Intracellular organization of DNA precursor biosynthetic enzymes

Genome Study of a Novel Virulent Phage vB_SspS_KASIA and Mu-like Prophages of Shewanella sp. M16 Provides Insights into the Genetic Diversity of the Shewanella Virome

Shewanella is a ubiquitous bacterial genus of aquatic ecosystems, and its bacteriophages are also isolated from aquatic environments (oceans, lakes, ice, and wastewater). In this study, the isolation and characterization of a novel virulent Shewanella phage vB_SspS_KASIA and the identification of three prophages of its host, Shewanella sp. M16, including a mitomycin-inducible Mu-like siphovirus, vB_SspS_MuM16-1, became the starting point for comparative analyses of phages infecting Shewanella spp. and the determination of their position among the known bacterial viruses. A similarity networking analysis revealed the high diversity of Shewanella phages in general, with vB_SspS_KASIA clustering exclusively with Colwellia phage 9A, with which it forms a single viral cluster composed of two separate viral subclusters. Furthermore, vB_SspS_MuM16-1 presented itself as being significantly different from the phages deposited in public databases, expanding the diversity of the known Mu-like phages and giving potential molecular markers for the identification of Mu-like prophages in bacterial genomes. Moreover, the functional analysis performed for vB_SspS_KASIA suggested that, despite the KASIA host, the M16 strain grows better in a rich medium and at 30 °C the phage replication cycle seems to be optimal in restrictive culture conditions mimicking their natural environment, the Zloty Stok gold and arsenic mine.

Diverse roles of nucleoside diphosphate kinase in genome stability and growth fitness

Nucleoside diphosphate kinase (NDK), a ubiquitous enzyme, catalyses reversible transfer of the γ phosphate from nucleoside triphosphates to nucleoside diphosphates and functions to maintain the pools of ribonucleotides and deoxyribonucleotides in the cell. As even a minor imbalance in the nucleotide pools can be mutagenic, NDK plays an antimutator role in maintaining genome integrity. However, the mechanism of the antimutator roles of NDK is not completely understood. In addition, NDKs play important roles in the host-pathogen interactions, metastasis, gene regulation, and various cellular metabolic processes. To add to these diverse roles of NDK in cells, a recent study now reveals that NDK may even confer mutator phenotypes to the cell by acting on the damaged deoxyribonucleoside diphosphates that may be formed during the oxidative stress. In this review, we discuss the roles of NDK in homeostasis of the nucleotide pools and genome integrity, and its possible implications in conferring growth/survival fitness to the organisms in the changing environmental niches.

Purinosome formation as a function of the cell cycle

The de novo purine biosynthetic pathway relies on six enzymes to catalyze the conversion of phosphoribosylpyrophosphate to inosine 5'-monophosphate. Under purine-depleted conditions, these enzymes form a multienzyme complex known as the purinosome. Previous studies have revealed the spatial organization and importance of the purinosome within mammalian cancer cells. In this study, time-lapse fluorescence microscopy was used to investigate the cell cycle dependency on purinosome formation in two cell models. Results in HeLa cells under purine-depleted conditions demonstrated a significantly higher number of cells with purinosomes in the G1 phase, which was further confirmed by cell synchronization. HGPRT-deficient fibroblast cells also exhibited the greatest purinosome formation in the G1 phase; however, elevated levels of purinosomes were also observed in the S and G2/M phases. The observed variation in cell cycle-dependent purinosome formation between the two cell models tested can be attributed to differences in purine biosynthetic mechanisms. Our results demonstrate that purinosome formation is closely related to the cell cycle.

Replitase: complete machinery for DNA synthesis

Replication of nuclear DNA in eukaryotes presents a tremendous challenge, not only due to the size and complexity of the genome, but also because of the time constraint imposed by a limited duration of S phase during which the entire genome has to be duplicated accurately and only once per cell division cycle. A challenge of this magnitude can only be met by the close coupling of DNA precursor synthesis to replication. Prokaryotic systems provide evidence for multienzyme and multiprotein complexes involved in DNA precursor synthesis and DNA replication. In addition, fractionation of nuclear proteins from proliferating mammalian cells shows co-sedimentation of enzymes involved in DNA replication with those required for synthesis of deoxynucleoside triphosphates (dNTPs). Such complexes can be isolated only from cells that are in S phase, but not from cells in G(0)/G(1) phases of cell cycle. The kinetics of deoxynucleotide metabolism supporting DNA replication in intact and permeabilized cells reveals close coupling and allosteric interaction between the enzymes of dNTP synthesis and DNA replication. These interactions contribute to channeling and compartmentation of deoxynucleotides in the microvicinity of DNA replication. A multienzyme and multiprotein megacomplex with these unique properties is called "replitase." In this article, we summarize some of the relevant evidence to date that supports the concept of replitase in mammalian cells, which originated from the observations in Dr. Pardee's laboratory. In addition, we show that androgen receptor (AR), which plays a critical role in proliferation and viability of prostate cancer cells, is associated with replitase, and that identification of constituents of replitase in androgen-dependent versus androgen-independent prostate cancer cells may provide insights into androgen-regulated events that control proliferation of prostate cancer cells and potentially offer an effective strategy for the treatment of prostate cancer.

Construction and complementation of in-frame deletions of the essential Escherichia coli thymidylate kinase gene

This work reports the construction of Escherichia coli in-frame deletion strains of tmk, which encodes thymidylate kinase, Tmk. The tmk gene is located at the third position of a putative five-gene operon at 24.9 min on the E. coli chromosome, which comprises the genes pabC, yceG, tmk, holB, and ycfH. To avoid potential polar effects on downstream genes of the operon, as well as recombination with plasmid-encoded tmk, the tmk gene was replaced by the kanamycin resistance gene kka1, encoding amino glycoside 3'-phosphotransferase kanamycin kinase. The kanamycin resistance gene is expressed under the control of the natural promoter(s) of the putative operon. The E. coli tmk gene is essential under any conditions tested. To show functional complementation in bacteria, the E. coli tmk gene was replaced by thymidylate kinases of bacteriophage T4 gp1, E. coli tmk, Saccharomyces cerevisiae cdc8, or the Homo sapiens homologue, dTYMK. Growth of these transgenic E. coli strains is completely dependent on thymidylate kinase activities of various origin expressed from plasmids. The substitution constructs show no polar effects on the downstream genes holB and ycfH with respect to cell viability. The presented transgenic bacteria could be of interest for testing of thymidylate kinase-specific phosphorylation of nucleoside analogues that are used in therapies against cancer and infectious diseases.

Escherichia coli thymidylate kinase: molecular cloning, nucleotide sequence, and genetic organization of the corresponding tmk locus

Thymidylate kinase (dTMP kinase; EC 2.7.4.9) catalyzes the phosphorylation of dTMP to form dTDP in both de novo and salvage pathways of dTTP synthesis. The nucleotide sequence of the tmk gene encoding this essential Escherichia coli enzyme is the last one among all the E. coli nucleoside and nucleotide kinase genes which has not yet been reported. By subcloning the 24.0-min region where the tmk gene has been previously mapped from the lambda phage 236 (E9G1) of the Kohara E. coli genomic library (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987), we precisely located tmk between acpP and holB genes. Here we report the nucleotide sequence of tmk, including the end portion of an upstream open reading frame (ORF 340) of unknown function that may be cotranscribed with the pabC gene. The tmk gene was located clockwise of and just upstream of the holB gene. Our sequencing data allowed the filling in of the unsequenced gap between the acpP and holB genes within the 24-min region of the E. coli chromosome. Identification of this region as the E. coli tmk gene was confirmed by functional complementation of a yeast dTMP kinase temperature-sensitive mutant and by in vitro enzyme assay of the thymidylate kinase activity in cell extracts of E. coli by use of tmk-overproducing plasmids. The deduced amino acid sequence of the E. coli tmk gene showed significant similarity to the sequences of the thymidylate kinases of vertebrates, yeasts, and viruses as well as two uncharacterized proteins of bacteria belonging to Bacillus and Haemophilus species.

Mouse MTH1 protein with 8-oxo-7,8-dihydro-2'-deoxyguanosine 5'-triphosphatase activity that prevents transversion mutation. cDNA cloning and tissue distribution

8-Oxo-7,8-dihydro-2'-deoxyguanosine 5'-triphosphate (8-oxo-dGTP) is formed in the nucleotide pool of a cell during normal cellular metabolism, and when it is incorporated into DNA causes mutation. Organisms possess 8-oxo-dGTPase, an enzyme that specifically degrades 8-oxo-dGTP to 8-oxo-dGMP. We isolated cDNA for mouse 8-oxo-dGTPase, using as a probe human MTH1 (Escherichia coli mutT homolog) cDNA. The nucleotide sequence of the cDNA revealed that the mouse MTH1 protein (molecular weight of 17,896) comprises 156 amino acid residues. When the cDNA for mouse 8-oxo-dGTPase was expressed in E. coli mutT- mutant cells devoid of their own 8-oxo-dGTPase activity, an 18-kDa protein, which is cross-reactive with an anti-human MTH1 antibody, was formed. In such cells, the level of spontaneous mutation frequency that was elevated reverted to normal. High levels of 8-oxo-dGTPase activity were found in liver, thymus, and large intestine, whereas all other organs examined contained smaller amounts of the enzyme. In embryonic stem cells, an exceedingly high level of the enzyme was present.

Thymine auxotrophy is associated with increased UV sensitivity in Escherichia coli and Bacillus subtilis

Thymine auxotrophy was shown to be associated with an increase in UV sensitivity both in Bacillus subtilis and in Escherichia coli. This UV sensitization became clearly evident in polA5 mutants of Bacillus subtilis: at UV doses of 16 J/m2, a reduction of more than 10-fold in the survivor population is observed in thymine requiring spontaneous mutants (polA5 thyA thyB) compared to the parental strains (polA5). Reversion of either thyA or thyB mutation led to a partial recovery in the UV resistance. This result suggests that DNA repair polymerization might be improved by the biosynthesis of thymidylate or some effect associated with such activity.

On the levels of enzymatic substrate specificity: implications for the early evolution of metabolic pathways

The most frequently invoked explanation for the origin of metabolic pathways is the retrograde evolution hypothesis. In contrast, according to the so-called "patchwork" theory, metabolism evolved by the recruitment of relatively inefficient small enzymes of broad specificity that could react with a wide range of chemically related substrates. In this paper it is argued that both sequence comparisons and experimental results on enzyme substrate specificity support the patchwork assembly theory. The available evidence supports previous suggestions that gene duplication events followed by a gradual neoDarwinian accumulation of mutations and other minute genetic changes lead to the narrowing and modification of enzyme function in at least some primordial metabolic pathways.

Ribonucleotide reductases and their occurrence in microorganisms: a link to the RNA/DNA transition

The evolution of a deoxyribonucleotide synthesizing ribonucleotide reductase might have initiated the transition from the ancient RNA world into the prevailing DNA world. At least five classes of ribonucleotide reductases have evolved. The ancient enzyme has not been identified. A reconstruction of the first ribonucleotide reductase requires knowledge of contemporary enzymes and of microbial evolution. Experimental work on the former focuses on few organisms, whereas the latter is now well understood on the basis of ribosomal RNA sequences. Deoxyribonucleotide formation has not been investigated in many evolutionary important microorganisms. This review covers our knowledge on deoxyribonucleotide synthesis in microorganisms and the distribution of ribonucleotide reductases in nature. Ecological constraints on enzyme evolution and knowledge deficiencies emerge from complete coverage of the phylogenetic groups.

The adenovirus DNA binding protein effects the kinetics of DNA replication by a mechanism distinct from NFI or Oct-1

Initiation of adenovirus DNA replication in vitro minimally requires the viral TP-DNA template and the precursor terminal protein-DNA polymerase heterodimer (pTP-pol). Optimal initiation occurs in the presence of the cellular transcription factors NFI and Oct-1 and the viral DNA binding protein (DBP). We have studied the influence of these three stimulatory proteins on the kinetics of formation of the pTP-dCMP initiation complex. NFI increases the Vmax of the reaction but does not affect the apparent Km for dC-TP. This indicates that NFI acts by enlarging the amount of active initiation complex in agreement with its stabilizing effect on binding of pTP-pol to the template. Similar kinetic effects were observed for Oct-1. Since Oct-1 does not stabilize binding of pTP-pol to the origin this suggests that Oct-1 increases the rate of pTP-dCMP formation. DBP stimulates the initiation reaction in two ways. First, it moderately increases the Vmax at suboptimal NFI concentrations, which is related to its enhancing effect on binding of NFI to the origin. Second, a much larger stimulation was caused by DBP itself based on a reduction of the Km for dCTP, which was independent of the concentration of pTP-pol or NFI. The Km for dCTP during initiation is lower than during elongation.

Characteristics of NADPH-dependent thymidylate synthetase purified from Streptomyces aureofaciens

NADPH-dependent thymidylate synthetase from Streptomyces aureofaciens has been purified to homogenity by a two-step chromatographic procedure including anion-exchange chromatography and affinity chromatography on methotrexate-Sepharose 4B. The enzyme was purified 1025-fold with a 34% yield. Basic characteristics of the enzyme were determined: molecular weight of the enzyme subunit (28,000), pH and temperature optimum, effect of cations, dependency on reducing agents, Km values for dUMP, mTHF, and NADPH (3.78, 21.1, and 38.9 microM, respectively), and inhibition effect of 5-FdUMP. Binding studies revealed the enzyme mechanism to be ordered sequential: dUMP bound before mTHF. S. aureofaciens thymidylate synthetase exhibits an absolute requirement for NADPH for the enzyme activity--a unique feature not displayed by any of the thymidylate synthetases isolated so far. NADPH is not consumed during enzyme reaction, indicating its regulatory role. The properties of S. aureofaciens thymidylate synthetase show that it is a monofunctional bacterial enzyme.

DNA precursor asymmetries, replication fidelity, and variable genome evolution

Balanced pools of deoxyribonucleoside triphosphates (dNTPs) are essential for DNA replication to occur with maximum fidelity. Conditions that create biased dNTP pools stimulate mutagenesis, as well as other phenomena, such as recombination or cell death. In this essay we consider the effective dNTP concentrations at replication sites under normal conditions, and we ask how maintenance of these levels contributes toward the natural fidelity of DNA replication. We focus upon two questions. (1) In prokaryotic systems, evidence suggests that replication is driven by small, localized, rapidly replenished dNTP pools that do not equilibrate with the bulk dNTP pools in the cell. Since these pools cannot be analyzed directly, what indirect approaches can illuminate the nature of these replication-active pools? (2) In eukaryotic cells, the normal dNTP pools are highly asymmetric, with dGTP being the least abundant nucleotide. Moreover, the composition of the dNTP pools changes as cells progress through the cell cycle. To what extent might these natural asymmetries contribute toward a recently described phenomenon, the differential rate of evolution of different genes in the same genome?

Mammalian DNA replication: mutation biases and the mutation rate

Experimental studies have shown that the fidelity of DNA replication can be affected by the concentrations of free deoxyribonucleotides present in the cell. Replication of mammalian chromosomes is achieved using pools of newly-synthesized deoxyribonucleotides which fluctuate during the cell cycle. Since regions of mammalian chromosomes are replicated sequentially, there is the potential for differences among mammalian loci in both the relative and absolute frequencies of the various transitional and transversional mutations which may occur. Where these mutations are effectively neutral, at silent sites in genes and in non-coding sequences, this may result in different rates of evolution and in different base compositions, as have been observed in data from mammalian genes. A simple model of the DNA replication process is developed to describe how the mutation rate could be affected by the G + C contents of the deoxyribonucleotide pools and of the replicating DNA. Mutation rates are predicted to vary from locus to locus; only in the particular case of identical G + C contents in the DNA locus and the deoxyribonucleotide pools, and no proofreading, will the mutation rate be uniform over all loci.

Analysis of mutagenesis induced by a thermolabile T4 phage deoxycytidylate hydroxymethylase suggests localized deoxyribonucleotide pool imbalance

To understand the molecular basis of mutation stimulated by deoxyribonucleotide pool imbalance, we studied a temperature-sensitive T4 phage gene 42 mutant (LB3), which specifies a thermolabile deoxycytidylate hydroxymethylase. Analysis of rII mutations, revertible to wild type along either GC-to-AT or AT-to-GC transition pathways, showed 8- to 80-fold stimulation of GC-to-AT mutations at a semi-permissive temperature (34 degrees C). One such marker, rII SN103, which showed the highest stimulation at 34 degrees C, was sequenced after amplification of the template by polymerase chain reaction. The mutant site in rII SN103 was identified at nucleotide position 265 from the rII B translational start as an AT-to-GC transition, which changes TCA to CCA. Sequence analysis of revertants and pseudorevertants generated at 34 degrees C showed that both cytosines within this triplet can undergo change to either thymine or adenine, consistent with the hypothesis that hydroxymethyldeoxycytidine triphosphate pools are depleted at replication sites. However, dNTP pool measurements in extracts of 34 degrees C cultures showed no significant deviations from values obtained at 30 degrees C, suggesting that pool imbalances occur only locally, close to replication forks. Our studies support the hypothesis that the mutator phenotype displayed by ts LB3 at semi-permissive temperature is a consequence of perturbation of the flow of nucleotide precursors into the DNA replication machinery. A putative localized depletion of hm-dCTP presumably enlarges effective dTTP/hm-dCTP and dATP/hm-dCTP pool ratios, resulting in the observed C-to-T transition and C-to-A transversion mutations.

Temperature-sensitive DNA mutant of Chinese hamster ovary cells with a thermolabile ribonucleotide reductase activity

JB3-B is a Chinese hamster ovary cell mutant previously shown to be temperature sensitive for DNA replication (J. J. Dermody, B. E. Wojcik, H. Du, and H. L. Ozer, Mol. Cell. Biol. 6:4594-4601, 1986). It was chosen for detailed study because of its novel property of inhibiting both polyomavirus and adenovirus DNA synthesis in a temperature-dependent manner. Pulse-labeling studies demonstrated a defect in the rate of adenovirus DNA synthesis. Measurement of deoxyribonucleoside triphosphate (dNTP) pools as a function of time after shift of uninfected cultures from 33 to 39 degrees C revealed that all four dNTP pools declined at similar rates in extracts prepared either from whole cells or from rapidly isolated nuclei. Ribonucleoside triphosphate pools were unaffected by a temperature shift, ruling out the possibility that the mutation affects nucleoside diphosphokinase. However, ribonucleotide reductase activity, as measured in extracts, declined after cell cultures underwent a temperature shift, in parallel with the decline in dNTP pool sizes. Moreover, the activity of cell extracts was thermolabile in vitro, consistent with the model that the JB3-B mutation affects the structural gene for one of the ribonucleotide reductase subunits. The kinetics of dNTP pool size changes after temperature shift are quite distinct from those reported after inhibition of ribonucleotide reductase with hydroxyurea. An indirect effect on ribonucleotide reductase activity in JB3-B has not been excluded since human sequences other than those encoding the enzyme subunits can correct the temperature-sensitive growth defect in the mutant.

Temperature-sensitive DNA mutant of Chinese hamster ovary cells with a thermolabile ribonucleotide reductase activity

JB3-B is a Chinese hamster ovary cell mutant previously shown to be temperature sensitive for DNA replication (J. J. Dermody, B. E. Wojcik, H. Du, and H. L. Ozer, Mol. Cell. Biol. 6:4594-4601, 1986). It was chosen for detailed study because of its novel property of inhibiting both polyomavirus and adenovirus DNA synthesis in a temperature-dependent manner. Pulse-labeling studies demonstrated a defect in the rate of adenovirus DNA synthesis. Measurement of deoxyribonucleoside triphosphate (dNTP) pools as a function of time after shift of uninfected cultures from 33 to 39 degrees C revealed that all four dNTP pools declined at similar rates in extracts prepared either from whole cells or from rapidly isolated nuclei. Ribonucleoside triphosphate pools were unaffected by a temperature shift, ruling out the possibility that the mutation affects nucleoside diphosphokinase. However, ribonucleotide reductase activity, as measured in extracts, declined after cell cultures underwent a temperature shift, in parallel with the decline in dNTP pool sizes. Moreover, the activity of cell extracts was thermolabile in vitro, consistent with the model that the JB3-B mutation affects the structural gene for one of the ribonucleotide reductase subunits. The kinetics of dNTP pool size changes after temperature shift are quite distinct from those reported after inhibition of ribonucleotide reductase with hydroxyurea. An indirect effect on ribonucleotide reductase activity in JB3-B has not been excluded since human sequences other than those encoding the enzyme subunits can correct the temperature-sensitive growth defect in the mutant.

Bacteriophage T4 nrdA and nrdB genes, encoding ribonucleotide reductase, are expressed both separately and coordinately: characterization of the nrdB promoter

We examined the expression of the bacteriophage T4 nrdA and nrdB genes, which encode the alpha 2 and beta 2 subunits, respectively, of ribonucleoside diphosphate reductase, the first committed enzyme in the pathway of synthesis of the deoxyribonucleoside triphosphates. T4 nrdA, located 700 bp upstream from nrdB, has been shown previously to be transcribed by two major transcripts: a prereplicative, polycistronic message, TU, orginating at an immediate-early promoter, PE, that is 3.5 kb upstream from nrdA, and a postreplicative message commencing from a late promoter in its 5' flank. We have found a third promoter initiating a transcript at 159 nucleotides upstream from the reading frame of nrdB. PnrdB functions only in the presence of the T4 motA gene product, which is required for middle (time) promoters, and therefore the onset of nrdB transcription is delayed more than 2 min after infection. Because of the distance of nrdA from PE, the inception of nrdA transcription (delayed early) coincides closely with that of nrdB. An apparent termination site, tA, occurs about 80 bp downstream from nrdA. Some of the polycistronic mRNA reading through the site after 5 min contributes to nrdB transcription. nrdA and nrdB genes in an uninfected host have been reported to be transcribed only coordinately. In contrast, T4 nrdA and nrdB are initially transcribed separately onto the PE and PnrdB transcripts, respectively, but at about 5 min after infection are transcribed both coordinately and on separate transcripts. Evidence is presented that TU coordinately transcribes a deoxyribonucleotide operon in the order: frd, td, gene 'Y,' nrdA, nrdB. Since the beta 2 subunit is known to be formed after the alpha 2 subunit, the expression of the nrdB gene determines the onset of deoxyribonucleoside triphosphate synthesis and thus of T4 DNA replication.