Analysis of normal and mutant forms of human adenosine deaminase — A review

Summary 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.     

Human adenosine deaminase. Purification and subunit structure.

Human erythrocyte adenosine deaminase has been purified approximately 800,000-fold to apparent homogeneity using antibody affinity chromatography. The enzyme was shown to be a single polypeptide chain with an estimated molecular weight of approximately 38,000. The three electrophoretic forms of erythrocyte adenosine deaminase purified simultaneously by this technique were indistinguishable by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. Several properties of the highly purified adenosine deaminase including pH optimum, Km for substrate, Ki for product, Stokes radius, sedimentation coefficient, and apparent substrate specificity were identical with the properties observed with an impure preparation of the enzyme.     

Purification and some properties of the soluble and membrane-bound adenosine deaminases of Micrococcus sodonensis ATCC 11880 and their distribution within the family Micrococcacea.

In Micrococcus sodonensis and some other Micrococcus species, adenosien deaminase is present both as a membran-bound and a soluble enzyme; The membran-bound adenosine deaminase can be extracted with n-butanol, and may account for up to 5% of the total cellular adenosine deaminase activity. In a number oc comparative tests, no differences between the two enzyme forms could be found, thus they are believed to be similar molecular species; The purified membran-bound or soluble enzyme had a molecular weight, obtained by gel-filtration, of 130 000 and was inactive toward adenine and adenine mononucleotides. It appears, therefore, to be more closely related to the calf-intestine enzyme than the Aspergillus oryzae form in respect to size and substrate specificity; Attempts to correlate membrane-bound adenosine deaminase activity with adenosine transport in isolated membrane vesicles of M. sodonensis indicated no obvious relationship between the two activities.     

Distribution of adenosine deaminase-complexing protein in murine tissues

It has been suggested that mouse and rat lack adenosine deaminase-complexing protein because in these species exclusively the small molecular weight form of adenosine deaminase (ADA-S) is found. This suggestion is based on the assumption that the adenosine deaminase binding capacity is an inherent functional characteristic of adenosine deaminase-complexing protein. We report on the presence of adenosine deaminase-complexing protein immunoreactivity in mouse and rat determined with a species cross-reactive polyclonal anti-adenosine deaminase-complexing protein serum. In the mouse the tissue and subcellular distribution and the electrophoretic mobility in starch and polyacrylamide gels of the protein correspond with those of adenosine deaminase-complexing protein, but it does not bind the small molecular weight form of adenosine deaminase. Furthermore, in human, mouse, and rat kidney cortex adenosine deaminase and adenosine deaminase-complexing protein did not colocalize by immunohistochemistry. It is suggested that the function of adenosine deaminase-complexing protein is not adenosine deaminase-related.     

Purification and characterization of adenosine deaminase from a genetically enriched mouse cell line

Mammalian adenosine deaminase has been shown by genetic and biochemical evidence to be essential for the development of the immune system. For the purpose of studying the function and structure of this enzyme, we have isolated by genetic selection a mouse cell line, B-1/50, in which adenosine deaminase levels were increased 4,300-fold over the parent cell line. The enzyme was purified from these cells in large quantity and high yield by a simple two-step purification scheme. The enzyme derived from the B-1/50 cells was indistinguishable from that of the parental cells as judged by several biochemical criteria. The Km (30 microM) and Ki (4 nM) values using adenosine as substrate and 2'-deoxycoformycin as inhibitor, respectively, were identical for the enzyme derived from the parental cells as well as the adenosine deaminase gene amplification mutants. The enzyme from both cell types exhibited multiple isoelectric focusing forms which co-purified using our purification protocol. Electrophoretic analysis using sodium dodecyl sulfate-polyacrylamide gels showed that adenosine deaminase migrated with an apparent molecular weight of 41,000 or 36,000 depending on whether the enzyme was reduced or oxidized, respectively. This shift was reversible, indicating that proteolysis was not responsible for the faster migrating form. Monospecific antibodies raised against purified adenosine deaminase cross-reacted with the enzyme derived from the parental cells and precipitated 37% of the total soluble protein in the B-1/50 cells. Continued genetic selection resulted in the isolation of cells in which adenosine deaminase was overproduced by 11,400-fold and accounted for over 75% of the soluble protein.     

Purine catabolism in man: characterization of placental microsomal 5'-nucleotidase.

Human placental microsomal 5'-nucleotidase (EC 3.1.3.5) was prepared free of alkaline phosphatase by isoelectric focusing. A total of seven electrophoretic variants were isolated during the preparation of six placentas. Only three to six variants were found in a single placenta. The isoelectric pH's were 6.70, 6.44, 6.23, 6.02, 5.76, 5.63 and 5.44. These were found to be composed of variable quantities of a large, medium and low molecular weight form. The apparent molecular weights of the medium and light form of the enzyme were 86 500 and 43 500, respectively, as estimated from Stokes radius and sedimentation velocity determinations. The electrophoretic variants were not distinguishable with respect to specific activity and Michaelis constants for AMP, GMP or CMP or inhibition by ATP, CTP or adenosine. These electrophoretic variants appeared to be pseudoisozymes based upon different states of aggregation of a common primary sequence. There was a wide range of substrate specificity among nucleoside 5'-monophosphates which included 2-deoxyribose compounds. With AMP as 100, substrate activity was: CMP, 122; NMN, 74; GMP, 68: IMP, 63; XMP, 28 and UDP-glucose, 68. The Michaelis constants for AMP, GMP and CMP ranged from 12-18 muM, from 33-67 muM and from 170-250 muM, respectively. Although 5'-nucleotidase was active in the absence of divalent cation, 5 mM MgCl2 stimulated the enzyme activity to 234% of control and shifted the pH optimum of 9.8 to a plateau from pH 7.4-9.8.     

The measurement of membrane potential during photosynthesis and during respiration in intact cells of Rhodopseudomonas capsulata by both electrochromism and by permeant ion redistribution.

Adenosine deaminase was purified 3038-fold to apparent homogeneity from human leukaemic granulocytes by adenosine affinity chromatography. The purified enzyme has a specific activity of 486 mumol/min per mg of protein at 35 degrees C. It exhibits a single band when subjected to sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, non-denaturing polyacrylamide-gel electrophoresis and isoelectric focusing. The pI is 4.4. The enzyme is a monomeric protein of molecular weight 44000. Both electrophoretic behaviour and molecular weight differ from those of the low-molecular-weight adenosine deaminase purified from human erythrocytes. Its amino acid composition is reported. Tests with periodic acid-Schiff reagent for associated carbohydrate are negative. Of the large group of physiological compounds tested as potential effectors, none has a significant effect. The enzyme is specific for adenosine and deoxyadenosine, with Km values of 48 microM and 34 microM respectively. There are no significant differences in enzyme function on the two substrates. erythro-9-(2-Hydroxy non-3-yl) adenine is a competitive inhibitor, with Ki 15 nM. Deoxycoformycin inhibits deamination of both adenosine and deoxyadenosine, with an apparent Ki of 60-90 pM. A specific antibody was developed against the purified enzyme, and a sensitive radioimmunoassay for adenosine deaminase protein is described.     

Comparison of two forms of pig heart phosphoprotein phosphatase.

A phosphoprotein phosphatase (phosphoprotein phosphohydrolase, EC 3.1.3.16) was partially purified from pig heart using as substrate H2B histone which had been phosphorylated at Ser-32 and Ser-36 by adenosine 3',5'-monophosphate-dependent protein kinase (EC 2.7.1.37). The enzyme had a molecular weight of approx. 250 000 and was converted to a smaller form with a molecular weight of approx. 30 000 upon treatment with ethanol. Phosphorylase alpha (EC 2.4.1.1) and phosphorylated H1 histone also served as substrates for both forms of the enzyme. The conversion of the large form of the enzyme to the small form decreased the phosphohistone phosphatase activity to 25-50% with a concomitant 7-fold increase in the phosphorylase alpha phosphatase activity. Ser-36 phosphate was removed 6- and 15-fold more rapidly than was Ser-32 phosphate by the large and small forms of the enzyme, respectively. Among Ser-36-containing tryptic phosphopeptides derived from phosphorylated H2B histone, Lys-Glu-Ser(P)-Tyr-Ser-Val-Tyr was the shortest phosphopeptide which was dephosphorylated at a significant reaction rate with the phosphoprotein phosphatase. The Km values for phosphorylated H2B histone and the tryptic phosphopeptide were 23.7 micron and 187.1 micron, respectively, with the large form, and 81.4 micron and 90.0 micron, respectively, with the small form of the enzyme.     

Protein kinase activities in Neurospora crassa

Adenosine deaminase (adenosine aminohydrolase, EC 3.5.4.4) 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.     

Genetic expression in partial adenosine deaminase deficiency. mRNA levels and protein turnover for the enzyme variants in human B-lymphoblast cell lines

A severe genetic deficiency of adenosine deaminase is causally associated with an autosomal recessive form of severe combined immunodeficiency disease, while subjects with absent erythrocyte but partial lymphocyte enzyme activity remain immunocompetent. The genetic expression of adenosine deaminase in B-lymphoblast cell lines derived from four unrelated subjects with the "partial" enzyme deficiency was examined. Enzymatic activity among these cell lines ranged from 5 to 50% of normal with the level of immunoreactive adenosine deaminase protein either proportional to enzyme activity or elevated in two of the cases. Northern blot analysis using a cDNA probe showed that adenosine deaminase mRNA in each of these cell lines was of normal expected size (1.6-1.8 kilobases) and was present in normal to above normal amounts. Rates of enzyme synthesis varied from 165 to 15% of normal. Adenosine deaminase protein degradation rates in these cell lines were 1.5 to almost 3 times faster than normal, consistent with the observed absence of the enzyme in erythrocytes. From these analyses apparent abnormalities in mRNA regulation, translation, and protein degradation can be identified among the partially adenosine deaminase-deficient cell lines studied. Ultimately, it will be essential to determine the nature of the protein mutation and the gene defect to define the structural alterations and functional abnormalities of enzyme variants isolated from subjects with partial adenosine deaminase deficiency.     

A novel type of phosphofructokinase from plants

A phosphofructokinase (PFK) has been purified to homogeneity from carrot roots as a large aggregated form (molecular weight greater than 5 million). The purified plant PFK, seemingly the cytosolic form, differed from its mammalian counterpart in a lower subunit molecular weight (60,000 verses 80,000), in being only sluggishly activated by fructose-2,6-bisphosphate, and in immunological properties. Similar to liver PFK, the purified carrot PFK could be dissociated by addition of 5 mM ATP to small and intermediate forms (respective molecular mass values of 2.4 X 10(5) and 6 X 10(5) Da). These small and intermediate forms could partially reassociate to the original large form in the presence of 5 mM Fru-6-P. Alkaline pH also effected the dissociation of the large and intermediate forms to the small form of PFK. All forms were present in significant amounts in freshly prepared carrot root extracts. The different forms of PFK showed characteristic pH activity profiles with pH optima of 8.6 (small form), 5.5 and 9.0 (intermediate form), and 7.0 and 8.5 (large forms). As alkaline pH (greater than or equal to approximately 8.5) dissociated the large and intermediate enzyme forms to yield the small form, it was concluded the "true" pH optima of the intermediate and large forms are pH 5.5 and 7.0, respectively. The pH optimum displayed by the intermediate and large forms in the alkaline region (pH 8.5-9.0) was considered to be due to their dissociation during assay. The different forms of PFK also had dissimilar regulatory properties, each showing a characteristic response to ATP, citrate, and Pi, but all were sensitive to inhibition by phosphoenolpyruvate and NADPH. Leaf cytosolic PFK, partially purified from spinach, showed similar properties. The results suggest that metabolite-dependent aggregation-disaggregation is a mechanism whereby plants regulate the activity of cytosolic PFK and the accompanying rate of glycolytic carbon flux.     

Amplification of adenosine deaminase gene sequences in deoxycoformycin-resistant rat hepatoma cells

Deoxycoformycin-resistant rat hepatoma cells exhibit up to a 2000-fold increase in adenosine deaminase activity compared to the sensitive parental cells. The increased enzyme activity in these cells is accompanied by similar increases in 1) the amount of adenosine deaminase protein, 2) the relative rate of adenosine deaminase synthesis in vivo, and 3) adenosine deaminase mRNA activity. To further investigate the mechanism(s) responsible for the overproduction of adenosine deaminase in these cells, we have isolated a recombinant plasmid containing a 1.4-kilobase insert complementary to at least part of the adenosine deaminase mRNA. Using this cDNA as a specific hybridization probe, all deoxycoformycin-resistant variants were shown to have increased amounts of adenosine deaminase mRNA and gene sequences. The relative increase in the level of mRNA and gene copy number was similar to the relative increase in enzyme activity for most resistant cell lines. However, the degree of adenosine deaminase gene amplification in one deoxycoformycin-resistant cell line (6-10-200) was 3-4-fold less than the relative increase in adenosine deaminase mRNA. These results indicate that the increased adenosine deaminase activity in deoxycoformycin-resistant rat hepatoma cells is due in large part, but not exclusively, to gene amplification.     

Bovine skeletal muscle adenosine deaminase. Purification and some properties

A low molecular weight form of adenosine deaminase from bovine skeletal muscle was purified about 930-fold. The enzyme had a mol. wt of 31,000, a Km value for adenosine of 2.37 X 10(-5) M and a pH optimum at 7.0. This enzyme is very resistant to heat inactivation and does not require metal activators or other dialysable cofactors. A possible role in the post-mortem metabolism of adenine nucleotide in skeletal muscle is discussed.     

Distribution of adenosine deaminase in some rat tissues. Inhibition by ethanol and dimethyl sulfoxide

The level of adenosine deaminase in various rat tissues has been tested. The enzyme activity of cytosolic fractions decreased in the following order: lung greater than spleen greater than small intestine greater than stomach greater than kidney greater than heart greater than liver greater than skeletal muscle greater than forebrain greater than cerebellum. The enzyme had identical patterns from tissue to tissue with respect to Km, V, and Ki values for ethanol and for dimethyl sulfoxide, with respect to electrophoretic behaviour and to inhibition by antibodies anti-rat brain adenosine deaminase.     

PURIFICATION OF PROTEIN CARBOXYMETHYLASE FROM OX BRAIN

Abstract— The enzyme protein carboxymethylase from the soluble fraction of ox brain was purified to electrophoretic homogeneity. Brain protein carboxymethylase activity was also detected in a membrane-bound form which could only be solubilized by treatment with detergent. The solubilized membrane-bound form differed from the 'native' soluble form in that the former irreversibly lost activity on removal of the detergent. The two forms, however, have several similarities, having a molecular weight of 35,000, a K _m of 2.7 × 10⁻⁶ M for S -adenosyl-L-methionine, and a pH optimum of 6.2 when ovalbumin was used as the methyl acceptor.     

Adenosine deaminase from camel tick Hyalomma dromedarii: purification and characterization

Adenosine deaminase is involved in purine metabolism and is a key enzyme for the control of the cellular levels of adenosine. Adenosine deaminase activity showed significant changes during embryogenesis of the camel tick Hyalomma dromedarii. From the elution profile of chromatography on DEAE-sepharose, three forms of enzyme (ADAI, ADAII and ADAIII) were separated. ADAII was purified to homogeneity after chromatography on Sephacryl S-200. The molecular mass of adenosine deaminase ADAII was 42 kDa for the native enzyme and represented a monomer of 42 kDa by SDS-PAGE. The enzyme had a pH optimum at 7.5 and temperature optimum at 40°C with heat stability up to 40°C. ADAII had a K _m of 0.5 mM adenosine with higher affinity toward deoxyadenosine and adenosine than other purines. Ni²⁺, Ba²⁺, Zn²⁺, Li²⁺, Hg²⁺ and Mg²⁺ partially inhibited the ADAII. Mg²⁺ was the strongest inhibitor by 91% of the enzyme's activity.     

Presence of Escherichia coli of a deaminase and a reductase involved in biosynthesis of riboflavin.

Two enzymes have been partially purified from extracts of Escherchia coli B which together catalyze the conversion of the product of the action of GTP cyclohydrolase II, 2,5-diamino-6-oxy-4-(5'-phosphoribosylamine)pyrimidine, to 5-amino-2,6-dioxy-4-(5'-phosphoribitylamine)pyrimidine. These two compounds are currently thought to be intermediates in the biosynthesis of riboflavin. The enzymatic conversion occurs in two steps. The product of the action of GTP cyclohydrolase II first undergoes hydrolytic deamination at carbon 2 of the ring, followed by reduction of the ribosylamino group to a ribitylamino group. The enzyme which catalyzes the first step, herein called the "deaminase," has been purified 200-fold. The activity was assayed by detecting the conversion of the product of the reaction catalyzed by GTP cyclohydrolase II to a compound which reacts with butanedione to form 6,7-dimethyllumazine. The enzyme has a molecular weight of approximately 80,000 and a pH optimum of 9.1. The dephosphorylated form of the substrate is not deaminated in the presence of the enzyme. The assay for the enzyme which catalyzes the second step, referred to here as the "reductase," involves the detection of the conversion of the product of the deaminase-catalyzed reaction to a compound which, after treatment with alkaline phosphatase, reacts with butanedione to form 6,7-dimethyl-8-ribityllumazine. The reductase has a molecular weight of approximately 40,000 and a pH optimum of 7.5. Like the deaminase, the reductase does not act on the dephosphorylated form of its substrate. Reduced nicotinamide adenine dinucleotide phosphate is required as a cofactor; reduced nicotinamide adenine dinucleotide can be used about 30% as well as the phosphate form. The activity of neither enzyme is inhibited by riboflavin, FMN, or flavine adenine dinucleotide.     

Adenosine deaminase from bovine brain: purification and partial characterization.

Bovine brain adenosine deaminase cytoplasmatic form was purified about 450 fold by salt fractionation, column chromatography on DEAE-cellulose, octyl-sepharose 4B and affinity chromatography on CH-sepharose 4B 9-(p-aminobenzyl)adenine. The purified enzyme was homogeneous on disc gel electrophoresis; the enzyme had a molecular mass of about 65 kDa with an isoelectric point at pH 4.87. The Km values for adenosine and 2'-deoxyadenosine were 4 x 10(-5) and 5.2 x 10(-5) M, respectively. The enzyme showed a great stability to temperature with a half life of 15 hours at 53 degrees C significantly different compared to that known for other mammalian forms of this enzyme. Aza and deaza analogs of adenosine and erythro-9-(2-hydroxy-3-nonyl) adenine were good inhibitors of the bovine brain enzyme with little difference with respect to those reported for the adenosine deaminases purified from other sources. Kinetic constants for the association and dissociation of coformycin and 2'-deoxycoformycin with the bovine brain adenosine deaminase are reported.     

Membrane milieu is regarded as the native environment of the cyclic AMP degrading enzyme cluster

The phenomenon of kinetic advantage of nucleoside formation from cyclic AMP, via the intermediate 5'AMP has been observed in the microsomal fraction after subcellular fractionation of beef adrenal cortex tissue. It was explained by the existence of a multienzyme sequence previously evidenced [H. Wombacher, 1982, Arch. Biochem. Biophys. 201, 8-19]. In the present study a similar enzyme cluster was prepared from the soluble fraction of the cell homogenate after two steps of gel-chromatography. An elusive channeling of cyclic AMP degradation could be disclosed. The time course reaction of cyclic AMP degradation to the nucleosides, adenosine and inosine, via 5'AMP as an intermediate compared with the time course reaction of 5'AMP hydrolysis to the nucleosides, adenosine and inosine, under otherwise identical conditions showed that the nucleoside formation from cyclic AMP was faster after the lag phase of the reaction sequence. This kinetic advantage effect, however, was much less pronounced than to be seen in the membrane-bound multienzyme sequence. For an analysis of the influence of the environmental conditions on the activity of both enzyme cluster forms they were treated by chaotropic agents, detergents and ultrasonic power. Common to all results was: the activity of the membrane-bound enzyme cluster is highly stable in comparison with the soluble form. On basis of these and previous findings a hypothesis is suggested explaining the similarities between the membrane-bound enzyme cluster and the soluble form. Thus, the soluble enzyme cluster form is considered a partially preserved form of the membrane-bound form arisen from the cell homogenization process and/or vice versa the soluble form might present a pro-form of the membrane-bound enzyme cluster, and the most stable and active assembly has to be yet first membrane-triggered.     

Adenosine deaminase of cultured brain cells

Two types of adenosine deaminase (EC 3.5.4.4) were found in cultured cells of central-nervous-system origin. The predominant and more active enzyme was obtained in soluble form from the cytosol of mouse neuroblastoma (N-18), neonatal hamster astrocytes (NN), human oligodendroglioma (HOL) and human astrocytoma (Cox Clone). Particulate adenosine deaminase was probably associated with the plasma membrane. When radioactive adenosine was added to superfusates of monolayer cultures it was rapidly converted into inosine and hypoxanthine. The metabolic conversion required adenosine uptake by the cells, a probable transition through the intracellular ATP pool(s) and a rapid excretion into the superfusate of the catabolic products. We discuss the evidence that points to adenosine and its derivatives as neurohumoral modulators of central-nervous-system function.