Adenosine kinase from human erythrocytes: kinetic studies and characterization of adenosine binding sites

Hawkins, Christopher F.; Bagnara, Aldo S.

doi:10.1021/bi00381a030

Cited by 55 publications

(56 citation statements)

References 33 publications

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“…Since the adenosine 1 binding site is significantly more buried and further from the solvent interface than adenosine 2, it seems reasonable to postulate that, without invoking a protein conformational change, adenosine binds prior to ATP. This is consistent with most of the earlier kinetic studies (21)(22)(23)(24) but not all (20).…”

Section: Discussionsupporting

confidence: 93%

“…Our studies confirm the presence of both binding sites and suggest that the substrate inhibition is due to competitive inhibition of ATP binding. It should be noted, however, that the latter conclusion is inconsistent with other kinetic data showing adenosine to be a noncompetitive inhibitor of ATP binding (21) 1 and with conclusions drawn from DTNB inactivation studies suggesting that the ATP-binding site is distinct from the two adenosine sites (23). These conclusions were based primarily on the failure of ATP to inhibit AK inactivation by DTNB, whereas inactivation was prevented by adenosine but only at concentrations an order of magnitude greater than the estimated dissociation constant for adenosine at the catalytic site.…”

Section: Discussionmentioning

confidence: 64%

“…Studies with partially purified adenosine kinase from Ehrlich ascites tumor cells identified ATP as the first substrate to bind and AMP as the last product to be released (20). Other studies, however, predicted adenosine to be the first substrate to bind (21)(22)(23)(24) while still others predicted ADP to be the last substrate to leave (15).…”

mentioning

confidence: 99%

“…Saturation kinetics suggested two adenosine-binding sites; one with high affinity which corresponded to the catalytic site and one with much lower affinity. The latter site was reported to differ from the triphosphate-binding site based on competition studies and may serve to regulate AK activity during times of ischemia and high adenosine production (23,25,26). Chemical modification studies supported the existence of a second adenosine-binding site distinct from the ATP site.…”

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confidence: 99%

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Structure of Human Adenosine Kinase at 1.5 Å Resolution^,

1998

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Adenosine kinase (AK) is a key enzyme in the regulation of extracellular adenosine and intracellular adenylate levels. Inhibitors of adenosine kinase elevate adenosine to levels that activate nearby adenosine receptors and produce a wide variety of therapeutically beneficial activities. Accordingly, AK is a promising target for new analgesic, neuroprotective, and cardioprotective agents. We determined the structure of human adenosine kinase by X-ray crystallography using MAD phasing techniques and refined the structure to 1.5 Å resolution. The enzyme structure consisted of one large R/ domain with nine -strands, eight R-helices, and one small R/ -domain with five -strands and two R-helices. The active site is formed along the edge of the -sheet in the large domain while the small domain acts as a lid to cover the upper face of the active site. The overall structure is similar to the recently reported structure of ribokinase from Escherichia coli [Sigrell et al. (1998) Structure 6, 183-193]. The structure of ribokinase was determined at 1.8 Å resolution and represents the first structure of a new family of carbohydrate kinases. Two molecules of adenosine were present in the AK crystal structure with one adenosine molecule located in a site that matches the ribose site in ribokinase and probably represents the substrate-binding site. The second adenosine site overlaps the ADP site in ribokinase and probably represents the ATP site. A Mg 2+ ion binding site is observed in a trough between the two adenosine sites. The structure of the active site is consistent with the observed substrate specificity. The active-site model suggests that Asp300 is an important catalytic residue involved in the deprotonation of the 5′-hydroxyl during the phosphate transfer.Adenosine kinase (ATP, adenosine 5′-phosphotransferase, EC 2.7.1.20) catalyzes the phosphorylation of ribofuranosylcontaining nucleoside analogues at the 5′-hydroxyl using ATP or GTP as the phosphate donor. Tissue distribution studies indicate that adenosine kinase (AK) is the most abundant nucleoside kinase in mammals with AK activity in humans and monkeys expressed at the highest levels in liver, kidney, and lung and at intermediate levels in the brain, heart, and skeletal muscle (1, 2). AK exhibits a relatively broad substrate specificity tolerating modifications in both the sugar and base moieties (3). Accordingly, numerous nucleoside antiviral and anticancer drugs are AK substrates and consequently undergo rapid phosphorylation in vivo to the 5′-monophosphate. In many cases, the monophosphate is subsequently converted by other kinases to the triphosphate which functions as the active metabolite. Examples include ribavirin (4) and mizoribine (5).The physiological function of AK is associated with the regulation of extracellular adenosine levels and the preservation of intracellular adenylate pools (6

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Section: Discussionsupporting

confidence: 93%

Section: Discussionmentioning

confidence: 64%

mentioning

confidence: 99%

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confidence: 99%

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Structure of Human Adenosine Kinase at 1.5 Å Resolution^,

1998

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“…Besides phosphorylating Ado, the enzyme also recognizes a wide variety of Ado analogues as substrates, thus making it a prospective target for chemotherapy [1]. Although the enzyme was kinetically characterized from a number of sources, including higher eukaryotes [2][3][4], parasitic protozoa [5][6][7][8], plants [9] and bacteria [10], the mechanism of substrate recognition and phosphorylation of various nucleosides/analogues by this enzyme was the subject of substantial debate until recently. Using 6-methylmercaptopurine riboside as the substrate, Henderson et al [11] claimed that the enzyme from Ehrlich ascites tumour cells carried out a reaction in which ATP was the first substrate to bind and 6-methylmercaptopurine riboside monophosphate was the last product to be released.…”

Section: Introductionmentioning

confidence: 99%

Mutational analysis of the active-site residues crucial for catalytic activity of adenosine kinase from Leishmania donovani

Datta

Das

Sen

et al. 2005

Biochemical Journal

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Leishmania donovani adenosine kinase (LdAdK) plays a pivotal role in scavenging of purines from the host. Exploiting interspecies homology and structural co-ordinates of the enzyme from other sources, we generated a model of LdAdK that led us to target several amino acid residues (namely Gly-62, Arg-69, Arg-131 and Asp-299). Replacement of Gly-62 with aspartate caused a drastic reduction in catalytic activity, with decreased affinity for either substrate. Asp-299 was found to be catalytically indispensable. Mutation of either Arg-131 or Arg-69 caused a significant reduction in k cat . R69A (Arg-69 → Ala) and R131A mutants exhibited unaltered K m for either substrate, whereas ATP K m for R69K increased 6-fold. Importance of both of the arginine residues was reaffirmed by the R69K/R131A double mutant, which exhibited approx. 0.5 % residual activity with a large increase in ATP K m . Phenylglyoxal, which inhibits the wild-type enzyme, also inactivated the arginine mutants to different extents. Adenosine protected both of the Arg-69 mutants, but not the R131A variant, from inactivation. Binding experiments revealed that the AMPbinding property of R69K or R69A and D299A mutants remained largely unaltered, but R131A and R69K/R131A mutants lost their AMP binding ability significantly. The G62D mutant did not bind AMP at all. Free energy calculations indicated that Arg-69 and Arg-131 are functionally independent. Thus, apart from the mandatory requirement of flexibility around the diglycyl (Gly-61-Gly-62) motif, our results identified Asp-299 and Arg-131 as key catalytic residues, with the former functioning as the proton abstractor from the 5 -OH of adenosine, while the latter acts as a bidentate electrophile to stabilize the negative charge on the leaving group during the phosphate transfer. Moreover, the positive charge distribution of Arg-69 probably helps in maintaining the flexibility of the α-3 helix needed for proper domain movement. These findings provide the first comprehensive biochemical evidence implicating the mechanistic roles of the functionally important residues of this chemotherapeutically exploitable enzyme.

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Chiral Phosphorothioates: Stereochemical Analysis of Enzymatic Substitution at Phosphorus

Frey

1989

Advances in Enzymology - And Related Areas of Molecular Biology

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Adenosine kinase from human erythrocytes: kinetic studies and characterization of adenosine binding sites

Cited by 55 publications

References 33 publications

Structure of Human Adenosine Kinase at 1.5 Å Resolution^,

Structure of Human Adenosine Kinase at 1.5 Å Resolution^,

Mutational analysis of the active-site residues crucial for catalytic activity of adenosine kinase from Leishmania donovani

Chiral Phosphorothioates: Stereochemical Analysis of Enzymatic Substitution at Phosphorus

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Adenosine kinase from human erythrocytes: kinetic studies and characterization of adenosine binding sites

Cited by 55 publications

References 33 publications

Structure of Human Adenosine Kinase at 1.5 Å Resolution,

Structure of Human Adenosine Kinase at 1.5 Å Resolution,

Mutational analysis of the active-site residues crucial for catalytic activity of adenosine kinase from Leishmania donovani

Chiral Phosphorothioates: Stereochemical Analysis of Enzymatic Substitution at Phosphorus

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Structure of Human Adenosine Kinase at 1.5 Å Resolution^,

Structure of Human Adenosine Kinase at 1.5 Å Resolution^,