Kinetic characterization of adenosine deaminase activity in zebrafish (Danio rerio) brain

Adenosine deaminase (ADA; EC 3.5.4.4) activity is responsible for cleaving adenosine to inosine. In this study we described the biochemical properties of adenosine deamination in soluble and membrane fractions of zebrafish (Danio rerio) brain. The optimum pH for ADA activity was in the range of 6.0-7.0 in soluble fraction and reached 5.0 in brain membranes. A decrease of 31.3% on adenosine deamination in membranes was observed in the presence of 5 mM Zn(2+), which was prevented by 5 mM EDTA. The apparent K(m) values for adenosine deamination were 0.22+/-0.03 and 0.19+/-0.04 mM for soluble and membrane fractions, respectively. The apparent V(max) value for soluble ADA activity was 12.3+/-0.73 nmol NH(3) min(-1) mg(-1) of protein whereas V(max) value in brain membranes was 17.5+/-0.51 nmol NH(3) min(-1) mg(-1) of protein. Adenosine and 2'-deoxyadenosine were deaminated in higher rates when compared to guanine nucleosides in both fractions. Furthermore, a significant inhibition on adenosine deamination in both soluble and membrane fractions was observed in the presence of 0.1 mM of erythro-9-(2-hydroxy-3-nonyl)adenine (EHNA). The presence of ADA activity in zebrafish brain may be important to regulate the adenosine/inosine levels in the CNS of this species.     

Adenosine deaminase activity of chicken erythrocyte and heart cytosols

1. The adenosine deaminase (ADA) activities of chicken erythrocyte and heart cytosols had pH optima of 6.5. The temperature optima for erythrocyte and heart ADA were 30 and 35 degrees C, respectively. 2. The deoxyadenosine/adenosine deamination ratios ranged from 0.75 to 0.84 for both ADA activities. 3. For erythrocyte ADA, Km values were 8.9-12.9 microM adenosine (range) and 8.3 microM 2'-deoxyadenosine. For heart ADA, Km values were 6.7-12.0 microM adenosine (range) and 5.3 microM 2'-deoxyadenosine. 4. Inosine was a competitive inhibitor of both erythrocyte (Ki = 73 microM) and heart (Ki = 109 microM) ADA.     

Enhanced antibody response in the presence of partial adenosine deaminase inhibition

The enzyme adenosine deaminase (ADA) catalyzes the conversion of adenosine and 2'-deoxyadenosine to inosine and 2'-deoxyinosine, respectively. In the absence of ADA activity, 2'-deoxyadenosine is phosphorylated to deoxyadenosine triphosphate. This study concerned the effects of the ADA inhibitor 2'-deoxycoformycin on the murine in vitro immune response to sheep red blood cells (Mishell-Dutton cultures). In the presence of 10(-7) M 2'-deoxycoformycin or 1 mM 2'-deoxyadenosine, there was a significant increase in the plaque-forming cell response when calculated as plaques per 10(6) viable cells recovered. Cultures containing 10(-7) M 2'-deoxycoformycin retained approximately 10% of residual ADA activity of control cultures. Partial ADA deficiency was not preferentially toxic for cells capable of suppressing plaque cell generation. However, there was a decrease of recovered viable cells in all ADA-deficient cultures. There was no change in the percentage of recovered cells which were L3T4+ or Lyt 2+. A significant decrease was observed in a population of cells expressing surface immunoglobulins. The number of plaque-forming cells/10(3) recovered B cells increased significantly. We conclude that partial ADA deficiency results in selective toxicity to a population of non-antigen-specific B cells. Further studies with antigen-specific cells are necessary to determine the possible mechanism(s) by which cellular activation may prevent susceptibility to the toxic effects of ADA deficiency.     

ADA2 isoform of adenosine deaminase from pleural fluid

Adenosine deaminase isoenzyme 2 (ADA2) was isolated from human pleural fluid for the first time. Molecular and kinetic properties were characterized. It was shown that the inhibitors of adenosine deaminase isoenzyme 1 (ADA1), adenosine, and erithro-9-(2-hydroxy-3-nonyl)adenine (EHNA) derivatives are poor inhibitors of ADA2. Comparison of the interaction of ADA2 and ADA1 with adenosine and its derivative, 1-deazaadenosine, indicates that the isoenzymes have similar active centers. The absence of ADA2 inhibition by EHNA is evidence of a difference of these active centers in a close environment. The possible role of Zn2+ ions and the participation of acidic amino acids Glu and Asp in adenosine deamination catalyzed by ADA2 were shown.     

Influence of dipeptidyl peptidase IV on enzymatic properties of adenosine deaminase

The importance of ADA (adenosine deaminase) in the immune system and the role of its interaction with an ADA-binding cell membrane protein dipeptidyl peptidase IV (DPPIV), identical to the activated immune cell antigen, CD26, has attracted the interest of researchers for many years. To investigate the specific properties in the structure-function relationship of the ADA/DPPIV-CD26 complex, its soluble form, identical to large ADA (LADA), was isolated from human blood serum, human pleural fluid and bovine kidney cortex. The kinetic constants (Km and Vmax) of LADA and of small ADA (SADA), purified from bovine lung and spleen, were compared using adenosine (Ado) and 2'-deoxyadenosine (2'-dAdo) as substrates. The Michaelis constant, Km, evidences a higher affinity of both substrates (in particular of more toxic 2'-dAdo) for LADA and proves the modulation of toxic nucleoside neutralization in the extracellular medium due to complex formation between ADA and DPPIV-CD26. The values of Vmax are significantly higher for SADA, but the efficiency, Vmax/Km, in LADA-catalyzed 2'-dAdo deamination is higher than that in Ado deamination. The interaction of all enzyme preparations with derivatives of adenosine and erythro-9-(2-hydroxy-3-nonyl)adenine (EHNA) was studied. 1-DeazaEHNA and 3-deazaEHNA demonstrate stronger inhibiting activity towards LADA, the DPPIV-CD26-bound form of ADA. The observed differences between the properties of the two ADA isoforms may be considered as a consequence of SADA binding with DPPIV-CD26. Both SADA and LADA indicated a similar pH-profile of adenosine deamination reaction with the optimum at pHs 6.5-7.5, while the pH-profile of dipeptidyl peptidase activity of the ADA/DPPIV-CD26 complex appeared in a more alkaline region.     

Is the anomeric effect an important factor in the rate of adenosine deaminase catalyzed hydrolysis of purine nucleosides? A direct comparison of nucleoside analogues constructed on ribose and carbocyclic templates with equivalent heterocyclic bases selected to promote hydration

The aglycone of (North)-methanocarbadeoxyadenosine [(N)-MCdA, (5)], a relatively weak substrate for adenosine deaminase (ADA)-relative rate of deamination ca. 100 times lower than adenosine-was modified with substitutions at positions 6 (6-fluoro, compound 6) and 8 (8-aza, compound 7) with the intent to improve the level of hydration and hence hydrolysis by ADA. In these substrates the fused cyclopropane moiety constrains the cyclopentane ring to mimic the conformation of a furanose sugar in the North hemisphere of the pseudorotational cycle, which matches the conformation of the ribose ring of adenosine in complex with ADA. The order of susceptibility to ADA hydrolysis was adenosine>(N)-MCdA (5) approximately equal to(N)-6F-MCdP (6)>(N)-8-aza-MCdA (7). Despite the known fact that 8-azaadenosine is hydrolyzed twice as fast as adenosine, the corresponding carbocyclic analogue 7 was hydrolyzed at approximately half the rate of the parent 5. These results argue in favor of the critical role of the O(4') oxygen atom and its associated anomeric effect in assisting hydrolysis by ADA.     

Establishment and characterization of adenosine deaminase-deficient human T cell lines

We have established long term cell lines from a patient with adenosine deaminase (ADA)-deficient severe combined immunodeficiency by stimulation of blood and bone marrow cells with PHA and IL-2 followed by transformation of the activated cells with the human retrovirus HTLV-I. Despite the absence of detectable T cells in the patients blood, cell lines grew that carried the phenotype of mature activated T cells. TJF-2, the line established from blood, was characterized in detail. The concentration of ADA in TJF-2 cells was less than 1% of normal (3.2 U vs 413.0 U). Studies with pharmacologic inhibitors of ADA suggest that the residual adenosine deaminating activity of TJF-2 is from an enzyme distinct from true ADA, a nonspecific aminohydrolyase. Growth of TJF-2 cells was hypersensitive to inhibition by 2'-deoxyadenosine compared to normal T cells (ID50, 55 microM vs greater than 1000 microM). Analysis of 2'-deoxyadenosine-challenged cells showed that TJF-2 cells accumulated significant levels of deoxyadenosine triphosphate, whereas normal T cells did not unless they were also incubated with the ADA inhibitor deoxycoformycin. Southern and Northern blot analysis of these cells revealed a grossly intact ADA gene that produced a normal size ADA mRNA. Yet, despite ADA deficiency, cells of the TJF-2 line were otherwise indistinguishable from HTLV-I-transformed T cells derived from normal donors with respect to dependence on exogenous IL-2 for growth, clonal rearrangement patterns of TCR beta-chain genes, response to PHA, and rapid restoration of cellular volume after hypotonic challenge. The TJF-2 line thus represents a unique HTLV-I-transformed human T cell line exhibiting ADA deficiency and its expected metabolic consequences.     

Introduction of sequences encoding functional human adenosine deaminase into mouse cells using a retroviral shuttle system

A retroviral packaging system was used to generate a murine virus carrying sequences encoding human adenosine deaminase (ADA). To this end, human ADA cDNA was inserted into the retroviral shuttle vector pZIP-NeoSV(X)1. This vector provides all of the cis-acting sequences necessary for the efficient packaging and transmission of the viral genome as well as a selectable gene for G418 resistance. Transfection of this recombinant plasmid into cells that provide essential virus products (psi-2 cells) yielded cell lines that stably produced virions carrying the coding sequence of human ADA. We have used these virions to infect NIH3T3 cells, which after 48 h synthesized catalytically active human ADA. Furthermore, G418-resistant cell lines were obtained from the virus-infected NIH3T3 cells that stably produced the human ADA enzyme.     

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.     

Evolution of the eukaryotic translation termination system: origins of release factors

Accurate translation termination is essential for cell viability. In eukaryotes, this process is strictly maintained by two proteins, eukaryotic release factor 1 (eRF1), which recognizes all stop codons and hydrolyzes peptidyl-tRNA, and eukaryotic release factor 3 (eRF3), which is an elongation factor 1alpha (EF-1alpha) homolog stimulating eRF1 activity. To retrace the evolution of this core system, we cloned and sequenced the eRF3 genes from Trichomonas vaginalis (Parabasalia) and Giardia lamblia (Diplomonada), which are generally thought to be "early-diverging eukaryotes," as well as those from two ciliates (Oxytricha trifallax and Euplotes aediculatus). We also determined the sequence of the eRF1 gene for G. lamblia. Surprisingly, the G. lamblia eRF3 appears to have only one domain, corresponding to EF-1alpha, while other eRF3s (including the T. vaginalis protein) have an additional N-terminal domain, of 66-411 amino acids. Considering this novel eRF3 structure and our extensive phylogenetic analyses, we suggest that (1) the current translation termination system in eukaryotes evolved from the archaea-like version, (2) eRF3 was introduced into the system prior to the divergence of extant eukaryotes, including G. lamblia, and (3) G. lamblia might be the first eukaryotic branch among the organisms considered.     

Enhanced activity or resistance of adenosine derivatives towards adenosine deaminase-catalyzed deamination: Influence of ribose modifications

The effect of the presence of the 1′-C-methyl group and 2′,3′-O-substitution in the adenosine structure on ADA activity has been investigated by modeling studies. Results show that the 2′- and 3′-O- substituents are harbored in a quite large cavity of intermediate polarity, whereas the 1′-C-substituent clashes against Ala180 distorting the architecture of the catalytic centre. Globally, the study emphasizes the ability of ADA to transform a large set of 2′,3′-O-substituted adenosine analogues as well as the opportunity to design 1′-C-substituted adenosine derivatives resistant to ADA-catalyzed deamination.     

Identification and comparative analysis of a second runx3 promoter

Adenosine deaminase (ADA) catalyzes the hydrolysis of adenosine to inosine. Its lack determines severe combined immunodeficiency in mammals, possibly due to accumulation of extracellular adenosine, which induces apoptosis in lymphocytes (Franco et al., 1998). Thus, presence of normal levels of ADA leads to normal growth and proliferation of lymphocytes. Several vertebrate and microbial ADA amino-acid sequences are known, with substantial similarity to each other. On the other hand, there are invertebrate growth factors as well as a candidate gene for the human cat eye syndrome (CECR1) (Riazi et al., 2000. Genomics 64, 277-285), which share substantial similarity to each other, and also to ADA. In this study, we report the expression and ADA enzymatic activity of a cDNA from the salivary glands of Lutzomyia longipalpis, a blood-sucking insect, with substantial similarity to insect growth factors and to human CECR1. We also demonstrate the existence of a subfamily of the adenosine deaminase family characterized by their unique amino-terminal region. Both Drosophila melanogaster and humans have both types of adenosine deaminases. Results indicate that these invertebrate proteins previously annotated as growth factors, as well as the human CECR1 gene product, may exert their actions through adenosine depletion. The different roles played by each type of adenosine deaminase in humans and Drosophila remains to be fully investigated.     

Erythrocyte acid phosphatase (ACP1) activity

Summary Erythrocyte acid phosphatase (ACP₁) activity was determined in the absence of modulators and in the presence of either adenosine or inosine as modulators in 154 samples of red blood cells collected from adult donors. Adenosine and inosine showed modulating effects (activation), that were genotype dependent in the allele order p^bac; the activation by inosine was much higher than by adenosine. The modulating effect was dependent on adenosine deaminase (ADA) genotype: In carriers of ADA² allele the activation with ACP₁ phenotype A was lower and that with phenotypes CA and CB was higher than in ADA¹/ADA¹ subjects. In addition, the basic ACP₁ activity (i.e., without modulators) also appeared to be dependent on ADA genotype: The lowest ACP₁ activity was observed in A and BA subjects carrying the ADA² allele. Since the deamination of adenosine to inosine associated with ADA2-1 phenotype is slower than that associated with ADA1, the interaction of ADA on ACP₁ activity may in fact be explained by a lower intracellular concentration of inosine in ADA² carriers and, therefore, by a lower modulating effect of this on acid phosphatase activity.     

Adenosine deamination to inosine in isolated basolateral membrane from kidney proximal tubule: Implications for modulation of the membrane-associated protein kinase A

In this work, the metabolism of adenosine by isolated BLM associated-enzymes and the implications of this process for the cAMP-signaling pathway are investigated. Inosine was identified as the major metabolic product, suggesting the presence of adenosine deaminase (ADA) activity in the BLM. This was confirmed by immunoblotting and ADA-specific enzyme assay. Implications for the enzymatic deamination of adenosine on the receptor-modulated cAMP-signaling pathway were also investigated. We observed that inosine induced a 2-fold increase in [³⁵S] GTPγS binding to the BLM and it was inhibited by 10⁻⁶ M DPCPX, an A₁ receptor-selective antagonist. Inosine (10⁻⁷ M) inhibited protein kinase A activity in a DPCPX-sensitive manner. Molecular association between ADA and G_αi-3 protein-coupled A₁ receptor was demonstrated by co-immunoprecipitation assay. These data show that adenosine is deaminated by A₁ receptor-associated ADA to inosine, which in turn modulates PKA in the BLM through A₁ receptor-mediated inhibition of adenylyl cyclase.     

结核感染T细胞斑点试验联合血清ADA、SAA、CA125对活动性肺结核诊断及治疗转归的评估价值

摘要 目的：探讨结核感染T细胞斑点试验（T-SPOT.TB）联合血清腺苷脱氨酶（ADA）、淀粉样蛋白A（SAA）、糖类抗原125（CA125）对活动性肺结核（APTB）诊断及治疗转归的评估价值。方法：选取2021年10月至2022年10月湖南省胸科医院收治的137例APTB患者（APTB组）和80例非APTB患者（对照组）,所有APTB患者接受常规抗结核治疗,根据治疗后转归情况分为转归组（92例）和未转归组（45例）。治疗前进行T-SPOT.TB,并检测血清ADA、SAA、CA125水平。受试者工作特征（ROC）曲线分析T-SPOT.TB联合血清ADA、SAA、CA125诊断APTB和预测治疗转归的效能。结果：APTB组T-SPOT.TB阳性率,血清ADA、SAA、CA125水平高于对照组（P＜0.05）。未转归组T-SPOT.TB阳性率,血清ADA、SAA、CA125水平高于转归组（P＜0.05）。T-SPOT.TB联合血清ADA、SAA、CA125诊断APTB以及预测其治疗转归的曲线下面积（AUC）分别为0.917、0.833,高于单一指标。结论：APTB患者T-SPOT.TB阳性率增加,血清ADA、SAA、CA125水平增高,与抗结核治疗后转归不良有关,T-SPOT.TB联合血清ADA、SAA、CA125在APTB诊断和治疗转归评估中具有较高价值。     

A Role for Adenosine Deaminase in Drosophila Larval Development

Adenosine deaminase (ADA) is an enzyme present in all organisms that catalyzes the irreversible deamination of adenosine and deoxyadenosine to inosine and deoxyinosine. Both adenosine and deoxyadenosine are biologically active purines that can have a deep impact on cellular physiology; notably, ADA deficiency in humans causes severe combined immunodeficiency. We have established a Drosophila model to study the effects of altered adenosine levels in vivo by genetic elimination of adenosine deaminase-related growth factor-A (ADGF-A), which has ADA activity and is expressed in the gut and hematopoietic organ. Here we show that the hemocytes (blood cells) are the main regulator of adenosine in the Drosophila larva, as was speculated previously for mammals. The elevated level of adenosine in the hemolymph due to lack of ADGF-A leads to apparently inconsistent phenotypic effects: precocious metamorphic changes including differentiation of macrophage-like cells and fat body disintegration on one hand, and delay of development with block of pupariation on the other. The block of pupariation appears to involve signaling through the adenosine receptor (AdoR), but fat body disintegration, which is promoted by action of the hemocytes, seems to be independent of the AdoR. The existence of such an independent mechanism has also been suggested in mammals.     

A role for adenosine deaminase in Drosophila larval development

Adenosine deaminase (ADA) is an enzyme present in all organisms that catalyzes the irreversible deamination of adenosine and deoxyadenosine to inosine and deoxyinosine. Both adenosine and deoxyadenosine are biologically active purines that can have a deep impact on cellular physiology; notably, ADA deficiency in humans causes severe combined immunodeficiency. We have established a Drosophila model to study the effects of altered adenosine levels in vivo by genetic elimination of adenosine deaminase-related growth factor-A (ADGF-A), which has ADA activity and is expressed in the gut and hematopoietic organ. Here we show that the hemocytes (blood cells) are the main regulator of adenosine in the Drosophila larva, as was speculated previously for mammals. The elevated level of adenosine in the hemolymph due to lack of ADGF-A leads to apparently inconsistent phenotypic effects: precocious metamorphic changes including differentiation of macrophage-like cells and fat body disintegration on one hand, and delay of development with block of pupariation on the other. The block of pupariation appears to involve signaling through the adenosine receptor (AdoR), but fat body disintegration, which is promoted by action of the hemocytes, seems to be independent of the AdoR. The existence of such an independent mechanism has also been suggested in mammals.