (Studier et al., J. Mol. Biol. 135:917-937, 1979). By using a T7 strain lacking gene 1.2, we have isolated a mutant of E. coli that was unable to support the growth of both point and deletion mutants defective in gene 1.2. The mutation, optA1, was located at approximately 3.6 min on the E. coli linkage map in the interval between dapD and tonA; optA1 was 92% cotransducible with dapD. By using the optA1 mutant, we have isolated six gene 1.2 point mutants of T7, all of which mapped between positions 15 and 16 on the T7 genetic map. These mutations have also been characterized by DNA sequence analysis, E. coli optA1 cells infected with T7 gene 1.2 mutants were defective in T7 DNA replication; early RNA and protein synthesis proceeded normally. The defect in T7 DNA replication is manifested by a premature cessation of DNA synthesis and degradation of the newly synthesized DNA. The defect was not observed in E. coli opt+ cells infected with T7 gene 1.2 mutants or in E. coli optA1 cells infected with wild-type T7 phage.     

Escherichia coli dGTP triphosphohydrolase is inhibited by gene 1.2 protein of bacteriophage T7

Escherichia coli has a unique enzyme, deoxyguanosine triphosphate triphosphohydrolase (dGTPase) that cleaves dGTP into deoxyguanosine and tripolyphosphate. An E. coli mutant, optA1, has a 50-fold increased level of the dGTPase (Beauchamp, B.B., and Richardson, C.C. (1988) Proc. Natl. Acad. Sci. U. S. A. 85, 2563-2567). Successful infection of E. coli optA1 by bacteriophage T7 is dependent on a 10-kDa protein encoded by gene 1.2 of the phage. In this report we show that the gene 1.2 protein is a specific inhibitor of the E. coli dGTPase. Gene 1.2 protein inhibits dGTPase activity by forming a complex with the dGTPase with an apparent stoichiometry of two monomers of gene 1.2 protein/tetramer of dGTPase. The interaction is reversible with a half-life of the complex of 30 min and an apparent binding constant Ki of 35 nM. The binding of inhibitor of dGTPase is cooperative, indicating allosteric interactions between dGTPase subunits with a Hill coefficient of 1.7. The interaction is modulated differentially by DNA, RNA, and deoxyguanosine mono-, di-, and triphosphate. Both the binding of the substrate dGTP and of the inhibitor gene 1.2 protein induce conformational changes in dGTPase. The conformation of the enzyme in the presence of saturating concentrations of dGTP virtually prevents the association with, and the dissociation from, gene 1.2 protein.     

Deoxyribonucleotide pool imbalance stimulates deletions in HeLa cell mitochondrial DNA

Mitochondrial neurogastrointestinal encephalomyopathy (MNGIE) is an autosomal recessive disorder associated with multiple mutations in mitochondrial DNA, both deletions and point mutations, and mutations in the nuclear gene for thymidine phosphorylase. Spinazzola et al. (Spinazzola, A., Marti, R., Nishino, I., Andreu, A., Naini, A., Tadesse, S., Pela, I., Zammarchi, E., Donati, M., Oliver, J., and Hirano, M. (2001) J. Biol. Chem. 277, 4128-4133) showed that MNGIE patients have elevated circulating thymidine levels and they hypothesized that this generates imbalanced mitochondrial deoxyribonucleoside triphosphate (dNTP) pools, which in turn are responsible for mitochondrial (mt) DNA mutagenesis. We tested this hypothesis by culturing HeLa cells in medium supplemented with 50 microM thymidine. After 8-month growth, mtDNA in the thymidine-treated culture, but not the control, showed multiple deletions, as detected both by Southern blotting and by long extension polymerase chain reaction. After 4-h growth in thymidine-supplemented medium, we found the mitochondrial dTTP and dGTP pools to expand significantly, the dCTP pool to drop significantly, and the dATP pool to drop slightly. In whole-cell extracts, dTTP and dGTP pools also expanded, but somewhat less than in mitochondria. The dCTP pool shrank by about 50%, and the dATP pool was essentially unchanged. These results are discussed in terms of the recent report by Nishigaki et al. (Nishigaki, Y., Marti, R., Copeland, W. C., and Hirano, M. (2003) J. Clin. Invest. 111, 1913-1921) that most mitochondrial point mutations in MNGIE patients involve T --> C transitions in sequences containing two As to the 5' side of a T residue. Our finding of dTTP and dGTP elevations and dATP depletion in mitochondrial dNTP pools are consistent with a mutagenic mechanism involving T-G mispairing followed by a next-nucleotide effect involving T insertion opposite A.     

Construction of a gene library using partial filling of DNA sticky ends

To prepare gene libraries, the incomplete filling of protruding ends has been used. DNAs from phages EMBL 3 and EMBL 3a were sequentially digested with SalI and EcoRI, followed by addition of dTTP, dCTP, and DNA polymerase I (Klenow's fragment). Separately, a genomic DNA was partially cleaved with Sau3AI, followed by addition of dATP, dGTP, and Klenow's fragment. The fragmented phage and genomic DNAs were mixed and ligated, and the recombinant DNAs packed in vitro with the phage proteins. The effectiveness of packaging per microgram of genomic DNA was 10(5) to 10(6) (for the wild phage DNA, 10(7)). The proposed procedure is very rapid and needs only microgram quantities of genomic DNA for preparing a representative gene library. It is also useful for other vectors, containing SalI sites.     

Deoxythymidine nucleotide metabolism in Bacillus subtilis W23 infected with bacteriophage SP1Oc: preliminary evidence that dTMP in SP10c DNA is synthesized by a novel, bacteriophage-specific mechanism.

Despite the fact that mature SP10c DNA contains dTMP, the acid-soluble fraction of infected cells contained no dTTP during the interval of phage replication. However, infected cells contained normal cellular levels of dATP, dGTP, and dCTP. Upon infection of deoxythymidine-starved Bacillus subtilis M160 (a deoxythymidine-requiring mutant of B. subtilis W23), mature phage DNA with a normal dTMP content was made. SP10c codes for an enzyme that seems to catalyze the tetrahydrofolate-dependent transfer of 1-carbon fragments to the 5 position of dUMP. The transfer of 1-carbon fragments is not accompanied by oxidation of tetrahydrofolage to dihydrofolate, implying that the enzyme in question is not a dTMP synthetase. It is proposed that dTMP in mature SP10c DNA is derived by the postreplicational modification of some other nucleotide and not by the direct incorporation of dTTP into DNA.     

An improved technique for the efficient construction of gene libraries by partial filling-in of cohesive ends

For the preparation of gene libraries, DNA from lambda EMBL3 phage was digested with SalI and EcoRI, and the cohesive ends partially filled-in by addition of dTTP, dCTP and Klenow fragment of DNA polymerase I (PolIk). Genomic DNA was cleaved partially with Sau3A and subsequently incubated with dATP, dGTP and PolIk. The phage and genomic DNAs were then mixed and ligated. The recombinant DNAs were packaged in vitro. The efficiency of packaging was 10(5)-10(6) of infectious phage lambda particles per microgram of the genomic DNA (as compared to approx. 10(7) per microgram for the wild-type lambda DNA). This procedure is very rapid and requires only microgram quantities of genomic DNA for preparing an entire gene library. The other important advantage is that multiple independent insertions of genomic DNA cannot occur in a single recombinant phage and self-ligation of phage DNA is blocked. It is also applicable for other SalI-containing vectors.     

Selective inhibition of in vitro DNA synthesis dependent on phiX174 compared with fd DNA. I. Protein requirements for selective inhibition.

Crude extracts of Escherichia coli selectively convert fd viral DNA and not phiX174 DNA to duplex DNA via a complex series of reactions one of which involves RNA polymerase. Reactions leading to formation of fd duplex-replicative (RFII) structures have been reconstituted with purified proteins from E. coli. Maximal synthesis requires the combined action of E. coli binding protein, DNA elongation factor I, DNA elongation factor II preparations (which are a mixture of dna Z and DNA elongation factor III), DNA polymerase III, DNA-dependent RNA polymerase, Mg2+, dATP, dGTP, dCTP, dTTP, and ATP, GTP, CTP, and UTP. In contrast to crude extracts of E. coli, purified protein fractions do not distinguish between fd DNA and phiX174 DNA in duplex DNA formation. The addition of crude fractions of E. coli to the purified components listed above selectively permits fd RFII formation and prevents phiX RFII formation. This selective inhibition was used as an assay to isolate proteins essential for this phenomenon; they include RNase H, discriminatory factor alpha, and discriminatory factor beta.     

Deoxyribonucleoside triphosphate and DNA synthesis in synchronized cultures of Chlamydomonas

Pool sizes of dATP, dTTP, dGTP and dCTP were determined during the life cycle of Chlamydomonas using light-dark synchronized cultures. The pools of all four nucleotides were small until the start of the DNA synthesis, when they all increased in close time relationship with the increase in rate of DNA synthesis. The dTTP and dATP pools increased more than 200-fold while the pools of dCTP and dGTP expanded approx. 10 times.     

UV-induced imbalance of the deoxyribonucleoside triphosphate pool in E. coli

The effect of UV irradiation on the intracellular DNA precursor pool in E. coli was investigated. UV irradiation of E. coli, followed by post-incubation for 1-1.5 h, altered the relative sizes of the deoxyribonucleoside triphosphate (dNTP) pool. The total amount of dNTPs increased: both dATP and dTTP increased several-fold, dCTP about twofold, while dGTP remained almost unchanged. In recA- and umuC- strains, which are defective in UV-induced mutagenesis, the pattern of nucleotide pool alterations was similar to that of wild-type strains.     

Kinetics of incorporation of O6-methyldeoxyguanosine monophosphate during in vitro DNA synthesis

O6-Methyldeoxyguanosine triphosphate (m6dGTP), known to be produced in vivo by methylation of deoxyguanosine triphosphate with simple methylating mutagens, is utilized by prokaryotic DNA polymerases during in vitro replication of synthetic and natural DNA template-primers. A study of the kinetic behavior of m6dGTP during DNA replication in vitro and of its effect on DNA replication indicates that m6dGTP acts as an analogue of dATP with Kappm of about 6 microM for Escherichia coli DNA polymerase I (Klenow fragment) compared to the Kappm of about 0.8 microM for dATP. m6dGTP is not incorporated in the complete absence of dATP (a competitive inhibitor). m6dGTP also inhibits in vitro DNA synthesis. Different DNA polymerases behave differently in utilization and turnover of m6dGTP. T4 DNA polymerase shows stronger discrimination against m6dGMP incorporation than either T5 DNA polymerase or E. coli DNA polymerase I. The possibility that m6dGTP is unlikely to contribute significantly to in vivo mutation is discussed.     

Synthesis of phage 2C-DNA in permeabilized B. subtilis.

Summary Bacillus subtilis cells, infected with bacteriophage 2C and then permeabilized, (plasmolysis, protoplast conversion, or treatment with organic solvents) incorporate dATP into DNA through a polymerization reaction requiring the 4 deoxyribonucleosidetri-phosphates dATP, dGTP, dCTP and dTTP. While uracil is an in vivo precursor of phage 2C DNA (in which hydroxymethyluracil completely replaces thymine), neither uracil, or dUTP, nor dUMP are incorporated into viral DNA by phage-infected permeabilized cells. Although the amount of dTTP incorporated under these conditions is small, this compound greatly enhances the incorporation of dATP into viral DNA.Synthesis of 2C-DNA in permeabilized cells is discontinuous; however, the Okazaki fragments (2x10⁶ daltons) which accumulate under these conditions, show no tendency to join and to form full strands, as they do in intact host cells. Finally, density shift experiments suggest that, in addition to repair synthesis, semiconservative duplication takes place within the permeabilized cells.When phage-infected bacteria are permeabilized at different moments of the viral cycle, labeled precursors are mainly incorporated into cell DNA during the eclipse phase, and into viral DNA during the maturation phase. Moreover, viral DNA formation is prevented when cells are infected with virions previously irradiated with ultraviolet light.Since most metabolic pathways and gene regulation patterns are not altered by the permeabilization process, allowing the use of direct DNA precursors, the systems of virus-infected permeabilized cells prove exceptional tools for a study of virus-host relationship.     

Quantitation of cellular deoxynucleoside triphosphates

Eukaryotic cells contain a delicate balance of minute amounts of the four deoxyribonucleoside triphosphates (dNTPs), sufficient only for a few minutes of DNA replication. Both a deficiency and a surplus of a single dNTP may result in increased mutation rates, faulty DNA repair or mitochondrial DNA depletion. dNTPs are usually quantified by an enzymatic assay in which incorporation of radioactive dATP (or radioactive dTTP in the assay for dATP) into specific synthetic oligonucleotides by a DNA polymerase is proportional to the concentration of the unknown dNTP. We find that the commonly used Klenow DNA polymerase may substitute the corresponding ribonucleotide for the unknown dNTP leading in some instances to a large overestimation of dNTPs. We now describe assay conditions for each dNTP that avoid ribonucleotide incorporation. For the dTTP and dATP assays it suffices to minimize the concentrations of the Klenow enzyme and of labeled dATP (or dTTP); for dCTP and dGTP we had to replace the Klenow enzyme with either the Taq DNA polymerase or Thermo Sequenase. We suggest that in some earlier reports ribonucleotide incorporation may have caused too high values for dGTP and dCTP.     

Toward understanding the mutagenicity of an environmental carcinogen: structural insights into nucleotide incorporation preferences

Bulky carcinogen-DNA adducts, including (+)-trans-anti-[BP]-N(2)-dG derived from the reaction of (+)-anti-benzo[a]pyrene diol epoxide with guanine, often block the progression of DNA polymerases. However, when rare bypass of the lesions does occur, they may be misreplicated. Experimental results have shown that nucleotides are inserted opposite the (+)-trans-anti-[BP]-N(2)-dG adduct by bacteriophage T7 DNA polymerase with the order of preference A>T>or=G>C. To gain structural insights into the effects of the bulky adduct on nucleotide incorporation within the polymerase active site, molecular modeling and molecular dynamics simulations were carried out using T7 DNA polymerase to permit the relation of function to structure. We modeled the (+)-trans-anti-[BP]-N(2)-dG adduct opposite incoming dGTP, dTTP and dCTP nucleotides, as well as unmodified guanine opposite its normal partner dCTP as a control, to compare with our previous simulation with dATP opposite the adduct. The modeling required that the (+)-trans-anti-[BP]-N(2)-dG adduct adopt the syn conformation in each case to avoid deranging essential protein-DNA interactions. While the dATP: (+)-trans-anti-[BP]-N(2)-dG pair was well accommodated within the active site of T7 DNA polymerase, dCTP fit poorly opposite the adduct, adopting an orientation perpendicular to the plane of the syn modified guanine during the simulation. Rotation about the glycosidic bond of the dCTP residue to this abnormal position was allowed because only one hydrogen bond between dCTP and the (+)-trans-anti-[BP]-N(2)-dG residue evolved during the simulation, and this hydrogen bond was directly across from the dCTP glycosidic bond. The dTTP and dGTP nucleotides, incorporated with an intermediate preference opposite (+)-trans-anti-[BP]-N(2)-dG, were accommodated reasonably well, but not as stably as the dATP nucleotide, due to a skewed primer-template alignment and more exposed BP moiety, respectively. In addition, the extent of stabilizing interactions between the nascent base-pair in each simulation was correlated positively with the incorporation preference of that particular nucleotide. The dATP nucleotide is accommodated most stably opposite the adduct, with protein-DNA hydrogen bonding interactions and an active-site pocket size that do not deviate significantly from those of the control simulation. The simulations of dTTP and dGTP opposite (+)-trans-anti-[BP]-N(2)-dG exhibited more instability in interactions between the protein and the nascent base-pair than the dATP system. However, the active-site pocket size of the dTTP and dGTP simulations remained stable. The dCTP: (+)-trans-anti-[BP]-N(2)-dG system had the least number of stabilizing interactions, and the active-site pocket of this system increased in size significantly compared to the control and other dNTPs opposite the adduct. These simulations elucidated why A is inserted opposite (+)-trans-anti-[BP]-N(2)-dG most frequently, while T and G are inserted opposite the adduct to an extent intermediate between A and C, and C is most rarely incorporated. Structural rationalization of the incorporation preference opposite (+)-trans-anti-[BP]-N(2)-dG by T7 DNA polymerase contributes to providing a molecular explanation for mutations caused by this carcinogen-DNA adduct in a model system.     

Biochemical characterization of TT1383 from Thermus thermophilus identifies a novel dNTP triphosphohydrolase activity stimulated by dATP and dTTP

The HD domain motif is found in a superfamily of proteins in bacteria, archaea and eukaryotes. A few of these proteins are known to have metal-dependant phosphohydrolase activity, but the others are functionally unknown. Here we have characterized an HD domain-containing protein, TT1383, from Thermus thermophilus HB8. This protein has sequence similarity to Escherichia coli dGTP triphosphohydrolase, however, no dGTP hydrolytic activity was detected. The hydrolytic activity of the protein was determined in the presence of more than two kinds of deoxyribonucleoside triphosphates (dNTPs), which were hydrolyzed to their respective deoxyribonucleosides and triphosphates, and was found to be strictly specific for dNTPs in the following order of relative activity: dCTP > dGTP > dTTP > dATP. Interestingly, this dNTP triphosphohydrolase (dNTPase) activity requires the presence of dATP or dTTP in the dNTP mixture. dADP, dTDP, dAMP, and dTMP, which themselves were not hydrolyzed, were nonetheless able to stimulate the hydrolysis of dCTP. These results suggest the existence of binding sites specific for dATP and dTTP as positive modulators, distinct from the dNTPase catalytic site. This is, to our knowledge, the first report of a non-specific dNTPase that is activated by dNTP itself.     

Assays for the fidelity of DNA polymerases in cell-free extracts of Escherichia coli are complicated by contaminating nucleoside triphosphatases.

In the presence of DNA and a divalent cation, an enzyme activity in cell-free extracts of Escherichia coli readily hydrolyses dATP to dADP. dGTP is degraded to a smaller extent, dCTP and dTTP being hardly affected. The artificial template primers poly(dC) . oligo(dG) and poly(dT) . oligo(dA) are also effective cofactors for this triphosphatase activity. As a consequence, assays measuring the misincorporation, by cell-free extracts, of dATP and dGTP into these defined templates are difficult to interpret, since the triphosphate substrate is being rapidly degraded during the polymerase reaction. A partial characterization of the dATPase activity was performed, demonstrating that the optimal conditions for its activity resemble those commonly used for assaying polymerase activity. Thus in crude extracts both polymerase and dATPase compete for the same substrate. The inclusion of an ATP-generating system in the reaction mixture maintains the levels of deoxynucleoside triphosphates and changes the kinetics of misincorporation of dAMP into poly(dC) . oligo(dG). No reproducible difference in such misincorporation has been found between lysates prepared from tif-1 cells grown at either permissive or restrictive temperature.     

Alterations in deoxynucleoside triphosphate metabolism in DNA damaged cells: identification and consequences of poly(ADP-ribose) polymerase dependent and independent processes

Treatment of L1210 cells with increasing concentrations of MNNG produces heterogeneous perturbations of cellular deoxynucleoside triphosphate pools, with the magnitude and direction of the shift depending on the deoxynucleotide and on the concentration and time of exposure of the DNA damaging agent. 5 microM MNNG stimulated an increase in dATP, dCTP and dTTP but dGTP pools remained constant. These increases were not affected by 3-aminobenzamide, indicating that the pool size increases were produced by poly(ADP-ribose) polymerase independent reactions. 30 microM MNNG caused a time dependent decrease in dATP, dGTP, dTTP and dCTP. The dGTP pool was most drastically affected, becoming totally depleted within 3 hours. The fall in all 4 dNTP pools was substantially prevented by 3-aminobenzamide, suggesting that the decrease in dNTPs following DNA damage is mediated by a poly(ADP-ribose) polymerase dependent reaction. Severe depression of dGTP pools consequent to NAD and ATP depletion may provide a metabolic pathway for rapidly stopping DNA synthesis as a consequence of DNA damage and the activation of poly(ADP-ribose) polymerase.