Slow-binding inhibition of human prostaglandin endoperoxide synthase-2 with darbufelone, an isoform-selective antiinflammatory di-tert-butyl phenol.

The antiinflammatory agent darbufelone, ((Z)-5-[[3,5-bis(1,1-dimethylethyl)-4-hydroxyphenyl] methylene]-2-imino-4-thiazolidinone, methanesulfonate salt), was discovered as a dual inhibitor of cellular prostaglandin and leukotriene production. To study the mechanism of action of this drug, we expressed human prostaglandin endoperoxide synthase-1 (PGHS-1) and PGHS-2 and purified the recombinant enzymes using buffers that contain octylglucoside. In cyclooxygenase assays following a 15-min incubation of enzyme with inhibitor, darbufelone potently inhibits PGHS-2 (IC(50) = 0.19 microM) but is much less potent with PGHS-1 (IC(50) = 20 microM). Interestingly, when the assay buffer contains traces of Tween 20 (0.0001%), darbufelone appears inactive with PGHS-2 due to a detergent interaction that is detectable by absorption spectroscopy. We therefore used octylglucoside, which does not affect darbufelone in this way, in place of Tween 20 in our PGHS buffers. Inhibition of PGHS-2 with darbufelone is time dependent: with no preincubation, darbufelone is a weak inhibitor (IC(50) = 14 microM), but after a 30-min incubation it is 20-fold more potent. Plots of PGHS-2 activity vs preincubation time at various darbufelone concentrations reach a plateau. This finding is inconsistent with irreversible or one-step slow-binding inhibition. A two-step slow-binding inhibition model is proposed in which the E.I complex (K(i) = 6.2 +/- 1.9 to 14 +/- 1 microM) slowly transforms (k(5) = 0.015-0.030 s(-)(1)) to a tightly bound E.I form with K(i) = 0.63 +/- 0.07 microM and k(6) = 0.0034 s(-)(1). In steady-state kinetics inhibition experiments performed with no preincubation, we find that darbufelone is a noncompetitive inhibitor of PGHS-2 (K(i) = 10 +/- 5 microM). Darbufelone quenches the fluorescence of PGHS-2 at 325 nm (lambda(ex) = 280 nm) with K(d) = 0.98 +/- 0.03 microM. The PGHS substrate, arachidonate, and various cyclooxygenase inhibitors do not alter this binding affinity of darbufelone but a structural analogue of darbufelone competes directly for binding to PGHS-2. Di-tert-butyl phenols such as darbufelone may inhibit PGHS-2 by exploiting a previously unrecognized binding site on the enzyme.     

7,8-Diaminoperlargonic acid aminotransferase from Mycobacterium tuberculosis, a potential therapeutic target. Characterization and inhibition studies

Diaminopelargonic acid aminotransferase (DAPA AT), which is involved in biotin biosynthesis, catalyzes the transamination of 8-amino-7-oxononanoic acid (KAPA) using S-adenosyl-l-methionine (AdoMet) as amino donor. Mycobacterium tuberculosis DAPA AT, a potential therapeutic target, has been overproduced in Escherichia coli and purified to homogeneity using a single efficient step on a nickel-affinity column. The enzyme shows an electronic absorption spectrum typical of pyridoxal 5'-phosphate-dependent enzymes and behaves as a homotetramer in solution. The pH profile of the activity at saturation shows a single ionization group with a pK(a) of 8.0, which was attributed to the active-site lysine residue. The enzyme shows a Ping Pong Bi Bi kinetic mechanism with strong substrate inhibition with the following parameters: K(mAdoMet) = 0.78 +/- 0.20 mm, K(mKAPA) = 3.8 +/- 1.0 microm, k(cat) = 1.0 +/- 0.2 min(-1), K(iKAPA) = 14 +/- 2 microm. Amiclenomycin and a new analogue, 4-(4c-aminocyclohexa-2,5-dien-1r-yl)propanol (referred to as compound 1), were shown to be suicide substrates of this enzyme, with the following inactivation parameters: K(i) = 12 +/- 2 microm, k(inact) = 0.35 +/- 0.05 min(-1), and K(i) = 20 +/- 2 microm, k(inact) = 0.56 +/- 0.05 min(-1), for amiclenomycin and compound 1, respectively. The inactivation was irreversible, and the partition ratios were 1.0 and 1.1 for amiclenomycin and compound 1, respectively, which make these inactivators particularly efficient. compound 1 (100 microg.mL(-1)) completely inhibited the growth of an E. coli C268bioA mutant strain transformed with a plasmid expressing the M. tuberculosis bioA gene, coding for DAPA AT. Reversal of the antibiotic effect was observed on the addition of biotin or DAPA. Thus, compound 1 specifically targets DAPA AT in vivo.     

Prostaglandin-H-synthase (PGHS)-1 and -2 microtiter assays for the testing of herbal drugs and in vitro inhibition of PGHS-isoenzyms by polyunsaturated fatty acids from Platycodi radix

In order to test inhibition of prostaglandin-H-synthase-1 and -2 (PGHS-1 and -2) by plant extracts, we have established two enzyme based in vitro assays with enzyme immunoassay (EIA) evaluation. The assays have been evaluated with known synthetic inhibitors and with plant extracts. In a screening of traditionally used Chinese herbs for anti-inflammatory activity, a series of n-hexane and dichloromethane extracts showed significant inhibitory effect in comparison with the known specific PGHS-2 inhibitors NS-398 (IC(50) = 2.6 microM) and nimesulide (IC(50) = 36 microM). The lipophilic extracts of the Chinese drug Jiengeng, the dried roots of Platycodon grandiflorum (Jacq.) A. DC. (Campanulaceae), showed good inhibitory activity against both PGHS isoenzymes. The directly prepared DCM-extract exhibited better activity against PGHS-2 (IC(50) = 4.0 microg/ml) than against PGHS-1 (IC(50) = 17.6 microg/ml). We identified fatty acids as main active constituents and quantified them. Linoleic acid showed the highest content (ca. 20% of the dried extract) and a high and preferential PGHS-2 inhibitory activity (IC(50) (PGHS-1) = 20 microM; IC(50) (PGHS-2) = 2 microM). The comparison of the concentration of linoleic acid and the inhibitory activity of the direct DCM-extract showed, that linoleic acid is mainly responsible for the in vitro activity of the extract on PGHS-2.     

Inactivation of cysteine proteases by (acyloxy)methyl ketones using S'-P' interactions

We have synthesized (acyloxy)methyl ketone inactivators of papain, cathepsin B, and interleukin-1beta conversion enzyme (ICE) that interact with both the S and S' subsites. The value of k(inact)/K(i) for these inactivators is strongly dependent on the leaving group. For example, Z-Phe-Gly-CH(2)-X is a poor inactivator of papain when X is OCOCH(3) (k(inact)/K(i) = 2.5 M(-)(1) s(-)(1)) but becomes a potent inactivator when X is OCO-L-Leu-Z (k(inact)/K(i) = 11 000 M(-)(1) s(-)(1)). Since these leaving groups have similar chemical reactivities, the difference in potency must be attributed to interactions with the S' sites. The potency of the leaving group correlates with the P' specificity of papain. Similar results are also observed for the inactivation of cathepsin B by these compounds. A series of inactivators with the general structure Fmoc-L-Asp-CH(2)-X were designed to inactivate ICE. No inhibition was observed when X was OCOCH(3). In contrast, ICE is inactivated when X is OCO-D-Pro-Z (k(inact)/K(i) = 131 M(-)(1) s(-)(1)). These results demonstrate that S'-P' interactions can be utilized to increase the efficacy and selectivity of (acyloxy)methyl ketone inactivators.     

Antiproliferative activity of guava leaf extract via inhibition of prostaglandin endoperoxide H synthase isoforms

Prostaglandin endoperoxide H synthase (PGHS) is a key enzyme for the synthesis of prostaglandins (PGs) which play important roles in inflammation and carcinogenesis. Because the extract from Psidium guajava is known to have a variety of beneficial effects on our body including the anti-inflammatory, antioxidative and antiproliferative activities, we investigated whether the extract inhibited the catalytic activity of the two PGHS isoforms using linoleic acid as an alternative substrate. The guava leaf extract inhibited the cyclooxygenase reaction of recombinant human PGHS-1 and PGHS-2 as assessed by conversion of linoleic acid to 9- and 13-hydroxyoctadecadienoic acids (HODEs). The guava leaf extract also inhibited the PG hydroperoxidase activity of PGHS-1, which was not affected by nonsteroidal anti-inflammatory drugs (NSAIDs). Quercetin which was one of the major components not only inhibited the cyclooxygenase activity of both isoforms but also partially inhibited the PG hydroperoxidase activity. Overexpression of human PGHS-1 and PGHS-2 in the human colon carcinoma cells increased the DNA synthesis rate as compared with mock-transfected cells which did not express any isoforms. The guava leaf extract not only inhibited the PGE₂ synthesis but also suppressed the DNA synthesis rate in the PGHS-1- and PGHS-2-expressing cells to the same level as mock-transfected cells. These results demonstrate the antiproliferative activity of the guava leaf extract which is at least in part caused by inhibition of the catalytic activity of PGHS isoforms.     

Differential effects of nitric oxide on the activity of prostaglandin endoperoxide H synthase-1 and -2 in vascular endothelial cells

A number of studies have demonstrated that prostacyclin and nitric oxide (NO) regulate blood pressure, blood flow and platelet aggregation. In this paper, we have examined the possible relationship between NO and prostaglandin endoperoxide H synthase (PGHS)-1 and -2 activities in cultured bovine aortic endothelial cells. In the non-activated condition endothelial cells expressed PGHS-1 activity alone. When these cells were pretreated with aspirin to inactivate their PGHS-1 and then activated by serum and phorbol ester (TPA) for 6 h, the cells expressed PGHS-2 activity alone. The PGHS activity was assessed by the generation of 6-ketoprostaglandin F1alpha (6-ketoPGF1alpha), a stable metabolite of prostacyclin, after the treatment of these cells with arachidonic acid. The simultaneous addition of NOC-7, a NO donor, with arachidonic acid did not affect the production of 6-ketoPGF1alpha in PGHS-1 expressed cells, but attenuated it in PGHS-2-expressed cells. The inhibitory effect of NOC-7 on PGHS-2 activity was dose dependent, and the different effects of NOC-7 on the activities of PGHS isozymes were also observed in other NO donors. To confirm the different effect of NO on PGHS isozymes demonstrated in the cultured endothelial cells, we carried out an ex vivo perfusion assay in aorta isolated from normal and lipopolysaccharide (LPS)-treated rats. In the aortae isolated from normal rats, where dominant expression of PGHS-1 was expected, the NO donor did not affect the PGHS activity, while in aortae isolated from LPS-treated rats, where PGHS-2 was dominantly expressed, the NO donor dramatically inhibited the PGHS activity, suggesting that NO suppressed PGHS-2 activity alone. The inhibitory effect of NO on PGHS-2 activity was not mediated by cyclic GMP (cGMP), since (a) methylene blue, an inhibitor of soluble guanylate cyclase did not abolish the inhibitory effect of the NO donor on PGHS-2 activity, and (b) 8-Br-cGMP, a permeable cGMP analogue, failed to mimic the effect of NO donors. These data suggest that the effect of NO on prostacyclin production in endothelial cells was dependent on the expression rate of PGHS-1 and PGHS-2 in the cells.     

Prostanoid production in Saccharomyces cerevisiae provides a novel assay for nonsteroidal anti-inflammatory drugs

Prostanoids are a large family of lipid mediators originating from prostaglandin H synthase (PGHS) activity on the 20-carbon polyunsaturated fatty acids dihomo-γ-linolenic acid (DGLA), arachidonic acid (AA) and eicosapentaenoic acid. The two mouse PGHS isoforms, PGHS-1 and PGHS-2, were expressed in Saccharomyces cerevisiae (yeast), as was a signal-peptide-deleted version of PGHS-1 (PGHS-1MA). PGHS-1 showed high activity with both AA and DGLA as substrate, whereas PGHS-2 activity was high with DGLA but low with AA. Signal peptide removal reduced the activity of PGHS-1MA by >50% relative to PGHS-1, but the residual activity indicated that correct targeting to the lumen of the endoplasmic reticulum may not be necessary for enzyme function. Coexpression of PGHS-1 with cDNAs encoding mouse prostaglandin I synthase and thromboxane A synthase, and with Trypanosoma brucei genomic DNA encoding prostaglandin F synthase in AA-supplemented yeast cultures resulted in production of the corresponding prostanoids, prostaglandin I₂, thromboxane A₂ and prostaglandin F_2α. The inhibitory effects of nonsteroidal anti-inflammatory drugs (NSAIDs) on prostanoid production were tested on yeast cells expressing PGHS-1 in AA-supplemented culture. Dose-dependent inhibition of prostaglandin H₂ production by aspirin, ibuprofen and indomethacin demonstrated the potential utility of this simple expression system in screening for novel NSAIDs.     

Involvement of phospholipid hydroperoxide glutathione peroxidase in the modulation of prostaglandin D2 synthesis

Antigenic cross-linking of the high affinity IgE receptors on mast cells induced the synthesis of prostaglandin D(2) (PGD(2)). The production of PGD(2) in L9 cells, which overexpressed non-mitochondrial phospholipid glutathione peroxidase (PHGPx), was only one-third that in the control line of cells (S1 cells). The reduction in the formation of PGD(2) in L9 cells was reversed upon inhibition of PHGPx activity by buthionine sulfoximine. Experiments with inhibitors demonstrated that prostaglandin H synthase-2 (PGHS-2) was the isozyme responsible for the production of PGD(2) upon cross-linking of IgE receptors. The conversion of radiolabeled arachidonic acid to prostaglandin H(2) (PGH(2)) was strongly inhibited in L9 cells, whereas the rate of conversion of PGH(2) to PGD(2) was the same in L9 cells and S1 cells, indicating that PGHS was inactivated in L9 cells. The PGHS activity in L9 cells was about half that in S1 cells. However, PGHS activity in L9 cells increased to the level in S1 cells upon the addition of the hydroperoxide 15-hydroperoxyeicosatetraenoic acid or of 3-chloroperoxybenzoic acid. These results suggest that non-mitochondrial PHGPx might be involved in the inactivation of PGHS-2 in nucleus and endoplasmic reticulum via reductions in levels of the hydroperoxides that are required for full activation of PGHS. Therefore, it appears that PHGPx might function as a modulator of the production of prostanoids, in addition to its role as an antioxidant enzyme.     

A comparative study of the purity, enzyme activity, and inactivation by hydrogen peroxide of commercially available horseradish peroxidase isoenzymes A and C

Horseradish peroxidase (HRP) is a commercially important enzyme that is available from a number of supply houses in a variety of grades of purity and isoenzymic combinations. The present article describes a comparative study made on nine HRP preparations. Six of these samples were predominantly composed of basic HRP, pl 8.5, and three of acidic HRP, pl 3.5. Two of the basic preparations were of lower purity than the others. The apparent molar catalytic activity of basic HRP with 0.5 mMABTS and 0.2 mM H(2)O(2) was around 950 s(-1) (about 770 s(-1) for the less pure samples) and with a 5 mM guaiacol and 0.6 mM H(2)O(2) was about 180 s(-1) for all the samples. A similar value (approximately 1000 s(-1)) was observed for acidic HRP but only at higher concentrations of ABTS (20 mM). With 20 mM guaiacol the molar catalytic activity of the acid isoenzyme was 65 s(-1). The apparent K(M) for ABTS of the acidic isoenzyme was 4 mM whereas for the basic isoenzyme it was 0.1 mM. All the enzymes were inactivated by H(2)O(2) when it was supplied as the only substrate. Under these conditions the partition ratio (r = number of catalytic cycles given by the enzyme before its inactivation), apparent dissociation constant (K(l)), and apparent rate constant of inactivation (k(inact)) were about twice as large for the acidic samples (1350, 2.6 mM, 9 . 10(-3) s(-1)) as for the basic (650, 1.3 mM, 5 . 10(-3) s(-1)). The apparent catalytic constant (k(cat)) was 3-4 times larger, and the efficiency of catalysis (k(cat)/K(l)) was double for the acidic isoenzyme, but the efficiency of inactivation (k(inact)/K(l)) was similar. The data obtained provide useful information for those using HRP isoenzymes for biotechnological applications (e.g., biosensors, bioreactors, or assays). (c) 1996 John Wiley & Sons, Inc.     

Kinetic and mechanistic properties of biotin sulfoxide reductase

Rhodobacter sphaeroides f. sp. denitrificans biotin sulfoxide reductase catalyzes the reduction of d-biotin d-sulfoxide (BSO) to biotin. Initial rate studies of the homogeneous recombinant enzyme, expressed in Escherichia coli, have demonstrated that the purified protein utilizes NADPH as a facile electron donor in the absence of any additional auxiliary proteins. We have previously shown [Pollock, V. V., and Barber, M. J. (1997) J. Biol. Chem. 272, 3355-3362] that, at pH 8 and in the presence of saturating concentrations of BSO, the enzyme exhibits, a marked preference for NADPH (k(cat,app) = 500 s(-1), K(m,app) = 269 microM, and k(cat,app)/K(m,app) = 1.86 x 10(6) M(-1) s(-1)) compared to NADH (k(cat,app) = 47 s(-1), K(m,app) = 394 microM, and k(cat,app)/K(m,app) = 1.19 x 10(5) M(-1) s(-1)). Production of biotin using NADPH as the electron donor was confirmed by both the disk biological assay and by reversed-phase HPLC analysis of the reaction products. The purified enzyme also utilized ferricyanide as an artificial electron acceptor, which effectively suppressed biotin sulfoxide reduction and biotin formation. Analysis of the enzyme isolated from tungsten-grown cells yielded decreased reduced methyl viologen:BSO reductase, NADPH:BSO reductase, and NADPH:FR activities, confirming that Mo is required for all activities. Kinetic analyses of substrate inhibition profiles revealed that the enzyme followed a Ping Pong Bi-Bi mechanism with both NADPH and BSO exhibiting double competitive substrate inhibition. Replots of the 1/v-axes intercepts of the parallel asymptotes obtained at several low concentrations of fixed substrate yielded a K(m) for BSO of 714 and 65 microM for NADPH. In contrast, utilizing NADH as an electron donor, the replots yielded a K(m) for BSO of 132 microM and 1.25 mM for NADH. Slope replots of data obtained at high concentrations of BSO yielded a K(i) for BSO of 6.10 mM and 900 microM for NADPH. Kinetic isotope studies utilizing stereospecifically deuterated NADPD indicated that BSO reductase uses specifically the 4R-hydrogen of the nicotinamide ring. Cyanide inhibited NADPH:BSO and NADPH:FR activities in a reversible manner while diethylpyrocarbonate treatment resulted in complete irreversible inactivation of the enzyme concomitant with molybdenum cofactor release, indicating that histidine residues are involved in cofactor-binding.     

A computational protocol for the integration of the monotopic protein prostaglandin H2 synthase into a phospholipid bilayer

Prostaglandin H2 synthase (PGHS) synthesizes PGH2, a prostaglandin precursor, from arachidonic acid and was the first monotopic enzyme to have its structure experimentally determined. Both isozymes of PGHS are inhibited by nonsteroidal antiinflammatory drugs, an important class of drugs that are the primary means of relieving pain and inflammation. Selectively inhibiting the second isozyme, PGHS-2, minimizes the gastrointestinal side-effects. This had been achieved by the new PGHS-2 selective NSAIDs (i.e., COX-2 inhibitors) but it has been recently suggested that they suffer from additional side-effects. The design of these drugs only made use of static structures from x-ray crystallographic experiments. Investigating the dynamics of both PGHS-1 and PGHS-2 using classical molecular dynamics is expected to generate new insight into the differences in behavior between the isozymes, and therefore may allow improved PGHS-2 selective inhibitors to be designed. We describe a molecular dynamics protocol that integrates PGHS monomers into phospholipid bilayers, thereby producing in silico atomistic models of the PGHS system. Our protocol exploits the vacuum created beneath the protein when several lipids are removed from the top leaflet of the bilayer. The protein integrates into the bilayer during the first 5 ns in a repeatable process. The integrated PGHS monomer is stable and forms multiple hydrogen bonds between the phosphate groups of the lipids and conserved basic residues (Arg, Lys) on the protein. These interactions stabilize the system and are similar to interactions observed for transmembrane proteins.     

Regulation of prostaglandin H synthase-2 expression in cerebromicrovascular smooth muscle by serum and epidermal growth factor

Growth factors may play a role in the formation of prostaglandins (PG) by cerebral blood vessels during development or reaction to injury. In smooth muscle cultures isolated from murine cerebral microvessels PG production was induced with either serum or epidermal growth factor (EGF). Prostaglandin H synthase (PGHS) activity peaked at 6 h after the addition of 10% serum or 50 ng/ml EGF. Increases in expression of PGHS-1 mRNA were small (7- to 10-fold) compared with PGHS-2 (30- to 120-fold), and the induction patterns were different for serum and EGF. An increase in PGHS-2 message was detected by 0.5 h of adding either agent, but peak induction occurred earlier for EGF than for serum, 1 h vs. 3 h, respectively. The response to either stimulus had returned to prestimulation levels by 12 h. The induction of PGHS-2 protein was also transient, but followed a more delayed time course (peak levels at 6 h). Induction of activity, message, and protein by either agent was blocked by 1 μM dexamethasone and attenuated by genistein (100 μM), a nonspecific tyrosine kinase inhibitor. Tyrphostin 47, a more selective EGF receptor tyrosine kinase inhibitor, dose-dependently inhibited EGF-stimulated PGHS activity, completely abolishing PG production at 100 μM. However, this inhibitor had no effect on serum-stimulated PG production. Curiously, 100 μM tyrphostin 47 enhanced EGF-induced PGHS-2 mRNA and protein expression. These data suggest that EGF induces the expression of PGHS-2 in cerebromicrovascular smooth muscle by a mechanism that requires tyrosine kinase activity and that is distinct from serum. J. Cell. Physiol. 176:495–505, 1998. © 1998 Wiley-Liss, Inc.     

Immunohistochemical localization of prostaglandin G/H synthase 1 and 2 in sheep placenta after glucocorticoid-induced and spontaneous labour

Enhanced prostaglandin production and release by the placenta is an essential element in the normal transition to labour in many animal species. In sheep, expression of prostaglandin G/H synthase (PGHS) is the central enzyme regulating this process. In this study immunohistochemistry was used to examine the distribution of cells expressing PGHS-1 and PGHS-2 in ovine placenta in association with spontaneous parturition (n = 6) and glucocorticoid-induced labour (n = 5). Labour was induced in ewes after the intrafetal injection of betamethasone on day 131 of gestation. Animals administered an intrafetal injection of isotonic saline (n = 5) acted as non-labour controls. In placentomes collected from all groups, immunoreactive PGHS-1 was present in the mononuclear trophoblast cells of the fetal placenta. Cells in the maternal mesenchyme and epithelial syncytium were weakly immunopositive for this enzyme. PGHS-1 immunoreactivity was also demonstrated in the endothelial cells of the chorionic vessels. The PGHS-2 isozyme was localized exclusively to the trophoblast epithelial cells. Immunoreactive PGHS-2 was not detectable in the maternal epithelial syncytium or the stroma of the cotyledons. The binucleate cells of the fetal placenta were consistently immunonegative for both PGHS isozymes. These results indicate that the cellular localization of PGHS-1 and PGHS-2 in ovine placenta does not change during the last 15 days of pregnancy. Co-localization of these isozymes indicates that the source of arachidonic acid and the site of prostanoid formation are the same. Quantitation of the percentage area of positive staining for PGHS-1 and PGHS-2 using image analysis software demonstrated a significant increase in PGHS-2 in the fetal trophoblast after glucocorticoid-induced labour and spontaneous parturition. This finding indicates that increased formation of the PGHS-2 isozyme is responsible for the large increase in prostaglandin production by the ovine placenta at term labour.     

Aromatic hydroxamic acids and hydrazides as inhibitors of the peroxidase activity of prostaglandin H2 synthase-2

The cyclooxygenase activity of the bifunctional enzyme prostaglandin H(2) synthase-2 (PGHS-2) is the target of non-steroidal anti-inflammatory drugs. Inhibition of the peroxidase activity of PGHS has been less studied. Using Soret absorption changes, the binding of aromatic hydroxamic acids to the peroxidase site of PGHS-2 was examined to investigate the structural determinants of inhibition. Typical of mammalian peroxidases, the K(d) for benzhydroxamic acid (42mM) is much greater than that for salicylhydroxamic acid (475microM). Binding of the hydroxamic acid tepoxalin (25microM) resulted in only minor Soret changes. However, tepoxalin is an efficient reducing cosubstrate, indicating that it is an alternative electron donor rather than an inhibitor of the peroxidase activity. Aromatic hydrazides are metabolically activated inhibitors of peroxidases. 2-Naphthoichydrazide (2-NZH) caused the time- and concentration-dependent inhibition of both PGHS-2 peroxidase and cyclooxygenase activities. H(2)O(2) was required for the inactivation of both PGHS-2 activities and indomethacin (which binds at the cyclooxygenase site) did not affect the peroxidase inhibitory potency of 2-NZH. A series of aromatic hydrazides were found to be potent inhibitors of PGHS-2 peroxidase activity with IC(50) values in the 6-100microM range for 13 of the 18 hydrazides examined. Selective inhibition of PGHS-2 over myeloperoxidase and horseradish peroxidase isozyme C was increased by certain ring substitutions. In particular, a chloro group para to the hydrazide moiety increased the PGHS-2 selectivity relative to both myeloperoxidase and horseradish peroxidase isozyme C.     

Distinct influences of carboxyl terminal segment structure on function in the two isoforms of prostaglandin H synthase

The cyclooxygenase activity of the two prostaglandin H synthase (PGHS) isoforms, PGHS-1 and -2, is a major control element in prostanoid biosynthesis. The two PGHS isoforms have 60% amino acid identity, with prominent differences near the C-terminus, where PGHS-2 has an additional 18-residue insert. Some mutations of the C-terminal residue in PGHS-1 and -2 have been found to disrupt catalytic activity and/or intracellular targeting of the proteins, but the relationship between C-terminal structure and function in the two isoforms has been poorly defined. Crystallographic data indicate the PGHS-1 and -2 C-termini are positioned to interact with the endoplasmic reticulum (ER) membrane, although the C-terminal segment structure was not resolved for either isoform. We constructed a series of C-terminal substitution, deletion, and insertion mutants of human PGHS-1 and -2 and evaluated the effects on cyclooxygenase activity and intracellular targeting in transfected COS-1 cells expressing the recombinant proteins. PGHS-1 cyclooxygenase activity was strongly disrupted by C-terminal substitutions and deletions, but not by elongation of the C-terminal segment, even when the ultimate residue was altered. Similar alterations to PGHS-2 had markedly less effect on cyclooxygenase activity. The results indicate that the functioning of the longer C-terminal segment in PGHS-2 is distinctly more tolerant of structural change than the shorter PGHS-1 C-terminal segment. C-Terminal substitutions or deletions did not change the subcellular localization of either isoform, even at short times after transfection, indicating that neither C-terminal segment contains indispensable intracellular targeting signals.     

Resveratrol is a peroxidase-mediated inactivator of COX-1 but not COX-2: a mechanistic approach to the design of COX-1 selective agents

Resveratrol (3,4',5-trihydroxy-trans-stilbene) is a phytoalexin found in grapes that has anti-inflammatory, cardiovascular protective, and cancer chemopreventive properties. It has been shown to target prostaglandin H(2) synthase (COX)-1 and COX-2, which catalyze the first committed step in the synthesis of prostaglandins via sequential cyclooxygenase and peroxidase reactions. Resveratrol discriminates between both COX isoforms. It is a potent inhibitor of both catalytic activities of COX-1, the desired drug target for the prevention of cardiovascular disease, but only a weak inhibitor of the peroxidase activity of COX-2, the isoform target for nonsteroidal anti-inflammatory drugs. We have investigated the unique inhibitory properties of resveratrol. We find that it is a potent peroxidase-mediated mechanism-based inactivator of COX-1 only (k(inact) = 0.069 +/- 0.004 s(-1), K(i(inact)) = 1.52 +/- 0.15 microm), with a calculated partition ratio of 22. Inactivation of COX-1 was time- and concentration-dependent, it had an absolute requirement for a peroxide substrate, and it was accompanied by a concomitant oxidation of resveratrol. Resveratrol-inactivated COX-1 was devoid of both the cyclooxygenase and peroxidase activities, neither of which could be restored upon gel-filtration chromatography. Inactivation of COX-1 by [(3)H]resveratrol was not accompanied by stable covalent modification as evident by both SDS-PAGE and reverse phase-high performance liquid chromatography analysis. Structure activity relationships on methoxy-resveratrol analogs showed that the m-hydroquinone moiety was essential for irreversible inactivation of COX-1. We propose that resveratrol inactivates COX-1 by a "hit-and-run" mechanism, and offers a basis for the design of selective COX-1 inactivators that work through a mechanism-based event at the peroxidase active site.     

Prostaglandin E2 production and induction of prostaglandin endoperoxide synthase-2 is inhibited in a murine macrophage-like cell line,RAW 264.7, by Mallotus japonicus phloroglucinol derivatives

An aqueous acetone extract obtained from the pericarps of Mallotus japonicus (MJE) was observed to inhibit prostaglandin (PG) E₂ production in a lipopolysaccharide (LPS)-activated murine macrophage-like cell line, RAW 264.7. Six phloroglucinol derivatives isolated from MJE exhibited inhibitory activity against PGE₂ production. Among these phloroglucinol derivatives, isomallotochromanol showed the strongest inhibitory activity, with an IC₅₀ of 1.0 μM. MJE and its phloroglucinol derivatives did not effect the enzyme activity of either prostaglandin endoperoxide synthase (PGHS)-1 or PGHS-2. However, induction of PGHS-2 in LPS-activated macrophages was inhibited by MJE and its phloroglucinol derivatives, whereas the level of PGHS-1 protein was not affected. Moreover, RT-PCR analysis showed that MJE and its phloroglucinol derivatives significantly suppressed PGHS-2 mRNA expression. Therefore, the observed inhibition of PGHS-2 induction by MJE and its phloroglucinol derivatives was likely due to a suppression of PGHS-2 mRNA expression. These results suggest that MJE and its phloroglucinol derivatives have the pharmacological ability to suppress PGE₂ production by activated macrophages.     

Substitution of tyrosine for the proximal histidine ligand to the heme of prostaglandin endoperoxide synthase 2: implications for the mechanism of cyclooxygenase activation and catalysis

Prostaglandin H(2) synthesis by prostaglandin endoperoxide synthase (PGHS) requires the heme-dependent activation of the protein's cyclooxygenase activity. The PGHS heme participates in cyclooxygenase activation by accepting an electron from Tyr385 located in the cyclooxygenase active site. Two mechanisms have been proposed for the oxidation of Tyr385 by the heme iron: (1) ferric enzyme oxidizes a hydroperoxide activator and the incipient peroxyl radical oxidizes Tyr385, or (2) ferric enzyme reduces a hydroperoxide activator and the incipient ferryl-oxo heme oxidizes Tyr385. The participation of ferrous PGHS in cyclooxygenase activation was evaluated by determining the reduction potential of PGHS-2. Under all conditions tested, this potential (<-135 mV) was well below that required for reactions leading to cyclooxygenase activation. Substitution of the proximal heme ligand, His388, with tyrosine was used as a mechanistic probe of cyclooxygenase activation. His388Tyr PGHS-2, expressed in insect cells and purified to homogeneity, retained cyclooxygenase activity but its peroxidase activity was diminished more than 300-fold. Concordant with this poor peroxidase activity, an extensive lag in His388Tyr cyclooxygenase activity was observed. Addition of hydroperoxides resulted in a concentration-dependent decrease in lag time consistent with each peroxide's ability to act as a His388Tyr peroxidase substrate. However, hydroperoxide treatment had no effect on the maximal rate of arachidonate oxygenation. These data imply that the ferryl-oxo intermediates of peroxidase catalysis, but not the Fe(III)/Fe(II) couple of PGHS, are essential for cyclooxygenase activation. In addition, our findings are strongly supportive of a branched-chain mechanism of cyclooxygenase catalysis in which one activation event leads to many cyclooxygenase turnovers.     

Full-length and N-TIMP-3 display equal inhibitory activities toward TNF-alpha convertase

We previously reported that tumor necrosis factor-alpha converting enzyme (TACE) was specifically inhibited by TIMP-3 but not TIMP-1, -2, and -4. Further mutagenesis studies showed that the N-terminal domain of TIMP-3 (N-TIMP-3) retained full inhibitory activity towards TACE. Full-length TIMP-3 and N-TIMP-3 exhibited indistinguishable values for the association rate constant and inhibitory affinity constant for the active catalytic domain of TACE (k(on) approximately 10(5) M(-1) s(-1) and K(app)(i) approximately 0.20 nM). Moreover, their k(on) (approximately 10(4) M(-1) s(-1)) and K(app)(i) (approximately 1.0 nM) values with a longer form of TACE (which encompasses the complete ectodomain including disintegrin, EGF and Crambin-like domains) were also shown to be similar. Detailed kinetic analyses indicated that TIMP-3 associated more quickly and with tighter final binding with TACE devoid of these C-terminal domains. We conclude that, unlike the interaction between many MMPs and TIMPs, the C-terminal domains of TIMP-3 and TACE are not essential in the formation of a tight binary complex.     

Comparison of the peroxidase reaction kinetics of prostaglandin H synthase-1 and -2.

Prostaglandin H synthase isoforms 1 and 2 (PGHS-1 and -2) each have a peroxidase activity and also a cyclooxygenase activity that requires initiation by hydroperoxide. The hydroperoxide initiator requirement for PGHS-2 cyclooxygenase is about 10-fold lower than for PGHS-1 cyclooxygenase, and this difference may contribute to the distinct control of cellular prostanoid synthesis by the two isoforms. We compared the kinetics of the initial peroxidase steps in PGHS-1 and -2 to quantify mechanistic differences between the isoforms that might contribute to the difference in cyclooxygenase initiation efficiency. The kinetics of formation of Intermediate I (an Fe(IV) species with a porphyrin free radical) and Intermediate II (an Fe(IV) species with a tyrosyl free radical, thought to be the crucial oxidant in cyclooxygenase catalysis) were monitored at 4 degrees c by stopped flow spectrophotometry with several hydroperoxides as substrate. With 15-hydroperoxyeicosatetraenoic acid, the rate constant for Intermediate I formation (k1) was 2.3 x 10(7) M-1 s-1 for PGHS-1 and 2.5 x 10(7) M-1 s-1 for PGHS-2, indicating that the isoforms have similar initial reactivity with this lipid hydroperoxide. For PGHS-1, the rate of conversion of Intermediate I to Intermediate II (k2) became the limiting factor when the hydroperoxide level was increased, indicating a rate constant of 10(2)-10(3) s-1 for the generation of the active cyclooxygenase species. For PGHS-2, however, the transition between Intermediates I and II was not rate-limiting even at the highest hydroperoxide concentrations tested, indicating that the k2 value for PGHS-2 was much greater than that for PGHS-1. Computer modelling predicted that faster formation of the active cyclooxygenase species (Intermediate II) or increased stability of the active species increases the resistance of the cyclooxygenase to inhibition by the intracellular hydroperoxide scavenger, glutathione peroxidase. Kinetic differences between the PGHS isoforms in forming or stabilizing the active cyclooxygenase species can thus contribute to the difference in the regulation of their cellular activities.