Catabolism of adenine nucleotides in adenosine deaminase deficient erythrocytes

$\text{In vitro}$ incubation studies using fluoride and iodoacetate as glycolytic inhibitors have been carried out on red cells of the two subjects with adenosine deaminase deficiency. For comparison, similar studies have also been carried out on red cells from a normal subject and from a child with severe combined immunodeficiency with normal adenosine deaminase activity. The adenosine formed in the adenosine deaminase deficient red cells is a measure of adenosine 5′-phosphate breakdown initiated by 5′-nucleotidase, whereas inosine 5′-phosphate, inosine and hypoxanthine formation is a measure of adenosine 5′-phosphate breakdown initiated by adenylate deaminase. With fluoride as inhibitor, nearly all of the adenosine 5′-phosphate breakdown proceeded by way of adenylate deaminase, while with iodoacetate as inhibitor, 20–30% of the adenosine 5′-phosphate breakdown was initiated by 5′-nucleotidase acting on adenosine 5′-phosphate. In addition, significant amounts of adenine were produced in adenosine deaminase deficient red cells in the presence of the glycolytic inhibitors. Possible explanations for the findings noted in this study are discussed and related to recent studies on the properties of the pertinent purine nucleotide catabolic enzymes.     

Activity of adenosine deaminase and adenylate deaminase on adenosine and 2', 3(')-isopropylidene adenosine: role of the protecting group at different pH values

The deamination rate of 2',3'-isopropylidene adenosine catalyzed by adenosine deaminase (ADA) from calf intestine and adenylate deaminase (AMPDA) from Aspergillus species has been evaluated and compared with that of the enzymatic reactions of adenosine, to elucidate the influence of the protecting group on enzyme activity.     

Effects of adenosine deaminase on cyclic adenosine monophosphate accumulation, lipolysis, and glucose metabolism of fat cells.

In fat cells isolated from the parametrial adipose tissue of rats, the addition of purified adenosine deaminase increased lipolysis and cyclic adenosine 3':5'-monophosphate (cyclic AMP) accumulation. Adenosine deaminase markedly potentiated cyclic AMP accumulation due to norepinephrine. The increase in cyclic AMP due to adenosine deaminase was as rapid as that of theophylline with near maximal effects seen after only a 20-sec incubation. The increases in cyclic AMP due to crystalline adenosine deaminase from intestinal mucosa were seen at concentrations as low as 0.05 mug per ml. Further purification of the crystalline enzyme preparation by Sephadex G-100 chromatography increased both adenosine deaminase activity and cyclic AMP accumulation by fat cells. The effects of adenosine deaminase on fat cell metabolism were reversed by the addition of low concentrations of N6-(phenylisopropyl)adenosine, an analog of adenosine which is not deaminated. The effects of adenosine deaminase on cyclic AMP accumulation were blocked by coformycin which is a potent inhibitor of the enzyme. These findings suggest that deamination of adenosine is responsible for the observed effects of adenosine deaminase preparations. Protein kinase activity of fat cell homogenates was unaffected by adenosine or N6-(phenylisopropyl)adenosine. Norepinephrine-activated adenylate cyclase activity of fat cell ghosts was not inhibited by N6-(phenylisopropyl)adenosine. Adenosine deaminase did not alter basal or norepinephrine-activated adenylate cyclase activity. Cyclic AMP phosphodiesterase activity of fat cell ghosts was also unaffected by adenosine deaminase. Basal and insulin-stimulated glucose oxidation were little affected by adenosine deaminase. However, the addition of adenosine deaminase to fat cells incubated with 1.5 muM norepinephrine abolished the antilipolytic action of insulin and markedly reduced the increase in glucose oxidation due to insulin. These effects were reversed by N6-(phenylisopropyl)adenosine. Phenylisopropyl adenosine did not affect insulin action during a 1-hour incubation. If fat cells were incubated for 2 hours with phenylisopropyl adenosine prior to the addition of insulin for 1 hour there was a marked potentiation of insulin action. The potentiation of insulin action by prior incubation with phenylisopropyl adenosine was not unique as prostaglandin E1, and nicotinic acid had similar effects.     

Comparative enzymology of AMP deaminase,adenylate kinase,and creatine kinase in vertebrate heart and skeletal muscle: the characteristic AMP deaminase levels of skeletal versus cardiac muscle are reversed in the North American toad

The specific activity of three characteristic enzymes, adenylate deaminase, adenylate kinase, and creatine kinase, in the skeletal muscles and heart of a variety of vertebrate land animals, including the human, are surveyed. Data from this study and available studies in the literature suggest that adenosine monophosphate deaminase in land vertebrates is quite high in white skeletal muscle, usually somewhat lower in red muscle, and 15-to 500-fold lower in cardiac muscle. Adenosine monophosphate deaminase is active primarily under ischemic or hypoxic conditions which occur frequently in white muscle, only occasionally in red muscle, and ought never occur in heart muscle, and this may therefore account for observed enzyme levels. The common North American toad, Bufo americanus, provides a striking exception to the rule with cardiac adenosine monophosphate deaminase as high as in mammalian skeletal muscle, whereas its skeletal muscle level of adenosine monophosphate deaminase is several times lower. The exceptional levels in the toad are not due to a change in substrate binding and are not accompanied by comparable change in the level of adenylate or creatine kinase. Nor do they signal any major change in isozyme composition, since a human muscle adenosine monophosphate deaminase-specific antiserum reacts with toad muscle adenosine monophosphate deaminase, but not with toad heart adenosine monophosphate deaminase. They do not represent any general anuran evolutionary strategy, since the bullfrog (Rana catesbeiana) and the giant tropic toad (Bufo marinus) have the usual vertebrate pattern of adenosine monophosphate deaminase distribution. Lower skeletal muscle activities in anurans may simply represent the contribution of tonic muscle fiber bundles containing low levels of adenosine monophosphate deaminase, but the explanation for the extremely high adenosine monophosphate deaminase levels in heart ventricular muscle is not apparent.Abbreviations AK adenylate kinase - AMP adenosine monophosphate - AMPD, AMP deaminase - CPK creatine (phospho)kinase - EHNA erythro-9-(2-hydroxy-3-nonyl)-adenine-HCl     

Characterization of the adenosine deaminase-adenosine deaminase complexing protein binding reaction

Glutaraldehyde-fixed membranes from rabbit kidney cortex were used to characterize binding of monomeric adenosine deaminase to the adenosine deaminase complexing protein. With the use of bovine adenosine deaminase it was shown that enzyme binding is a saturable, high affinity process. The K value for binding of the bovine enzyme was 11 nM. Maximum enzyme binding and rate of binding to a constant amount of membrane did not vary significantly from pH 5.0 to 9.5. Metal ions, with the exception of Hg2+, sulfhydryl reagents, and other proteins had little or a slightly stimulatory effect on maximum binding. Mercuric ion inhibited binding. Using biotinylated bovine adenosine deaminase it was shown that purified rabbit, human, and monkey enzymes compete for binding sites on fixed membranes. The K values for the rabbit and human enzymes were 9 and 6 nM, respectively. Mouse or guinea pig adenosine deaminase did not bind to the membranes or compete with the biotinylated bovine enzyme for binding sites. The retention of characteristics required for binding by enzymes from rabbit, human, monkey, and calf tissues argues for biologic significance of the adenosine deaminase-complexing protein interaction. The basis for the apparent failure of rodent adenosine deaminase to bind to complexing protein remains to be determined.     

Adenosine deaminase activity of insect-derived growth factor is essential for its growth factor activity

Insect-derived growth factor (IDGF) was originally isolated from conditioned medium of NIH-Sape-4 cells derived from flesh fly embryos. Here we demonstrated that IDGF has adenosine deaminase activity. The substrate specificity of IDGF was similar to that of the mammalian cytoplasmic adenosine deaminase. The adenosine deaminase activity of IDGF was shown to be indispensable for its growth factor activity toward NIH-Sape-4 cells. We found that there are specific binding sites for IDGF on the surface of NIH-Sape-4 cells and that it binds to these sites with a K(d) value of 2.4 x 10(-10) m. We propose that the cell surface binding sites for IDGF are specific receptors modified with an adenosine moiety. When IDGF binds to these receptors, it may deaminate the adenosine moiety, and this process may be prerequisite for the signal transduction via this receptor.     

ECTO-enzyme activity of human erythrocyte adenosine deaminase

Summary Adenosine deaminase is found primarily in the cytoplasm of many cell types. In the human erythrocyte, about 30 per cent of the total adenosine deaminase activity is membrane associated, and about two-thirds of this is inactivated by treatment of intact erythrocytes with the nonpenetrating reagent diazotized sulfanilic acid, without affecting lactate dehydrogenase, a soluble cytoplasmic enzyme. This indicates that within the cell membranes, the catalytic site of about two-thirds of the adenosine deaminase faces the external medium, i.e., ecto adenosine deaminase. Localization of adenosine deaminase activity at the cell membrane is demonstrated directly by electron microscopy by use of the substrate 6-Chloropurine ribonucleoside, which is dechlorinated by adenosine deaminase to produce Cl^–, which is precipitated at its locus of formation by added Ag⁺, and the precipitated AgCl converted into the electron dense Ag⁰ upon exposure to light.From the Hydropathic Profile of the amino acid sequence of adenosine deaminase it is evident that there are two hydrophobic domains of sufficient length to span a biological membrane, and it is proposed that these domains could function to anchor the enzyme to the membrane.The importance of adenosine deaminase is indicated by the fatal immuno-deficiency which results from untreated genetic adenosine deaminase deficiency. It may be important to determine whether the amount of ecto adenosine deaminase activity is better suited to assess the clinical status of adenosine deaminase deficient patients that the currently used total cellular enzyme activity.Abbreviations ADA Adenosine Deaminase - LDH Lactate Dehydrogenase - HEPES N-2-Hydroxyethylpiperazine-N-2-ethanesulfonic acid - CPR 6-Chloropurine Ribonucleoside - SDS Sodium Dodecyl Sulfate - NAD -Nicotinamide Adenine Dinucleotide - HBSS Hank's Balanced Salt Solution - DASA Diazotized Sulfanilic Acid     

Involvement of calcium in the inhibition by insulin of the glucagon-stimulated adenylate-cyclase activity.

1. The inhibitory effect of adenosine on the glucagon-stimulated adenylate cyclase activity of liver plasma membranes, prepared from PVG/c rats, was potentiated by insulin. In the presence of EGTA, such potentiating effect of insulin was lost. 2. Calcium (10 microM) potentiated the inhibitory effects of both adenosine and insulin on the glucagon-stimulated cyclase activity. The synergestic effect of calcium + insulin required the presence of adenosine as judged from the use of adenosine deaminase. 3. Insulin had no significant inhibitory effect on the glucagon-stimulated cyclase activity of liver plasma membranes, prepared from young Wistar rats, unless both adenosine (50 microM) and calcium (10 microM) were added externally. 4. Results demonstrate an interaction of calcium and insulin at membrane level that, in the presence of adenosine, results in the inhibition of the glucagon-stimulated adenylate cyclase activity.     

Rat cerebral-cortex adenosine deaminase activity and its subcellular distribution

A radioisotopic assay for adenosine deaminase (EC 3.5.4.4) is described together with its application in investigating the activity of the enzyme in rat cerebral cortex. Activity of the adenosine deaminase was determined to be 115nmol/min per g of tissue, measured in isoosmotic sucrose dispersions of the neocortex, and to be 170nmol/min per g of tissue after treatment with Triton X-100. The enzyme was concluded to be largely cytoplasmic, with a K(m) of 54-57mum for adenosine. Action of the deaminase, and other aspects of the metabolism of adenosine in intact neocortical tissue, were quantitatively appraised on the basis of the newly determined characteristics.     

Adenosine and gpp(NH)p modulate mouse sperm adenylate cyclase

The possible roles of adenosine and the GTP analogue Gpp(NH)p in regulating mouse sperm adenylate cyclase activity were investigated during incubation in vitro under conditions in which after 30 min the spermatozoa are essentially uncapacitated and poorly fertile, whereas after 120 min they are capacitated and highly fertile. Adenylate cyclase activity, assayed in the presence of 1 mM ATP and 2 mM Mn²⁺, was determined by monitoring cAMP production. When adenosine deaminase (1 U/ml) was included in the assay to deplete endogenous adenosine, enzyme activity was decreased in the 30-min suspensions but increased in the 120-min samples (P < 0.02). This suggests that endogenous adenosine has a stimulatory effect on adenylate cyclase in uncapacitated spermatozoa but is inhibitory in capacitated cells. Since the expression of adenosine effects at low nucleoside concentrations usually requires guanine nucleotides, the effect of adding adenosine in the presence of 5 x 10^–5 M Gpp(NH)p was examined. While either endogenous adenosine or adenosine deaminase may have masked low concentration (10^?9?10^?7 M) effects of exogenous adenosine, a marked inhibition (P < 0.001) of adenylate cyclase activity in both uncapacitated and capacitated suspensions was observed with higher concentrations (>10^?5 M) of adenosine. Similar inhibition was also observed in the absence of Gpp(NH)p, suggesting the presence of an inhibitory P site on the enzyme. In further experiments, the effects of Gpp(NH)p in the presence and absence of adenosine deaminase were examined. Activity in 30-min suspensions was stimulated by the guanine nucleotide and in the presence of adenosine deaminase this stimulation was marked, reversing the inhibition seen with adenosine deaminase alone. In capacitated suspensions the opposite profile was observed, with Gpp(NH)p plus adenosine deaminase being inhibitory; again, this was a reversal of the effects obtained in the presence of adenosine deaminase alone, which had stimulated enzyme activity. These results suggest the existence of a stimulatory adenosine receptor site (R_a) on mouse sperm adenylate cyclase that is expressed in uncapacitated spermatozoa and an inhibitory receptor site (R_i) that is expressed in capacitated cells, with guanine nucleotides modifying the final response to adenosine. It is concluded that adenosine and guanine nucleotides may regulate mouse sperm adenylate cyclase activity during capacitation.     

Preliminary characterization of adenosine deaminase from Bacillus cereus

Adenosine deaminase from Bacillus cereus is quite unstable, similarly to other bacterial deaminases, but it shows a peculiar stabilizing effect by some monovalent cations. These include K+, Li+, NH4+ and to a lesser extent Cs+. Maximal stabilization of the deaminase is exerted by K+ at concentrations higher than 20 mM. The enzyme can be rapidly inactivated by sulphydryl reagents such as p-hydroxymercuribenzoate. Since adenosine deaminase from B. cereus, in addition to monovalent cations, is stabilized also by dithiothreitol, a possible influence of monovalent cations on the reactivity of some sulphydryl groups on the enzyme has been suggested.     

Conformation of adenosine deaminase in complexes with inhibitors: application of selective quenching of fluorescence emission

The effect of inhibitors, 1-deazaadenosine (1-dAdo) and erythro-9-(2-hydroxy-3-nonyl)adenine (EHNA), on the conformation of adenosine deaminase was studied using the method of selective quenching of fluorescence emission by acrylamide, I- and Cs+. Both in free adenosine deaminase and in its complexes with the inhibitors, the wavelength maxima and half-width of the emission characterize the environment of fluorescing tryptophan residues in adenosine deaminase as weak polar with limited access to solvent. The formation of complexes with the ground state inhibitors used did not quench or change the main emission characteristics of tryptophan fluorescence in adenosine deaminase. Small blue shifts of emission maxima were observed upon quenching in all three samples. The Stern-Volmer parameters of tryptophan fluorescence quenching by acrylamide were not essentially influenced by complex formation of the enzyme with the inhibitors: in general, the folding of the enzyme molecule in the complexes is not perturbed. On the contrary, the emission quenching by charged heavy ions, I- and Cs+, in the complexes was hindered in comparison with free adenosine deaminase. In the complex with 1-deazaadenosine, the parameters for quenching by both ions evidence the essential worsening of their interaction with tryptophans. In the complex with erythro-9-(2-hydroxy-3-nonyl)adenine, along with the worse quenching by I-, complete prohibition of quenching by Cs+ was observed. These data indicate that the local environments of fluorescing tryptophan residues is substantially distorted compared with free adenosine deaminase, which leads to their screening from charged heavy ions.     

Adenosine deaminase activity in hepatomas of varying degrees of malignancy]

In highly malignant Gelshtein 22A hepatcma and ascites Ehrlich carcinoma adenosine deaminase activity was found to be reduced 3-fold as compared with that of the normal mouse liver. In less malignant hepatomas adenosine deaminase activity drops only by 20%. A certain reduction of adenosine deaminase activity was also noted in the liver to tumour-bearing mice.     

Human red cell porphobilinogen deaminase. A simpler method of purification and some unusual properties

A simpler method for purifying human red cell deaminase, using a mixture of n-butanol and chloroform, which denatures hemoglobin, followed by ammonium sulphate fractionation, heat treatment, Sephadex G-100 and DEAE-cellulose chromatography, yielding a 3400 fold purified enzyme is described. Some properties of purified deaminase were studied. The enzyme seems to have a strict requirement for oxygen, neither PBG consumption nor uroporphyrinogens formation were measured under anaerobiosis. Uroporphyrinogens formation was linear with both protein and time over a wide range of enzyme concentration and up to 2 h. The optimum pH was 7.4 and the mol. wt was 40,000 +/- 4000. The enzyme was heat-stable and increased its activity by heating. Ammonium and hydroxylamine ions inhibited the reaction. K+ and Na+ ions did not greatly affect activity, while most divalent cations tested significantly diminished uroporphyrinogen formation and to a lesser degree PBG consumption. Direct plots of velocity against PBG concentration were hyperbolic, however double-reciprocal plots were non-linear, Hill plots gave an n value of 2 and Eadie plots were bell-shaped, indicating the existence of weakly positive cooperative effect between 2 binding sites for PBG per molecule of deaminase.     

Effect of benzodiazepines on the activity of AMP deaminase and adenosine deaminase in rat brain tissue in vivo

Phenazepam (5 mg/200 g) and seduxen (3 mg/200 g) injected intraperitoneally to 184 rats altered AMP-deaminase and adenosine deaminase brain activity. Seduxen was observed to increase AMP-deaminase and adenosine deaminase activity by 89.1% and 32.4%, respectively an hour after the injection. Phenazepam increased the activity of the enzymes by 35.5% and 38.5%, respectively two hours after the injection. The effect is suggested to be due to de novo benzodiazepine-induced enzyme synthesis.     

The role of divalent cations in structure and function of murine adenosine deaminase.

For murine adenosine deaminase, we have determined that a single zinc or cobalt cofactor bound in a high affinity site is required for catalytic function while metal ions bound at an additional site(s) inhibit the enzyme. A catalytically inactive apoenzyme of murine adenosine deaminase was produced by dialysis in the presence of specific zinc chelators in an acidic buffer. This represents the first production of the apoenzyme and demonstrates a rigorous method for removing the occult cofactor. Restoration to the holoenzyme is achieved with stoichiometric amounts of either Zn2+ or Co2+ yielding at least 95% of initial activity. Far UV CD and fluorescence spectra are the same for both the apo- and holoenzyme, providing evidence that removal of the cofactor does not alter secondary or tertiary structure. The substrate binding site remains functional as determined by similar quenching measured by tryptophan fluorescence of apo- or holoenzyme upon mixing with the transition state analog, deoxycoformycin. Excess levels of adenosine or N6- methyladenosine incubated with the apoenzyme prior to the addition of metal prevent restoration, suggesting that the cofactor adds through the substrate binding cleft. The cations Ca2+, Cd2+, Cr2+, Cu+, Cu2+, Mn2+, Fe2+, Fe3+, Pb2+, or Mg2+ did not restore adenosine deaminase activity to the apoenzyme. Mn2+, Cu2+, and Zn2+ were found to be competitive inhibitors of the holoenzyme with respect to substrate and Cd2+ and Co2+ were noncompetitive inhibitors. Weak inhibition (Ki > or = 1000 microM) was noted for Ca2+, Fe2+, and Fe3+.     

Purification and characterization of adenosine deaminase from Klebsiella sp. LF 1202

Adenosine deaminase was induced when the cells of Klebsiella sp. LF 1202 were cultured in the medium containing adenosine as a sole source of carbon and nitrogen. The induction was partially repressed by the addition of ammonium sulfate in the medium. The amount of adenosine deaminase reached approximately 4.6% of the total intracellular soluble proteins. The enzyme was purified approximately 22-fold with a 25% activity yield. The enzyme was a monomer with a molecular weight of 26,000. The optimal activity was obtained at pH 8.0, 37°C, and the K_m value for adenosine was 37 μM. Metal ions such as Zn²⁺, Co²⁺, Fe² and Ni⁺ inhibited the activity of the enzyme. Sulfhydryl blocking agents such as p-chloromercuribenzoate and HgCl₂ were also found to be potent inhibitors for adenosine deaminase.     

Adenosine deaminase activity in rat intestine: assay with a microdialysis technique

Using microdialysis, we measured adenosine deaminase activity in rat intestine by detecting inosine, a breakdown product of adenosine. The dialysis probe consisted of a 3 x 0.22 mm dialysis fiber with a 50,000 mol wt cut off. When the probe was perfused at 1 microl/min in vitro, the average relative recovery rate of inosine was 22.1+/-0.9%). The dialysis probe was implanted in the intestinal mucosa and perfused with Tyrode solution containing adenosine at 1 microl/min. The dialysate samples were analyzed for inosine by high-performance liquid chromatography with ultraviolet (HPLC-UV) detection at 260 nm. When adenosine (100-1000 microM) was perfused, the level of inosine increased dose-dependently and was saturatable at about 1 mM adenosine. The ED50 of adenosine was 192.6 microM, with a maximum attainable inosine concentration of 59.7 microM. In the presence of aminoguanidine, a adenosine deaminase inhibitor (10 mM or 10 n mol/microl/min), the elevation of inosine was not observed. The dialysis technique makes it possible to measure adenosine deaminase activity in intestinal mucosa.     

2',3'-isopropylidene group, a molecular scaffold to study the activity of adenosine and adenylate deaminase on adenosine analogues modified in the ribose moiety

2 ',3 '-Isopropylidene group can be used as a molecular scaffold for the introduction of modifications at 5 ' and 1 ' positions of adenosine and these modified nucleosides are used to evaluate the biocatalytic activity of adenosine and adenylate deaminase.     

Relationship between 5'-nucleotidase, adenosine deaminase, AMP deaminase, ATP-(Mg2+)-ase activities and dTMP kinase activity in rat liver mitochondria.

The activities of dTMP kinase (ATP-deoxythymidine monophosphate phosphotransferase, EC 2.7.4.9), 5'-nucleotidase (5'-ribonucleoside phosphohydrolase, EC 3.1.3.5), adenosine deaminase (adenosine aminohydrolase, EC 3.5.4.4), AMP deaminase (AMP aminohydrolase, EC 3.5.3.6) and ATP-(Mg2+)-ase (ATP phosphohydrolase, EC 3.6.1.3) were assayed in mitochondria of normal and regenerating rat liver. In regenerating mitochondria, the dTMP kinase activity increased 20 times, 5'-nucleotidase (5'Nase) activity for dTMP diminished by 65% and its activity for other nucleoside monophosphates did not change; adenosine deaminase activity for adenosine (AR) increased by 40%, but for deoxyadenosine (AdR) decreased by 70%. AMP deaminase and ATP-(Mg2+)-ase activities behaved similarly in mitochondria from regenerating liver, decreasing by 70 and 64% respectively. The changes of the amount of dTMP in mitochondria depend on enzyme activities which regulate the AdR concentration.