Dynamics of the cellular metabolome during human cytomegalovirus infection.
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Viral replication requires energy and macromolecular precursors derived from the metabolic network of the host cell. Despite this reliance, the effect of viral infection on host cell metabolic composition remains poorly understood. Here we applied liquid chromatography-tandem mass spectrometry to measure the levels of 63 different intracellular metabolites at multiple times after human cytomegalovirus (HCMV) infection of human fibroblasts. Parallel microarray analysis provided complementary data on transcriptional regulation of metabolic pathways. As the infection progressed, the levels of metabolites involved in glycolysis, the citric acid cycle, and pyrimidine nucleotide biosynthesis markedly increased. HCMV-induced transcriptional upregulation of specific glycolytic and citric acid cycle enzymes mirrored the increases in metabolite levels. The peak levels of numerous metabolites during infection far exceeded those observed during normal fibroblast growth or quiescence, demonstrating that HCMV markedly disrupts cellular metabolic homeostasis and institutes its own specific metabolic program. (+info)
Internal conversion to the electronic ground state occurs via two distinct pathways for pyrimidine bases in aqueous solution.
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The femtosecond transient absorption technique was used to study the relaxation of excited electronic states created by absorption of 267-nm light in all of the naturally occurring pyrimidine DNA and RNA bases in aqueous solution. The results reveal a surprising bifurcation of the initial excited-state population in <1 ps to two nonradiative decay channels within the manifold of singlet states. The first is the subpicosecond internal conversion channel first characterized in 2000. The second channel involves passage through a dark intermediate state assigned to a lowest-energy (1)npi* state. Approximately 10-50% of all photoexcited pyrimidine bases decay via the (1)npi* state, which has a lifetime of 10-150 ps. Three- to 6-fold-longer lifetimes are seen for pyrimidine nucleotides and nucleosides than for the corresponding free bases, revealing an unprecedented effect of ribosyl substitution on electronic energy relaxation. A small fraction of the (1)npi* population is proposed to undergo intersystem crossing to the lowest triplet state in competition with vibrational cooling, explaining the higher triplet yields observed for pyrimidine versus purine bases at room temperature. Some simple correlations exist between yields of the (1)npi* state and yields of some pyrimidine photoproducts, but more work is needed before the photochemical consequences of this state can be definitively determined. These findings lead to a dramatically different picture of electronic energy relaxation in single pyrimidine bases with important ramifications for understanding DNA photostability. (+info)
Thermodynamic properties of enzyme-catalyzed reactions involving cytosine, uracil, thymine, and their nucleosides and nucleotides.
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The standard Gibbs energies of formation of species in the cytidine triphosphate series, uridine triphosphate series, and thymidine triphosphate series have been calculated on the basis of the convention that Delta(f)G=0 for the neutral form of cytidine in aqueous solution at 298.15 K at zero ionic strength. This makes it possible to calculate apparent equilibrium constants for a number of reactions for which apparent equilibrium constants have not been measured or cannot be measured because they are too large. This paper adds fifteen reactants to the database BasicBiochemData3 at MathSource that includes 199 reactants. The standard transformed Gibbs energies of formation of these fifteen reactants are used to calculate apparent equilibrium constants at 298.15 K, ionic strength 0.25 M, and pHs 5, 6, 7, 8, and 9 for thirty two reactions. The pKs, standard Gibbs energies of hydrolysis, and standard Gibbs energies of deamination are given for these fifteen reactants. (+info)
Fluorescent pyrimidine ribonucleotide: synthesis, enzymatic incorporation, and utilization.
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Fluorescent nucleobase analogues that respond to changes in their microenvironment are valuable for studying RNA structure, dynamics, and recognition. The most commonly used fluorescent ribonucleoside is 2-aminopurine, a highly responsive purine analogue. Responsive isosteric fluorescent pyrimidine analogues are, however, rare. Appending five-membered aromatic heterocycles at the 5-position on a pyrimidine core has recently been found to provide a family of responsive fluorescent nucleoside analogues with emission in the visible range. To explore the potential utility of this chromophore for studying RNA-ligand interactions, an efficient incorporation method is necessary. Here we describe the synthesis of the furan-containing ribonucleoside and its triphosphate, as well as their basic photophysical characteristics. We demonstrate that T7 RNA polymerase accepts this fluorescent ribonucleoside triphosphate as a substrate in in vitro transcription reactions and very efficiently incorporates it into RNA oligonucleotides, generating fluorescent constructs. Furthermore, we utilize this triphosphate for the enzymatic preparation of a fluorescent bacterial A-site, an RNA construct of potential therapeutic utility. We show that the binding of this RNA target to aminoglycoside antibiotics, its cognate ligands, can be effectively monitored by fluorescence spectroscopy. These observations are significant since isosteric emissive U derivatives are scarce and the trivial synthesis and effective enzymatic incorporation of the furan-containing U triphosphate make it accessible to the biophysical community. (+info)
Enantioselectivity of human AMP, dTMP and UMP-CMP kinases.
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L-nucleoside analogues such as lamivudine are active for treating viral infections. Like D-nucleosides, the biological activity of the L-enantiomers requires their stepwise phosphorylation by cellular or viral kinases to give the triphosphate. The enantioselectivity of NMP kinases has not been thoroughly studied, unlike that of deoxyribonucleoside kinases. We have therefore investigated the capacity of L-enantiomers of some natural (d)NMP to act as substrates for the recombinant forms of human uridylate-cytidylate kinase, thymidylate kinase and adenylate kinases 1 and 2. Both cytosolic and mitochondrial adenylate kinases were strictly enantioselective, as they phosphorylated only D-(d)AMP. L-dTMP was a substrate for thymidylate kinase, but with an efficiency 150-fold less than D-dTMP. Both L-dUMP and L-(d)CMP were phosphorylated by UMP-CMP kinase although much less efficiently than their natural counterparts. The stereopreference was conserved with the 2'-azido derivatives of dUMP and dUMP while, unexpectedly, the 2'-azido-D-dCMP was a 4-fold better substrate for UMP-CMP kinase than was CMP. Docking simulations showed that the small differences in the binding of D-(d)NMP to their respective kinases could account for the differences in interactions of the L-isomers with the enzymes. This in vitro information was then used to develop the in vivo activation pathway for L-dT. (+info)
Lethal mutagenesis of poliovirus mediated by a mutagenic pyrimidine analogue.
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Lethal mutagenesis is the mechanism of action of ribavirin against poliovirus (PV) and numerous other RNA viruses. However, there is still considerable debate regarding the mechanism of action of ribavirin against a variety of RNA viruses. Here we show by using T7 RNA polymerase-mediated production of PV genomic RNA, PV polymerase-catalyzed primer extension, and cell-free PV synthesis that a pyrimidine ribonucleoside triphosphate analogue (rPTP) with ambiguous base-pairing capacity is an efficient mutagen of the PV genome. The in vitro incorporation properties of rPTP are superior to ribavirin triphosphate. We observed a log-linear relationship between virus titer reduction and the number of rPMP molecules incorporated. A PV genome encoding a high-fidelity polymerase was more sensitive to rPMP incorporation, consistent with diminished mutational robustness of high-fidelity PV. The nucleoside (rP) did not exhibit antiviral activity in cell culture, owing to the inability of rP to be converted to rPMP by cellular nucleotide kinases. rP was also a poor substrate for herpes simplex virus thymidine kinase. The block to nucleoside phosphorylation could be bypassed by treatment with the P nucleobase, which exhibited both antiviral activity and mutagenesis, presumably a reflection of rP nucleotide formation by a nucleotide salvage pathway. These studies provide additional support for lethal mutagenesis as an antiviral strategy, suggest that rPMP prodrugs may be highly efficacious antiviral agents, and provide a new tool to determine the sensitivity of RNA virus genomes to mutagenesis as well as interrogation of the impact of mutational load on the population dynamics of these viruses. (+info)
Alanosine toxicity in Novikoff rat hepatoma cells due to inhibition of the conversion of inosine monophosphate to adenosine monophosphate.
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2-Amino-3-(hydroxynitrosoamino)propionic acid (alanosine), at a concentration as low as 2.7 muM, completely inhibits the incorporation of hypoxanthine into adenosine triphosphate by cultured Novikoff rat hepatoma cells. Alanosine inhibits the first step in the conversion of inosine monophosphate to adenosine monophosphate because inosine monophosphate, but not adenylosuccinate, accumulates in treated cells. However, the alanosine inhibition is not prevented by aspartic acid, even at a concentration of 1 mM. Alanosine treatment results in the inhibition of cell division, DNA synthesis, RNA and protein synthesis (in this order), and a depletion of the cells of adenosine triphosphate. Some of the cells accumulate in late G2 or M, but the remainder become arrested in other stages of the cell cycle. All effects are due to the inhibition of adenosine monophosphate synthesis and the consequent depletion of the adenosine triphosphate pool since they are completely prevented or reversed by addition of adenine, but not hypoxanthine, to the medium. Pyrimidine nucleotide synthesis is not significantly inhibited by alanosine, since the uridine triphosphate pool is not affected and uridine fails to reverse the cytotoxicity of alanosine. Alanosine also inhibits the transport of aspartic acid, but has a much lower affinity for this transport system than aspartic acid. (+info)
pyr RNA binding to the Bacillus caldolyticus PyrR attenuation protein - characterization and regulation by uridine and guanosine nucleotides.
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