Functional investigations of thromboxane synthase (CYP5A1) in lipid bilayers of nanodiscs.

CYP5A1 is a membrane-associated cytochrome P450 that metabolizes the cyclooxygenase product prostaglandin (PGH2 ) into thromboxane A2 (TXA2 ), a potent inducer of vasoconstriction and platelet aggregation. Although CYP5A1 is an ER-bound protein, the role of membranes in modulating the thermodynamics and kinetics of substrate binding to this protein has not been elucidated. In this work, we incorporated thromboxane synthase into lipid bilayers of nanodiscs for functional studies. We measured the redox potential of CYP5A1 in nanodiscs and showed that the redox potential is within a similar range of other drug-metabolizing P450 enzymes in membranes. Further, we showed that binding of substrate to CYP5A1 can induce conformational changes in the protein that block small-molecule ligand egress by measuring the kinetics of cyanide binding to CYP5A1 as a function of substrate concentration. Notably, we observed that sensitivity to cyanide binding was different for two substrate analogues, U44069 and U46619, thus indicating that they bind differently to the active site of CYP5A1. We also characterized the effects of the different lipids on CYP5A1 catalytic activity by using nanodiscs to create unary, binary, and ternary lipid systems. CYP5A1 activity increased dramatically in the presence of charged lipids POPS and POPE, as compared to the unary POPC system. These results suggest the importance of lipid composition on modulating the activity of CYP5A1 to increase thromboxane formation.

Characterization of the responses of equine digital veins and arteries to calcitonin gene-related peptide.

OBJECTIVE: To compare responses of equine digital arteries (EDAs) and veins (EDVs) to human-αcalcitonin gene-related peptide (hαCGRP), evaluate effect of the endothelium, and characterize receptors and sources of endogenous CGRP. SAMPLE: Palmar digital vessels (5 to 9/experiment) from healthy adult horses killed at an abattoir. PROCEDURES: Vessel rings were mounted under tension in organ baths containing Krebs-Henseleit solution at 30 °C, with relaxation responses examined in vessels preconstricted with a thromboxane-mimetic (3 × 10(-8)M). Responses of endothelium-intact (+e) and -denuded (-e) EDAs and EDVs to hαCGRP C10(-10) to 3 × 10(-7)M) were compared. Following incubation with an hαCGRP receptor antagonist (hαCGRP(8-37); 1 µM), responses of EDA(-e) and EDV(-e) to hαCGRP (10(-7)M) were obtained. Responses of endothelium-intact and -denuded arteries and veins to hαCGRP (3 × 10(-7)M) or capsaicin (10(-5)M) were evaluated as well as responses of endothelium-intact and -denuded EDA and EDV to hαCGRP (10(-10) to 10(-6)M) after incubation with endothelin-1 (ET-1; 10(-12)M). RESULTS: hαCGRP resulted in nonendothelium, concentration-dependent relaxation in EDAs and EDVs, with greater responses in EDAs. Treatment with hαCGRP(8-37) had minimal effect on responses to hαCGRP in either vessel type. Capsaicin induced relaxation in both vessel types. There were no differences between responses to hαCGRP for vessels pretreated with ET-1 or vehicle. CONCLUSIONS AND CLINICAL RELEVANCE: Both hαCGRP and capsaicin induced digital vasodilation unaffected by a functional endothelium. This suggested that endogenous CGRP likely emanates from sensory-motor nerves and may contribute to digital vasodilation.

Arachidonic acid epoxygenase and 12(S)-lipoxygenase: evidence of their concerted involvement in ductus arteriosus constriction to oxygen.

Oxygen promotes closure of the ductus arteriosus at birth. We have previously presented a scheme for oxygen action with a cytochrome P450 (CYP450) hemoprotein and endothelin-1 (ET-1) being, respectively, sensor and effector, and a hypothetical monooxygenase product serving as a coupling link. We have also found in the vessel arachidonic acid (AA) 12(S)-lipoxygenase (12-lipoxygenase) undergoing upregulation at birth. Here, we examined the feasibility of a sensor-to-effector messenger originating from AA monooxygenase and 12-lipoxygenase pathways. The epoxygenase inhibitor, N-methylsulfonyl-6-(2-)hexanamide, suppressed the tonic contraction of ductus to oxygen. A similar effect was obtained with 12-lipoxygenase inhibitors baicalein and PD 146176. By contrast, none of the inhibitors modified the endothelin-1 contraction. Furthermore, an AA ω-hydroxylation product, 20-hydroxyeicosatetraenoic acid (20-HETE), reportedly responsible for oxygen contraction in the systemic microvasculature, had no such effect on the ductus. We conclude that AA epoxygenase and 12-lipoxygenase jointly produce a hitherto uncharacterized compound acting as oxygen messenger in the ductus.

Different behavior of artemisinin and tetraoxane in the oxidative degradation of phospholipid.

The reaction of trioxane and tetraoxane endoperoxides with unsaturated phospholipid 1 in the presence of Fe(II) was investigated in the absence of oxygen by means of tandem ESI-MS analysis. The spectral analyses for the reaction mixtures showed that artemisinin 2 with a trioxane structure gave no peak except that for the remaining intact phospholipid 1 (m/z 758.9), indicating that there was no structural change to 1. On other hand, the reaction mixture of 1 with tetraoxanes 3 and 4 afforded a number of new peaks (m/z 620-850) that were presumably assigned to oxidative degradation products originating from phospholipid 1. Since this reaction was completely inhibited by the addition of a phenolic antioxidant, the process was considered to involve some free radical species. The newly discovered marked differences in reactivity between the trioxane and the tetraoxanes possibly reflects their different anti-malarial mechanisms, and this reactivity may contribute to the classification of a number of anti-malarial endoperoxides whose mode of action is based on phospholipid oxidation.

Endothelin, PAF and thromboxane A2 in allergic pulmonary hyperreactivity in mice.

The role of endothelin, PAF and thromboxane A2 in airway hyperreactivity (AHR) to carbachol induced by ovalbumin sensitization and challenge in Balb/c mice was investigated. Ovalbumin sensitization and challenge induced significant AHR to carbachol in actively sensitized and challenged mice. Treatment of these mice with the PAF antagonist CV-3988 (10 microg kg(-1), i.v.) completely abolished OVA-induced AHR to carbachol. Treatment of sensitized mice with the TxA2 antagonist L-654,664 (1 mg kg(-1), i.v.) partially blocked the induction of AHR in OVA-challenged mice. The intranasal administration of 50 pmol of the ET(A) receptor antagonist BQ-123 had no effect on the PIP but produced a significant reduction at the dose of 100 pmol. The intravenous administration of BQ-123 (100 pmol) reduced the PIP only at the highest doses of carbachol. The ET(B) receptor antagonist BQ-788 administered either via the intranasal or intravenous route had no effect on the PIP at the dose of 100 pmol. Naïve mice treated with either U-44069 (25 or 100 microg kg(-1), i.v.), endothelin-1 (100 pmol, intranasally) or the ET(B) receptor agonist IRL-1620 (100 pmol, intranasally) showed a marked increase in airway reactivity to carbachol. These results suggest an important role for endothelin, PAF and thromboxane A2 in AHR in mice actively sensitized and challenged with ovalbumin.

Carbon monoxide released by CORM-3 inhibits human platelets by a mechanism independent of soluble guanylate cyclase.

OBJECTIVE: Carbon monoxide (CO) modulates several physiological functions through activation of a cGMP-dependent pathway similar to that of nitric oxide (NO). Here we investigated the possible involvement of soluble guanylate cyclase in the anti-aggregatory effect of micromolar concentrations of CO released by a novel, water-soluble, CO releasing molecule (CORM) in human platelets. METHODS: Human platelet aggregation was induced by collagen or thrombin, and the effects of CO releasing molecule (CORM-3) and an NO donor on platelet aggregation were compared. RESULTS: CORM-3 liberated CO in a time- and concentration-dependent manner as evidenced by the formation of carbon monoxy myoglobin (MbCO) using a spectrophotometric assay. When added to washed platelets, CORM-3 (10-300 microM) inhibited collagen- and thrombin-induced aggregation in a concentration-dependent manner. The anti-aggregatory effect of CORM-3 was reversed by deoxy-Mb (50 microM). Interestingly, in the presence of an inhibitor of guanylate cyclase (ODQ, 5 microM), inhibition of collagen-induced aggregation by CORM-3 was not blocked but potentiated. Under the same experimental conditions, inhibition of platelet aggregation by an NO donor (SNAP, 1 microM) was prevented by ODQ. In collagen-induced or thrombin-induced platelet aggregation, a stimulator of guanylate cyclase (YC-1, 0.3 microM) did not alter the effect of CORM-3, whereas it markedly potentiated the inhibition of platelet aggregation mediated by SNAP. Notably, CORM-3-induced inhibition of platelet aggregation was of similar degree when platelets were activated by a low (20 mU/ml) or by high concentration of thrombin (100-200 mU/ml), whereas NO donors (SNP and SNAP)- or carbaprostacylin (cPGI(2))-induced effects were considerably attenuated when platelets were activated by high concentrations of thrombin. CONCLUSIONS: Inhibition of platelet aggregation by CO released by a novel, water-soluble CORM is not mediated by activation of soluble guanylate cyclase. In contrast to NO and PGI(2), CO effectively inhibits platelets even when cells are activated excessively. We suggest that despite the fact that CO is not a potent inhibitor of platelet activation, it may gain importance when NO and PGI(2) alone are insufficient to overcome excessive platelet activation.

Evaluation of the serotonin receptor blockers ketanserin and methiothepin on the pulmonary hypertensive responses of broilers to intravenously infused serotonin.

The pathogenesis of pulmonary hypertension remains incompletely understood. Many factors have been implicated; however, there has been great interest in the potent pulmonary vasoconstrictor serotonin (5-HT) due to episodes of primary pulmonary hypertension in humans triggered by serotoninergic appetite-suppressant drugs. Pulmonary hypertensive patients have elevated blood 5-HT levels and pulmonary vasoconstriction induced by 5-HT is believed to be mediated through 5-HT1B/1D and 5-HT2A receptors that are expressed by pulmonary smooth muscle cells. The vascular remodeling associated with pulmonary hypertension also appears to require the serotonin transporter. We investigated the roles of 5-HT receptor blockers on the development of pulmonary hypertension induced by infusing 5-HT i.v. in broilers. For this purpose, we treated broilers with the selective 5-HT2A receptor antagonist ketanserin (5 mg/ kg of BW) or with the nonselective 5-HT1/2 receptor antagonist methiothepin (3 mg/kg of BW). Receptor blockade was followed by infusion of 5-HT while recording pulmonary arterial pressure and pulmonary arterial blood flow. The results demonstrate that methiothepin, but not ketanserin, eliminated the 5-HT-induced pulmonary hypertensive responses in broilers. The 5-HT2A receptor does not, therefore, appear to play a role in the 5-HT-induced pulmonary hypertensive responses in broilers. Methiothepin did not inhibit pulmonary vascular contractility per se, because the pulmonary hypertensive response to the thromboxane A2 mimetic U44069 remained intact in methiothepin-treated broilers. Methiothepin will be a useful tool for evaluating the role of 5-HT in the pathogenesis of pulmonary hypertension syndrome (ascites) as well as the onset of pulmonary hypertension triggered by inflammatory stimuli such as bacterial lipolysaccharide.

Glibenclamide inhibits agonist-induced vasoconstriction of placental chorionic plate arteries.

BACKGROUND: Preliminary data suggest that K(ATP) channels may be expressed in placental arteries and veins [Wareing M, Turner C, Greenwood SL, Baker PN, Fyfe GK. Expression of mRNA encoding K+ channels in chorionic plate arteries and veins. J Soc Gynecol Investig 2004;11:353A]. However, no data exist on glibenclamide's effects in placental chorionic plate arteries. AIM: To assess the effect of glibenclamide on placental chorionic plate arterial vasoconstriction. METHODS: Arteries were dissected from placental chorionic plate biopsies obtained at term from uncomplicated pregnancies (N=63). Arteries were mounted onto a wire myograph in HCO3- -buffered physiological salt solution (PSS) at 37 degrees C (5% O2/5% CO2 bubbling) and normalised at 0.9 of L5.1 kPa. Constriction viability was assessed with 120 mmol l(-1) potassium solution (KPSS). Dose-response curves were produced with the thromboxane-mimetics U46619 and U44069 (10(-10)-2 x 10(-6)M), arginine vasopressin (10(-10)-5 x 10(-8)M) and endothelin-1 (10(-11)-3 x 10(-7)M) in the presence or absence of 50 micromol l(-1) glibenclamide. The effect of glibenclamide on arginine vasopressin- and U46619-induced constriction was also assessed in the presence of the cyclo-oxygenase inhibitor indomethacin (10 micromol l(-1)). RESULTS: Pre-incubation with 50 micromol l(-1) glibenclamide significantly right-shifted dose-response curves to all vasoconstrictive agonists tested (repeated measures ANOVA). Indomethacin did not modify the inhibitory effect of glibenclamide. CONCLUSION: Glibenclamide's effects on agonist-induced constrictions are unlikely to be via an inhibition of ATP-sensitive K+ channels, and with U46619- and U44069-induced constrictions, glibenclamide may be acting as a competitive antagonist of thromboxane receptors.

Solution structure of a common substrate mimetic of cyclooxygenase-downstream synthases bound to an engineered thromboxane A2 synthase using a high-resolution NMR technique.

Understanding the docking mechanism of the common substrate, prostaglandin H(2) (PGH(2)), into the active sites of different cyclooxygenase(COX)-downstream synthases is a key step toward uncovering the molecular basis of the isomerization of PGH(2) to different prostanoids. A high-resolution NMR spectroscopy was used to determine the conformational changes and solution 3D structure of U44069, a PGH(2) analogue, bound to one of the COX-downstream synthases-an engineered thromboxane A(2) synthase (TXAS). The dynamic binding was clearly observed by (1)D NMR titration. The detailed conformational change and 3D structure of U44069 bound to the TXAS were demonstrated by 2D (1)H NMR experiments using transferred NOEs. Through the assignments for the 2D (1)H NMR spectra, TOCSY, DQF-COSY, NOESY, and the structural calculations based on the NOE constraints, they demonstrated that the widely open conformation with a triangle shape of the free U44069 changed to a compact structure with an oval shape when bound to the TXAS. The putative substrate-binding pocket of the TXAS model fits the conformation of the TXAS-bound U44069 appropriately, but could not fit the free form of U44069. It was the first to provide structural information for the dynamic docking of the PGH(2) mimic of the TXAS in solution, and to imply that PGH(2) undergoes conformational changes when bound to different COX-downstream synthases, which may play important roles in the isomerization of PGH(2) to different prostanoids. The NMR technique can be used as a powerful tool to determine the conformations of PGH(2) bound to other COX-downstream synthases.

In-vitro contraction of the equine aortic valve.

BACKGROUND AND AIM OF THE STUDY: The equine aortic valve is subject to non-inflammatory degenerative changes, associated with aortic valvular regurgitation (AR). This disease shares pathological and epidemiological features with AR in humans, and may serve as a useful model to study in-vitro functional responses associated with aging and disease. The study aim was to determine the contractile properties of the normal equine aortic valve. METHODS: The contractile responses of equine aortic valves to angiotensin II, the thromboxane-mimetic U44069, endothelin-1, 5-hydroxytryptamine and the alpha-adrenoceptor agonists medetomidine, norepinephrine and phenylephrine were studied in vitro in organ baths. Selective antagonists were used to confirm the receptors involved. RESULTS: The order of potency of the agents causing contraction of equine aortic valve segments was angiotensin II > endothelin-1 > U44069 > medetomidine norepinephrine phenylephrine. 5-Hydroxytryptamine did not cause contraction of the equine aortic valve. The contractile response to angiotensin II was abolished by the AT1 receptor antagonist Sar1-Ile8-Angiotensin II, and that of U44069 by the thromboxane TXA2 receptor (TP) antagonist SQ29548. The contractile effects of endothelin-1 were blocked by the ET(A) receptor antagonist BQ123, but not by the ET(B) receptor antagonist BQ788. Yohimbine inhibited the contractile effects of phenylephrine, suggesting an alpha-2 adrenoceptor-mediated response. CONCLUSION: Equine aortic valves contract in response to a number of physiologically important endocrine, paracrine and neuronal mediators. Regulation of valvular tone could therefore be important in the normal functioning of the valve, and further understanding of these mechanisms may lead to insights into the pathophysiology of naturally occurring equine aortic insufficiency. In this respect, the horse should be considered as a model of the human condition.

Purification and characterization of recombinant human prostacyclin synthase.

Prostacyclin synthase (PGIS), which catalyzes the conversion of prostaglandin (PG) H(2) to prostacyclin (PGI(2)), is a member of the cytochrome P-450 (P450) superfamily, CYP8A1. To study the enzymatic and protein characteristics of human PGIS, the enzyme was overexpressed in Spodoptera frugiperda 21 (Sf21) cells using the baculovirus expression system. PGIS was expressed in the microsomes of the infected Sf21 cells after culture in 5 microg/ml hematin-supplemented medium for 72 h. The holoenzyme was isolated from the solubilized microsomal fraction by calcium phosphate gel absorption and purified to homogeneity by DEAE-Sepharose and hydroxyapatite column chromatography. The K(m) and V(max) values of the purified human PGIS for PGH(2) were 30 microM and 15 micromol/min/mg of protein at 24 degrees C, respectively. The optical absorption and EPR spectra of the enzyme revealed the characteristics of a low-spin form of P450 in the oxidized state. The carbon monoxide-reduced difference spectrum, however, exhibited a peak at 418 nm rather than 450 nm. The addition of a PGH(2) analogue, U46619, to the enzyme produced an oxygen-ligand type of the difference spectrum with maximum absorption at 407 nm and minimum absorption at 430 nm. Treatment with another PGH(2) analogue, U44069, produced a peak at 387 nm and a trough at 432 nm in the spectrum (Type I), while treatment with tranylcypromine, a PGIS inhibitor, produced a peak at 434 nm and a trough at 412 nm (Type II). A Cys441His mutant of the enzyme possessed no heme-binding ability or enzyme activity. Thus, we succeeded in obtaining a sufficient amount of the purified recombinant human PGIS from infected insect cells for spectral analyses that has high specific activity and the characteristics of a P450, indicating substrate specificity.

Glibenclamide inhibits thromboxane-mediated vasoconstriction by thromboxane receptor blockade.

Because sulfonylureas, such as glibenclamide, are used to treat Type 2 diabetes and because this disease is associated with various cardiovascular complications that may be mediated by thromboxane (TX), this study was designed to characterize the role of glibenclamide on TX-mediated contractions in isolated ring segments of bovine coronary arteries and rabbit aortas. A series of TXA(2) analogs [9,11 Dideoxy-9alpha, 11alpha-methanoepoxy prostaglandin F(2alpha) (U46619), [1S-(1alpha, 2beta(5Z),3alpha(1E, 3R*),4alpha)]-7-[3-(3-hydroxy-4-(4'-iodophenoxy)-1-butenyl)-7-oxabicyclo [2.2.1]heptan-2-yl]-5-heptenoic acid (I-BOP), carbocyclic TXA(2) (CTA(2)) and 9,11-dideoxy-9alpha,11alpha-epoxymethano prostaglandin F(2alpha) (U44069)], endothelin and phenylephrine contracted both types of blood vessels. Glibenclamide (10 microM) inhibited the contraction to each of the TX agonists but had no effect on endothelin- or phenylephrine-induced contractions. We hypothesized that this effect was due to a direct effect to block the vascular smooth muscle cell TX receptor. Receptor binding studies were performed in rabbit vascular smooth muscle cells and indicated that glibenclamide (10 microM) inhibited (125)I-BOP binding by more than 80%. The inhibition constants or K(i) for glibenclamide was 0.53 microM. These studies provide the first evidence that the ability of glibenclamide to inhibit TX-mediated contractions occurs independent of the vascular K(ATP) channel and is, instead, mediated by the blockade of the vascular TX receptor.

Crucial role of the peroxyketal function for antimalarial activity in the G-factor series.

New endoperoxides, related to the natural phytohormones known as G factors (G1, G2, G3), were modified on the side chain and the ketalic position. An unexpected rearrangement, specific to one diastereoisomer was observed in the deprotection step of O-silylated compounds and attributed to a hexacoordinated fluorosilicon intermediate. The reduction potential of these new peroxides was determined. They exhibited good to moderate antimalarial activity, greatly related to the presence of peroxyketal function.

Protein engineering of thromboxane synthase: conversion of membrane-bound to soluble form.

Thromboxane A2 synthase (TXAS) binds to the endoplasmic reticulum membrane and catalyzes both an isomerization of prostaglandin H2 (PGH2) to form thromboxane A2 (TXA2) and a fragmentation of PGH2 to form 12-hydroxy-5,8,10-heptadecatrienoic acid (HHT) and malondialdehyde (MDA). TXAS is a non-classic cytochrome P450 in that it does not require molecular oxygen or an external electron donor for catalysis. Difficulty in obtaining crystals from the membrane-bound TXAS prompted us to modify the protein to a soluble form. Results from site-directed mutagenesis, hydropathy analysis, and homology modeling led us to identify a putative membrane association segment near the end of helix F in TXAS. We report here the generation of a soluble form of TXAS by deletion of the amino-terminal membrane-anchoring domain and replacement of the helix F and F-G loop region with the corresponding region of the structurally characterized microsomal P450 2C5. The resultant TXAS/2C5 chimera is expressed in bacteria as a cytosolic and monomeric protein. Addition of an amino-terminal leader sequence to enhance expression and a tetra-histidine segment at the carboxyl-terminus to facilitate purification yielded approximately 4 mg of nearly homogeneous TXAS/2C5 per liter of bacterial culture. The TXAS/2C5 chimera contains heme at nearly a 1:1 molar ratio and catalyzes the formation of TXA2, MDA, and HHT at a 1:1:1 ratio, although with a reduced catalytic activity compared to wild type TXAS. TXAS/2C5 exhibits electronic absorption spectra similar to wild type TXAS and has similar affinities toward distal heme ligands such as imidazole and U44069. The chimera was mono-dispersive and thus is promising for crystallization trials.

Resonance Raman investigation of the interaction of thromboxane synthase with substrate analogues.

Thromboxane synthase is a hemethiolate enzyme that catalyzes the isomerization of prostaglandin H2 to thromboxane A2. We report the first resonance Raman (RR) spectra of recombinant human thromboxane synthase (TXAS) in both the presence and the absence of substrate analogues U44069 and U46619. The resting enzyme and its U44069 complex are found to have a 6-coordinate, low spin (6c/ls) heme, in agreement with earlier experiments. The U46619-bound enzyme is detected as a 6c/ls heme too, which is in contradiction with a previous conclusion based on absorption difference spectroscopy. Two new vibrations at 368 and 424 cm(-1) are observed upon binding of the substrate analogues in the heme pocket and are assigned to the second propionate and vinyl bending modes, respectively. We interpret the changes in these vibrational modes as the disruption of the protein environment and the hydrogen-bonding network of one of the propionate groups when the substrate analogues enter the heme pocket. We use carbocyclic thromboxane A2 (CTA2) to convert the TXAS heme cofactor to its 5-coordinate, high spin (5c/hs) form, as is confirmed by optical and RR spectroscopy. In this 5c/hs state of the enzyme, the Fe-S stretching frequency is determined at 350 cm(-1) with excitation at 356.4 nm. This assignment is supported by comparison to the spectrum of resting enzyme excited at 356.4 nm and by exciting at different wavelengths. Implications of our findings for substrate binding and the catalytic mechanism of TXAS will be discussed.

Intravenous endotoxin triggers pulmonary vasoconstriction and pulmonary hypertension in broiler chickens.

Bacterial endotoxins stimulate endothelin-mediated, thromboxane-dependent increases in pulmonary vascular resistance in mammals, and thromboxane has been shown to cause an immediate but transient pulmonary vasoconstriction in broiler chickens. In the present study, i.v. injections of 1 mg endotoxin into anesthetized male broilers caused a pulmonary vasoconstrictive response that was delayed in onset by 15 min and that elevated the pulmonary arterial pressure by 10 mm Hg within 25 min postinjection. Thereafter, pulmonary hemodynamic variables gradually (> or = 15 min) returned toward pre-injection levels, and supplemental injections of 4 mg endotoxin during this recovery period failed to reinitiate pulmonary hypertension. In contrast, injecting the thromboxane A2 mimetic U44069 during the endotoxin recovery period triggered pulmonary vasoconstriction and pulmonary hypertension similar in magnitude to the responses triggered by U44069 before endotoxin had been administered. The time course and magnitude of the pulmonary hemodynamic responses to endotoxin were highly variable among individual broilers, whereas the individual responses to U44069 were more consistent. Unanesthetized broilers resembled anesthetized broilers in the time course, magnitude, and variability of their pulmonary hemodynamic responses to endotoxin. Overall, these observations are consistent with the hypothesis that endotoxin initiates a biochemical cascade, culminating in the delayed onset of pulmonary vasoconstriction and pulmonary hypertension within 20 min postinjection. Subsequently, the pulmonary vasculature remains responsive to large bolus injections of exogenous thromboxane mimetic; however depletion of endogenous vasoconstrictive components of the endotoxin-mediated cascade, a compensatory increase in endogenous vasodilators, or the induction of a transient cellular tolerance to endotoxin prevented fourfold higher doses of endotoxin from reversing the return toward a normal pulmonary vascular tone. Individual differences among broilers in their susceptibility to pulmonary hypertension syndrome (ascites) may be related to innate or acquired variability in their pulmonary vascular responsiveness to vasoactive mediators.

Substrate binding is the rate-limiting step in thromboxane synthase catalysis.

Thromboxane synthase (TXAS) is a "non-classical" cytochrome P450. Without any need for an external electron donor, or for a reductase or molecular oxygen, it uses prostaglandin H2 (PGH2) to catalyze either an isomerization reaction to form thromboxane A2 (TXA2) or a fragmentation reaction to form 12-l-hydroxy-5,8,10-heptadecatrienoic acid and malondialdehyde (MDA) at a ratio of 1:1:1 (TXA2:heptadecatrienoic acid:MDA). We report here kinetics of TXAS with heme ligands in binding study and with PGH2 in enzymatic study. We determined that 1) binding of U44069, an oxygen-based ligand, is a two-step process; U44069 first binds TXAS, then ligates the heme-iron with a maximal rate constant of 105-130 s(-1); 2) binding of cyanide, a carbon-based ligand, is a one-step process with k(on) of 2.4 M(-1) s(-1) and k(off) of 0.112 s(-1); and 3) both imidazole and clotrimazole (nitrogen-based ligands) bind TXAS in a two-step process; an initial binding to the heme-iron with on-rate constants of 8.4 x 10(4) M(-1) s(-1) and 1.5 x 10(5) M(-1) s(-1) for imidazole and clotrimazole, respectively, followed by a slow conformational change with off-rate constants of 8.8 s(-1) and 0.53 s(-1), respectively. The results of our binding study indicate that the TXAS active site is hydrophobic and spacious. In addition, steady-state kinetic study revealed that TXAS consumed PGH2 at a rate of 3,800 min(-1) and that the k(cat)/K(m) for PGH2 consumption was 3 x 10(6) M(-1) s(-1). Based on these data, TXAS appears to be a very efficient catalyst. Surprisingly, rapid-scan stopped-flow experiments revealed marginal absorbance changes upon mixing TXAS with PGH2, indicating minimal accumulation of any heme-derived intermediates. Freeze-quench EPR measurements for the same reaction showed minimal change of heme redox state. Further kinetic analysis using a combination of rapid-mixing chemical quench and computer simulation showed that the kinetic parameters of TXAS-catalyzed reaction are: PGH2 bound TXAS at a rate of 1.2-2.0 x 10(7) M(-1) s(-1); the rate of catalytic conversion of PGH2 to TXA2 or MDA was at least 15,000 s(-1) and the lower limit of the rates for products release was 4,000-6,000 s(-1). Given that the cellular PGH2 concentration is quite low, we concluded that under physiological conditions, the substrate-binding step is the rate-limiting step of the TXAS-catalyzed reaction, in sharp contrast with "classical" P450 enzymes.

Identification of the substrate interaction site in the N-terminal membrane anchor segment of thromboxane A2 synthase by determination of its substrate analog conformational changes using high resolution NMR technique.

The present studies describe an investigation for the interaction of N-terminal membrane anchor domain of thromboxane A(2) synthase (TXAS) with its substrate analog in a membrane-bound environment using the two-dimensional NMR technique. TXAS and prostaglandin I(2) synthase (PGIS), respectively, convert the same substrate, prostaglandin H(2) (PGH(2)), to thromboxane A(2) and prostaglandin I(2), which have opposite biological functions. Our topology studies have indicated that the N-terminal region of TXAS has a longer N-terminal endoplasmic reticulum (ER) membrane anchor region compared with the same segment proposed for PGIS. The differences in their interaction with the ER membrane may have an important impact to facilitate their common substrate, PGH(2), across the membrane into their active sites from the luminal to the cytoplasmic side of the ER. To test this hypothesis, we first investigated the interaction of the TXAS N-terminal membrane anchor domain with its substrate analog. A synthetic peptide corresponding to the N-terminal membrane anchor domain (residues 1-35) of TXAS, which adopted a stable helical structure and exhibited a membrane anchor function in the membrane-bound environment, was used to interact with a stable PGH(2) analog,. High resolution two-dimensional NMR experiments, NOESY and TOCSY, were performed to solve the solution structures of in a membrane-mimicking environment using dodecylphosphocholine micelles. Different conformations were clearly observed in the presence and absence of the TXAS N-terminal membrane anchor domain. Through combination of the two-dimensional NMR experiments, completed (1)H NMR assignments of were obtained, and the data were used to construct three-dimensional structures of in H(2)O and dodecylphosphocholine micelles, showing the detailed conformation change upon the interaction with the membrane anchor domain. The observation supported the presence of a substrate interaction site in the N-terminal region. The combination of the structural information of and was able to simulate a solution structure of the unstable TXAS and PGIS substrate, PGH(2).

Spontaneous contractions in elasmobranch vessels in vitro.

Isolated vessels from four elasmobranchs, yellow stingray (Urolophus jamaicensis), clearnose skate (Raja eglanteria), ghost shark (Hydrolagus novaezelandiae), and spiny dogfish (Squalus acanthias), were examined for the presence of spontaneous contractions (SC). SC were observed in otherwise unstimulated dorsal aortas (DA) from stingray and ghost shark, but not in skate DA. Unstimulated ventral aortas (VA) did not exhibit SC. After treatment of VA with a contractile agonist, SC appeared in stingray and skate but not ghost shark or dogfish. SC in stingray VA were subsequently inhibited by either epinephrine (10(-5) M) or indomethacin (10(-4) M). Agonist contraction also elicited strong SC in ductus Cuvier from stingray, but not from ghost shark or dogfish. SC in dogfish hepatic portal veins (HPV) produced a rhythmical oscillation in tension. The frequency of HPV SC was highest (approximately 1 min(-1)) in intact veins and lower (approximately 3 min(-1)) in vein segments, indicative of a dominant pacemaker in the intact vessel. SC in HPV were depressed during the first 30 min of hypoxia, but there was substantial recovery over an additional 30 min of hypoxia and complete recovery upon return to normoxia. Addition of 80 mM KCl completely inhibited HPV SC and lowered resting tone. These results show that SC are a common feature of elasmobranch vessels and there appears to be a correlation between swimming behavior and the propensity for SC. KCl inhibition of SC and tonus in HPV is highly unusual for vascular smooth muscle.