Studies on the reduction of endogenously generated prostaglandin G2 by prostaglandin H synthase

Prostaglandin H synthase oxidizes arachidonic acid to prostaglandin G2 (PGG2) via its cyclooxygenase activity and reduces PGG2 to prostaglandin H2 by its peroxidase activity. The purpose of this study was to determine if endogenously generated PGG2 is the preferred substrate for the peroxidase compared with exogenous PGG2. Arachidonic acid and varying concentrations of exogenous PGG2 were incubated with ram seminal vesicle microsomes or purified prostaglandin H synthase in the presence of the reducing cosubstrate, aminopyrine. The formation of the aminopyrine cation free radical (AP.+) served as an index of peroxide reduction. The simultaneous addition of PGG2 with arachidonic acid did not alter cyclooxygenase activity of ram seminal vesicle microsomes or the formation of the AP.+. This suggests that the formation of AP.+, catalyzed by the peroxidase, was supported by endogenous endoperoxide formed from arachidonic acid oxidation rather than by the reduction of exogenous PGG2. In addition to the AP.+ assay, the reduction of exogenous versus endogenous PGG2 was studied by using [5,6,8,9,11,12,14,15-2H]arachidonic acid and unlabeled PGG2 as substrates, with gas chromatography-mass spectrometry techniques to measure the amount of reduction of endogenous versus exogenous PGG2. Two distinct results were observed. With ram seminal vesicle microsomes, little reduction of exogenous PGG2 was observed even under conditions in which all of the endogenous PGG2 was reduced. In contrast, studies with purified prostaglandin H synthase showed complete reduction of both exogenous and endogenous PGG2 using similar experimental conditions. Our findings indicate that PGG2 formed by the oxidation of arachidonic acid by prostaglandin H synthase in microsomal membranes is reduced preferentially by prostaglandin H synthase.     

The aspirin and heme-binding sites of ovine and murine prostaglandin endoperoxide synthases

Acetylation of Ser-530 of sheep prostaglandin endoperoxide (PGG/H) synthase by aspirin causes irreversible inactivation of the cyclooxygenase activity of the enzyme. To determine the catalytic function of the hydroxyl group of Ser-530, we used site-directed mutagenesis to replace Ser-530 with an alanine. Cos-1 cells transfected with expression vectors containing the native (Ser-530) or mutant (Ala-530) cDNAs for sheep PGG/H synthase expressed comparable cyclooxygenase and hydroperoxidase activities. Km values for arachidonate (8 microM) and ID50 values for reversible inhibition by the cyclooxygenase inhibitors, flurbiprofen (5 microM), flufenamate (20 microM), and aspirin (20 mM), were also the same for both native and mutant PGG/H synthases; however, only the native enzyme was irreversibly inactivated by aspirin. Thus, the "active site" Ser-530 of PGG/H synthase is not essential for catalysis or substrate binding. Apparently, acetylation of native PGG/H synthase by aspirin introduces a bulky sidechain at position 530 which interferes with arachidonate binding. In related studies, a cDNA for mouse PGG/H synthase was cloned and sequenced. A sequence of 35 residues with Ser-530 at the midpoint was identical in the two proteins. Thus, Ser-530 does lie in a highly conserved region, probably involved in cyclooxygenase catalysis. Sequence comparisons of mouse and sheep PGG/H synthase also provided information about the heme-binding site of the enzyme. The sheep HYPR sequence (residues 274-277), which had been proposed to form a portion of the distal heme-binding site, is not conserved in the mouse PGG/H synthase, suggesting that this region is not the distal heme-binding site. One sequence, TIWLREHNRV (residues 303-312 of the sheep enzyme), is very closely related to the sequence TLW(L)LREHNRL common to thyroid peroxidase and myeloperoxidase. The histidine in this latter sequence is the putative axial heme ligand of these peroxidases. We suggest that the histidine (His-309) of sheep PGG/H synthase sequence is the axial heme ligand of this enzyme.     

Modulation of platelet cyclic nucleotide content by PGE1 and the prostaglandin endoperoxide PGG2.

The effects of prostaglandin E1 and prostaglandin G2, the prostaglandin endoperoxide, on platelet cyclic nucleotide concentrations were measured in platelet rich plasma (PRP), and in washed intact platelets. PGE1 was found to be a potent stimulator of platelet cAMP levels in both PRP and washed cells, and to inhibit aggregation in both systems. PGE1 did not change platelet cGMP levels in either PRP or washed cells. PGG2 which is a potent inducer of platelet aggregation, did not affect either the basal cAMP or the basal cGMP concentration. However, PGG2 was found to antagonize the increases in cAMP content in response to PGE1 in both PRP and washed platelets. The addition to our system of a cyclic nucleotide phosphodiesterase inhbitor, theophylline, did not change our findings. It is suggested that PGG2 may induce platelet aggregation by inhibiting PGE1-stimulated cAMP accumulation.     

Activation of soluble splenic cell guanylate cyclase by prostaglandin endoperoxides and fatty acid hydroperoxides.

Purified prostaglandin endoperoxides (PGG2 and PGH2) and hydroperoxides (15-OOH-PGE2) as well as fatty acid hydroperoxides (12-OOH-20:4, 15-00H-20:4, and 13-OOH-18:2) were examined as effectors of soluble splenic cell guanylate cyclase activity. The procedures described (in the miniprint supplement) for the preparation, purification, and characterization of these components circumvented the use of diethyl ether which obscured effects of lipid effectors because of contaminants presumed to be ether peroxides which were stimulatory to the cyclase. Addition of prostaglandin endoperoxides or fatty acid hydroperoxides to the reaction mixture led to a time-dependent activation of guanylate cyclase activity; 2.5- to 5-fold stimulation was seen during the first 6 min. The degree of stimulation and rate of activation were dependent on the concentration of the fatty acid effector; when initial velocities (6 min) were assessed half-maximal stimulation was achieved in the range of 2 to 3 micrometer. However, by extending the incubation time to 90 min similar maximal increases in specific activity could be achieved with 3 or 10 micrometer PGG2 or PGH2. Activation of guanylate cyclase upon addition of prostaglandin endoperoxides or fatty acid hydroperoxides was prevented or reversed by the thiol reductants dithiothreitol (3 to 5 mM) or glutathione (10 to 15 mM). Na2S2O4, not known as an effective reducing agent of disulfides, prevented but was relatively ineffective in reversing activation after it had been induced by PGG2. Pretreatment of the enzyme preparation with increasing concentrations of N-ethylmaleimide in the range of 0.01 to 1.0 mM prevented activation by PGG2 without affecting basal guanylate cyclase activity. These observations indicate that fatty acid hydroperoxides and prostaglandin endoperoxides promote activation of the cyclase by oxidation of enzyme-related thiol functions. In contrast PGE2, PGF2a, hydroxy fatty acids (13-OH-18:2, 12-OH-20:4) as well as saturated (18:0) monoenoic (18:1), dienoic (18:2), and tetraenoic (20:4) fatty acids were ineffective in promoting cyclase activation in the range of 1 to 10 micrometer. Studies to identify the species of the rapidly metabolized prostaglandin endoperoxides that serve as effectors of the cyclase indicated that PGG2 but not 15-OOH-PGE2 (the major buffer-rearrangement product of PGG2) is most likely an activator. In the case of PGH2, a rapidly generated (30 s) metabolite of PGH2 was found which contained a hydroperoxy or endoperoxy functional group and was equally as effective as PGH2 as an apparent activator of the enzyme. The combined effects of PGG2 and dehydroascorbic acid, another class of activator, exhibited additivity with respect to the rate at which the time-dependent activation was induced. These results suggest that activation of soluble guanylate cyclase from splenic cells can be achieved by the oxidation of sulfhydryl groups that may be associated with specific hydrophobic sites of the enzyme or a related regulatory component.     

Structural basis of hematopoietic prostaglandin D synthase activity elucidated by site-directed mutagenesis

Hematopoietic prostaglandin (PG) D synthase (PGDS) is the first identified vertebrate ortholog in the Sigma class of the glutathione S-transferase (GST) family and catalyzes both isomerization of PGH(2) to PGD(2) and conjugation of glutathione to 1-chloro-2, 4-dinitrobenzene. We introduced site-directed mutations of Tyr(8), Arg(14), Trp(104), Lys(112), Tyr(152), Cys(156), Lys(198), and Leu(199), which are presumed to participate in catalysis or PGH(2) substrate binding based on the crystallographic structure. Mutants were analyzed in terms of structure, GST and PGDS activities, and activation of the glutathione thiol group. Of all the mutants, only Y8F, W104I, K112E, and L199F showed minor but substantial differences in their far-UV circular dichroism spectra from the wild-type enzyme. Y8F, R14K/E, and W104I were completely inactive. C156L/Y selectively lost only PGDS activity. K112E reduced GST activity slightly and PGDS activity markedly, whereas K198E caused a selective decrease in PGDS activity and K(m) for glutathione and PGH(2) in the PGDS reaction. No significant changes were observed in the catalytic activities of Y152F and L199F, although their K(m) for glutathione was increased. Using 5,5'-dithiobis(2-nitrobenzoic acid) as an SH-selective agent, we found that only Y8F and R14E/K did not accelerate the reactivity of the glutathione thiol group under the low reactivity condition of pH 5.0. These results indicate that Lys(112), Cys(156), and Lys(198) are involved in the binding of PGH(2); Trp(104) is critical for structural integrity of the catalytic center for GST and PGDS activities; and Tyr(8) and Arg(14) are essential for activation of the thiol group of glutathione.     

A critical role in structure-specific DNA binding for the acetylatable lysine residues in HMGB1

The structure-specific DNA-binding protein HMGB1 (high-mobility group protein B1) which comprises two tandem HMG boxes (A and B) and an acidic C-terminal tail, is acetylated in vivo at Lys(2) and Lys(11) in the A box. Mutation to alanine of both residues in the isolated A domain, which has a strong preference for pre-bent DNA, abolishes binding to four-way junctions and 88 bp DNA minicircles. The same mutations in full-length HMGB1 also abolish its binding to four-way junctions, and binding to minicircles is substantially impaired. In contrast, when the acidic tail is absent (AB di-domain) there is little effect of the double mutation on four-way junction binding, although binding to minicircles is reduced approximately 15-fold. Therefore it appears that in AB the B domain is able to substitute for the non-functional A domain, whereas in full-length HMGB1 the B domain is masked by the acidic tail. In no case does single substitution of Lys(2) or Lys(11) abolish DNA binding. The double mutation does not significantly perturb the structure of the A domain. We conclude that Lys(2) and Lys(11) are critical for binding of the isolated A domain and HMGB1 to distorted DNA substrates.     

Functional interactions between the proline-rich and repeat regions of tau enhance microtubule binding and assembly.

Tau is a neuronal microtubule-associated protein that promotes microtubule assembly, stability, and bundling in axons. Two distinct regions of tau are important for the tau-microtubule interaction, a relatively well-characterized "repeat region" in the carboxyl terminus (containing either three or four imperfect 18-amino acid repeats separated by 13- or 14-amino acid long inter-repeats) and a more centrally located, relatively poorly characterized proline-rich region. By using amino-terminal truncation analyses of tau, we have localized the microtubule binding activity of the proline-rich region to Lys215-Asn246 and identified a small sequence within this region, 215KKVAVVR221, that exerts a strong influence on microtubule binding and assembly in both three- and four-repeat tau isoforms. Site-directed mutagenesis experiments indicate that these capabilities are derived largely from Lys215/Lys216 and Arg221. In marked contrast to synthetic peptides corresponding to the repeat region, peptides corresponding to Lys215-Asn246 and Lys215-Thr222 alone possess little or no ability to promote microtubule assembly, and the peptide Lys215-Thr222 does not effectively suppress in vitro microtubule dynamics. However, combining the proline-rich region sequences (Lys215-Asn246) with their adjacent repeat region sequences within a single peptide (Lys215-Lys272) enhances microtubule assembly by 10-fold, suggesting intramolecular interactions between the proline-rich and repeat regions. Structural complexity in this region of tau also is suggested by sequential amino-terminal deletions through the proline-rich and repeat regions, which reveal an unusual pattern of loss and gain of function. Thus, these data lead to a model in which efficient microtubule binding and assembly activities by tau require intramolecular interactions between its repeat and proline-rich regions. This model, invoking structural complexity for the microtubule-bound conformation of tau, is fundamentally different from previous models of tau structure and function, which viewed tau as a simple linear array of independently acting tubulin-binding sites.     

The role of selenium-dependent and selenium-independent glutathione peroxidases in the formation of prostaglandin F2 alpha

In recent years, growing evidence suggests that glutathione peroxidases (GSH-Pxs), both selenium-dependent GSH-Px (Se-GSH-Px) and selenium-independent GSH-Px (non-Se-GSH-Px) play an important role in the biosynthesis of prostaglandins and leukotrienes and in the regulation of key enzymes associated with the arachidonic acid cascade. The precise nature of their involvement in eicosanoid metabolism, however, is not yet completely understood. In the study reported here, we have systematically determined the catalytic efficiencies of Se-GSH-Px and non-Se-GSH-Px toward prostaglandin (PG) G2 (PGG2) and PGH2. Se-GSH-Px exhibited high catalytic activity for the reduction of PGG2 as indicated by Km and Vmax values of 12 microM and 78 mumol/min/mg, respectively, whereas PGH2 was found to be a poor substrate, an indication that Se-GSH-Px reduces the hydroperoxide moiety but not the endoperoxide moiety of PGG2. The kinetic constants of Se-GSH-Px toward PGG2 were comparable to those determined for such classical substrates as H2O2 and cumene hydroperoxide. In contrast to Se-GSH-Px, non-Se-GSH-Px associated with cationic isozyme II of glutathione S-transferases (GSTs) from sheep lung cytosol was very active in the conversion of PGH2 to PGF2 alpha with a Vmax of 960 nmol/min/mg and a Km of 77 microM. This study shows that PGF2 alpha formation by non-Se-GSH-Px occurred in a GSH-dependent reduction of either PGG2 or PGH2. When PGG2 was used as the substrate for non-Se-GSH-Px, a novel intermediate compound appeared and was later identified by several methods of structural analysis as 15-hydroperoxy PGF2 alpha. Thus, the reductive cleavage of the endoperoxide occurs faster than the 15-hydroperoxide reduction allowing 15-hydroperoxy PGF2 alpha to accumulate briefly. A study of GSTs from several different tissues and species indicated that the transformation of PG endoperoxides to PGF2 alpha is catalyzed specifically by GST isozymes, which contain Ya size subunits. This specificity of GST isozymes in PG biosynthesis, coupled with their tissue-specific expression, may be a mechanism by which the body modulates the type of PGs produced in these tissues. Also, these results suggest a possible interaction of Se-GSH-Px and non-Se-GSH-Px in the biosynthesis of PGF2 alpha.     

Mutation of a critical arginine in microsomal prostaglandin E synthase-1 shifts the isomerase activity to a reductase activity that converts prostaglandin H2 into prostaglandin F2alpha

Microsomal prostaglandin E synthase type 1 (mPGES-1) converts prostaglandin endoperoxides, generated from arachidonic acid by cyclooxygenases, into prostaglandin E2. This enzyme belongs to the membrane-associated proteins in eicosanoid and glutathione metabolism (MAPEG) family of integral membrane proteins, and because of its link to inflammatory conditions and preferential coupling to cyclooxygenase 2, it has received considerable attention as a drug target. Based on the high resolution crystal structure of human leukotriene C4 synthase, a model of mPGES-1 has been constructed in which the tripeptide co-substrate glutathione is bound in a horseshoe-shaped conformation with its thiol group positioned in close proximity to Arg-126. Mutation of Arg-126 into an Ala or Gln strongly reduces the enzyme's prostaglandin E synthase activity (85-95%), whereas mutation of a neighboring Arg-122 does not have any significant effect. Interestingly, R126A and R126Q mPGES-1 exhibit a novel, glutathione-dependent, reductase activity, which allows conversion of prostaglandin H2 into prostaglandin F2alpha. Our data show that Arg-126 is a catalytic residue in mPGES-1 and suggest that MAPEG enzymes share significant structural components of their active sites.     

Different catalytically competent arrangements of arachidonic acid within the cyclooxygenase active site of prostaglandin endoperoxide H synthase-1 lead to the formation of different oxygenated products

Arachidonic acid is converted to prostaglandin G(2) (PGG(2)) by the cyclooxygenase activities of prostaglandin endoperoxide H synthases (PGHSs) 1 and 2. The initial, rate-limiting step is abstraction of the 13-proS hydrogen from arachidonate which, for PGG(2) formation, is followed by insertion of O(2) at C-11, cyclization, and a second O( 2) insertion at C-15. As an accompaniment to ongoing structural studies designed to determine the orientation of arachidonate in the cyclooxygenase site, we analyzed the products formed from arachidonate by (a) solubilized, partially purified ovine (o) PGHS-1; (b) membrane-associated, recombinant oPGHS-1; and (c) a membrane-associated, recombinant active site mutant (V349L oPGHS-1) and determined kinetic values for formation of each product. Native forms of oPGHS-1 produced primarily PGG(2) but also several monohydroxy acids, which, in order of abundance, were 11R-hydroxy-5Z, 8Z,12E,14Z-eicosatetraenoic acid (11R-HETE), 15S-hydroxy-5Z,8Z,11Z, 13E-eicosatetraenoic acid (15S-HETE), and 15R-HETE. V349L oPGHS-1 formed primarily PGG(2), 15S-HETE, and 15R-HETE but only trace amounts of 11R-HETE. With native enzyme, the K(m) values for PGG(2), 11-HETE, and 15-HETE formation were each different (5.5, 12.1, and 19.4 microM, respectively); similarly, the K(m) values for PGG(2) and 15-HETE formation by V349L oPGHS-1 were different (11 and 5 microM, respectively). These results establish that arachidonate can assume at least three catalytically productive arrangements within the cyclooxygenase site of oPGHS-1 leading to PGG(2), 11R-HETE, and 15S-HETE and/or 15R-HETE, respectively. IC(50) values for inhibition of formation of the individual products by the competitive inhibitor, ibuprofen, were determined and found to be the same for a given enzyme form (i.e. 175 microM for oPGHS-1 and 15 microM for V349L oPGHS-1). These latter results are most simply rationalized by a kinetic model in which arachidonate forms various catalytically competent arrangements only after entering the cyclooxygenase active site.     

Human platelet/erythroleukemia cell prostaglandin G/H synthase: cDNA cloning, expression, and gene chromosomal assignment

Platelets metabolize arachidonic acid to thromboxane A2, a potent platelet aggregator and vasoconstrictor compound. The first step of this transformation is catalyzed by prostaglandin (PG) G/H synthase, a target site for nonsteroidal antiinflammatory drugs. We have isolated the cDNA for both human platelet and human erythroleukemia cell PGG/H synthase using the polymerase chain reaction and conventional screening procedures. The cDNA encoding the full-length protein was expressed in COS-M6 cells. Microsomal fractions from transfected cells produced prostaglandin endoperoxide-derived products which were inhibited by indomethacin and aspirin. Mutagenesis of the serine residue at position 529, the putative aspirin acetylation site, to an asparagine reduced cyclooxygenase activity to barely detectable levels, an effect observed previously with the expressed sheep vesicular gland enzyme. Platelet-derived growth factor and phorbol ester differentially regulated the expression of PGG/H synthase mRNA levels in the megakaryocytic/platelet-like HEL cell line. The PGG/H synthase gene was assigned to chromosome 9 by analysis of a human--hamster somatic hybrid DNA panel. The availability of platelet PGG/H synthase cDNA should enhance our understanding of the important structure/function domains of this protein and its gene regulation.     

Negative regulation of MAPKK by phosphorylation of a conserved serine residue equivalent to Ser212 of MEK1

The MAPKKs MEK1 and MEK2 are activated by phosphorylation, but little is known about how these enzymes are inactivated. Here, we show that MEK1 is phosphorylated in vivo at Ser(212), a residue conserved among all MAPKK family members. Mutation of Ser(212) to alanine enhanced the basal activity of MEK1, whereas the phosphomimetic aspartate mutation completely suppressed the activation of both wild-type MEK1 and the constitutively activated MEK1(S218D/S222D) mutant. Phosphorylation of Ser(212) did not interfere with activating phosphorylation of MEK1 at Ser(218)/Ser(222) or with binding to ERK2 substrate. Importantly, mimicking phosphorylation of the equivalent Ser(212) residue of the yeast MAPKKs Pbs2p and Ste7p similarly abrogated their biological function. Our findings suggest that Ser(212) phosphorylation represents an evolutionarily conserved mechanism involved in the negative regulation of MAPKKs.     

Prostaglandin G2 levels during reaction of prostaglandin H synthase with arachidonic acid

Prostaglandin H synthase catalyzes the formation of prostaglandin (PG) G2 from arachidonic acid (cyclooxygenase activity), and also the reduction of PGG2 to PGH2 (peroxidase activity). The ability of the pure synthase to accumulate the hydroperoxide, PGG2, under conditions allowing the concurrent function of both catalytic activities was investigated. The peroxidase velocity was continuously determined from the absorbance increases at 611 nm that accompanied oxidation of a peroxidase cosubstrate, N,N,N',N'-tetramethylphenylenediamine, and PGG2 concentrations were calculated from the peroxidase velocities and the peroxidase Vmax and Km values. Cyclooxygenase velocities were then calculated from the changes in PGG2. Parallel reactions monitored by the use of radiolabelled arachidonate or with a polarographic oxygen electrode were used to confirm the calculated PGG2 levels and the cyclooxygenase velocities. The concentration of PGG2 was found to follow a transient course as the reaction of the synthase progressed, rapidly rising to a maximum of 0.7 microM in the first 10 s, and then declining slowly, reaching 0.1 microM after 60 s. The maximal level of PGG2 achieved during the reaction was constant at about 0.7 microM with higher amounts of added cyclooxygenase capacity (0.3-0.6 microM PGG2/s) but was only about 0.4 microM when the added cyclooxygenase capacity was 0.1 microM PGG2/s. The peroxidase was found to lose only 30% of its activity after 90 s, a point where the cyclooxygenase was almost completely inactive. These results support the concept of a burst of catalytic action from the cyclooxygenase and a reactive, more sustained, catalytic action from the peroxidase during the reaction of the synthase with arachidonic acid.     

Identification of two cyclooxygenase active site residues, Leucine 384 and Glycine 526, that control carbon ring cyclization in prostaglandin biosynthesis

The cyclooxygenase (COX) reaction of prostaglandin (PG) biosynthesis begins with the highly specific oxygenation of arachidonic acid in the 11R configuration and ends with a 15S oxygenation to form PGG2. To obtain new insights into the mechanisms of stereocontrol of oxygenation, we mutated active site residues of human COX-2 that have potential contacts with C-11 of the reacting substrate. Although the 11R oxygenation was not perturbed, changing Leu-384 (into Phe, Trp), Trp-387 (Phe, Tyr), Phe-518 (Ile, Trp, Tyr), and Gly-526 (Ala, Ser, Thr, Val) impaired or abrogated PGG2 synthesis, and typically 11R-HETE was the main product formed. The Gly-526 and Leu-384 mutants formed, in addition, three novel products identified by LC-MS, NMR, and circular dichroism as 8,9-11,12-diepoxy-13R-(or 15R)-hydro(pero)xy derivatives of arachidonic acid. Mechanistically, we propose these arise from a free radical intermediate in which a C-8 carbon radical displaces the 9,11-endoperoxide O-O bond to yield an 8,9-11,12-diepoxide that is finally oxygenated stereospecifically in the 13R or 15R configuration. Formation of these novel products signals an arrest in the normal course of prostaglandin synthesis just prior to closing of the 5-membered carbon ring, and points to a crucial role for Leu-384 and Gly-526 in the correct positioning of the reacting fatty acid intermediate. Some of the Gly-526 and Leu-384 mutants catalyzed both formation of PGG2 (with the normal 15S configuration) and the 13R- or 15R-oxygenated diepoxides. This result suggests that oxygenation specificity can be determined by the orientation of the reacting fatty acid radical and is not a predetermined outcome based solely on the structure of the cyclooxygenase active site.     

Different suicide inactivation processes for the peroxidase and cyclooxygenase activities of prostaglandin endoperoxide H synthase-1.

Prostaglandin endoperoxide H synthases (PGHSs)-1 and -2 have a cyclooxygenase (COX) activity involved in forming prostaglandin G2 (PGG2) from arachidonic acid and an associated peroxidase (POX) activity that reduces PGG2 to PGH2. Suicide inactivation processes are observed for both POX and COX reactions. Here we report COX reaction conditions for PGHS-1 under which complete COX inactivation occurs but with > or = 60% retention of POX activity. The rates of POX inactivation were compared for native oPGHS-1 versus Y385F oPGHS-1, a mutant that cannot form the Tyr385 radical of COX Intermediate II; the rates were the same for both native and Y385F oPGHS-1. Our data indicate that a COX Intermediate II/acyl or product complex is the precursor in COX inactivation. However, another species, probably an Intermediate II-like species but with a radical centered on a tyrosine other than Tyr385, is the immediate precursor for POX inactivation.     

Radical scavenging as the mechanism for stimulation of prostaglandin cyclooxygenase and depression of inflammation by lipoic acid and sodium iodide.

Certain radical-trapping reducing agents have been shown to stimulate prostaglandin biosynthesis in vitro (1--6) and to depress phorbol myristate acetate-induced mouse ear edema (16). The increased prostaglandin synthesis resulted from influences on the cyclooxygenase. To ascertain whether these alterations were due to direct interaction with the enzyme or to indirect scavenging of the oxidant released during PGG2 reduction, we report the effects of lipoic acid and sodium iodide. Both of these agents stimulated the enzymatic oxygenation of arachidonic acid, increased the reduction of PGG2 to PGH2, quenched the EPR signal induced by arachidonic acid and depressed mouse ear edema. In addition to discovering two unusual antiinflammatory agents, we have confirmed that materials with entirely different structures can have identical effects on the cyclooxygenase, suggesting indirect stimulation of this enzyme due to trapping of the oxidant.     

Crystal structure of arachidonic acid bound to a mutant of prostaglandin endoperoxide H synthase-1 that forms predominantly 11-hydroperoxyeicosatetraenoic acid

Kinetic studies and analysis of the products formed by native and mutant forms of ovine prostaglandin endoperoxide H synthase-1 (oPGHS-1) have suggested that arachidonic acid (AA) can exist in the cyclooxygenase active site of the enzyme in three different, catalytically competent conformations that lead to prostaglandin G2 (PGG2), 11R-hydroperoxyeicosatetraenoic acid (HPETE), and 15R,S-HPETE, respectively. We have identified an oPGHS-1 mutant (V349A/W387F) that forms predominantly 11R-HPETE. Thus, the preferred catalytically competent arrangement of AA in the cyclooxygenase site of this double mutant must be one that leads to 11-HPETE. The crystal structure of Co3+-protoporphyrin IX V349A/W387F oPGHS-1 in a complex with AA was determined to 3.1 A. Significant differences are observed in the positions of atoms C-3, C-4, C-5, C-6, C-10, C-11, and C-12 of bound AA between native and V349A/W387F oPGHS-1; in comparison, the positions of the side chains of cyclooxygenase active site residues are unchanged. The structure of the double mutant presented here provides structural insight as to how Val349 and Trp387 help position C-9 and C-11 of AA so that the incipient 11-peroxyl radical intermediate is able to add to C-9 to form the 9,11 endoperoxide group of PGG2. In the V349A/W387F oPGHS-1.AA complex the locations of C-9 and C-11 of AA with respect to one another make it difficult to form the endoperoxide group from the 11-hydroperoxyl radical. Therefore, the reaction apparently aborts yielding 11R-HPETE instead of PGG2. In addition, the observed differences in the positions of carbon atoms of AA bound to this mutant provides indirect support for the concept that the conformer of AA shown previously to be bound within the cyclooxygenase active site of native oPGHS-1 is the one that leads to PGG2.     

Cloning,expression, crystallization,and preliminary X-ray analysis of recombinant mouse lipocalin-type prostaglandin D synthase,a somnogen-producing enzyme

Lipocalin-type prostaglandin D synthase is the key enzyme for the production of prostaglandin D(2), a potent endogenous somnogen, in the brain. We cloned, produced, and crystallized the native enzyme and selenomethionyl Cys(65)Ala mutants of the recombinant mouse protein by the hanging drop vapor-diffusion method with both malonate and citrate as precipitants. The native crystals obtained with malonate belong to orthorhombic space group P2(1)2(1)2(1) with lattice constants a = 46.2, b = 66.8, and c = 105.3 A. The selenomethionyl crystals obtained with citrate belong to orthorhombic space group C222(1) with lattice constants a = 45.5, b = 66.8, and c = 104.5 A. The native crystals diffracted beyond 2.1 A resolution.     

Human hematopoietic prostaglandin D synthase inhibitor complex structures

In mast and Th2 cells, hematopoietic prostaglandin (PG) D synthase (H-PGDS) catalyses the isomerization of PGH(2) in the presence of glutathione (GSH) to produce the allergic and inflammatory mediator PGD(2). We determined the X-ray structures of human H-PGDS inhibitor complexes with 1-amino-4-{4-[4-chloro-6-(2-sulpho-phenylamino)-[1,3,5]triazin-2-ylmethyl]-3-sulpho-phenylamino}-9,10-dioxo-9,10-dihydro-anthracene-2-sulphonic acid (Cibacron Blue) and 1-amino-4-(4-aminosulphonyl) phenyl-anthraquinone-2-sulphonic acid (APAS) at 2.0 ? resolution. When complexed with H-PGDS, Cibacron Blue had an IC(50) value of 40 nM and APAS 2.1 μM. The Cibacron Blue molecule was stabilized by four hydrogen bonds and π-π stacking between the anthraquinone ring and Trp104, the ceiling of the active site H-PGDS pocket. Among the four hydrogen bonds, the Cibacron Blue terminal sulphonic group directly interacted with conserved residues Lys112 and Lys198, which recognize the PGH(2) substrate α-chain. In contrast, the APAS anthraquinone ring was inverted to interact with Trp104, while its benzenesulphonic group penetrated the GSH-bound region at the bottom of the active site. Due to the lack of extended aromatic rings, APAS could not directly hydrogen bond with the two conserved lysine residues, thus decreasing the total number of hydrogen bond from four to one. These factors may contribute to the 50-fold difference in the IC(50) values obtained for the two inhibitors.     

用酵母双杂交技术研究IGF-1与其结合蛋白3的相互作用

 为了探讨胰岛素样生长因子结合蛋白 3(IGFBP- 3)分子上的胰岛素样生长因子 1 (IGF- 1 )结合位点并找出其关键氨基酸残基组成 ,首先建立了研究 IGF- 1与 IGFBP- 3相互作用的酵母双杂交模型 ,可以定性和定量地分析两个蛋白质之间的相互作用大小 ;同时利用基因体外定点突变的方法 ,对推断出的 IGF- 1结合位点中的氨基酸突变 ,经 DNA序列分析 ,构建了 5种 IGFBP- 3突变体 .然后在酵母双杂交模型中通过对报告基因活性的定量分析 ,检测 IGF- 1与各种 IGFBP- 3突变体之间相互作用的大小 .结果表明 ,IGFBP- 3分子上的 Lys2 2 2 ,Gln2 2 3突变后 ,与 IGF- 1的结合力大大下降 ,而 Arg2 2 5,Pro2 2 6,Ser2 2 7突变后也导致与 IGF- 1结合力的部分下降 .从而初步确定了IGFBP- 3分子中第 2 2 2～ 2 2 7位的氨基酸区域为 IGF- 1的结合位点 ,并且 IGFBP- 3分子上 Lys2 2 2 ,Gln2 2 3在与 IGF- 1结合中起着重要作用 .