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102. A dynamic Asp-Arg interaction is essential for catalysis in microsomal prostaglandin E2 synthase.

Author

Brock, Joseph S., Hamberg, Mats, Balagunaseelan, Navisraj, Goodman, Michael, Morgenstern, Ralf, Strandback, Emilia, Samuelsson, Bengt, Rinaldo-Matthis, Agnes, and Haeggström, Jesper Z.

Subjects
TOXICOLOGICAL interactions, CATALYSIS, PROSTAGLANDINS, SYNTHASES, TARGETED drug delivery, ENZYMES, THIOLATES
Abstract

Microsomal prostaglandin E2 synthase type 1 (mPGES-1) is responsible for the formation of the potent lipid mediator prostaglandin E2 under proinflammatory conditions, and this enzyme has received considerable attention as a drug target. Recently, a high-resolution crystal structure of human mPGES-1 was presented, with Ser-127 being proposed as the hydrogen-bond donor stabilizing thiolate anion formation within the cofactor, glutathione (GSH).We have combined site-directed mutagenesis and activity assays with a structural dynamics analysis to probe the functional roles of such putative catalytic residues.We found that Ser-127 is not required for activity, whereas an interaction between Arg-126 and Asp-49 is essential for catalysis. We postulate that both residues, in addition to a crystallographicwater, serve critical roles within the enzymatic mechanism. After characterizing the size or charge conservative mutations Arg-126-Gln, Asp-49-Asn, and Arg- 126-Lys, we inferred that a crystallographic water acts as a general base during GSH thiolate formation, stabilized by interaction with Arg-126, which is itself modulated by its respective interaction with Asp-49. We subsequently found hidden conformational ensembles within the crystal structure that correlate well with our biochemical data. The resulting contact signaling network connects Asp-49 to distal residues involved in GSH binding and is ligand dependent. Our work has broad implications for development of efficientmPGES-1 inhibitors, potential anti-inflammatory and anticancer agents. [ABSTRACT FROM AUTHOR]

Published
2016
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104. Inhibition and Structure of Trichomonas vaginalis Purine Nucleoside Phosphorylase with Picomolar Transition State Analogues

Author

Rinaldo-Matthis, Agnes, primary, Wing, Corin, additional, Ghanem, Mahmoud, additional, Deng, Hua, additional, Wu, Peng, additional, Gupta, Arti, additional, Tyler, Peter C., additional, Evans, Gary B., additional, Furneaux, Richard H., additional, Almo, Steven C., additional, Wang, Ching C., additional, and Schramm, Vern L., additional

Published
2006
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113. Structure and Inhibition of Mouse Leukotriene C4 Synthase.

Author

Niegowski, Damian, Kleinschmidt, Thea, Ahmad, Shabbir, Qureshi, Abdul Aziz, Mårback, Michaela, Rinaldo-Matthis, Agnes, and Haeggström, Jesper Z.

Subjects
LABORATORY mice, LEUKOTRIENES synthesis, ISOENZYMES, CARCINOGENESIS, INFLAMMATION, CHEMICAL kinetics
Abstract

Leukotriene (LT) C4 synthase (LTC4S) is an integral membrane protein that catalyzes the conjugation reaction between the fatty acid LTA4 and GSH to form the pro-inflammatory LTC4, an important mediator of asthma. Mouse models of inflammatory disorders such as asthma are key to improve our understanding of pathogenesis and potential therapeutic targets. Here, we solved the crystal structure of mouse LTC4S in complex with GSH and a product analog, S-hexyl-GSH. Furthermore, we synthesized a nM inhibitor and compared its efficiency and binding mode against the purified mouse and human isoenzymes, along with the enzymes’ steady-state kinetics. Although structural differences near the active site and along the C-terminal α-helix V suggest that the mouse and human LTC4S may function differently in vivo, our data indicate that mouse LTC4S will be a useful tool in future pharmacological research and drug development. [ABSTRACT FROM AUTHOR]

Published
2014
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114. Binding of Pro-Gly-Pro at the active site of leukotriene A4 hydrolase/aminopeptidase and development of an epoxide hydrolase selective inhibitor.

Author

Stsiapanava, Alena, Olsson, Ulrika, Min Wan, Kleinschmidt, Thea, Rutishauser, Dorothea, Zubarev, Roman A., Samuelsson, Bengt, Rinaldo-Matthis, Agnes, and Haeggström, Jesper Z.

Subjects
LEUKOTRIENE antagonists, HYDROLASES, AMINOPEPTIDASES, EPOXIDE hydrolase, MASS spectrometry
Abstract

Leukotriene (LT) A4 hydrolase/aminopeptidase (LTA4H) is a bifunctional zinc metalloenzyme that catalyzes the committed step in the formation of the proinflammatory mediator LTB4. Recently, the chemotactic tripeptide Pro-Gly-Pro was identified as an endogenous aminopeptidase substrate for LTA4 hydrolase. Here, we determined the crystal structure of LTA4 hydrolase in complex with a Pro-Gly-Pro analog at 1.72 Å. From the structure, which includes the catalytic water, and mass spectrometric analysis of enzymatic hydrolysis products of Pro-Gly-Pro, it could be inferred that LTA4 hydrolase cleaves at the N terminus of the palindromic tripeptide. Furthermore, we designed a small molecule, 4-(4-benzylphenyl) thiazol-2-amine, denoted ARM1, that inhibits LTB4 synthesis in human neutrophils (IC50 of ∼0.5 μM) and conversion of LTA4 into LTB4 by purified LTA4H with a Ki of 2.3 μM. In contrast, 50- to 100-fold higher concentrations of ARM1 did not significantly affect hydrolysis of Pro-Gly-Pro. A 1.62-Å crystal structure of LTA4 hydrolase in a dual complex with ARM1 and the Pro-Gly-Pro analog revealed that ARM1 binds in the hydrophobic pocket that accommodates the ω-end of LTA4, distant from the aminopeptidase active site, thus providing a molecular basis for its inhibitory profile. Hence, ARM1 selectively blocks conversion of LTA4 into LTB4, although sparing the enzyme's anti-inflammatory aminopeptidase activity (i.e., degradation and inactivation of Pro-Gly-Pro). ARM1 represents a new class of LTA4 hydrolase inhibitor that holds promise for improved anti-inflammatory properties. [ABSTRACT FROM AUTHOR]

Published
2014
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115. Pre-Steady-State Kinetic Characterization of Thiolate Anion Formation in Human Leukotriene C4 Synthase.

Author

Rinaldo-Matthis, Agnes, Ahmad, Shabbir, Wetterholm, Anders, Lachmann, Peter, Morgenstern, Ralf, and Haeggström, Jesper Z.

Subjects
*THIOLATES, *ANIONS, *LEUKOTRIENES synthesis, *MEMBRANE proteins, *CYSTEINYL-transfer RNA, *ASTHMA, *CRYSTALLOGRAPHY
Abstract

Human leukotriene C4 synthase (hLTC4S) is an integral membrane protein that catalyzes the committed step in the biosynthesis of cysteinyl-leukotrienes, i.e., formation of leukotriene C4 (LTC4). This molecule, together with its metabolites LTD4 and LTE4, induces inflammatory responses, particularly in asthma, and thus, the enzyme is an attractive drug target. During the catalytic cycle, glutathione (GSH) is activated by hLTC4S that forms a nucleophilic thiolate anion that will attack LTA4, presumably according to an SN2 reaction to form LTC4. We observed that GSH thiolate anion formation is rapid and occurs at all three monomers of the homotrimer and is concomitant with stoichiometric release of protons to the medium. The pKa (5.9) for enzyme-bound GSH thiol and the rate of thiolate formation were determined (kobs = 200 s-1). Taking advantage of a strong competitive inhibitor, glutathionesulfonic acid, shown here by crystallography to bind in the same location as GSH, we determined the overall dissociation constant (KdGS– = 14.3 μM). The release of the thiolate was assessed using a GSH release experiment (1.3 s-1). Taken together, these data establish that thiolate anion formation in hLTC4S is not the rate-limiting step for the overall reaction of LTC4 production (kcat = 26 s-1), and compared to the related microsomal glutathione transferase 1, which displays very slow GSH thiolate anion formation and one-third of the sites reactivity, hLTC4S has evolved a different catalytic mechanism. [ABSTRACT FROM AUTHOR]

Published
2012
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116. Crystal structures of the mitochondrial deoxyribonucleotidase in complex with two specific inhibitors.

Author

Agnes, Rinaldo-Matthis, Chiara, Rampazzo, Jan, Balzarini, Peter, Reichard, Vera, Bianchi, and Pr, Nordlund

Abstract

Monophosphate nucleotidases are enzymes that dephosphorylate nucleotides to their corresponding nucleosides. They play potentially important roles in controlling the activation of nucleotide-based drugs targeted against viral infections or cancer cells. The human mitochondrial deoxyribonucleotidase (dNT-2) dephosphorylates thymidine and deoxyuridine monophosphates. We describe the high resolution structures of the dNT-2 enzyme in complex with two potent nucleoside phosphonate inhibitors, (S)-1-[2'-deoxy-3',5'-O-(1-phosphono) benzylidene-beta-d-threo-pentofuranosyl]thymine (DPB-T) at 1.6-A resolution and (+/-)-1-trans-(2-phosphonomethoxycyclopentyl)uracil (PMcP-U) at 1.4-A resolution. The mixed competitive inhibitor DPB-T and the competitive inhibitor PMcP-U both bind in the active site of dNT-2 but in distinctly different binding modes, explaining their different kinetics of inhibition. The pyrimidine part of the inhibitors binds with very similar hydrogen bond interactions to the protein but with their phosphonate moieties in different binding sites compared with each other and to the previously determined position of phosphate bound to dNT-2. Together, these phosphate/phosphonate binding sites describe what might constitute a functionally relevant phosphate entrance tunnel to the active site. The structures of the inhibitors in complex with dNT-2, being the first such complexes of any nucleotidase, might provide important information for the design of more specific inhibitors to control the activation of nucleotide-based drugs.

Published
2004

118. A dynamic Asp-Arg interaction is essential for catalysis in microsomal prostaglandin E2 synthase.

Author

Brock JS, Hamberg M, Balagunaseelan N, Goodman M, Morgenstern R, Strandback E, Samuelsson B, Rinaldo-Matthis A, and Haeggström JZ

Subjects
Catalysis, Catalytic Domain, Crystallography, X-Ray, Glutathione metabolism, Intramolecular Oxidoreductases metabolism, Ligands, Mutagenesis, Site-Directed, Prostaglandin-E Synthases, Protein Conformation, Dipeptides chemistry, Intramolecular Oxidoreductases chemistry, Microsomes enzymology
Abstract

Microsomal prostaglandin E2 synthase type 1 (mPGES-1) is responsible for the formation of the potent lipid mediator prostaglandin E2 under proinflammatory conditions, and this enzyme has received considerable attention as a drug target. Recently, a high-resolution crystal structure of human mPGES-1 was presented, with Ser-127 being proposed as the hydrogen-bond donor stabilizing thiolate anion formation within the cofactor, glutathione (GSH). We have combined site-directed mutagenesis and activity assays with a structural dynamics analysis to probe the functional roles of such putative catalytic residues. We found that Ser-127 is not required for activity, whereas an interaction between Arg-126 and Asp-49 is essential for catalysis. We postulate that both residues, in addition to a crystallographic water, serve critical roles within the enzymatic mechanism. After characterizing the size or charge conservative mutations Arg-126-Gln, Asp-49-Asn, and Arg-126-Lys, we inferred that a crystallographic water acts as a general base during GSH thiolate formation, stabilized by interaction with Arg-126, which is itself modulated by its respective interaction with Asp-49. We subsequently found hidden conformational ensembles within the crystal structure that correlate well with our biochemical data. The resulting contact signaling network connects Asp-49 to distal residues involved in GSH binding and is ligand dependent. Our work has broad implications for development of efficient mPGES-1 inhibitors, potential anti-inflammatory and anticancer agents.

Published
2016
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119. Trimeric microsomal glutathione transferase 2 displays one third of the sites reactivity.

Author

Ahmad S, Thulasingam M, Palombo I, Daley DO, Johnson KA, Morgenstern R, Haeggström JZ, and Rinaldo-Matthis A

Subjects
Amino Acid Sequence, Calorimetry, Catalytic Domain, Dinitrochlorobenzene metabolism, Electrophoresis, Polyacrylamide Gel, Gene Expression, Glutathione metabolism, Glutathione Transferase genetics, Humans, Kinetics, Microsomes enzymology, Molecular Dynamics Simulation, Molecular Sequence Data, Pichia genetics, Pichia metabolism, Protein Multimerization, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Alignment, Sequence Homology, Amino Acid, Dinitrochlorobenzene chemistry, Glutathione chemistry, Glutathione Transferase chemistry, Glutathione Transferase metabolism
Abstract

Human microsomal glutathione transferase 2 (MGST2) is a trimeric integral membrane protein that belongs to the membrane-associated proteins in eicosanoid and glutathione metabolism (MAPEG) family. The mammalian MAPEG family consists of six members where four have been structurally determined. MGST2 activates glutathione to form a thiolate that is crucial for GSH peroxidase activity and GSH conjugation reactions with electrophilic substrates, such as 1-chloro-2,4-dinitrobenzene (CDNB). Several studies have shown that MGST2 is able to catalyze a GSH conjugation reaction with the epoxide LTA4 forming the pro-inflammatory LTC4. Unlike its closest homologue leukotriene C4 synthase (LTC4S), MGST2 appears to activate its substrate GSH using only one of the three potential active sites [Ahmad S, et al. (2013) Biochemistry. 52, 1755-1764]. In order to demonstrate and detail the mechanism of one-third of the sites reactivity of MGST2, we have determined the enzyme oligomeric state, by Blue native PAGE and Differential Scanning Calorimetry, as well as the stoichiometry of substrate and substrate analog inhibitor binding to MGST2, using equilibrium dialysis and Isothermal Titration Calorimetry, respectively. Global simulations were used to fit kinetic data to determine the catalytic mechanism of MGST2 with GSH and CDNB (1-chloro-2,4-dinitrobenzene) as substrates. The best fit was observed with 1/3 of the sites catalysis as compared with a simulation where all three sites were active. In contrast to LTC4S, MGST2 displays a 1/3 the sites reactivity, a mechanism shared with the more distant family member MGST1 and recently suggested also for microsomal prostaglandin E synthase-1., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published
2015
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120. A mutation interfering with 5-lipoxygenase domain interaction leads to increased enzyme activity.

Author

Rakonjac Ryge M, Tanabe M, Provost P, Persson B, Chen X, Funk CD, Rinaldo-Matthis A, Hofmann B, Steinhilber D, Watanabe T, Samuelsson B, and Rådmark O

Subjects
Amino Acid Sequence, Arachidonate 5-Lipoxygenase genetics, Catalytic Domain, Enzyme Activation, Humans, Leukotrienes metabolism, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Point Mutation, Protein Structure, Tertiary, Arachidonate 5-Lipoxygenase chemistry, Arachidonate 5-Lipoxygenase metabolism
Abstract

5-Lipoxygenase (5-LOX) catalyzes two steps in conversion of arachidonic acid to proinflammatory leukotrienes. Lipoxygenases, including human 5-LOX, consist of an N-terminal C2-like β-sandwich and a catalytic domain. We expressed the 5-LOX domains separately, these were found to interact in the yeast two-hybrid system. The 5-LOX structure suggested association between Arg(101) in the β-sandwich and Asp(166) in the catalytic domain, due to electrostatic interaction as well as hydrogen bonds. Indeed, mutagenic replacements of these residues led to loss of two-hybrid interaction. Interestingly, when Arg(101) was mutated to Asp in intact 5-LOX, enzyme activity was increased. Thus, higher initial velocity of the reaction (vinit) and increased final amount of products were monitored for 5-LOX-R101D, at several different assay conditions. In the 5-LOX crystal structure, helix α2 and adjacent loops (including Asp(166)) of the 5-LOX catalytic domain has been proposed to form a flexible lid controlling access to the active site, and lid movement would be determined by bonding of lid residues to the C2-like β-sandwich. The more efficient catalysis following disruption of the R101-D166 ionic association supports the concept of such a flexible lid in human 5-LOX., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published
2014
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121. Crystal structures of leukotriene C4 synthase in complex with product analogs: implications for the enzyme mechanism.

Author

Niegowski D, Kleinschmidt T, Olsson U, Ahmad S, Rinaldo-Matthis A, and Haeggström JZ

Subjects
Biocatalysis, Crystallography, X-Ray, Glutathione metabolism, Glutathione Transferase metabolism, Humans, Kinetics, Leukotriene A4 chemistry, Leukotriene C4 chemistry, Models, Molecular, Mutant Proteins chemistry, Mutant Proteins metabolism, Protein Conformation, Substrate Specificity, Tryptophan metabolism, Glutathione analogs & derivatives, Glutathione Transferase chemistry
Abstract

Leukotriene (LT) C4 synthase (LTC4S) catalyzes the conjugation of the fatty acid LTA4 with the tripeptide GSH to produce LTC4, the parent compound of the cysteinyl leukotrienes, important mediators of asthma. Here we mutated Trp-116 in human LTC4S, a residue proposed to play a key role in substrate binding, into an Ala or Phe. Biochemical and structural characterization of these mutants along with crystal structures of the wild type and mutated enzymes in complex with three product analogs, viz. S-hexyl-, 4-phenyl-butyl-, and 2-hydroxy-4-phenyl-butyl-glutathione, provide new insights to binding of substrates and product, identify a new conformation of the GSH moiety at the active site, and suggest a route for product release, aided by Trp-116.

Published
2014
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122. Product formation controlled by substrate dynamics in leukotriene A4 hydrolase.

Author

Stsiapanava A, Tholander F, Kumar RB, Qureshi AA, Niegowski D, Hasan M, Thunnissen M, Haeggström JZ, and Rinaldo-Matthis A

Subjects
Amino Acid Sequence, Animals, Catalytic Domain, Crystallography, X-Ray, Humans, Hydrolysis, Hydroxyeicosatetraenoic Acids chemistry, Kinetics, Leukotriene B4 chemistry, Models, Molecular, Molecular Sequence Data, Protein Multimerization, Sequence Homology, Amino Acid, Substrate Specificity, Epoxide Hydrolases chemistry, Hydroxyeicosatetraenoic Acids metabolism, Leukotriene B4 metabolism, Xenopus Proteins chemistry, Xenopus laevis metabolism
Abstract

Leukotriene A4 hydrolase/aminopeptidase (LTA4H) (EC 3.3.2.6) is a bifunctional zinc metalloenzyme with both an epoxide hydrolase and an aminopeptidase activity. LTA4H from the African claw toad, Xenopus laevis (xlLTA4H) has been shown to, unlike the human enzyme, convert LTA4 to two enzymatic metabolites, LTB4 and another biologically active product Δ(6)-trans-Δ(8)-cis-LTB4 (5(S),12R-dihydroxy-6,10-trans-8,14-cis-eicosatetraenoic acid). In order to study the molecular aspect of the formation of this product we have characterized the structure and function of xlLTA4H. We solved the structure of xlLTA4H to a resolution of 2.3Å. It is a dimeric structure where each monomer has three domains with the active site in between the domains, similar as to the human structure. An important difference between the human and amphibian enzyme is the phenylalanine to tyrosine exchange at position 375. Our studies show that mutating F375 in xlLTA4H to tyrosine abolishes the formation of the LTB4 isomeric product Δ(6)-trans-Δ(8)-cis-LTB4. In an attempt to understand how one amino acid exchange leads to a new product profile as seen in the xlLTA4H, we performed a conformer analysis of the triene part of the substrate LTA4. Our results show that the Boltzmann distribution of substrate conformers correlates with the observed distribution of products. We suggest that the observed difference in product profile between the human and the xlLTA4H arises from different level of discrimination between substrate LTA4 conformers., (Copyright © 2013. Published by Elsevier B.V.)

Published
2014
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123. Arginine 104 is a key catalytic residue in leukotriene C4 synthase.

Author

Rinaldo-Matthis A, Wetterholm A, Martinez Molina D, Holm J, Niegowski D, Ohlson E, Nordlund P, Morgenstern R, and Haeggström JZ

Subjects
Amino Acid Substitution, Arginine genetics, Arginine metabolism, Catalysis, Catalytic Domain, Crystallography, X-Ray, Glutathione Transferase genetics, Glutathione Transferase metabolism, Humans, Mutagenesis, Site-Directed, Mutation, Missense, Oxidation-Reduction, Spectrophotometry, Ultraviolet, Arginine chemistry, Glutathione Transferase chemistry
Abstract

Human leukotriene C(4) synthase (hLTC(4)S) is an integral membrane enzyme that conjugates leukotriene (LT) A(4) with glutathione to form LTC(4), a precursor to the cysteinyl leukotrienes (LTC(4), LTD(4), and LTE(4)) that are involved in the pathogenesis of human bronchial asthma. From the crystal structure of hLTC(4)S, Arg-104 and Arg-31 have been implicated in the conjugation reaction. Here, we used site-directed mutagenesis, UV spectroscopy, and x-ray crystallography to examine the catalytic role of Arg-104 and Arg-31. Exchange of Arg-104 with Ala, Ser, Thr, or Lys abolished 94.3-99.9% of the specific activity against LTA(4). Steady-state kinetics of R104A and R104S revealed that the K(m) for GSH was not significantly affected. UV difference spectra of the binary enzyme-GSH complex indicated that GSH ionization depends on the presence of Arg-104 because no thiolate signal, with λ(max) at 239 nm, could be detected using R104A or R104S hLTC(4)S. Apparently, the interaction of Arg-104 with the thiol group of GSH reduces its pK(a) to allow formation of a thiolate anion and subsequent nucleophilic attack at C6 of LTA(4). On the other hand, exchange of Arg-31 with Ala or Glu reduced the catalytic activity of hLTC(4)S by 88 and 70%, respectively, without significantly affecting the k(cat)/K(m) values for GSH, and a crystal structure of R31Q hLTC(4)S (2.1 Å) revealed a Gln-31 side chain pointing away from the active site. We conclude that Arg-104 plays a critical role in the catalytic mechanism of hLTC(4)S, whereas a functional role of Arg-31 seems more elusive. Because Arg-104 is a conserved residue, our results pertain to other homologous membrane proteins and represent a structure-function paradigm probably common to all microsomal GSH transferases.

Published
2010
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124. Structures and mechanisms of enzymes in the leukotriene cascade.

Author

Rinaldo-Matthis A and Haeggström JZ

Subjects
Animals, Arachidonic Acid metabolism, Epoxide Hydrolases chemistry, Epoxide Hydrolases metabolism, Glutathione Transferase chemistry, Glutathione Transferase metabolism, Humans, Inflammation Mediators metabolism, Models, Molecular, Protein Conformation, Signal Transduction, Arachidonate 5-Lipoxygenase chemistry, Arachidonate 5-Lipoxygenase metabolism, Leukotrienes metabolism
Abstract

Leukotrienes are a family of proinflammatory lipid mediators of the innate immune response and are important signaling molecules in inflammatory and allergic conditions. The leukotrienes are formed from arachidonic acid, which is released from membranes by cPLA(2), and further converted by 5-lipoxygenase to form the labile epoxide leukotriene (LT) A(4). This intermediate is converted by either of the two enzymes, LTA(4) hydrolase or LTC(4) synthase, to form LTB(4) or LTC(4), respectively. In order for 5-lipoxygenase to work efficiently in cells, five-lipoxygenase-activating protein needs to be present. LTB(4) is one of the most powerful chemotactic agents whereas LTC(4) induces smooth muscle contractions, for example in the airways causing bronchoconstriction in asthmatic patients. The leukotrienes and the five enzymes/proteins involved in their formation have been subject to intense studies including drug design programs. Compounds blocking the formation or action of leukotrienes are potentially beneficial in treatment of several acute and chronic inflammatory diseases of the cardiovascular and respiratory systems. In order to succeed with drug development studies, knowledge of the molecular characteristics of the targets is indispensable. This chapter reviews the biochemistry, catalytic, and structural properties of the enzymes in the leukotriene cascade., (Copyright 2010 Elsevier Masson SAS. All rights reserved.)

Published
2010
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125. Four generations of transition-state analogues for human purine nucleoside phosphorylase.

Author

Ho MC, Shi W, Rinaldo-Matthis A, Tyler PC, Evans GB, Clinch K, Almo SC, and Schramm VL

Subjects
Animals, Catalytic Domain, Cattle, Enzyme Inhibitors pharmacology, Humans, Models, Molecular, Protein Conformation, Purine Nucleosides chemistry, Purine Nucleosides pharmacology, Pyrimidinones chemistry, Pyrimidinones pharmacology, Pyrrolidines chemistry, Pyrrolidines pharmacology, Thermodynamics, Enzyme Inhibitors chemistry, Purine-Nucleoside Phosphorylase antagonists & inhibitors, Purine-Nucleoside Phosphorylase chemistry
Abstract

Inhibition of human purine nucleoside phosphorylase (PNP) stops growth of activated T-cells and the formation of 6-oxypurine bases, making it a target for leukemia, autoimmune disorders, and gout. Four generations of ribocation transition-state mimics bound to PNP are structurally characterized. Immucillin-H (K*i(1/4) 58 pM, first generation)contains an iminoribitol cation with four asymmetric carbons. DADMe-Immucillin-H (K*i(1/4) 9 pM, second-generation),uses a methylene-bridged dihydroxypyrrolidine cation with twoasymmetric centers.DATMe-Immucillin-H (K*i(1/4)9 pM, third-generation) contains an open-chain amino alcohol cation with two asymmetric carbons. SerMe-ImmH (K*i(1/4) 5 pM, fourth-generation) uses achiral dihydroxyaminoalcohol seramide as the ribocation mimic. Crystal structures of PNPs establish features of tight binding to be; 1) ion-pair formation between bound phosphate (or its mimic) and inhibitor cation, 2) leaving-group interactions to N1, O6, and N7 of 9-deazahypoxanthine, 3) interaction between phosphate and inhibitor hydroxyl groups, and 4) His257 interacting with the 5'-hydroxyl group. The first generation analogue is an imperfect fit to the catalytic site with a long ion pair distance between the iminoribitol and bound phosphate and weaker interactions to the leaving group. Increasing the ribocation to leaving-group distance in the second- to fourth-generation analogues provides powerful binding interactions and a facile synthetic route to powerful inhibitors. Despite chemical diversity in the four generations of transition-state analogues, the catalytic site geometry is almost the same for all analogues. Multiple solutions in transition-state analogue design are available to convert the energy of catalytic rate enhancement to binding energy in human PNP.

Published
2010
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