A study on the inhibition of adenosine deaminase

Adenosine deaminase (ADA, EC 3.5.4.4) catalyses the irreversible deamination of adenosine and 2'-deoxyadenosine to inosine and 2'-deoxyinosine, respectively. In this study the inhibition of ADA from bovine spleen by several molecules with structure related to that of the substrate or product has been quantified. The inhibitors adenine, purine, inosine, 2-aminopurine, 4-aminopyrimidine, 4-aminopyridine, 4-hydroxypyridine and phenylhydrazine are shown to be competitive inhibitors with K(I) (mM) values of 0.17, 1.1, 0.35, 0.33, 1.3, 1.8, 1.4 and 0.25, respectively. Synergistic inhibition by various combinations of molecules that imitate the structure of the substrate has never been observed. Some general conclusions are: i) the enzyme ADA from bovine spleen we have used is appropriate for kinetic studies of inhibition and mechanistic studies; it can be a reference catalytic system for the homogeneous comparison of various inhibitors; ii) this enzyme presents very rigid requirements for binding the substrate: variations in the structure of adenosine imply the loss of important interactions.     

Adenosine aminohydrolase inhibition in cosolvent--buffer mixtures

Adenosine aminohydrolase from calf intestinal mucosa is sensitive to changes in the cooperative water structure of its environment as induced by the cosolvent dioxane. When dioxane is added to lower the dielectric constant from that of 78 of neat water to about 74, V is approximately halved, competitive inhibition by N⁶-(Δ²-isopentenyl)adenosine is virtually abolished, and competitive inhibition by the product of the reaction, i.e., inosine, is significantly decreased (K_i changes from 0.2 to 0.5 mm inosine). Yet K_m remains unaltered at 40 μm adenosine even to a dielectric constant of 66.Since both N⁶-(Δ²-isopentenyl)adenosine and inosine are competitive inhibitors, they cannot be bound by the enzyme at the same time as adenosine. The fact that substrate binding remains unaltered at dielectric constants where these inhibitors are impotent indicates that binding of these inhibitors by portions of the enzyme not directly involved in substrate binding is important. The degree of alteration of binding with increasing dioxane concentration is different for these two inhibitors, with appreciable inosine binding at mole fractions dioxane where N⁶-(Δ²-isopentenyl)-adenosine binding cannot be demonstrated. Because of this differential effect of dioxane on inosine and N⁶-(Δ²-isopentenyl)adenosine binding, it is apparent that two substances can be competitive inhibitors kinetically and yet be bound differently by an enzyme. Cosolvents may thus be useful probes for the study of enzyme inhibitor interactions. It is proposed that studies of cosolvent effects on enzyme catalysis and substrate and inhibitor binding are capable of revealing the sensitivities of these various sites to alterations in the dielectric constant of the medium and thus may be considered as models for enzyme behavior near cytoplasmic membranes in vivo.     

Structure-Activity Relationships of Adenosine Deaminase Inhibitors

Abstract

Adenosine deaminase (ADA) is an important catabolic enzyme which converts adenosine and deoxyadenosine to inosine and deoxyinosine, respectively. ADA exists in two different isoenzymes, namely ADA1 and ADA2, whose balance in monocytes-macrophages seems to guarantee the homeostasis of adenine nucleosides. Modifications of the purine moiety or/and substitution of the sugar moiety of adenosine with aliphatic chains led to derivatives which are good ADA inhibitors.     

Use of the integrated steady state rate equation to investigate product inhibition of human red cell adenosine deaminase and its relevance to immune dysfunction

The analysis of progress curves using the integrated rate equation was applied to the adenosine deaminase-catalyzed conversion of adenosine to inosine. Adenosine deaminase was purified from human red blood cells of phenotypes ADA 1, ADA 2, and ADA 2-1. For all three types, no measurable product inhibition by inosine was observed. These results do not confirm the hypothesis that inosine accumulation in purine nucleoside phosphorylase deficiency causes adenosine deaminase inhibition, resulting in a common mechanism for the immune defects related to these two enzyme deficiencies.     

Interaction of adenosine deaminase with inhibitors. Chemical modification by diethyl pyrocarbonate

The interaction of adenosine deaminase (adenosine aminohydrolase, ADA) from bovine spleen with inhibitors— erythro-9-(2-hydroxy-3-nonyl)adenine, erythro-9-(2-hydroxy-3-nonyl)-3-deazaadenine, and 1-deazaadenosine—was investigated. Using selective chemical modification by diethyl pyrocarbonate (DEP), the possible involvement of His residues in this interaction was studied. The graphical method of Tsou indicates that of six His residues modified in the presence of DEP, only one is essential for ADA activity. Inactivation of the enzyme, though with low rate, in complex with any of the inhibitors suggests that the adenine moiety of the inhibitors (and consequently, of the substrate) does not bind with the essential His to prevent its modification. The absence of noticeable changes in the dissociation constants of any of the enzyme–inhibitor complexes for the DEP-modified and control enzyme indicates that at least the most available His residues modified in our experiments do not participate in binding the inhibitors—derivatives of adenosine or erythro-9-(2-hydroxy-3-nonyl)adenine.     

Adenosine deaminase prefers a distinct sugar ring conformation for binding and catalysis: kinetic and structural studies

Several recent X-ray crystal structures of adenosine deaminase (ADA) in complex with various adenosine surrogates have illustrated the preferred mode of substrate binding for this enzyme. To define more specific structural details of substrate preferences for binding and catalysis, we have studied the ADA binding efficiencies and deamination kinetics of several synthetic adenosine analogues in which the furanosyl ring is biased toward a particular conformation. NMR solution studies and pseudorotational analyses were used to ascertain the preferred furanose ring puckers (P, nu(MAX)) and rotamer distributions (chi and gamma) of the nucleoside analogues. It was shown that derivatives which are biased toward a "Northern" (3'-endo, N) sugar ring pucker were deaminated up to 65-fold faster and bound more tightly to the enzyme than those that preferred a "Southern" (2'-endo, S) conformation. This behavior, however, could be modulated by other structural factors. Similarly, purine riboside inhibitors of ADA that prefer the N hemisphere were more potent inhibitors than S analogues. These binding propensities were corroborated by detailed molecular modeling studies. Docking of both N- and S-type analogues into the ADA crystal structure coordinates showed that N-type substrates formed a stable complex with ADA, whereas for S-type substrates, it was necessary for the sugar pucker to adjust to a 3'-endo (N-type) conformation to remain in the ADA substrate binding site. These data outline the intricate structural details for optimum binding in the catalytic cleft of ADA.     

Allosteric regulation of purine nucleoside phosphorylase.

Purine nucleoside phosphorylase (EC 2.4.2.1) from bovine spleen is allosterically regulated. With the substrate inosine the enzyme displayed complex kinetics: positive cooperativity vs inosine when this substrate was close to physiological concentrations, negative cooperativity at inosine concentrations greater than 60 microM, and substrate inhibition at inosine greater than 1 mM. No cooperativity was observed with the alternative substrate, guanosine. The activity of purine nucleoside phosphorylase toward the substrate inosine was sensitive to the presence of reducing thiols; oxidation caused a loss of cooperativity toward inosine, as well as a 10-fold decreased affinity for inosine. The enzyme also displayed negative cooperativity toward phosphate at physiological concentrations of Pi, but oxidation had no effect on either the affinity or cooperativity toward phosphate. The importance of reduced cysteines on the enzyme is thus specific for binding of the nucleoside substrate. The enzyme was modestly inhibited by the pyrimidine nucleotides CTP (Ki = 118 microM) and UTP (Ki = 164 microM), but showed greater sensitivity to 5-phosphoribosyl-1-pyrophosphate (Ki = 5.2 microM).     

Recognition of Ribose Moiety by Adenosine (Phosphate) Deaminase from Squid Liver

An adenosine (phosphate) deaminase from the squid liver had much lower activity for 5′-deoxyadenosine than that for adenosine, 2′-, or 3′-deoxyadenosine. 3′-IMP and inosine as well as purine riboside and adenine competitively inhibited the deamination of adenosine 3′ phenylphosphonate by the enzyme, but 5′-AMP and 5′-IMP did not. The enzyme deaminated the 5′-hydroxyl terminal adenosine residue in dinucleotides and trinucleotide, but not the 3′-hydroxyl terminal one in dinucleotides. The 5′-hydroxyl group of the ribose moiety was necessary for the substrate binding and catalytic activity of the squid enzyme. These results indicated that the recognition of ribose moiety in the substrate by the squid enzyme might be intermediate between those by adenosine deaminase and adenosine (phosphate) deaminase from microorganisms.     

Probing Aplysia californica adenosine 5'-diphosphate ribosyl cyclase for substrate binding requirements: design of potent inhibitors.

Readily synthesized nicotinamide adenine dinucleotide (NAD(+)) analogues have been used to investigate aspects of the cyclization of NAD(+) to cyclic adenosine 5'-O-diphosphate ribose (cADPR) catalyzed by the enzyme adenosine 5'-O-diphosphate (ADP) ribosyl cyclase and to produce the first potent inhibitors of this enzyme. In all cases, inhibition of Aplysia californica cyclase by various substrate analogues was found to be competitive while inhibition by nicotinamide exhibited mixed-behavior characteristics. Nicotinamide hypoxanthine dinucleotide (NHD(+)), nicotinamide guanine dinucleotide (NGD(+)), C1'-m-benzamide adenine dinucleotide (Bp(2)A), and C1'-m-benzamide nicotinamide dinucleotide (Bp(2)N) were found to be nanomolar potency inhibitors with inhibition constants of 70, 143, 189, and 201 nM, respectively. However, NHD(+) and NGD(+) are also known substrates and are slowly converted to cyclic products, thus preventing their further use as inhibitors. The symmetrical bis-nucleotides, bis-adenine dinucleotide (Ap(2)A), bis-hypoxanthine dinucleotide (Hp(2)H), and bis-nicotinamide dinucleotide (Np(2)N), exhibited micromolar competitive inhibition, with Ap(2)A displaying the greatest affinity for the enzyme. 2',3'-Di-O-acetyl nicotinamide adenine dinucleotide (AcONAD(+)) was not a substrate for the A. californica cyclase but also displayed some inhibition at a micromolar level. Finally, inhibition of the cyclase by adenosine 5'-O-diphosphate ribose (ADPR) and inosine 5'-O-diphosphate ribose (IDPR) was observed at millimolar concentration. The nicotinamide aromatic ring appears to be the optimal motif required for enzymatic recognition, while modifications of the 2'- and 3'-hydroxyls of the nicotinamide ribose seem to hamper binding to the enzyme. Stabilizing enzyme/inhibitor interactions and the inability of the enzyme to release unprocessed material are both considered to explain nanomolar inhibition. Recognition of inhibitors by other ADP ribosyl cyclases has also been investigated, and this study now provides the first potent nonhydrolyzable sea urchin ADP ribosyl cyclase and cADPR hydrolase inhibitor Bp(2)A, with inhibition observed at the micromolar and nanomolar level, respectively. The benzamide derivatives did not inhibit CD38 cyclase or hydrolase activity when NGD(+) was used as substrate. These results emphasize the difference between CD38 and other enzymes in which the cADPR cyclase activity predominates.     

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.     

Synthesis and Evaluation of an RNA Editing Substrate Bearing 2′-Deoxy-2′-Mercaptoadenosine

The RNA-editing adenosine deaminases (ADARs) catalyze deamination of adenosine to inosine in double stranded structure found in various RNA substrates, including mRNAs. Here we describe the synthesis of a phosphoramidite of 2 ′-deoxy-2 ′-mercaptoadenosine and its incorporation into an ADAR substrate. Surprisingly, no deamination product was observed with this substrate indicating replacing the 2 ′-OH with a 2 ′-SH at the editing site is highly inhibitory. Modeling of nucleotide binding into the active site suggests the side chain of T375 of human ADAR2 to be in proximity of the 2 ′-substituent. Mutation of this residue to cysteine caused a greater that 100-fold reduction in deamination rate with the 2 ′-OH substrate.     

Evidence for two variants of poly(adenosine diphosphate ribose) glycohydrolase in rat testis.

The specific activity of rat poly(adenosine diphosphate ribose) glycohydrolase was higher in the testis than in the liver, brain, spleen or kidney. The enzyme was found primarily in the soluble fraction of the testis. When the soluble enzyme was chromatographed on phosphocellulose, the activity eluted in two peaks, at 0.22 and 0.34 m KCl, respectively, referred to in the present study as enzyme A and B. Enzyme A has an optimal pH of 7.25 and was stimulated by 150 mm KCl. The optimal pH of enyzme B was 6.5, but it was not stimulated by KCl. For maximal activity both enzymes required 10 mm 2-mercaptoethanol, and they were strongly inhibited by 100 μmp-chloromercuribenzoate. The K_m values of enzyme A and B for poly(adenosine diphosphate ribose) were 1.52 and 0.70 μm, respectively. Ribose 5′-phosphate, guanosine 3′,5′-monophosphate, adenosine 3′,5′-monophosphate and adenosine diphosphate ribose inhibited both enzymes. The two latter nucleotides behave as noncompetitive inhibitors. Denatured DNA and the homopolypurines poly(G), poly(I) and poly(A) were very potent inhibitors of both glycohydrolases. The mode of hydrolysis of poly(adenosine diphosphate ribose) by glycohydrolases A and B was exoglycosidic, yielding adenosine diphosphate ribose as the final product.     

Bovine skeletal muscle adenosine deaminase: kinetic and thermodynamic studies

Adenosine deaminase from bovine skeletal muscle catalyzes the hydrolytic deamination of adenosine to inosine and ammonia via an ordered Uni-Bi mechanism, if water is not considered as a true second substrate, as deduced from the inhibition pattern products. The inhibition constants (Ki) obtained for inosine and ammonia were 316 mumol/l and 2 mol/l, respectively. The activation energy of the reaction has been calculated as 10 kcal/mol, delta H* and delta F* as 7.9 and 15.6 kcal/mol, respectively, and delta S* as -23 cal/mol/degrees K.     

9-[(Hydroxymethyl)phenyl]adenines: new aryladenine substrates of adenosine deaminase

New phenyl adenine compounds 5-7 were synthesized as analogues of adenosine and studied for their adenosine deaminase (ADA) substrate activity. The 9-[(o-hydroxymethyl)phenyl]methyl]adenine 5 and 9-[(m-hydroxymethyl)phenyl]adenine 7 were deaminated by ADA, and 9-[(o-hydroxyethyl)phenyl]adenine 6 was not deaminated up to 7 days. The ADA substrates 5 and 7 were deaminated quantitatively to their inosine analogues in 10 and 6h, respectively.     

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.     

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.     

A Kinetic Study of the Rat Liver Adenosine Kinase Reverse Reaction

Adenosine kinase is an enzyme catalyzing the reaction: adenosine + ATP → AMP + ADP. We studied some biochemical properties not hitherto investigated and demonstrated that the reaction can be easily reversed when coupled with adenosine deaminase, which transforms adenosine into inosine and ammonia. The overall reaction is: AMP + ADP → ATP + inosine + NH₃. The exoergonic ADA reaction shifts the equilibrium and fills the energy gap necessary for synthesis of ATP. This reaction could be used by cells under particular conditions of energy deficiency and, together with myokinase activity, may help to restore physiological ATP levels.     

Purification and characterization of Plasmodium yoelii adenosine deaminase

Plasmodium lacks the de novo pathway for purine biosynthesis and relies exclusively on the salvage pathway. Adenosine deaminase (ADA), first enzyme of the pathway, was purified and characterized from Plasmodium yoelii, a rodent malarial species, using ion exchange and gel exclusion chromatography. The purified enzyme is a 41 kDa monomer. The enzyme showed K_m values of 41 μM and 34 μM for adenosine and 2′-deoxyadenosine, respectively. Erythro-9-(2-hydroxy-3-nonyl) adenine competitively inhibited P. yoelii ADA with K_i value of 0.5 μM. The enzyme was inhibited by DEPC and protein denaturing agents, urea and GdmCl. Purine analogues significantly inhibited ADA activity. Inhibition by p-chloromercuribenzoate (pCMB) and N-ethylmaleimide (NEM) indicated the presence of functional –SH groups. Tryptophan fluorescence maxima of ADA shifted from 339 nm to 357 nm in presence of GdmCl. Refolding studies showed that higher GdmCl concentration irreversibly denatured the purified ADA. Fluorescence quenchers (KI and acrylamide) quenched the ADA fluorescence intensity to the varied degree. The observed differences in kinetic properties of P. yoelii ADA as compared to the erythrocyte enzyme may facilitate in designing specific inhibitors against ADA.     

The ecto-enzymes CD73 and adenosine deaminase modulate 5′-AMP-derived adenosine in myofibroblasts of the rat small intestine

Adenosine is a versatile signaling molecule recognized to physiologically influence gut motor functions. Both the duration and magnitude of adenosine signaling in enteric neuromuscular function depend on its availability, which is regulated by the ecto-enzymes ecto-5′-nucleotidase (CD73), alkaline phosphatase (AP), and ecto-adenosine deaminase (ADA) and by dipyridamole-sensitive equilibrative transporters (ENTs). Our purpose was to assess the involvement of CD73, APs, ecto-ADA in the formation of AMP-derived adenosine in primary cultures of ileal myofibroblasts (IMFs). IMFs were isolated from rat ileum longitudinal muscle segments by means of primary explant technique and identified by immunofluorescence staining for vimentin and α-smooth muscle actin. IMFs confluent monolayers were exposed to exogenous 5′-AMP in the presence or absence of CD73, APs, ecto-ADA, or ENTs inhibitors. The formation of adenosine and its metabolites in the IMFs medium was monitored by high-performance liquid chromatography. The distribution of CD73 and ADA in IMFs was detected by confocal immunocytochemistry and qRT-PCR. Exogenous 5′-AMP was rapidly cleared being almost undetectable after 60-min incubation, while adenosine levels significantly increased. Treatment of IMFs with CD73 inhibitors markedly reduced 5′-AMP clearance whereas ADA blockade or inhibition of both ADA and ENTs prevented adenosine catabolism. By contrast, inhibition of APs did not affect 5′-AMP metabolism. Immunofluorescence staining and qRT-PCR analysis confirmed the expression of CD73 and ADA in IMFs. Overall, our data show that in IMFs an extracellular AMP-adenosine pathway is functionally active and among the different enzymatic pathways regulating extracellular adenosine levels, CD73 and ecto-ADA represent the critical catabolic pathway.