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Query: UNIPROT:P06889 (Mol)
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The structure of human adenosine deaminase mRNA from normal and mutant lymphoblasts was examined by sequence analysis of a cDNA for normal mRNA and electrophoretic analyses of DNA fragments generated by S1 endonuclease cleavage of mRNA-cDNA hybrids. The 1,533-base sequence of the cloned cDNA represents the complete mRNA sequence with the possible exception of some of the 5' untranslated region. S1 nuclease analyses of hybrids between cloned cDNA and normal adenosine deaminase mRNA confirmed that a 76-base sequence in a previously examined adenosine deaminase cDNA is an intron. S1 nuclease analyses of mRNAs from seven mutant cell lines demonstrated that four of the mutants, those in the GM-2471, GM-2756, GM-4258, and GM-2606 cells, contain small defects, such as single-base changes, that are not detectable by the S1 nuclease technique. Three of the mRNAs, those in GM-3043, GM-2294, and GM-2825A cells, do contain defects detectable with S1 nuclease. These defects differ from each other and have been mapped to specific regions of the mRNA. Some or all of these defective mRNAs are postulated to result from anomalous RNA processing.
Mol Cell Biol 1984 Sep
PMID:Structure of adenosine deaminase mRNAs from normal and adenosine deaminase-deficient human cell lines. 620 79

The isolated intact white adipocyte of the Swiss mouse responds to both ACTH and catecholamines by an elevation of cAMP levels and an increase in lipolysis. However, in the isolated plasma membrane of the mouse adipocyte, adenylate cyclase loses its responsiveness to ACTH but retains its ability to respond to catecholamines. This lack of responsiveness to ACTH by adenylate cyclase of mouse adipocyte plasma membrane can be overcome, at least partially, by addition of GPP (NH)p, an analog of GTP, to the assay medium. The data on mouse adipocyte membrane suggests that the coupling of ACTH receptor to adenylate cyclase is dependent on GTP and that catecholamine-activation of adenylate cyclase is less dependent on this nucleotide. The isolated intact white adipocyte of adult New Zealand rabbit responds to ACTH, but does not (or only weakly) respond to catecholamines. In contrast to the mouse plasma membrane preparation, adenylate cyclase of adipocyte membrane of the rabbit responds to ACTH. And the addition of GPP(NH)P is not required to demonstrate the CTH: sensitive adenylate cyclase activity. The difference between mouse and rabbit adipocyte membrane in the requirement for GPP(NH)P in ACTH action is not readily explained. The lack of catecholamine sensitivity of rabbit membrane enzyme cannot be reversed by addition of GPP(NH)P or adenosine deaminase. These two adenylate cyclase model systems using mouse and rabbit adipocyte plasma membrane may be useful tools for the study of the specificity and mechanism of action of lipolytic hormones such as ACTH and catecholamines.
Mol Cell Biochem 1981 Jan 20
PMID:Response of white adipocyte of mouse and rabbit to catecholamines and ACTH. 2. Stability and restoration of activity of hormone-sensitive adenylate cyclase of adipocyte plasma membrane. 626 26

Plasmodium falciparum trophozoites were isolated by mechanical rupture of infected human erythrocytes followed by a series of differential centrifugation steps. After lysis with sonication, the 100 000 x g supernatant of parasites and uninfected host cells was used to determine the specific activities of a number of enzymes involved in purine and pyrimidine metabolism. P. falciparum possessed the purine salvage enzymes: adenosine deaminase, purine nucleoside phosphorylase, hypoxanthine-guanine phosphoribosyltransferase (PRTase), xanthine PRTase, adenine PRTase, adenosine kinase. The last two enzymes, however, were present at much lower activity levels. Hypoxanthine was converted (presumably via IMP) into adenine and guanine nucleotides only in the presence both of supernatant and membrane fractions of P. falciparum. Two enzymes involved in the de novo synthesis of pyrimidines, orotic acid PRTase, and orotidine 5'-phosphate decarboxylase, were present in parasite extracts as were the enzymes for pyrimidine nucleotide phosphorylation: UMP-CMP kinase, dTMP kinase, nucleoside diphosphate kinase. Xanthine oxidase, CTP synthetase, cytidine deaminase and several kinases for the salvage of pyrimidine nucleosides were not detected in the parasites. Both phosphoribosyl pyrophosphate synthetase and uracil PRTase were present but at low activity levels. Human erythrocytes displayed similar but not identical enzyme patterns. Enzyme specific activities, however, were generally much lower than those of the corresponding parasite enzymes.
Mol Biochem Parasitol 1982 May
PMID:Enzymes of purine and pyrimidine metabolism from the human malaria parasite, Plasmodium falciparum. 628 90

Some enzymes of purine salvage were detected in the cell-free preparations from bloodstream forms of African trypanosomes: Trypanosoma vivax; T. brucei and T. congolense. Extracts of trypanosomes cleave adenosine and inosine hydrolytically except in T. congolense where adenosine cleavage was mediated by a phosphorylase. All the trypanosomes apparently lacked adenosine deaminase. Adenine aminohydrolase was found only in T. vivax while adenosine monophosphate deaminase was detected in T. brucei and T. congolense. There was no detectable adenosine kinase activity in T. brucei. A pathway is proposed for the metabolism of purines in these trypanosomes.
Mol Biochem Parasitol 1983 Dec
PMID:Comparative aspects of purine metabolism in some African trypanosomes. 641 98

The aliphatic adenine analogues, D-eritadenine, L-eritadenine, L-threoeritadenine, and 9-(S)-(2,3-dihydroxypropyl)adenine [(S)DHPA] function as inhibitors/inactivators of purified S-adenosylhomocysteine (AdoHcy) hydrolase, but these compounds did not induce reduction of enzyme-bound NAD+. D-Eritadenine, L-eritadenine, (S)DHPA, and L-threo-eritadenine inactivated AdoHcy hydrolase in hepatocytes, and the efficiency decreased in the order mentioned. Concurrently, there was an increase in the AdoHcy content. The accumulation of AdoHcy in the presence of (S)DHPA was more pronounced than would be expected from the inactivation of enzyme activity, suggesting that this compound may function as a reversible inhibitor as well. Furthermore, the inactivation of the intracellular enzyme by (S)DHPA is remarkable in the light of the fact that this compound induces no inactivation of purified AdoHcy hydrolase, but merely functions as an inhibitor of the enzyme. At low concentration of D-eritadenine (less than 6 microM), a distinct lag period could be demonstrated before accumulation of AdoHcy occurred. This suggests that the AdoHcy hydrolase activity must be decreased below a certain level to cause an increase in cellular AdoHcy. None of the analogues tested completely inactivated AdoHcy hydrolase and a residual enzyme activity was observed. The adenosine deaminase inhibitor, 2'-deoxycoformycin, did not potentiate the effect of these compounds on AdoHcy catabolism. The inactive enzyme formed in the presence of aliphatic adenine analogues was not reactivated under conditions where the inactivation induced by 9-beta-D-arabinofuranosyladenine was reversible.
Mol Pharmacol 1984 Nov
PMID:The effect of aliphatic adenine analogues on S-adenosylhomocysteine and S-adenosylhomocysteine hydrolase in intact rat hepatocytes. 649 10

Insulin action and insulin binding in isolated rat fat cells incubated with adenosine or adenosine deaminase were studied. Adenosine enhanced the effects of insulin on glucose transport and glucose metabolism. The nucleoside shifted the concentration-response curves of insulin-stimulated D-[3-3H]glucose incorporation into total lipids, and of D-[U-14C]glucose conversion to fatty acids to smaller insulin concentrations. In addition, the maximal response of the fatty acid synthesis was increased. Insulin sensitivity and maximal response to insulin of the glucose transport system, as assessed by the rate of uptake of 2-deoxyglucose and 3-O-methylglucose, were increased by adenosine. The adenosine derivative N6-phenylisopropyladenosine similarly enhanced deoxyglucose transport in the presence of insulin. However, insulin binding was not affected by adenosine. The results suggest that adenosine modulates insulin action at a step distal from the insulin receptor, and before, or at, the glucose transport system.
Mol Pharmacol 1982 Nov
PMID:Modulation of insulin sensitivity by adenosine. Effects on glucose transport, lipid synthesis, and insulin receptors of the adipocyte. 675 15

Adenosine kinase, adenosine deaminase, hypoxanthine phosphoribosyltransferase, inosine-nucleoside phosphorylase, 5'-AMP deaminase and 5'-IMP nucleotidase were identified in cell-free extracts of duckling erythrocytes; no evidence for 5'-AMP nucleotidase and xanthine oxidase activity was found. The Km values for the duckling red cell enzymes were similar to those reported for human erythrocytes. Plasmodium lophurae extracts demonstrated similar enzyme activities except for 5'-AMP deaminase and 5'-IMP nucleotidase which were absent. It is proposed that during infection erythrocytic AMP is catabolized to IMP, inosine and hypoxanthine; the hypoxanthine is taken up by the plasmodium, utilized to form IMP, and this in turn is converted into adenine and guanine nucleotides.
Mol Biochem Parasitol 1981 Apr
PMID:Purine metabolizing enzymes of Plasmodium lophurae and its host cell, the duckling (Anas domesticus) erythrocyte. 678 22

A deficiency of the enzyme adenosine deaminase is associated with an autosomal recessive form of severe combined immunodeficiency disease in man. The molecular forms of the normal human enzyme have now been well characterized in an effort to better understand the nature of the enzyme defect in affected patients. In some human tissues adenosine deaminase exists predominantly as a small molecular form while in other tissues a large form composed of adenosine deaminase (small form) and an adenosine deaminase-binding protein predominates. The small form of the enzyme purified to homogeneity by antibody affinity chromatography is a monomer of native molecular weight of 37,600. The adenosine deaminase-binding protein, purified by adenosine deaminase affinity chromatography, appears to be a dimer of native molecular weight 213,000 and contains carbohydrate. Based on direct binding measurements, chemical cross-linking studies and sedimentation equilibrium analyses, small form adenosine deaminase has been shown to combine with purified binding protein in a molar ratio of 2:1 respectively to produce the large form adenosine deaminase. Reduced, but widely ranging levels of adenosine deaminating activity, have been reported in various tissues of adenosine deaminase deficient patients. Further, the characteristics of this residual enzyme activity have been analyzed immunochemically to substantiate genetic heterogeneity in this disorder. While many types of immunodeficiency are currently recognized in man, in most cases the molecular defect is unknown. The discovery of a deficiency of the enzyme, adenosine deaminase, ADA, (EC 3.5.4.4), in some patients with severe combined immunodeficiency disease represented an early clue to the pathogenesis of immune dysfunction at the molecular level 1-4. Affected patients with markedly reduced levels of ADA exhibit a defect of both cellular and humoral immunity characterized clinically by severe recurrent infections with a fatal outcome if untreated. Attempts to elucidate the nature of the genetic mutation(s) leading to the reduction of ADA activity in these immunodeficient patients have been complicated in part by an incomplete understanding of the nature of ADA in normal tissues. In this review we will consider the structural characteristics of the normal and mutant forms of ADA as they are currently understood.
Mol Cell Biochem 1980 Feb 08
PMID:Analysis of normal and mutant forms of human adenosine deaminase - a review. 698 97

Adenosine deaminase (adenosine aminohydrolase, EC3.5.4.4) has been purified from human erythrocytes using a simple chromatographic procedure. Purified enzyme was obtained from individuals who were homozygous for the principal isozyme (ADA 1) as well as from individuals who were heterogyzous for the major variant (ADA 2-1). Although ADA 1 and ADA 2-1 are electrophoretically distinguishable, they have many common physical and catalytic properties. No significant differences between the two isozymic forms were found in measurements of molecular weight, catalytic activity in the presence of various substrates and inhibitors, pH optimum, turnover number, and stability in conditions of both high and low pH. ADA 2-1 was, however, substantially less stable than ADA 1 with respect to thermal denaturation. These studies support the idea that adenosine deaminase activity in erythrocytes is lower in those individuals who possess the variant form of the enzyme.
Mol Cell Biochem 1982 Oct 18
PMID:Physical and catalytic properties of the isozymes of adenosine deaminase from human red blood cells. 714 44

The structure of the human gene encoding the double-stranded RNA (dsRNA) adenosine deaminase (DRADA) was characterized. This nuclear localized enzyme is involved in the RNA editing required for the expression of certain subtypes of glutamate-gated ion channel subunits. The DRADA gene span 30 kb pairs and harbors 15 exons. The transcription of the DRADA gene driven by the putative promoter region, which contains no typical TATA or CCAAT box-like sequences, is initiated at multiple sites, 164 to 216 nucleotides upstream of the translation initiation codon. The three dsRNA binding motifs (DRBM), 70 amino acid residues long, are each encoded by two exons plus an intervening sequence that interrupts the motif at the identical amino acid position. This finding is consistent with the notion that the dsRNA binding domains may be composed of two separate functional subdomains. Fluorescent in situ hybridization localized the DRADA gene on the long arm chromosome 1, region q21. The gene structure and sequence information reported in this study will facilitate the investigation of involvement of DRADA in hereditary diseases that may be the result of malfunction of glutamate-gated ion channels.
J Mol Biol 1995 Nov 24
PMID:Genomic organization and chromosomal location of the human dsRNA adenosine deaminase gene: the enzyme for glutamate-activated ion channel RNA editing. 749 Jul 42

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