超氧自由基与嘧啶碱基及其核苷反应的ESR研究

用自旋捕集技术和ＥＳＲ方法,以ＭＮＰ为捕集剂,研究了紫外线辐照核黄素产生超氧自由基等活性氧与嘧啶碱基及其核苷的反应,确定了尿嘧啶,胞嘧啶和胸腺嘧啶及其核苷所产生的自旋加合物自由基的类别,讨论了自由基的形成机制,揭示了超氧自由基与嘧啶碱基及其核苷的反应是不是直接进行的,而是通过羟基自由基来实现的。     

SYNTHESIS AND BIOLOGICAL ACTIVITY OF 2′-DEOXY-4′-THIO-PYRAZOLO[3,4-d]PYRIMIDINE NUCLEOSIDES

The coupling of 4-aminopyrazolo [3, 4-d]pyrimidine with the appropriate thio sugar gave a 3:1 ratio of α,β blocked 4-amino-1-(2-deoxy-4-thio-D-erythropentofuranosyl)- 1H pyrazolo[3,4-d]pyrimidine nucleosides. The mixture was deblocked, both the anomers were separated, and the β-anomer was readily deaminated by adenosine deaminase. The nucleosides have been characterized, and their anomeric configurations have been determined by proton NMR. All three nucleosides were evaluated against a panel of human tumor cell lines for cytotoxicity in vitro. The details of a convenient and high yielding synthesis of these nucleosides are described.     

Synthesis and biological activity of 2'-deoxy-4'-thio-pyrazolo[3,4-d]pyrimidine nucleosides

The coupling of 4-aminopyrazolo [3, 4-d]pyrimidine with the appropriate thio sugar gave a 3:1 ratio of alpha,beta blocked 4-amino-1-(2-deoxy-4-thio-D-erythropentofuranosyl)-1H pyrazolo[3,4-d]pyrimidine nucleosides. The mixture was deblocked, both the anomers were separated, and the beta-anomer was readily deaminated by adenosine deaminase. The nucleosides have been characterized, and their anomeric configurations have been determined by proton NMR. All three nucleosides were evaluated against a panel of human tumor cell lines for cytotoxicity in vitro. The details of a convenient and high yielding synthesis of these nucleosides are described.     

Pyrimidine as constituent of natural biologically active compounds

This review describes the various manifestations of the pyrimidine system (alkylated, glycosylated, benzo-annelated.). These comprise pyrimidine nucleosides as well as alkaloids and antibiotics--some of them have been discovered and isolated from natural sources already long time ago, others have been reported very recently. A short overview on pyrimidine syntheses (prebiotic synthesis, biosynthesis, and metabolism) is given. The biological activities of most of the pyrimidine analogs are briefly described, and, in some cases, syntheses are formulated.     

Nucleoside transport systems in Escherichia coli K12: Specificty and regulation

Two nucleoside transport systems have been verified and separated by mating and recombination experiments. The recipient strain was a mutant which is negative for transport of all nucleosides. The two systems differ in specificity and in regulation. One system transports pyrimidine and adenine in specificity and in regulation. One system transports pyrimidine and adenine nucleosides, but not guanine nucleosides. It is regulated by the cytR gene. The other system transports all nucleosides and is regulated by the cytR as well as by the deoR genes. Enzyme assays performed on whole cells of strains, able or unable to transport nucleosides, indicate that the nucleoside catabolizing enzymes are located inside the permeability barrier of the cell.     

Docking simulation with a purine nucleoside specific homology model of deoxycytidine kinase, a target enzyme for anticancer and antiviral therapy

5'-Phosphorylation, catalyzed by human deoxycytidine kinase (dCK), is a crucial step in the metabolic activation of anticancer and antiviral nucleoside antimetabolites, such as cytarabine (AraC), gemcitabine, cladribine (CdA), and lamivudine. Recently, crystal structures of dCK (dCKc) with various pyrimidine nucleosides as substrates have been reported. However, there is no crystal structure of dCK with a bound purine nucleoside, although purines are good substrates for dCK. We have developed a model of dCK (dCKm) specific for purine nucleosides based on the crystal structure of purine nucleoside bound deoxyguanosine kinase (dGKc) as the template. dCKm is essential for computer aided molecular design (CAMD) of novel anticancer and antiviral drugs that are based on purine nucleosides since these did not bind to dCKc in our docking experiments. The active site of dCKm was larger than that of dCKc and the amino acid (aa) residues of dCKm and dCKc, in particular Y86, Q97, D133, R104, R128, and E197, were not in identical positions. Comparative docking simulations of deoxycytidine (dC), cytidine (Cyd), AraC, CdA, deoxyadenosine (dA), and deoxyguanosine (dG) with dCKm and dCKc were carried out using the FlexX docking program. Only dC (pyrimidine nucleoside) docked into the active site of dCKc but not the purine nucleosides dG and dA. As expected, the active site of dCKm appeared to be more adapted to bind purine nucleosides than the pyrimidine nucleosides. While water molecules were essential for docking experiments using dCKc, the absence of water molecules in dCKm did not affect the ability to correctly dock various purine nucleosides.     

Evidence for separate carriers for purine nucleosides and for pyrimidine nucleosides in the renal brush border membrane.

The aim of the present study was to test if the transport of all nucleosides in rat renal brush border membranes occurs via a common carrier or if specific carriers exist for various groups of nucleosides. We measured the inward transport of radiolabeled nucleosides into brush border vesicles. The effect of unlabeled nucleosides present inside of the vesicles (trans-stimulation) or outside of the vesicles (cis-inhibition) was studied. Uphill influx of a nucleoside into the vesicles could be driven by the efflux of another nucleoside (trans-stimulation) if they were both purines or both pyrimidines but not if one nucleoside was a purine and the other one a pyrimidine. Thus, there exist a carrier that transports various purine nucleosides, and a carrier that transports various pyrimidine nucleosides, but the tested purine nucleosides and the tested pyrimidine nucleosides do not appear to be transported by the same carrier. Uridine and thymidine were similarly potent for the inhibition of cytidine transport whereas uridine was much more potent than thymidine for the inhibition of adenosine transport. This suggests that cytidine and adenosine can use different carriers. Preincubation of the vesicles with N-ethylmaleimide resulted in a marked decrease of the rate of transport of purine nucleosides but it had little effect on the transport of pyrimidine nucleosides. These data are best explained by the presence in the renal brush border membrane of two carriers, one for purine nucleosides, the other one for pyrimidine nucleosides.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolism of pyrimidine bases and nucleosides by pyrimidine-nucleoside phosphorylases in cultured human lymphoid cells

The anabolism of pyrimidine ribo- and deoxyribonucleosides from uracil and thymine was investigated in phytohemagglutinin-stimulated human peripheral blood lymphocytes and in a Burkitt's lymphoma-derived cell line (Raji). We studied the ability of these cells to synthesize pyrimidine nucleosides by ribo- and deoxyribosyl transfer between pyrimidine bases or nucleosides and the purine nucleosides inosine and deoxyinosine as donors of ribose 1-phosphate and deoxyribose 1-phosphate, respectively: these reactions involve the activities of purine-nucleoside phosphorylase, and of the two pyrimidine-nucleoside phosphorylases (uridine phosphorylase and thymidine phosphorylase). The ability of the cells to synthesize uridine was estimated from their ability to grow on uridine precursors in the presence of an inhibitor of pyrimidine de novo synthesis (pyrazofurin). Their ability to synthesize thymidine and deoxyuridine was estimated from the inhibition of the incorporation of radiolabelled thymidine in cells cultured in the presence of unlabelled precursors. In addition to these studies on intact cells, we determined the activities of purine- and pyrimidine-nucleoside phosphorylases in cell extracts. Our results show that Raji cells efficiently metabolize preformed uridine, deoxyuridine and thymidine, are unable to salvage pyrimidine bases, and possess a low uridine phosphorylase activity and markedly decreased (about 1% of peripheral blood lymphocytes) thymidine phosphorylase activity. Lymphocytes have higher pyrimidine-nucleoside phosphorylases activities, they can synthesize deoxyuridine and thymidine from bases, but at high an non-physiological concentrations of precursors. Neither type of cell is able to salvage uracil into uridine. These results suggest that pyrimidine-nucleoside phosphorylases have a catabolic, rather than an anabolic, role in human lymphoid cells. The facts that, compared to peripheral blood lymphocytes, lymphoblasts possess decreased pyrimidine-nucleoside phosphorylases activities, and, on the other hand, more efficiently salvage pyrimidine nucleosides, are consistent with a greater need of these rapidly proliferating cells for pyrimidine nucleotides.     

Formation of l-Butyl-5-hydroxy-methylpyrrole-2-carboxaldehyde in the Maillard Reaction between Lactose and n-Butylamine

A new mutant Shm^r-001-1 has been isolated by treating showdomycin-resistant mutant Shm^r-001 cells with N-methyl-N′-nitro-N-nitrosoguanidine. This mutant was resistant to high level of showdomycin, and took up practically no showdomycin and little pyrimidine nucleosides, and it showed different ability to take up purine nucleosides. Strains Shm^r-001–1, Shm^r-001, and K–12 (wild type) were compared: in susceptibility to showdomycin, in ability to take up the antibiotic and various nucleosides, on effects of other nucleosides on entry of particular nucleosides, and on kinetics of the entry of nucleosides and showdomycin. From these experiments, at least three different nucleoside transport systems were observed in Escherichia coli K–12 cells: the first system was common to adenine nucleosides, pyrimidine nucleosides, and showdomycin; the second system was common to adenine nucleosides, guanine nucleosides, inosine, pyrimidine nucleosides, and showdomycin; and the third system was common to adenine nucleosides, guanine nucleosides, and inosine. The first system was not observable in Shm^r-001 cells. In Shm^r-001–1 cells both the first and the second systems were no longer detectable but the third system was found to be active.     

Synthesis and in vitro evaluation of novel anti-varicella-zoster virus (VZV) nucleosides

A series of alkyl-aryl, -phenoxy, and -thiophenoxy bicyclic furo pyrimidine nucleosides have been successfully synthesised by Pd-coupling of 5-iodo-2'-deoxyuridine (IDU) with terminal alkynes, followed by in situ copper-cyclisation. Synthesised compounds (4a-i) showed an anti-VZV activity at low microM concentration, comparable to that of current treatment acyclovir.     

Enthalpic and entropic determinants for the specificity of alkylation of the histidine-12 residue of ribonuclease A by four bromoacetamido nucleoside affinity labels and bromoacetamide

The binding and alkylation rate constants for the reaction of four bromoacetamido pyrimidine nucleosides and bromoacetamide with bovine pancreatic ribonuclease A (RNase A) have been determined as a function of temperature. The four nucleoside derivatives react exclusively or preferentially with the NE2 atom of histidine-12 and include 2'-bromoacetamido-2'-deoxyuridine, 2'-bromoacetamido-2'deoxyxylofuranosyluracil, 3'-bromoacetamido-3'-deoxythymidine and 3'-bromoacetamido-3'-deoxyarabinofuranosyluracil. Transition-state parameters, delta H++ and delta S++, reveal that nucleosides with "up" OH groups experience relative rate enhancements which have been attributed to contacts between these groups and the enzyme in the transition state (1). Variations in alkylation rates are explained in terms of different degrees of entropic destabilization (2) of the nucleosides in the enzyme.affinity label complex.     

The metabolism of pyrimidine compounds by Tetrahymena pyriformis

The pyrimidine requirements for growth of T. pyriformis and for reversal of the growth inhibition caused by folate deprivation have been studied. The effects of thymidine and 5-fluorodeoxyuridine have been shown to be quantitatively different from the effects of these compounds on growth and the rate of DNA synthesis in mammalian cells. Labelled nucleosides added to the medium have been found to be converted to the corresponding bases with the exception of deoxycytidine, which is first deaminated to deoxyuridine. As a result no deoxynucleosides other than thymidine specifically label DNA. The results allow deductions to be made concerning the enzymes involved in pyrimidine utilization by this organism. It is suggested that pyrimidine utilization is always channeled through uracil in the case of those compounds that can supply the pyrimidine requirement for growth.     

Salvage of circulating pyrimidine nucleosides by tissues of the mouse

The metabolism of pyrimidine nucleosides present in the plasma of the mouse has been examined. Uridine and cytidine are rapidly cleared from the circulation with t1/2 of less than 5 min. Uracil, deoxycytidine, deoxyuridine, and thymidine are cleared more slowly with t1/2 of 9 to 13 min. Various tissues differed markedly in the extent of nucleotide formation from circulating nucleosides. Cytidine and uridine are predominantly converted to nucleotides (greater than 50%) rather than catabolized, whereas uracil is almost entirely degraded. Thymidine, deoxyuridine, and deoxycytidine are intermediate in the extent of their conversion to nucleotides: 8.9 to 21% of these nucleosides are salvaged in the mouse. Both anabolic and catabolic routes are important in the metabolism of pyrimidine nucleosides in vivo.     

5-Fluoropyrimidine-resistant mutants of pneumococcus

Three classes of 5-fluorpyrimidine-resistant mutants of Diplococcus pneumoniae have been characterized. The mutant strain upp is resistant to high concentrations of the fluoropyrimidine bases fluorouracil (FU) and fluorocytosine (FC); strain upp has a defective uridine monophosphate pyrophosphorylase. The mutant strain udk is resistant to inhibition by fluorouridine (FUR) and exhibits defective uridine kinase activity. The mutant strain fun is resistant to inhibition by the nucleosides fluorodeoxyuridine, fluorodeoxycytidine, and FUR, but shows normal activity for all pyrimidine pathway enzymes tested. This strain may be defective in the activity of a transport system that governs the cellular uptake of pyrimidine ribo- and deoxyribonucleosides. Biochemical studies on wild-type and fluoropyrimidine-resistant pneumococci are discussed with respect to the transport and early metabolism of preformed pyrimidine precursors by this organism.     

Sodium-dependent nucleoside transport in choroid plexus from rabbit. Evidence for a single transporter for purine and pyrimidine nucleosides.

The overall goal of this study was to determine the mechanisms by which nucleosides are transported in choroid plexus. Choroid plexus tissue slices obtained from rabbit brain were depleted of ATP with 2,4-dinitrophenol. Uridine and thymidine accumulated in the slices against a concentration gradient in the presence of an inwardly directed Na+ gradient. The Na(+)-driven uptake of uridine and thymidine was saturable with Km values of 18.1 +/- 2.0 and 13.0 +/- 2.3 microM and Vmax values of 5.5 +/- 0.3 and 1.0 +/- 0.2 nmol/g/s, respectively. Na(+)-driven uridine uptake was inhibited by naturally occurring ribo- and deoxyribonucleosides (adenosine, cytidine, and thymidine) but not by synthetic nucleoside analogs (dideoxyadenosine, dideoxycytidine, cytidine arabinoside, and 3'-azidothymidine). Both purine (guanosine, inosine, formycin B) and pyrimidine nucleosides (uridine and cytidine) were potent inhibitors of Na(+)-thymidine transport with IC50 values ranging between 5 and 23 microM. Formycin B competitively inhibited Na(+)-thymidine uptake and thymidine trans-stimulated formycin B uptake. These data suggest that both purine and pyrimidine nucleosides are substrates of the same system. The stoichiometric coupling ratios between Na+ and the nucleosides, guanosine, uridine, and thymidine, were 1.87 +/- 0.10, 1.99 +/- 0.35, and 2.07 +/- 0.09, respectively. The system differs from Na(+)-nucleoside co-transport systems in other tissues which are generally selective for either purine or pyrimidine nucleosides and which have stoichiometric ratios of 1. This study represents the first direct demonstration of a unique Na(+)-nucleoside co-transport system in choroid plexus.     

Pyrimidine metabolism in Tritrichomonas foetus

The pyrimidine metabolism of Tritrichomonas foetus (KV 1) was studied using whole cells and cell homogenates. Pyrimidines and pyrimidine nucleosides were readily incorporated into nucleic acids. Orotate and aspartate were not incorporated into pyrimidine bases. Enzymes of the pyrimidine salvage pathway (i.e., thymidine and uridine phosphorylases and uridine kinase) were detected in trophozoite homogenates, but the activities of de novo pyrimidine synthesis enzymes (i.e., carbamoylphosphate synthase, aspartate transcarbamoylase, dihydroorotase and dihydroorotate dehydrogenase) were below the level of detection in these same homogenates. The evidence presented supports the proposal that T. foetus is incapable of synthesizing pyrimidines de novo but is capable of salvaging preformed pyrimidines and pyrimidine nucleosides from the growth medium and that enzymes of this parasite's pyrimidine salvage pathway are not organelle-associated.     

Brain nucleoside recycling

The rate limiting reactions of nucleotide synthesis are modulated by intracellular fluctuations of nucleoside triphosphate concentrations. This topic has been mostly studied at the level of the de novo nucleotide synthesis from simple precursors. However, there are districts, such as brain, which rely more heavily on the salvage of preformed purine and pyrimidine rings, mainly in the form of nucleosides. This raises the following question: how do these districts maintain the right balance between the purine and pyrimidine pools? We believe that it is now safe to state that a cross talk exists between the extra- and intracellular metabolism of purine and pyrimidine nucleosides in the brain. The extracellular space is the major site of nucleoside generation through successive dephosphorylations of released triphosphates, whereas brain cytosol is the major site of multiple phosphorylations of uptaken nucleosides at their 5′-position. Modulation of both extracellular nucleoside generation by membrane bound ectonucleotidases, and intracellular nucleoside phosphorylation by cytosolic kinases might contribute to maintain the right extra- and intracellular purine and pyrimidine nucleotide balance in the brain.     

The effect of various concentrations of nucleobases, nucleosides or glutamine on the incorporation of [3H]thymidine into DNA in rat mesenteric-lymph-node lymphocytes stimulated by phytohaemagglutinin.

1. The rate of [3H]thymidine incorporation into DNA was measured in phytohaemagglutinin-stimulated lymph-node lymphocytes of the rat. 2. Addition of nucleobases or nucleosides to culture medium that already contained 0.2 mM-glutamine had a small stimulatory effect on incorporation. At lower concentrations of glutamine, adenosine (even at 1 microM) caused a marked increase in the rate of incorporation. 3. In the absence of added glutamine, addition of nucleosides or nucleobases markedly increased the rate of incorporation: nucleosides were more effective than nucleobases; and the rate of proliferation in the presence of 10 microM-adenosine plus 10 microM-uridine was similar to that in the presence of optimal concentrations of glutamine. 4. The rate of incorporation was dramatically decreased by an inhibitor of the pathway of pyrimidine nucleotide synthesis de novo. Addition of the pyrimidine nucleosides completely overcame the inhibition; addition of the pyrimidine nucleobases was much less effective. 5. These results indicate that, for proliferation of lymphocytes, glutamine is not essential and can be partially or totally replaced by nucleosides and, to some extent, by nucleobases.     

Demonstration of pyrimidine nucleoside phosphorylases in breast cancer

Two pyrimidine phosphorylase activities have been isolated from the cytosol of cultivated MCF-7 cells of a human breast cancer, by ion exchange chromatography. Both enzymes are responsible for the cleavage of thymidine into thymine and deoxyribose-1-phosphate, for the synthesis of thymidine and for the transfer of deoxyribose from d-uridine to thymine. These activities are likely to participate in the regulation of the pool of pyrimidine nucleosides required for DNA synthesis.