Purine metabolism in Toxoplasma gondii

We have studied the incorporation and interconversion of purines into nucleotides by freshly isolated Toxoplasma gondii. They did not synthesize nucleotides from formate, glycine, or serine. The purine bases hypoxanthine, xanthine, guanine, and adenine were incorporated at 9.2, 6.2, 5.1, and 4.3 pmol/10(7) cells/h, respectively. The purine nucleosides adenosine, inosine, guanosine, and xanthosine were incorporated at 110, 9.0, 2.7, and 0.3 pmol/10(7) cells/h, respectively. Guanine, xanthine, and their respective nucleosides labeled only guanine nucleotides. Inosine, hypoxanthine, and adenine labeled both adenine and guanine nucleotide pools at nearly equal ratios. Adenosine kinase was greater than 10-fold more active than the next most active enzyme in vitro. This is consistent with the metabolic data in vivo. No other nucleoside kinase or phosphotransferase activities were found. Phosphorylase activities were detected for guanosine and inosine; no other cleavage activities were detected. Deaminases were found for adenine and guanine. Phosphoribosyltransferase activities were detected for all four purine nucleobases. Interconversion occurs only in the direction of adenine to guanine nucleotides.     

Pathways of Nucleotide Biosynthesis in Mycoplasma mycoides subsp. mycoides

By measuring the specific activity of nucleotides isolated from ribonucleic acid after the incorporation of (14)C-labeled precursors under various conditions of growth, we have defined the major pathways of ribonucleotide synthesis in Mycoplasma mycoides subsp. mycoides. M. mycoides did not possess pathways for the de novo synthesis of nucleotides but was capable of interconversion of nucleotides. Thus, uracil provided the requirement for both pyrimidine ribonucleotides. Thymine is also required, suggesting that the methylation step is unavailable. No use was made of cytosine. Uridine was rapidly degraded to uracil. Cytidine competed effectively with uracil to provide most of the cytidine nucleotide and also provided an appreciable proportion of uridine nucleotide. In keeping with these results, there was a slow deamination of cytidine to uridine with further degradation to uracil in cultures of M. mycoides. Guanine was capable of meeting the full requirement of the organism for purine nucleotide, presumably by conversion of guanosine 5'-monophosphate to adenosine 5'-monophosphate via the intermediate inosine 5'-monophosphate. When available with guanine, adenine effectively gave a complete provision of adenine nucleotide, whereas hypoxanthine gave a partial provision. Neither adenine nor hypoxanthine was able to act as a precursor for the synthesis of guanine nucleotide. Exogenous guanosine, inosine, and adenosine underwent rapid cleavage to the corresponding bases and so show a pattern of utilization similar to that of the latter.     

Direct covalent mercuration of nucleotides and polynucleotides.

Nucleotides of cytosine and uracil are readily mercurated by heating at 37-50 degrees in buffered aqueous solutions (pH 5.0-8.0) containing mercuric acetate. Proton magnetic resonance, elemental, electrophoretic, and chromatographic analyses have shown the products to be 5-mercuricytosine and 5-mercuriuracil derivatives, where the mercury atom is covalently bonded. Polynucleotides can be mercurated under similar conditions. Cytosine and uracil bases are modified in RNA while only cytosine residues in DNA are substituted. There is little, if any, reaction with adenine, thymine, or guanine bases. The rate of polymer mercuration is, unlike that of mononucleotides, markedly influenced by the ionic strength of the reaction mixture: the lower the ionic strength the faster the reaction rate. Pyrimidine residues in single- and double-stranded polymers react at essentially the same rate. Although most polynucleotides can be extensively mercurated at pH 7.0 in sodium or Trisacetate buffers, tRNA undergoes only limited substitution in Tris buffers. The mild reaction conditions give minimal single-strand breakage and, unlike direct iodination procedures, do not produce pyrimidine hydrates. Mercurated polynucleotides can be exploited in a variety of ways, particularly by crystallographic and electron microscopic techniques, as tools for studying polynucleotide structure.     

Strand scission of deoxyribonucleic acid by neocarzinostatin, auromomycin, and bleomycin: studies on base release and nucleotide sequence specificity

The nucleotide sequence specificity of neocarzinostatin (NCS), auromomycin (AUR), bleomycin (Blm), phleomycin (Phlm), and tallysomycin (Tlm) has been determined by using these antibiotics and their associated chromophores to create strand scissions in end-labeled restriction fragments of DNA and then determining the base sequence of the oligonucleotides formed. NCS and the NCS chromophore induce similar patterns of cleavage in DNA fragments labeled at the 5' terminus. The pattern produced by the AUR chromophore also resembles that of its holoantibiotic. Dithiothreitol enhances the rate of cleavage of DNA by the AUR chromophore but does not alter the sequence specificity. The results suggest that the polypeptide component of AUR and NCS serves primarily as a carrier for the chromophore. When tested with a fragment labeled at the 3' terminus, the products of NCS and AUR cleavage do not display the patterns of chemically produced oligonucleotides cleaved at phosphodiester bonds, suggesting that the 5' terminus is modified by a sugar fragment. NCS primarily attacks thymine (75% of the total bases attacked) and, to a lesser extent, adenine (19%) and cytosine (6%). AUR preferentially attacks guanine (67% of total bases), while attacking less often thymine (24%) and adenine (9%). Bleomycin and its analogues preferentially cleave purine--pyrimidine (5' leads to 3') and pyrimidine--pyrimidine (3' leads to 5') sequences. All (5' leads to 3') GT and GC sequences were cleaved. Phlm G and Phlm-Pep are less active than bleomycin toward purines while Tlm was more active. The patterns of cleavage produced by Blm A2 and Blm B6 are similar, while those produced by Phlm-Pep, Phlm G, Blm-B1', and Blm-Pep resemble one another. The cleavage pattern of Tlm shows quantitative differences from the other analogues tested. Differences between bleomycin and its analogues may be related to structural differences in these molecules.     

2'',3''-Dideoxy-3'' aminonucleoside 5''-triphosphates are the terminators of DNA synthesis catalyzed by DNA polymerases.

It is shown that 2',3'-dideoxy-3'-aminonucleoside 5'-triphosphates with adenine, guanine, cytosine and thymine bases are effective inhibitors of DNA polymerase I, calf thymus DNA polymerase alpha and rat liver DNA polymerase beta. The effect of the above-mentioned compounds is markedly higher than corresponding action of the well-known DNA synthesis inhibitors arabinonucleoside 5'-triphosphates and 2',3'-dideoxynucleoside 5'-triphosphates. 2',3'-dideoxy-3'-aminonucleoside 5'-monophosphate residues incorporate into the 3'-terminus of the primer and terminate the DNA chain elongation. The possibility of using 2',3'-dideoxy-3'-aminonucleoside 5'-triphosphates as terminators for DNA sequencing by the polymerization method is demonstrated.     

Toxoplasma gondii: mechanism of the parasitostatic action of 6-thioxanthine

In contrast to the cytocidal effect of 6-thiopurines on mammalian cells, the action of 6-thioxanthine on Toxoplasma gondii was only parasitostatic. 6-Thioxanthine was a substrate of the parasite's hypoxanthine-guanine phosphoribosyltransferase. That enzyme converted 6-thioxanthine to 6-thioxanthosine 5'-phosphate which accumulated to near millimolar concentrations within parasites incubated intracellularly in medium containing the drug. 6-Thioxanthosine 5'-phosphate was the only detectable metabolite of 6-thioxanthine. The absence of 6-thioguanine nucleotides explains the lack of a parasitocidal effect because the incorporation of 6-thiodeoxyguanosine triphosphate into DNA is the mechanism of the lethal effect of 6-thiopurines on mammalian cells. Extracellular parasites that had accumulated a high concentration of 6-thioxanthosine 5'-phosphate incorporated more labeled hypoxanthine or xanthine into their nucleotide pools than did control parasites. The basis for this increased nucleobase salvage remains unexplained. It was not due to up-regulation of hypoxanthine-guanine phosphoribosyltransferase and could not be explained by reduced use of labeled nucleotides for nucleic acid synthesis. Extracellular parasites that had accumulated a high concentration of 6-thioxanthosine 5'-phosphate used labeled hypoxanthine almost entirely to make adenine nucleotides while control parasites made both adenine and guanine nucleotides. Both extracellular parasites that had accumulated a high concentration of 6-thioxanthosine 5'-phosphate and control parasites efficiently used labeled xanthine to make guanine nucleotides. These observations suggested that inosine 5'-phosphate-dehydrogenase was inhibited while guanosine 5'-phosphate synthase was not. Assay of inosine 5'-phosphate dehydrogenase in soluble extracts of T. gondii confirmed that 6-thioxanthosine 5'-phosphate was an inhibitor. We conclude that 6-thioxanthine blocks the growth of T. gondii by a depletion a guanine nucleotides.     

Hematoporphyrin-induced photo-oxidation and photodynamic cross-linking of nucleic acids and their constituents

The pH-dependency of photo-oxidation of the physiological purine and pyrimidine bases and some of their derivatives was studied, with hematoporphyrin as sensitizer. At high pH these bases (adenine, guanine, uracil, thymine and cytosine) were photo-oxidizable. In the physiological pH range only guanine, and to a much less extent thymine, were sensitive to photo-oxidation. At physiological pH values a slow photo-oxidation of RNA and DNA took place. The photo-oxidation of nuclei acids was strongly augmented by perturbation of their structure in 8 M urea. In model experiments photodynamic cross-linking of tryptophan and cysteine to DNA was demonstrated. No covalent binding of purine or pyrimidine bases to DNA was observed. In similar model experiments covalent photodynamic coupling of guanosine and guanosine-monophosphate to proteins could be shown, whereas no coupling of the other bases occured. These studies confirm the preferential photo-oxidation of guanine in nucleic acids and demonstrate the possible photodynamic cross-linking of proteins to the guanine moiety in other molecules.     

Methylation Pattern of Lambda Deoxyribonucleic Acid

Deoxyribonucleic acid (DNA) extracted from phage lambda grown on Escherichia coli K-12 strain W4032 had 113 +/- 10 5-methylcytosine residues and 215 +/- 20 6-methyl adenine residues per genome, as determined by three independent methods. These methylated nucleotides were distributed equally among the two strands of lambda DNA. Shearing of double-stranded DNA to half-length fragments revealed a slight deficiency of 5-methyl cytosine in the 55% guanine plus cytosine half. Shearing the DNA to fragments of smaller length showed that the distribution of methylated nucleotides along the double helix was uniform with the exception of an undermethylated fragment arising from the center of the lambda DNA molecule. The implication of these results for the function of methylated nucleotides in the lambda DNA molecule is discussed.     

Profiles of purine metabolism in leaves and roots of Camellia sinensis seedlings

To determine the metabolic profiles of purine nucleotides and related compounds in leaves and roots of tea (Camellia sinensis), we studied the in situ metabolic fate of 10 different (14)C-labeled precursors in segments from tea seedlings. The activities of key enzymes in tea leaf extracts were also investigated. The rates of uptake of purine precursors were greater in leaf segments than in root segments. Adenine and adenosine were taken up more rapidly than other purine bases and nucleosides. Xanthosine was slowest. Some adenosine, guanosine and inosine was converted to nucleotides by adenosine kinase and inosine/guanosine kinase, but these compounds were easily hydrolyzed, and adenine, guanine and hypoxanthine were generated. These purine bases were salvaged by adenine phosphoribosyltransferase and hypoxanthine/guanine phosphoribosyltransferase. Salvage activity of adenine and adenosine was high, and they were converted exclusively to nucleotides. Inosine and hypoxanthine were salvaged to a lesser extent. In situ (14)C-tracer experiments revealed that xanthosine and xanthine were not salvaged, although xanthine phosphoribosyltransferase activity was found in tea extracts. Only some deoxyadenosine and deoxyguanosine was salvaged and utilized for DNA synthesis. However, most of these deoxynucleosides were hydrolyzed to adenine and guanine and then utilized for RNA synthesis. Purine alkaloid biosynthesis in leaves is much greater than in roots. In situ experiments indicate that adenosine, adenine, guanosine, guanine and inosine are better precursors than xanthosine, which is a direct precursor of a major pathway of caffeine biosynthesis. Based on these results, possible routes of purine metabolism are discussed.     

Binding and structural studies of the complexes of type 1 ribosome inactivating protein from Momordica balsamina with cytosine,cytidine, and cytidine diphosphate

The type 1 ribosome inactivating protein from Momordica balsamina (MbRIP1) has been shown to interact with purine bases, adenine and guanine of RNA/DNA. We report here the binding and structural studies of MbRIP1 with a pyrimidine base, cytosine; cytosine containing nucleoside, cytidine; and cytosine containing nucleotide, cytidine diphosphate. All three compounds bound to MbRIP1 at the active site with dissociation constants of 10^?4 M–10^?7 M. As reported earlier, in the structure of native MbRIP1, there are 10 water molecules in the substrate binding site. Upon binding of cytosine to MbRIP1, four water molecules were dislodged from the substrate binding site while five water molecules were dislodged when cytidine bound to MbRIP1. Seven water molecules were dislocated when cytidine diphosphate bound to MbRIP1. This showed that cytidine diphosphate occupied a larger space in the substrate binding site enhancing the buried surface area thus making it a relatively better inhibitor of MbRIP1 as compared to cytosine and cytidine. The key residues involved in the recognition of cytosine, cytidine and cytidine diphosphate were Ile71, Glu85, Tyr111 and Arg163. The orientation of cytosine in the cleft is different from that of adenine or guanine indicating a notable difference in the modes of binding of purine and pyrimidine bases. Since adenine containing nucleosides/nucleotides are suitable substrates, the cytosine containing nucleosides/nucleotides may act as inhibitors.     

Probing the TRAP-RNA interaction with nucleoside analogs

The trp RNA-binding Attenuation Protein (TRAP) from Bacillus subtilis binds a series of GAG and UAG repeats separated by 2-3 nonconserved spacer nucleotides in trp leader mRNA. To identify chemical groups on the RNA required for stability of the TRAP-RNA complex, we introduced several different nucleoside analogs into each pentamer of the RNA sequence 5'-(UAGCC)-3' repeated 11 times and measured their effect on the TRAP-RNA interaction. Deoxyribonucleoside substitutions revealed that a 2'-hydroxyl group (2'-OH) is required only on the guanosine occupying the third residue of the RNA triplets for high-affinity binding to TRAP. The remaining hydroxyl groups are dispensable. Base analog substitutions identified all of the exocyclic functional groups and N1 nitrogens of adenine and guanine in the second and third nucleotides, respectively, of the triplets as being involved in binding TRAP. In contrast, none of the substitutions made in the first residue caused any detectable changes in affinity, indicating that elements of these bases are not necessary for complex formation and stability. Studies using abasic nucleotides in the first residue of the triplets and in the two spacer residues confirmed that the majority of the specificity and stability of the TRAP-RNA complex is provided by the AG dinucleotide of the triplet repeats. In addition to direct effects on binding, we demonstrate that the N7-nitrogen of adenosine and guanosine in UAG triplet and the 2'-OHs of (UAGCC)11 RNA are involved in the formation of an as yet undetermined structure that interferes with TRAP binding.     

The synthesis of [([beta-D-ribofuranosyloxy)methyl]nucleosides

The coupling reaction of acetoxymethoxy ribofuranoside 4 with nucleic acid bases 5a-f to synthesize novel (ribofuranosyloxy)methyl uracil, thymine, cytosine, adenine, guanine derivatives 6a-g respectively in preference to the expected formation of natural nucleosides 2',3',5'-tri-O-benzoyl uridine, methyluridine, cytidine, adenosine and guanosine 7a-g is described. Detailed study of these reactions catalysed by Lewis acids TMSOTf and SnCl4 is described. TMSOTf exhibited selectivity for the formation of ribofuranosyloxy methyl derivatives 6a-g rather than 7a-g. Reason for formation of 6a-g is explained by HSAB principle.     

Recognition of the DNA helix stabilizing anthramycin-N2 guanine adduct by UVRABC nuclease

The binding of the anti-tumor antibiotic anthramycin to a defined linear DNA fragment was investigated using both exonuclease III and lambda exonuclease. We show that most of the guanine residues are reactive toward anthramycin; however, several guanine residues showed preferential reactivity for the drug. Using purified UVRA, UVRB and UVRC proteins we present evidence that these three proteins in concert are able to recognize and produce specific strand cleavage flanking anthramycin-DNA adducts. The cleavage of anthramycin adducts by UVRABC nuclease is specific and results in strand breaks at five or six bases 5' and three or four bases 3'-flanking an adduct. At some guanine residues single incisions were observed only on one side of the adduct. The 5' strand breaks observed often occurred as doublet bands on sequencing gels, indicating plasticity in the site of 5' cleavage whereas the 3' cleavage did not show this effect. When DNA fragments modified with elevated levels of anthramycin were used as substrates the activity of the UVRABC nuclease toward the anthramycin adducts decreased. Possible mechanisms for the recognition and specific cleavage of the helix-stabilizing anthramycin DNA adduct and other helix destabilizing lesions by the UVRABC nuclease are discussed.     

NUCLEOTIDE METABOLISM IN RAT BRAIN

Abstract— The uptake, the conversion to nucleotides, and their incorporation into RNA for labelled glycine, aspartate, the free bases and nucleosides of purines and pyrimidines were investigated with cortical slices of rat cerebrum. At the end of a 1-hr incubation time the slice-to-medium ratio of the radioactivities for labelled aspartate, glycine, adenine and adenosine were 34, 26, 20 and 5, respectively, while the slice-to-medium ratios for hypoxanthine, inosine, guanine, guanosine, xanthine, orotate, cytidine, cytosine, uridine, and uracil ranged from 1.3:1 to 2:1. Over 99 per cent of the total radioactivity taken up by the cortical slices was present in the TCA supernatant and 86, 82, 65, 50, 34, 23, 20 and 1.6 per cent of this radioactivity was in the form of nucleotides at the end of a 1-hr incubation with labelled adenine, adenosine, hypoxanthine, inosine, uridine, orotate, cytidine, and glycine, respectively. The incorporation of various radioactive precursors into RNA of cortical slices suggests that nucleotides originating from either de novo synthesis or preformed purine derivatives enter the same nucleotide pool utilized for RNA synthesis. The supernatant fraction from homogenized cerebrum was investigated for the presence of various anabolic and catabolic enzymes associated with nucleotide metabolism. These results were correlated with the data from the RNA incorporation studies, and a possible role for AMP: pyrophosphate phosphoribosyltransferase (adenine phosphoribosyltransferase, I.U.B. 2.4.2.7) to achieve intercellular transfer of AMP is discussed.     

The formation of acetylaminofluorene adducts in poly(dC-dG) and poly(dA-dT) on reaction with N-acetoxy-2-acetylaminofluorene and the effect of such modification upon the polymers as templates for DNA polymerases

N-Acetoxy-2-acetylaminofluorene (AcO-AAF) reacts with the alternating DNA-like polynucleotides poly(dC-dG) and poly(dA-dT) in vitro to give adducts of the guanine and adenine bases similar to those reported to be formed in DNA. A previously unobserved guanine adduct was detected in the poly(dC-dG). Using a double-labelled [U-14C-dG, 8-3H-G]-poly(dC-dG) we show that this adduct does not involve the 7- or 8-positions of the guanine. Similarly a thymine adduct of unknown structure was observed in poly(dA-dT). Modification of the polymers with AcO-AAF inhibits their capacity to act as templates for Escherichia coli DNA polymerase I and mammalian DNA polymerase alpha although the binding of the polymerases to the polynucleotides is unaffected. Such modification also leads to an increase in the levels of non-complementary nucleotides incorporated into newly synthesised DNA.     

Microbiology of Saturated Salt Solutions and Other Harsh Environments. IV. New Observations of Ribonucleotide-Induced Recovery of KCl-Habituated Penicillium notatum

Salt-tolerant mutant Penicillium notatum sub-cultured in a glucose-peptone broth saturated with KCl shows continued attenuated growth when transferred to salt-free broth. Additional tests have shown E. coli S-RNA to be inferior to yeast RNA preparations, that base-free phosphate sources are inactive, but that nicotinamide adenine dinucleotide and flavine adenine dinucleotide are moderately active. All phosphate derivatives of adenine, cytosine and guanosine and inosine were active including 5'-polyphosphates, 3'(2')-monophosphates 5'-monophosphates, and adenine 3', 5'-cyclic monophosphate. Uracil derivatives were of low activity at best.Among base precursors, orotic acid was moderately active whereas imidazoles were not. The high activity of inosine 5'-phosphate a precursor of other purine nucleotides suggested that one mode of KCl action might involve a block in conversion of 4-amino-5-imidazole carboxamide ribonucleoside to the hypoxanthine nucleotide.     

Cross section calculations for electron scattering from DNA and RNA bases

Differential and integral cross sections for elastic electron collisions with uracil, cytosine, guanine, adenine and thymine have been calculated using the independent atom method with a static-polarization model potential for incident energies ranging from 50 to 4000 eV. Total cross sections for single electron-impact ionization of selected DNA and RNA bases have also been calculated with the binary-encounter-Bethe model from the ionization threshold up to 5000 eV. Cross sections within the investigated energy range, can be related to the molecular symmetry, the number of target electrons and molecular size; elastic and ionization processes are most efficient for guanine and adenine molecules, while the lowest cross sections were obtained for the uracil molecule. The ionization cross sections for cytosine, thymine, adenine and guanine are compared with those recently obtained with a semi-classical and binary-encounter-Bethe formalisms. No theoretical and experimental data for elastic electron scattering from DNA and RNA bases are available, but comparisons with calculations for molecules of similar size and geometry allows the validity of the theoretical approach to be verified.     

Detection of 5-methylcytosine in DNA sequences.

Col E1 DNA has methylated cytosine in the sequence 5'-CC*(A/T)GG-3' and methylated adenine in the sequence 5'-GA*TC-3' at the positions indicated by asterisks(*). When the Maxam-Gilbert DNA sequencing method is applied to this DNA, the methylated cytosine (5-methylcytosine) is found to be less reactive to hydrazine than are cytosine and thymine, so that a band corresponding to that base does not appear in the pyrimidine cleavage patterns. The existence of the methylated cytosine can be confirmed by analyzing the complementary strand or unmethylated DNA. In contrast, the methylated adenine (probably N6-methyladenine) cannot be distinguished from adenine with standard conditions for cleavage at adenine.     

Purine metabolism in human lymphocytes.

In peripheral human blood lymphocytes the uptake and metabolism of adenine, guanine, and hypoxanthine was investigated. This was achieved by incubation of purified lymphocytes with 14C-purine bases, separation of cells from the incubation medium by a rapid filtration technique, and subsequent separation of the acid soluble material by thin-layer chromatography. No perferential uptake for one of the purine bases was observed. In all cases only traces of 14C-purine bases not added originally and labeled nucleosides could be demonstrated. Approximately 2/3 of adenine and 1/2 of guanine or hypoxanthine were converted to nucleotides. Separation of formed nucleotides showed that adenine and guanine were metabolized mainly to their corresponding nucleotides; hypoxanthine was converted to a considerable amount to adenine nucleotides and only to a small proportion into its own nucleotides. These results demonstrate the predomonance of adenine nucleotide formation in normal human lymphocytes.     

The RNA i-Motif in the Primordial RNA World

The primordial RNA world is a hypothetical era prior to the appearance of protein and DNA, when RNA molecules were the sole building blocks for early forms of life on Earth. A critical concern with the RNA-world hypothesis is the instability of the cytosine nucleobase compared to the other three bases (adenine, guanine, and uracil). The author proposes that cytosine residues could have stably existed in the primordial world in the RNA i-motif, a four-stranded quadruplex structure formed by base-pairing of protonated and unprotonated cytosine residues under acidic conditions. The i-motif structure not only increases the lifetime of cytosine residues by slowing their deamination rate, but could also allow RNA polymers to bind to certain ligands (e.g., anions) to perform critical functions. Future studies focused on determining the rate of cytosine deamination in RNA i-motifs over a range of pH, temperature, and pressure conditions, and on interrogating the interactions between ligands and RNA i-motifs, could uncover new evidence of the origin of life on Earth.