In vitro effects of thyroid hormones on ectonucleotidase activities in synaptosomes from hippocampus of rats

1. Studies have shown that adenosine transport and adenosine A1 receptors in rat brain are subjected to regulation by thyroid hormone levels. Since the ectonucleotidase pathway is an important source of adenosine extracellular, in the present study the in vitro action of T3 and T4 hormones on ectonucleotidase activities in hippocampal synaptosomes was evaluated.2. T3 (Triiodo-l-thyronine) significantly inhibited, in an uncompetitive manner, the ATP and ADP hydrolysis promoted by ATP diphosphohydrolase activity in hippocampal synaptosomes of adult rats.3. In contrast, T4 (Thyroxine) only inhibited ATP hydrolysis in an uncompetitive mechanism, at the concentrations tested (100–500 M), but at the same time did not affect ADP hydrolysis.4. In the present study, we also investigate the in vitro effect of T3 and T4 on 5-nucleotidase activity. However, there are no changes in the activity of this enzyme in the presence of T3 and T4 in the hippocampal synaptosomes of rats.5. These results suggest that thyroid hormones could be involved in the regulation of ectonucleotidase activities, such as ecto-ATP diphosphohydrolase and ecto-ATPase, possibly exerting a modulatory role in extracellular adenosine levels.     

Acute Caffeine Treatment Increases Extracellular Nucleotide Hydrolysis from Rat Striatal and Hippocampal Synaptosomes

The psychostimulant caffeine promotes behavioral effects such as hyperlocomotion, anxiety, and disruption of sleep by blockade of adenosine receptors. The availability of extracellular adenosine depends on its release by transporters or by the extracellular ATP catabolism performed by the ecto-nucleotidase pathway. This study verified the effect of caffeine on NTP-Dase 1 (ATP diphosphohydrolase) and 5-nucleotidase of synaptosomes from hippocampus and striatum of rats. Caffeine and theophylline tested in vitro were unable to modify nucleotide hydrolysis. Caffeine chronically administered in the drinking water at 0.3 g/L or 1 g/L for 14 days failed to affect nucleotide hydrolysis. However, acute administration of caffeine (30 mg/kg, ip) produced an enhancement of ATP (50%) and ADP (32%) hydrolysis in synaptosomes of hippocampus and striatum, respectively. This activation of ATP and ADP hydrolysis after acute treatment suggests a compensatory effect to increase adenosine levels and counteract the antagonist action of caffeine.     

Regulation of the Ecto-Nucleotidase Pathway in Rat Hippocampal Nerve Terminals

Ecto-nucleotidases play a pivotal role in terminating the signalling via ATP and in producing adenosine, a neuromodulator in the nervous system. We have now investigated the pattern of adenosine formation with different concentrations of extracellular ATP in rat hippocampal nerve terminals. It was found that adenosine formation is delayed with increasing concentrations of ATP. Also, the rate of adenosine formation increased sharply when the extracellular concentrations of ATP + ADP decrease below 5 M, indicating that ATP/ADP feed-forwardly inhibit ecto-5-nucleotidase allowing a burst-like formation of adenosine possibly designed to activate facilitatory A_2A receptors. Initial rate measurements of ecto-5-nucleotidase in hippocampal nerve terminals, using IMP as substrate, showed that ATP and ADP are competitive inhibitors (apparent K_i of 14 and 4 M). In contrast, in hippocampal immunopurified cholinergic nerve terminals, a burst-like formation of adenosine is not apparent, suggesting that channelling processes may overcome the feed-forward inhibition of ecto-5-nucleotidase, thus favouring A₁ receptor activation.     

Effect of Melatonin on the Intensity of Adenosine Production in the Rat Forebrain under Conditions of Acute Hypoxia and Varied Photoperiodicity

We studied the effect of injections of melatonin and modifications of the duration of illumination on the activity of 5-nucleotidase, an enzyme providing synthesis of adenosine, in the forebrain of juvenile male albino rats. The measurements were performed under conditions of acute hypobaric hypoxia. We found that, under conditions of natural illumination, neither isolated injections of melatonin nor acute hypoxia noticeably changed the activity of 5-nucleotidase. At the same time, acute hypoxia combined with melatonin injections increased the activity of this enzyme. A similar noticeable rise in the activity of 5-nucleotidase was observed after melatonin injections in normoxic animals kept in constant darkness, and in rats subjected to hypoxia without the above injections but under conditions of constant illumination. These data allow us to suppose that melatonin (whose level in the extracellular medium is a factor providing synchronization of endogenous temporal rhythms) stimulates 5-nucleotidase-mediated production of adenosine in brain neurons. Acute hypoxia promotes such an effect of melatonin.     

Localization of 5′-nucleotidase in bovine brain myelin fraction and myelin subfractions

Purified myelin from fresh calf brain white matter was subfractionated in a discontinuous sucrose gradient; significant recovery of protein and 2,3-cyclic nucleotide 3-phosphohydrolase (CNP) and 5-nucleotidase (5N) activities occurred in all three obtained subfractions, the highest recovery being in the light subfraction; highest 5N and CNP specific activities were in medium myelin. Purified myelin was also subfractionated in a continuous sucrose gradient, with a similar localization of protein; CNP activity and 5N activity maxima suggest that myelin may be a predominant locus of 5N in bovine brain white matter. Freezing of brain white matter caused an increase in protein and in CNP and 5N total activity recoveries in denser myelin subfractions. Cytochemistry showed the reaction product of 5N in the whole myelin fraction to be associated with the innermost, outermost and medial compact myelin layers. Effects of non-ionic detergent (Lubrol WX) on 5N activity were studied, and the results also suggest the intrinsic nature of 5N as an ectoenzyme in myelin membranes. Lubrol WX was viewed as an advisable detergent for the stimulation of myelin 5N activity, but not for the solubilization of this enzyme.     

Isolation and characterization of bovine brain myelin distribution of 5′-nucleotidase

Myelin was isolated from bovine brain by several published procedures and modifications of these procedures. High activity of the myelin marker (2,3-cyclic nucleotide 3-phosphohydrolase) and low activity of contaminants markers in white matter homogenates in respect to cerebral cortex showed the white matter to be better than the cerebral cortex or the whole brain for myelin isolation. A procedure is described for the preparation of purified myelin from bovine white matter which yielded a content of protein (40%), myelin marker (51%), and 5-nucleotidase (25%) in purified myelin higher than by any used method. Acetylcholinesterase or succinate dehydrogenase was lower than 7% of its activity in the white matter homogenate, and monoamine oxidase and NADPH: cytochrome c reductase were not recovered in myelin fraction. Morphologically, myelin fraction was shown to mainly consist of multilamellar membranes of different sizes. Sodium dodecyl sulphate polyacrylamide gel electrophoresis of myelin fraction showed a characteristic protein pattern of myelin. When our procedure was applied to frozen white matter, lower protein (32%) and myelin marker (34%) and similar 5-nucleotidase activity (24%) were recovered in myelin, increasing its recovery in denser fractions of white matter.     

Distribution of 5′-nucleotidase in the renal interstitium of the rat

Summary The hydrolysis of 5-AMP by 5-nucleotidase is the main source of adenosine. In various tissues adenosine is a local mediator adjusting the organ work to the available energy. In the kidney it regulates renal hemodynamics, glomerular filtration rate and renin release via specific receptors of the arteriolar walls. By immunocytochemistry we identified interstitial and tubular sites of 5-nucleotidase in the rat kidney. In the interstitium the enzyme was detected only in the cortical labyrinth, the compartment that comprises all arteriolar vessels besides other putative targets of adenosine. The 5-nucleotidase-positive cells of the interstitium were identified as fibroblasts. The fibroblasts are in close contact with the tubules as well as with the vessels. Thus, any 5-AMP released by the tubules into the interstitial space would be converted to adenosine in the direct vicinity of its assumed targets. Adenosine produced by tubular cells would hardly have access to its known targets, since 5-nucleotidase is restricted to the luminal cell surface. Pathological events affecting the fibroblasts might influence renal function by modifying the interstitial adenosine production.     

5′-Nucleotidase and adenosine deaminase in developing fetal guinea pig brain and the effect of maternal hypoxia

The activity of key enzymes of adenosine metabolism was studied in the developing fetal guinea pig brain. The activities of 5-nucleotidase and adenosine deaminase were determined in the brains of fetal guinea pigs at 30, 35, 40, 45, 50, 55, and 60 days of gestation. The level of 5-nucleotidase activity was extremely low at 30 and 35 days of gestation but increased rapidly during the 40 to 60 day period. The enzyme activity increased in the presence of Mg²⁺ with the Mg²⁺-dependent activation increasing with the age of gestation. This Mg²⁺-dependent activity was primarily associated with the membrane fraction. Prenatal hypoxia significantly increased the fetal brain M²⁺-independent 5-nucleotidase activity at 45 days of gestational age and beyond. Prior to this age, no effect was evident. Furthermore, following hypoxia, the Mg²⁺-dependent activation of 5-nucleotidase activity was lost. The activity of adenosine deaminase was present at 30 days of gestation and, unlike 5-nucleotidase, it remained at the same level until 60 days. The results indicate that the term fetal guinea pig brain has the enzymatic mechanisms of adenosine metabolism and thus the potential for adenosine-mediated regulation of cerebrovasculature during hypoxia.     

Adenine nucleotide metabolism in Azotobacter vinelandii. Two metabolic pathways of AMP degradation

AMP-degrading pathways in Azotobacter vinelandii cells were investigated. AMP nucleosidase (EC 3.2.2.4) was rapidly synthesized and reached a maximum at 24 h, while the activity of 5-nucleotidase (EC 3.1.3.5) specific for AMP, which was negligible during the logarithmic phase of the growth, first appeared in 24 h-cultures, and reached a maximum after complete exhaustion of sucrose from the growth medium (70 h).Cell-free extracts of A. vinelandii of 48 h-cultures hydrolyzed AMP to ribose 5-phosphate and adenine in the presence of ATP, and adenine was deaminated to hypoxanthine. When ATP was excluded, AMP was dephosphorylated to adenosine, which was further metabolized to inosine, and finally to hypoxanthine. Hypoxanthine thus formed was reutilized for the salvage synthesis of IMP under the conditions where 5-phosphoribosyl 1-pyrophosphate was able to be supplied. These results suggest that the levels of ATP can determine the rate of AMP degradation by the AMP nucleosidase- and 5-nucleotidase-pathways. The role of ATP in the AMP degradation was discussed in relation to the regulatory properties of AMP nucleosidase, inosine nucleosidase (EC 3.2.2.2) and adenosine deaminase (EC 3.5.4.4).     

Preparation of 5′-GMP-rich yeast extracts from spent brewer's yeast

Spent brewer's yeast was autolysed and used as a raw material for the preparation of 5-GMP-rich yeast extracts. Malt rootlets were used as a source of 5-phosphodiesterase. The crude enzyme was extracted from malt rootlets and pretreated to inactivate 5-nucleotidase. The optimum pretreatment conditions were heating at 65 °C for 30 min or 70 °C for 7 min. The effects of autolysis time, phosphodiesterase concentration and incubation period on 5-GMP content were examined. The suitable autolysis time was 8 h. The preferable enzyme treatment period was in the range of 8–14 h. Longer autolysis and enzyme incubation periods caused a decrease in the 5-GMP content from 0.7–0.9% (w/w) to 0.2–0.4% (w/w). The 5-GMP content in extracts from debittered and non-debittered yeast was similar. The highest 5-GMP content in yeast extract was 0.93% (w/w), obtained with a phosphodiesterase concentration of 1.6unit/ml of yeast extract (5% solids content).     

Oxidative Inactivation of Brain Ecto-5′-Nucleotidase by Thiols/Fe2+ System

5-Nucleotidase, responsible for the conversion of adenosine-5-monophosphate into adenosine, was purified from bovine brain membranes, and subjected to oxidative inactivation. The 5-nucleotidase activity decreased slightly after the exposure to either glutathione or Fe²⁺. The glutathione-mediated inactivation of 5-nucleotidase was potentiated remarkably by Fe²⁺, but not Cu²⁺, in a concentration-dependent manner. Similarly, glutathione exhibited a concentration-dependent enhancement of the Fe²⁺-mediated inactivation. In comparison, the glutathione/Fe²⁺ system was much more effective than the ascorbate/Fe²⁺ system in inactivating the enzyme. In support of an intermediary role of superoxide ions or H₂O₂ in the action of glutathione/Fe²⁺ system, superoxide dismutase and catalase expressed a substantial protection against the inactivation by the glutathione/Fe²⁺ system. Meanwhile, hydroxyl radical scavangers such as mannitol, benzoate or ethanol were incapable of preventing the inactivation, excluding the participation of extraneous hydroxyl radicals. Whereas adenosine 5-monophosphate as substrate exhibited a modest protection against the glutathione/Fe²⁺ action, a remarkable protection was expressed by divalent metal ions such as Zn²⁺ or Mn²⁺. Structure-activity study with a variety of thiols indicates that the inactivating action of thiols in combination with Fe²⁺ resides in the free sulfhydyl group and amino group of thiols. Overall, thiols, expressing more inhibitory effect on the activity of 5-nucleotidase, were found to be more effective in potentiating the Fe²⁺- mediated inactivation. Further, kinetic analyses indicate that Fe²⁺ and thiols inhibit the 5-nucleotidase in a competitive or uncompetitive manner, respectively. These results suggest that ecto-5-nucleotidase from brain membrane is one of proteins susceptible to thiols/ Fe²⁺-catalyzed oxidation, and the oxidative inactivation may be related to the selective association of Fe²⁺ and thiols to the enzyme molecule.     

5′-Nucleotidase in PC12 cells as revealed by immunocytochemistry

5-Nucleotidase hydrolyzes 5-mononucleotides to their nucleosides but is also thought to have a function in neuronal differentiation and synapse formation. The distribution of the enzyme, a glycosyl-phosphatidylinositol-anchored sialoglycoprotein, was investigated in PC12 cells using immunofluorescence microscopy. 5-Nucleotidase was located both in intracellular compartments and at the cell surface. There was no principal difference in the cellular distribution between undifferentiated cells and after neuritogenic differentiation by nerve growth factor. Intracellularly, 5-nucleotidase often revealed a sickle-shaped perinuclear distribution and a dotted pattern throughout the cytoplasm, including that of neurites and growth cones. The intracellular distribution was clearly different from that of the synaptic vesicle protein synaptophysin. However, the dotted fluorescence resembled that obtained after uptake of the endosomal marker acridine orange. 5-Nucleotidase was present on the entire cell surface including all neurites formed after differentiation. There was no increase in 5-nucleotidase fluorescence at synapse-like contacts between the tips of neurites and other PC12 cells. Surfacelocated 5-nucleotidase could no longer be detected after the application of glycosyl-phosphatidylinositol-specific phospholipase C to cultured cells. This treatment did not affect PC12 cell differentiation. Our results thus reveal 5-nucleotidase both at the surface and within organelles and suggest that PC12 cells may be used as a model system for the study of the physiological function of 5-nucleotidase in neural cells.     

Purification and properties of the ATP: adenylylsulphate 3′-phosphotransferase from Chlamydomonas reinhardii

APS-kinase (ATP: adenylylsulphate 3-phosphotransferase, EC 2.7.1.25) has been purified from the alga Chlamydomonas reinhardii, strain CW 15 by means of chromatofocussing and affinity chromatography. The isolated protein showed an apparent molecular mass of 44,000 upon sodium dodecylsulphate polyacrylamide gel electrophoresis. The transfer of phosphate groups from ATP onto APS required a pH of 6.8, the presence of Mg²⁺ ions and a reducing thiol. Its catalytical activity was destroyed by sulphhydryl group inhibitors (phenyl-mercuri compounds, dithiopyridine) and alkylating reagents.The purified enzyme attained a V _max of 360 pkat under optimal reaction conditions declining to v _limit of 260 pkat in the presence of excess substrate APS. This sensitivity towards changes in substrate concentrations was parallelled by a high affinity and specificity: apparent K _m APS: 2 · 10^-6 mol · l^-1, and K _m ATP: 7 · 10^-6 mol · l^-1. The enzyme was found specific for ATP, d-ATP and CTP, while UTP, ITP and GTP showed marginal activity. The Hill coefficients suggested 4 binding sites for APS and 1 for ATP. Excessive APS resulted in a negative slope indicating 3 inhibiting sites of the substrate.Abbreviations APS Adenosine 5-phosphosulphate - dATP 2-deoxyadenosine 5-triphosphate - p-CMB p-chloromercuribenzoate - DTE dithioerythritol - DTT dithiothreitol - -MSH -mercaptoethanol - PAPS 3-phosphoadenosine 5-phosphosulphate - PAP 3-phosphoadenosine 5-phosphate - SDS sodium dodecyl sulphate This work is part of a dissertation submitted by H. G. J., Bochum 1982     

Lipid peroxidation as the mechanism of modification of brain 5′-nucleotidase activity in vitro

The effect of lipid peroxidation on the Mg²⁺-independent and Mg²⁺-dependent activity of brain cell membrane 5-nucleotidase was determined and the affinity of the active sites of Mg²⁺-dependent enzyme for 5-AMP (substrate) and Mg²⁺ (activator) was examined. Brain cell membranes were peroxidized at 37°C in the presence of 100 M ascorbate and 25 M FeCl₂ (resultant) for 10 min. The activity of 5-nucleotidase and lipid peroxidation products (thiobarbituric acid reactive substances) were determined. At 10 min, the level of lipid peroxidation products increased from 0.20±0.10 to 17.5±1.5 nmoles malonaldehyde/mg membrane protein. The activity of Mg²⁺-independent 5-nucleotidase increased from 0.201±0.020 in controls to 0.305±0.028 mol Pi/mg protein/hr in peroxidized membranes. In the presence of 10mM Mg²⁺, the activity increased by 5.8-fold in the peroxidized membrane preparation in comparison to 14-fold in control In peroxidized preparation, the affinity of active site of Mg²⁺-dependent 5-nucleotidase for 5-AMP tripled, as indicated by a significant decrease inK _m (K _m=95±2 M AMP for control;K _m=32±2 MAMP for peroxidized).V _max was significantly reduced from 3.35±0.16 in control to 1.70±.09 moles Pi/mg protein in peroxidized membranes. The affinity of the active site for Mg²⁺ significantly increased (K _m=6.17±0.37 mM Mg²⁺ for control;K _m=4.0±0.31 peroxidized). The data demonstrate that lipid peroxidation modifies the Mg²⁺-dependent 5-nucleotidase function by altering the active sites for both the substrate and the activator. The modification of the 5-nucleotidase activity and the loss of Mg²⁺-dependent activation observed in this in-vitro study are similar to the changes previously observed by us in the hypoxic brain in-vivo. This suggests that lipid peroxidation which specifically alters the active site may be the underlying mechanism of the modification of 5-nucleotidase during hypoxia.     

Cyclic nucleotide phosphodiesterase and 5′-nucleotidase: A coupled system

Evidence is presented that multiple forms of cyclic nucleotide phophodiesterase (PDE) activity chromatographically separated from the soluble fraction of bovine hypothalamus are co-eluted with multiple forms of 5-nucleotidase (5N) activity. The enzymes could not be resolved from each other by anion-exchange chromatography on DEAE-TSK; by affinity chromatography on phenyl-, blue-, concanavalin A-, 5 AMP-sepharose, cAMP-silica gel; or by gel filtration on sephacryl S-200. The catalytic activities were found to be associated with the tetrameric, dimeric, and monomeric forms of the enzymes. The molecular weights determined by gel filtration or by SDS-gel electrophoresis were 220, 114, and 57 kDa, respectively. Kinetic analysis revealed that the first-order rate constant for 5 AMP hydrolysis measured in the reactions: cAMP5AMPadenosine was 100 times higher than that in the reaction: 5AMPadenosine. Thus, functional interrelation between PDE and 5N was expressed in drastic acceleration of the consecutive reactions: cAMP 5AMPadenosine. The results confirm the conclusion about the existence of a multienzyme system involving PDE and 5N or of a single bifunctional enzyme in brain tissue.This revised version was published online in June 2005 with corrections to the author name Gurvits.     

Inverse relationship between poly (ADP-ribose) polymerase activity and 2′,5′-oligoadenylates core level in estrogen-treated immature rat

Summary The activity of poly (ADP-ribose) polymerase (ADPRP) and the content of 2,5-oligodenylates core (2,5A_n; n = 2,3 and 4) were measured in homogenates of the uterus and of the liver of immature rats immediately before (time 0) or at different times after injection of estradiol-valerate. ADPRP activity increased gradualy, starting 6 hours after estrogen injection, for about 4 days. Instead, the content of 2,5 A_n decreased by about 50% within 6 hours, and thereafter more slowly for 4 days to about 20% of starting values. Estrogen increased ADPRP activity and decreased 2,5A_n concentration also in the kidney and in the cardiac muscle of the same animals, but not in the skeletal muscle, where neither of the two parameters was affected. Injection of vehicle only (sesame oil) had no effect on ADPRP activity nor on 2,5A_n content of immature rat tissues.     

Formation of nucleoside 5′-phosphoramidates under potentially prebiological conditions

Summary Adenosine 5-phosphoramidates form when solutions containing adenosine 5-polyphosphates p_nA (n 3) or P₁, P₂-diadenosine 5-diphosphate and amines are allowed to dry out. Mg ions catalyze these reactions. We have studied systems containing ammonia, imidazole, glycine, ethylenediamine and histamine. The yields of adenosine 5-phosphoramidates range from 10–50 % based on the nucleotide. The prebiotic significance of the reactions is discussed.Abbreviations Im imidazole - hist histamine - gly glycine - en ethylenediamine - CDI 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide hydrochloride - EDTA ethylenediaminetetraacetic acid - A adenosine - P_n (n = 1, 2 ) linear polyphosphate containing n phosphate residues - p_nA adenosine 5-polyphosphate containing n phosphate residues - ADP adenosine 5-diphosphate - ATP adenosine 5-triphosphate - AppA P₁, P₂-diadenosine 5-diphosphate - gly-pA adenylyl-(5N)-glycine - ImpA adenosine 5-phosphorimidazolide - NH₂-pA adenosine 5-phosphoramidate - en-pA adenylyl-(5N)-ethylenediamine - hist (NH) - pA adenosine 5-phospho-[2-(4-imidazolyl)-ethylamide] - hist(Im)-pA adenosine 5-phospho-[4-(2-aminoethyl)-imidazolide] - enP_1,2 phosphoramidates of ethylenediamine derived from H₃PO₄ and H₄P₂O₇     

Adenosine-5′-phosphosulfate (APS) as sulfate donor for assimilatory sulfate reduction in Rhodospirillum rubrum

Crude extracts of Rhodospirillum rubrum catalyzed the formation of acid-volatile radioactivity from (³⁵S) sulfate, (³⁵S) adenosine-5-phosphosulfate, and (³⁵S) 3-phosphoadenosine-5-phosphosulfate. An enzyme fraction similar to APS-sulfotransferases from plant sources was purified 228-fold from Rhodospirillum rubrum. It is suggested here that this enzyme is specific for adenosine-5-phosphosulfate, because the purified enzyme fraction metabolized adenosine-5-phosphosulfate, however, only at a rate of 1/10 of that with adenosine-5-phosphosulfate. Further, the reaction with 3-phosphoadenosine-5-phosphosulfate was inhibited with 3-phosphoadenosine-5-phosphate whereas this nucleotide had no effect on the reaction with adenosine-5-phosphosulfate. For this activity with adenosine-5-phosphosulfate the name APS-sulfotransferase is suggested. This APS-sulfotransferase needs thiols for activity; good rates were obtained with either dithioerythritol or reduced glutathione; other thiols like cysteine, 2-3-dimercaptopropanol or mercaptoethanol are less effective. The electron donor methylviologen did not catalyze this reaction. The pH-optimum was about 9.0; the apparent K _m for adenosine-5-phosphosulfate was determined to be 0.05 mM with this so far purified enzyme fraction. Enzyme activity was increased with K₂SO₄ and Na₂SO₄ and was inhibited by 5-AMP. These properties are similar to assimilatory APS-sulfotransferases from spinach and Chlorella.Abbreviations APS adenosine-5-phosphosulfate - PAPS 3-phosphoadenosine-5-phosphosulfate - 5-AMP adenosine-5-monophosphate - 3-AMP adenosine-3-monophosphate - 3-5-ADP 3-phosphoadenosine-5-phosphate (PAP) - DTE dithiorythritol - GSH reduced glutathione - BAL 2-3-dimercaptopropanol     

Polymerization of nucleotide analogues I: Reaction of nucleoside 5′-phosphorimidazolides with 2′-amino-2′-deoxyuridine

Summary 2-Amino-2-deoxyuridine reacts efficiently with nucleoside 5-phosphorimidazolides in aqueous solution. The dinucleoside monophosphate analogues were obtained in yields exceeding 80% under conditions in which little reaction occurs with the natural nucleosides.In a similar way, the 5-phosphorimidazolide of 2-amino-2-deoxyuridine undergoes self-condensation in aqueous solution to give a complex mixture of oligomers.The phosphoramidate bond in the dinucleoside monophosphate analogues is stable for several days at room temperature and pH 7. The mechanisms of their hydrolysis under acidic and alkaline conditions are described.Abbreviations A adenosine - C cytidine - G guanosine - U uridine - T thymidine - U_{N 3} 2-azido-2-deoxyuridine - U_{NH 2} 2-amino-2-deoxyuridine - ImpA adenosine 5-phosphorimidazolide - ImpU uridine 5-phosphorimidazolide - ImpU_{N 3} 2-azido-2-deoxyuridine 5-phosphorimidazolide - ImpU_{NH 2} 2-amino-2-deoxyuridine 5-phosphorimidazolide - pA adenosine 5-phosphate - pU uridine 5-phosphate - pU_{N 3} 2-azido-2-deoxyuridine 5-phosphate - pU_{NH 2} 2-amino-2-deoxyuridine 5-phosphate - UpA uridylyl-[35]-adenosine - UpU uridylyl-[35]-uridine - U_NpA adenylyl-[52]-2-amino-2-deoxy-uridine - U_NpU uridylyl-[52]-2-amino-2-deoxyuridine (pU_N)_n n=2,3,4 [25]-linked oligomers of pU_{NH 2} poly(A) polyadenylic acid - Im imidazole - MeIm l-methylimidazole     

Monomers for Oligonucleotide Synthesis with Linkers Carrying Reactive Residues: II. The Synthesis of Phosphoamidites on the Basis of Uridine and Cytosine and Containing a Linker with Methoxyoxalamide Groups in Position 2′

A convenient preparative synthesis of 2-amino-2-deoxyuridine was developed. Starting from 2-amino-2-deoxyuridine and 2-amino-2-deoxycytidine, monomers for the phosphoamidite oligonucleotide synthesis were obtained that carry a linker with methoxyoxalamide groups in position 2.