Combined effect of adenosine and papaverine on the metabolism of adenine nucleotides in rat thymocytes

It is shown that in [14C]adenine-labelled thymocytes adenosine increases the content of adenine nucleotides and simultaneously accelerates their catabolism. Papaverine induces acceleration of splitting and a decrease of the specific ATP radioactivity but increases the AMP content and its specific radioactivity. The both effectors intensify considerably the outlet of total radioactive label from cells. If the papaverine effect in the extracellular medium results in accumulation mainly of hypoxanthine in the extracellular medium then the adenosine presence causes accumulation of inosine and hypoxanthine approximately in equal amounts. The release of labelled adenosine from thymocytes in all cases is an insignificant part of extracellular radioactivity. A conclusion is drawn that under conditions of the combined action of the substances under study papaverine removes the adenosine effect caused by its under study papaverine removes the adenosine effect caused by its phosphorylation with the formation of ATP and exerts the dose-depended action on adenine nucleotide metabolism in thymocytes.     

Metabolism of adenine nucleotides in thymocyte cytoplasm and subcellular fractions after treatment with concanavalin A, papaverine and adenosine

Studies with rat thymocytes labeled with [14C]adenine and fractionated by digitonin treatment revealed that the cytoplasm of these cells contains about 60% of the total adenine nucleotide pool with a higher ATP/ADP ratio and metabolic activity as compared with the structural components. The incorporation of [14C]adenine and [14C]adenosine into thymocyte adenine nucleotides results in predominant labeling of cytoplasmic ATP, in which the specific radioactivity of this nucleoside triphosphate is two and three times as high as in subcellular structures. Concanavalin A decreases the ATP level in thymocytes without changing its specific radioactivity. This compound does not influence the total content and amount labeled adenine nucleotides in the structural fraction. Papaverine accelerates the catabolism of ATP, mainly in thymocyte cytoplasm and, in a lesser degree, in its structural fraction. In each fraction the papaverine-induced catabolism of ATP is localized in the compartment which is more intensively labeled with [14C]adenine than the whole fractionation ATP pool. Adenosine markedly accelerates adenine nucleotide catabolism in the cytoplasmic and structural fractions of thymocytes; however, only in the first one of them this acceleration is due to ATP elevation. Papaverine and adenosine do not directly influence either the content or specific radioactivity of adenine nucleotides of the structural fraction isolated from [14C]adenine-labeled thymocytes.     

Characteristics of adenosine activity on adenine nucleotide metabolism of rat thymocytes

The effects of adenosine on adenine nucleotide metabolism in [14C]adenine-labeled rat thymocytes were studied. It was shown that adenosine increases the intracellular pool of adenine nucleotides, predominantly ATP, which is accompanied by marked acceleration of their catabolism and a release of labeled products (especially inosine, hypoxanthine and adenosine) from the thymocytes. The effect of adenosine depends on its concentration and manifests itself already at 10(-6) M. 2-Deoxycoformycin partly relieves the effect of adenosine on adenine nucleotide metabolism. Exogenous deoxyadenosine, inosine, hypoxanthine and adenine, unlike adenosine, do not significantly affect the adenine nucleotide catabolism and the label release from the cells. All the effectors under study strongly increase inosine transport from the thymocytes, and inhibit, with the exception of adenosine, the hypoxanthine release from the cells.     

Catabolism of adenine nucleotides in suspension-cultured plant cells

Profiles of the catabolism of adenine nucleotides in cultured plant cells were investigated. Adenine nucleotides, prelabelled by incubation of suspension-cultured Catharantus roseus cells with [8-14C]adenosine, were catabolized rapidly and most of the radioactivity appeared in 14CO2. Allantoin and allantoic acid, intermediates of the oxidative catabolic pathway of purines, were temporarily labelled. When the cells, prelabelled with [8-14C]adenosine, were incubated with high concentrations of adenosine, the rate of catabolism of adenine nucleotides increased. The results suggest that the relative rate of catabolism of adenine nucleotides is strongly dependent on the concentration of adenine nucleotides in the cells. Studies using allopurinol, coformycin and tiazofurin, inhibitors of enzymes involved in purine metabolism, suggest that participation of AMP deaminase and xanthine oxidoreductase in the catabolism of adenine nucleotides in plant cells. AMP deaminase was found in extracts from C. roseus cells and its activity increased significantly in the presence of ATP. In contrast, no adenosine deaminase or adenine deaminase activity was detected. Qualitative differences in the catabolic activity of AMP were observed between suspension-cultured cells from different species of plants.     

Metabolism of adenosine, AMP and ATP in rats

Metabolism of [14C]adenosine in a dose of 100 mg per 1 kg of mass and [14C]ATP in the equimolar quantity was studied in rats after intraperitoneal administration. Adenosine is shown to enter tissues of the liver, spleen, thymus, heart and erythrocytes where it phosphorylates into adenine nucleotides (mainly ATP) and deaminates into inosine. The content of adenosine increases for a short period in the above tissues, except for erythrocytes and plasma. The latter accumulates a considerable amount of inosine and hypoxanthine, but only traces of uric acid, xanthine and adenine nucleotides. ATP administered to rats catabolizes through the adenosine formation. The exogenic adenosine and ATP replace in tissues and erythrocytes only a slight part (1-12%) of their total adenine nucleotide pool. The content of these metabolites and ADP in the blood plasma does not change essentially under the effect of adenosine, ATP and AMP. It is shown on rats whose adenine nucleotide pool of cells is marked by the previous administration of [14C]adenine that injections of adenosine, ATP and inosine do not accelerate catabolism of adenine nucleotides in tissues and erythrocytes as well as do not increase the level of catabolism products in the blood plasma. Adenosine enhances and ATP lowers the content of cAMP in spleen and myocardium, respectively.     

Adenosine induction of rapid catabolism of adenine ribonucleotides and independent elevation of the ATP content in quiescent mouse fibroblasts

The influence of adenosine on the ribonucleotide metabolism in quiescent BALB/c 3T3 cells was studied. The cellular adenine ribonucleotides were labelled by pretreating the cells with [2-3H]-adenine. After addition of adenosine to the cell cultures, the amount and radioactivity of the cellular purine ribonucleotides and the radioactivity of the purine compounds in the medium were determined. It appeared that adenosine gave rise both to rapid catabolism of adenine ribonucleotides with inosine 5'-monophosphate (IMP) as an intermediate and to expansion of the cellular adenosine 5'-triphosphate (ATP) pool. The maximal rates and the apparent activation constants for the two processes have been determined. Experiments with varying concentrations of coformycin (an inhibitor of adenosine 5'-monophosphate [AMP] deaminase and adenosine deaminase) and of 5'-amino-5'-deoxyadenosine (an inhibitor of adenosine kinase), respectively, showed that each compound may almost completely inhibit the adenosine-induced catabolism. This effect can be obtained under conditions where there was little or no effect by the two inhibitors on the rate of expansion of the cellular ATP pool. These results may best be explained by assuming that the process of expansion of the ATP pool is independent of the induced catabolism of adenine ribonucleotides, even though both processes seem to depend on the phosphorylation of adenosine to AMP. The total increase in the pool size of ATP and of guanosine 5'-triphosphate (GTP), both caused by adenosine, seems not to have regulatory effect on adenine ribonucleotide catabolism.     

Fructose-induced adenine nucleotide catabolism in isolated rat hepatocytes

The mechanism of fructose-induced nucleotide catabolism was studied using isolated rat hepatocytes in which the adenine nucleotide pool was prelabelled with [14C]adenine. Incubation of these cells with fructose caused a rapid depletion of the adenine nucleotides and a corresponding increase in allantoin. There was no accumulation of radioactivity in adenosine in the presence or absence of the adenosine deaminase inhibitor 9-erythro-(2-hydroxy-3-nonyl)adenine. This confirms the previous hypothesis that fructose-induced adenine nucleotide catabolism occurs by way of AMP deaminase (AMP amino-hydrolase, EC 3.5.4.6).     

Purine and pyrimidine metabolism in cultured white spruce (Picea glauca) cells: Metabolic fate of 14C-labeled precursors and activity of key enzymes

In order to examine the biosynthesis, interconversion, and degradation of purine and pyrimidine nucleotides in white spruce cells, radiolabeled adenine, adenosine, inosine, uracil, uridine, and orotic acid were supplied exogenously to the cells and the overall metabolism of these compounds was monitored. [8‐¹⁴C]adenine and [8‐¹⁴C]adenosine were metabolized to adenylates and part of the adenylates were converted to guanylates and incorporated into both adenine and guanine bases of nucleic acids. A small amount of [8‐¹⁴C]inosine was converted into nucleotides and incorporated into both adenine and guanine bases of nucleic acids. High adenosine kinase and adenine phosphoribosyltransferase activities in the extract suggested that adenosine and adenine were converted to AMP by these enzymes. No adenosine nucleosidase activity was detected. Inosine was apparently converted to AMP by inosine kinase and/or a non‐specific nucleoside phosphotransferase. The radioactivity of [8‐¹⁴C]adenosine, [8‐¹⁴C]adenine, and [8‐¹⁴C]inosine was also detected in ureide, especially allantoic acid, and CO₂. Among these 3 precursors, the radioactivity from [8‐¹⁴C]inosine was predominantly incorporated into CO₂. These results suggest the operation of a conventional degradation pathway. Both [2‐¹⁴C]uracil and [2‐¹⁴C]uridine were converted to uridine nucleotides and incorporated into uracil and cytosine bases of nucleic acids. The salvage enzymes, uridine kinase and uracil phosphoribosyltransferase, were detected in white spruce extracts. [6‐¹⁴C]orotic acid, an intermediate of the de novo pyrimidine biosynthesis, was efficiently converted into uridine nucleotides and also incorporated into uracil and cytosine bases of nucleic acids. High activity of orotate phosphoribosyltransferase was observed in the extracts. A large proportion of radioactivity from [2‐¹⁴C]uracil was recovered as CO₂ and β‐ureidopropionate. Thus, a reductive pathway of uracil degradation is functional in these cells. Therefore, white spruce cells in culture demonstrate both the de novo and salvage pathways of purine and pyrimidine metabolism, as well as some degradation of the substrates into CO₂.     

Protein sequencing: thermal conversion of thiazolinone derivatives of amino acids to thiohydantoins.

A tlc method is presented for the separation on PEI-cellulose of adenine derivatives from the acid-soluble fraction of brain tissue. The procedure permits the quantitative estimation of radioactivity distributed among adenine nucleotides and the determination of ATP specific activity following labeling with [¹⁴C] adenosine. Two rapid one-dimensional separations produce excellent resolution of AMP, ADP, ATP, adenine, and adenosine from each other and from the corresponding guanosine derivatives. A two-dimensional procedure gives excellent separation of ATP from all other deoxy- and ribonucleotides. The recovery of the separated components by elution is better than 94% and requires few technical manipulations. The technique possesses the advantages of simplicity and sensitivity and is applicable to small amounts of biological material.     

Transfer of adenine nucleotides between the releasable and nonreleasable compartments of rabbit blood platelets

The metabolic pool of adenine nucleotides in platelets can be labeled by incubating platelets for 1 h in vitro with [14C]adenosine or [32P]orthophosphate. When these platelets are treated with thrombin, the adenine nucleotides released are not labeled. Because of this, Holmsen's suggestion of a metabolically inert pool of granule nucleotides has been generally accepted. We have found that upon incubation of labeled rabbit platelets for longer times (up to 6 h) in vitro, or upon reinjection and reharvesting at times up to 66 h, the releasable pool of adenine nucleotides becomes labeled. Because the rates of 32p and 14C incorporation into this releasable pool are similar, it seems likely that these labels enter the granules as ATP. Equilibrium between the metabolic and granule pools is complete by 18 h. When rabbit platelets are labeled in vivo by intravenous injection of [32P]orthophosphate, peak labeling occurs between 60 and 70 h; this corresponds to their maturation time. The platelets probably incorporate 32P during their production in the megakaryocytes. The specific radioactivity of the adenine nucleotides in the releasable (granule) pool of these platelets is the same as the specific radioactivity in the nonreleasable (metabolic) pool. Since inorganic phosphate in platelets (and undoubtedly in the megakaryocytes) exchanges with inorganic phosphate in plasma, and since the radioactivity of the latter decreases rapidly, the adenine nucleotides in the two pools must exchange to maintain the same specific radioactivity. Transfer of adenine nucleotides into storage granules may represent a general phenomenon because it has been observed in the chromaffin cells of the adrenal medulla also.     

Release of Purines, Noradrenaline, and GABA from Rat Hippocampal Slices by Field Stimulation

Labelled adenine, noradrenaline (NA), and gamma-aminobutyric acid (GABA) were taken up by the transversely cut hippocampal slice. [3H]NA and [14C]GABA were retained as such, [3H]- (or [14C]-) adenine mainly as adenine nucleotides. There was a spontaneous overflow of all three types of compounds ranging from 0.1 (GABA) to 0.21 (NA) %/min. The rate of [3H]NA overflow increased rapidly during electrical field stimulation. The release rate was well maintained over a 15-min period. The rate of [14C]GABA release also increased rapidly but it was not maintained over a 15-min period even if uptake and/or metabolism was inhibited by nipecotic acid (1 mM) and aminooxyacetic acid (AOAA, 0.1 mM). The bulk of the purines was released after the stimulation period. For all compounds the amounts released were frequency- and calcium-dependent. At a frequency of 3 Hz a 10 V stimulation was sufficient to cause a maximal [3H]NA release and 20 V to cause maximal [14C]GABA release, but 14C-purine release was increased further by increasing the voltage to 40 V. The evoked purine release was inhibited by a nucleoside uptake inhibitor (dipyridamole). On stimulation of [3H]NA-labelled slices the released radioactivity was composed of greater than 95% unchanged NA. The specific activities of NA in the slice and in the superfusate were practically identical. In [3H]adenine-labelled slices the released radioactivity was composed of adenosine, inosine, and hypoxanthine, but the activity in the slice of ATP, ADP, and AMP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Radioenzymatic determination of adenosine

Adenosine has been measured at the nanomolar level by an enzymatic radioactive assay. The nucleoside is converted into [U-14C]ribose-labeled inosine via the following reactions: adenosine + H2O----adenine + ribose (adenosine nucleosidase); adenine + [U-14C]ribose 1-phosphate in equilibrium with T[U-14C]ribose-adenosine + Pi (adenosine phosphorylase); [U-14C]ribose-adenosine + H2O----[U-14C]ribose-inosine + NH3 (adenosine deaminase). The radioactivity of inosine, separated by thin-layer chromatography, is a measure of the adenosine initially present.     

An ATP pool associated with adenyl cyclase of brain tissue

R adioactive adenine has been frequently used to label cyclic adenosine 3', 5'-monophosphate (cAMP) in diverse cells and tissues (K uo and D e R enzo , 1969; S himizu , D aly and C reveling , 1969, B rooker , 1971). We have previously reported that cAMP from the guinea-pig cerebral cortex is derived from a precursor pool of adenine nucleotides which is more highly labelled than the bulk cellular ATP (S himizu , C reveling and D aly , 1970a). The present study was carried out to throw additional light on the property of the precursor pool. Levels of cAMP and ATP and specific activities of [¹⁴C]cAMP and [¹⁴C]ATP were determined simultaneously in cerebral slices which were prelabelled with [¹⁴C]adenine and subsequently incubated with veratridine, histamine or adenosine.     

Purine reutilization in phytohemagglutinin-stimulated human T-lymphocytes.

Incubation of human peripheral blood T-lymphocytes with phytohemagglutinin (PHA) resulted in increased rates of metabolism of the purine bases adenine, hypoxanthine, and guanine. The respective rates decreased to unmeasurable levels in cells incubated without PHA. [¹⁴C]Adenine was converted predominantly into adenine nucleotides, with slight catabolism to hypoxanthine and very low conversion into guanine nucleotides. [¹⁴C]Guanine labeled predominantly the guanine nucleotide pool, but some adenine nucleotide formation also took place. From [¹⁴C]hypoxanthine, adenine nucleotides in the soluble pool were more heavily labeled than the guanine nucleotides, whereas in the nucleic acid fraction the latter contained more radioactivity. Adenosine at low concentrations was mainly phosphorylated to adenine nucleotides, but at higher concentrations this process leveled off, while deamination continued to increase linearly. PHA-stimulation resulted in an increased rate of adenosine metabolism but no qualitative differences in comparison to unstimulated cells were observed. Enzyme assays indicated that after PHA-stimulation the activities of adenine and hypoxanthine phosphoribosyltransferases, and those of adenosine deaminase and kinase, increased with a peak at 48 h, when expressed on a per cell basis, but not at all when expressed per mg of protein. We conclude that stimulation of human T-lymphocytes with PHA increases the capacity of the cells for purine nucleotide synthesis from all the directly re-utilizable catabolic products, namely the purine bases and adenosine.     

Comparison of adenosine metabolism in leaves of several mangrove plants and a poplar species

A possible increased demand for ATP in salt- tolerant mangrove plants was studied by the comparison of metabolic fates of [8-¹⁴C] adenosine in leaf disks of several mangrove plants and of poplar. In mangrove trees, Rhizophora stylosa, Bruguiera gymnorrhiza, Kandelia candel and Sonneratia alba, 56–92% of [8-¹⁴C]adenosine taken up by leaf disks was converted during 3 h incubation to salvage products, i.e., nucleotides and RNA. Synthesis of nucleotides including ATP was stimulated by salt stress induced by 250 mM NaCl. In leaf disks of Avicennia marina, a mangrove shrub that produces glycinebetaine as compatible solutes, 46% of radioactivity entered salvage products when [8-¹⁴C] adenosine was continuously supplied to the leaf disks. Hydrolysis of adenosine to adenine was extremely active in this mangrove shrub. This is probably due to the high activity of adenosine nucleosidase (EC 3.2.2.7). In leaf disks of another mangrove shrub, Lumnitzera racemosa, only limited amounts of [8-¹⁴C]adenosine were metabolised (< ca. 30% taken up by leaf disks), but synthesis of ATP and ADP was stimulated by salt stress. In Pemphis acidula leaf disks, adenosine salvage activity was low and more than 30% of adenosine was hydrolysed to adenine. In leaf disks of poplar, a non-salt-resistant plant, ca. 40% of [8-¹⁴C] adenosine was converted to salvage products during 3 h of incubation, but the rate was slightly reduced by treatment with 250 mM NaCl. The present results suggest that large mangrove trees generally have efficient adenosine salvage ability, which is stimulated by salt. Lesser salvage activity is found in small size mangrove shrubs, although salt generally still enhances salvage activity.     

Adenylic acid catabolism in thymocytes of the regenerating thymus in mice

The T-cell non-peptide mitogenic factor isolated from the thymus stimulates thymus regeneration in mice previously treated with hydrocortisone. [8-14C]AMP catabolism in cortisone resistant thymocytes of mice has been investigated. Incorporation of radioactivity into hypoxanthine in cortisone resistant thymocytes is found to increase as compared with the total thymocyte population. Accumulation of labeled AMP catabolites in the form of hypoxanthine grows considerably after in vitro incubation of cortisone-resistant thymocytes with the non-peptide T-cell mitogenic factor. A large proportion of [8-14C]AMP catabolite radioactivity incorporated into cortisone-resistant thymocytes is excreted into the medium as hypoxanthine. It is supposed that hypoxanthine accumulation abrogates limitation of thymocyte DNA synthesis inhibited by relative excess of dGTP.     

Adenine cycle in hepatopancreocytes of Helix pomatia (Gastropoda)

Intact hepatopancreocytes were obtained from hibernating or active purinotelic snails, H. pomatia (Gastropoda). When incubated with [14C]glycine or [14C]formate, they synthesized de novo purine compounds, including also adenylates, adenosine and adenine. Hepatopancreocytes resynthesized also adenylates and other purine compounds from [3H]adenine or from [3H]adenosine split by the H. pomatia cell enzyme to adenine; the resynthesis of ADP+ATP was proportional to adenine concentration. Thus all reactions of the postulated adenine cycle: AMP leads to adenosine leads to adenine leads to AMP occur in the intact hepatopancreocytes; this cycle could probably be responsible for maintenance of the high level of adenylates during winter sleep.     

Metabolism of [14C]adenine and derivatives by cerebral tissues, superfused and electrically stimulated

1. Uptake of [(14)C]adenine and [(14)C]adenosine from surrounding fluids to guinea-pig cerebral tissues was measured during incubation in vitro. Output of (14)C-labelled compounds from the loaded tissues to superfusion fluids occurred on continued incubation, at about 0.2% of the tissue's content/min, and this rate was increased about fourfold by electrical excitation of the tissue. 2. The compounds released from the tissue to superfusion fluids included adenine, adenosine, inosine and hypoxanthine with small amounts of nucleotides. Output of all these compounds, except adenine, increased on excitation. Media depleted of oxygen or glucose also increased the output of (14)C-labelled derivatives from [(14)C]adenine-loaded tissues, and this augmented output was further increased by electrical stimulation. 3. [(14)C]Adenosine was found as the main product from [(14)C]ATP when this was added at low concentrations to fluids superfusing cerebral tissue. Metabolic and neurohumoural explanations of the liberation and action of adenosine derivatives in the tissue are discussed.     

Measurement of bile acid synthesis by 14CO2: the metabolism of propionyl CoA.

The relationship between 14CO2 evolution from the catabolism of [26 or 2714C] cholesterol to bile acids was studied in rats with biliary fistulae. When equal quantities of [26 or 2714C] cholesterol and [414C] cholesterol were administered, there was a significant linear relationship between 14CO2 expiration in the breath and [414C] bile acid excreted in the bile. Bile acid synthesis calculated as the ratio of 14CO2: molar specific activity of biliary cholesterol correlated highly with biliary bile acid excretion in the bile acid depleted rat. Phenobarbital, a known inducer of gamma-amino levulenic acid formation from succinyl CoA did not alter the relationship between the 14CO2 estimation of bile acid synthesis and biliary bile acid excretion, indicating that the relationship between [26 or 2714C] cholesterol side chain cleavage and 14CO2 formation was not altered. Phenobarbital, however, did cause a reduction in bile acid synthesis measured by 14CO2 evolution and by biliary bile acid excretion. The 14CO2 method underestimated bile acid excretion. 8.7% in untreated and phenobarbital treated rats respectively. Since 11% of the radioactivity which was expired as 14CO2 was isolated as bile acids, radioactivity cleaved as [1 or 314C] propionyl CoA may enter cholesterol-bile acid biosynthesis resulting in the underestimation of bile acid synthesis. To test whether radioactivity from propionyl CoA enters steroid biosynthesis [114C] propionate and [214C] propionate were given to untreated biliary fistula rats and the biliary lipids excreted in 60 hours were analyzed. Incorporation of radioactivity into cholesterol and bile acids was greater after the administration of [214C] propionate than after [114C] propionate than after [114C] propionate, suggesting that radioactivity from propionyl CoA may enter steroid biosynthesis by metabolic events in which the methylene and carboxyl carbon atoms are differentiated. Although the use of 14CO2 expiration from [26 or 2714C] cholesterol catabolism underestimates the rate of bile acid synthesis, it should have many applications because of the constant relationship between 14CO2 formation and cholesterol side chain cleavage.     

A sensitive fluorimetric procedure for the determination of aliphatic epoxides under physiological conditions

Ribose 1-phosphate has been measured in rat tissues by an enzymatic radioactive assay. The sugar phosphate is converted into [¹⁴C]inosine via the two following combined reactions: ribose 1-phosphate + [¹⁴C]adenine ? [¹⁴C]adenosine + phosphate (adenosine phosphorylase); [¹⁴C]adenosine + H₂O → [¹⁴C]inosine + NH₃ (adenosine deaminase). Tissue extracts are incubated in the presence of excess [¹⁴C]adenine. The radioactivity of inosine, separated by a thin-layer chromatographic system, is a measure of ribose 1-phosphate present in tissue extracts. Liver was found to contain the highest level of ribose 1-phosphate (ca. 800 nmol/g wet wt).