Thromboxane A2 induces itch-associated responses through TP receptors in the skin in mice

Thromboxane A2 (TXA2), a metabolite of arachidonic acid produced by cyclooxygenase and thromboxane synthase, is thought to participate in chronic dermatitis. This study investigated the involvement of TXA2 in cutaneous itch. An intradermal injection of U-46619, a stable analogue of TXA2, elicited scratching, an itch-associated response, in mice. Dose-response curve was bell shaped with a maximum effect at 10 nmol per site. The action of U-46619 was inhibited by a coinjection of the TP antagonist ONO-3708 and was abolished by TP receptor deficiency. TP receptor was mainly expressed in nerve fiber in the skin and keratinocytes. Thromboxane synthase was also expressed in keratinocytes. U-46619 increased intracellular Ca2+ ion concentration in primary cultures of dorsal root ganglion neurons and keratinocytes. The results suggest that TXA2 synthesized by keratinocytes acts as an itch mediator. It may elicit itch through the activation of TP receptors on primary afferents and keratinocytes; keratinocytes may produce itch mediators including TXA2. Thus, thromboxane synthase inhibitor and TP receptor antagonists will be candidates for antipruritic medicines.

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.

Advance in understanding the biosynthesis of prostacyclin and thromboxane A2 in the endoplasmic reticulum membrane via the cyclooxygenase pathway

Recent advances in topological and structural characterization of the prostacyclin (PGI(2)) and thromboxane A(2) (TXA(2)) synthases have led to the understanding of the biosynthesis of PGI(2) and TXA(2) at a structural level. This mini-review focuses on the molecular mechanism of the isomerization of the prostaglandin H(2) to PGI(2)and TXA(2) by their synthases in the endoplasmic reticulum (ER) membrane coordinated with cyclooxygenase-1 or -2. This review summarizes the evidences in which the biosynthesis of PGI(2)and TXA(2) are influenced/modulated by the membrane anchor residues of the synthases and the ER membrane itself, and provides the structural basis for engineering the synthases for the next generation of gene therapy and drug designs targeting the specific synthases.

Modulation of eicosanoid metabolism in endothelial cells in a xenograft model. Role of cyclooxygenase-2

Lipid inflammatory mediators are thought to play a critical role in the pathogenesis of vascular injury. Among the events which might cause the synthesis of eicosanoids in blood vessels is activation of the complement. To evaluate how complement might influence eicosanoid metabolism, we investigated endothelial cells exposed to xenoreactive antibodies and complement, as might occur in rejecting xenografts where severe vascular injury is a typical feature. While resting porcine aortic endothelial cells released only prostaglandin (PG) I2, endothelial cells stimulated with xenoreactive antibodies and complement released PGE2 and thromboxane A2 (TXA2), in addition to increased amounts of PGI2. This alteration in eicosanoid metabolism was associated with induction of cyclooxygenase (Cox)-2 and thromboxane synthase, but not Cox-1. Unlike results seen in other systems, the upregulation of Cox-2 and the subsequent release of eicosanoids by endothelial cells was not directly induced by complement but rather required production of IL-1alpha, which acted on endothelial cells as an autocrine factor. Since eicosanoids have a potent effect on inflammation, vascular tone and platelet aggregation, we postulated that the abnormalities in eicosanoid release induced by xenoreactive antibodies and complement might provide one explanation for the vascular injury, focal ischemia, and thrombosis observed in acute vascular rejection and other vasculitides mediated by complement.

Immunoreactive thromboxane synthase is measurable in ovine fetal hypothalamus as early as 86 days' gestation

Thromboxane A2 (TxA2) augments hypothalamus-pituitary-adrenal axis activity in both fetal and adult animals. We have proposed that TxA2 acts as a neuromodulator within the brain to stimulate the release of corticotropin releasing hormone (CRH) or arginine vasopressin (AVP) into the hypophyseal-portal blood. We performed the present experiments to identify immunoreactive thromboxane synthase (TxS) within fetal brain regions and to quantify developmental changes in the TxS immunoreactivity measurable within those regions. We found that immunoreactive TxS was present in fetal hypothalamus, pituitary, brainstem, and lung. In fetal hypothalamus, we found immunoreactive TxS in three identifiable molecular weights, approximately 65, 42, and 35 kD. In fetal pituitary and lung, we found the 65 and 35 kD forms, and in the brainstem we found only the 35 kD form. In fetal pituitary, there was a clear ontogenetic change in TxS immunoreactivity. The 42 kD TxS immunoreactivity was not present in the youngest fetal sheep studied (86-90 days' gestation), but was expressed in the other age groups (125-128, 135-139, 141-term, and postnatal ages). The other molecular weight forms appeared to increase in the older fetuses, but the changes were not significant. In the hypothalamus, all three forms of TxS were measurable at all ages, and there was no significant change in relative abundance. We conclude that immunoreactive TxS is present in the fetal brain throughout the last half of fetal gestation, but that the significance of multiple molecular weight forms is not clear.

FMLP actions and its binding sites in isolated human coronary arteries

The chemoattractant f-Met-Leu-Phe (FMLP) can modulate human coronary arterial tone without the involvement of peripheral leukocytes. We investigated the actions of FMLP and its cellular mechanism in human coronary arteries isolated 2-3 h after death. A single dose of FMLP (0.01-10 microM) produced transient contraction (or, followed by relaxation) responses in most human coronary rings examined. These responses to FMLP were in large part mediated by the generation of cyclooxygenase products, mainly thromboxane A2 (TXA2) and prostaglandin I2 (PGI2). Radiolabeled N-formyl hexapeptide. 125I-f-Nle-Leu-Phe-Nle-Tyr-Lys bound densely to intimal and adventitial sites that accumulated macrophages (CD68-positive) with a Kd of 14-29 nM and, further, weakly to the media with a Kd of 2.4-3.6 microM. Several cell types including macrophages, endothelial cells and smooth muscle cells were positively immunostained for both TXA2 synthase and PGI2 synthase. However, there was no significant relation between the magnitude of the responses to FMLP and dense macrophage accumulation in the intimal plaques or the adventitia. A reverse transcription-polymerase chain reaction showed predominant expression of FMLP receptor homologues, FPRH1 and FPRH2 mRNA, in human coronary medial tissues relative to that in leukocytes. In conclusion. FMLP produced transient tension changes in human coronary arteries, mainly via the generation of TXA2 and PGI2. This effect of FMLP did not appear to be mediated by the activation of densely accumulated intimal and/or adventitial macrophages, but by the activation of unidentified medial tissue cells which might have functional FMLP receptor homologues.

Intravillous eicosanoid compartmentalization and regulation of placental blood flow

OBJECTIVE

To determine the roles of the eicosanoids thromboxane and prostacyclin, and their compartmentalization, in the regulation of placental blood flow.

METHODS

First, the sites of production of thromboxane and prostacyclin were determined within the placental villus using immunohistochemical staining for thromboxane and prostacyclin synthetase. Second, the production of both eicosanoids was studied in cultured trophoblasts and compared with that in the villous core by measuring the metabolites thromboxane B2 and 6-keto-prostaglandin F 1 alpha. Finally, eicosanoid production was assessed in intact villi after stimulation by an acute change in oxygen content, 5% to 95%.

RESULTS

Immunohistochemical staining showed that thromboxane production was primarily within the trophoblasts, whereas prostacyclin production was localized to the endothelial cells within the villi. In culture, we found preferential production of prostacyclin by the villous core cells and increased production of thromboxane by trophoblasts. Perifusion of intact villi demonstrated increased production of thromboxane by trophoblasts in response to an increase in oxygen content. Prostacyclin levels were too low to be detected.

CONCLUSIONS

Placental blood flow appears to be regulated by compartmentalized eicosanoids, with thromboxane affecting primarily the maternal side of the placental circulation and prostacyclin affecting primarily the fetal side.

Expression of prostacyclin and thromboxane synthases in placenta and placental bed after pre-eclamptic pregnancies

Prostacyclin and thromboxane are potent antagonistic regulators of vascular tone and platelet aggregation. In pre-eclampsia, the ratio of their metabolites is decreased. Little is known about the local regulation of intrauterine prostacyclin and thromboxane production in this condition. Placenta and placental bed biopsies were obtained from uncomplicated and pre-eclamptic pregnancies. Prostacyclin synthase (PCS) and thromboxane synthase (TXS) and their mRNA's were localized by immunohistochemistry using monoclonal antibodies and in situ hybridization. Protein and mRNA levels were quantified by immunoblot and RNase protection assay. PCS-like immunoreactivity was found in endothelial cells and leiomyocytes, whereas fetal and maternal macrophages showed positive staining for TXS. Their mRNA was localized to trophoblast and endothelium, and TXS mRNA could also be detected in macrophages. Quantitative analysis showed no significant difference in intrauterine protein or mRNA expression after pre-eclampsia. The prostacyclin and thromboxane production seems to be compartmentalized within the uteroplacental unit. The expression of their synthesizing enzymes might be regulated post-transcriptionally. Additional regulation of prostaglandin production could be metabolically or on the substrate level and requires further elucidation.

Activated microglia are the principal glial source of thromboxane in the central nervous system

Thromboxane A2(TxA2) is a potent vasoconstrictor associated with cerebrovascular disease and is thought to be synthesized within tissues of the brain. In order to determine the cellular sources of TxA2 in the central nervous system (CNS), we measured the release of the stable metabolite TxB2 in cultures of mixed or highly enriched populations of brain glia. Using techniques which isolated large numbers of highly enriched microglia and astroglia, we found that only microglia release TxB2. Moreover, microglia, not astroglia, contain the requisite synthetic enzyme thromboxane synthase. Phagocytic signals and lipopolysaccharide are potent stimulants of microglial release of thromboxane, with lesser effects shown by platelet activating factor and substance P. We conclude that microglia, when activated, are the principal source of brain-derived thromboxane and may help to control vascular flow at sites of acute CNS injury.

Immunohistochemical localization of thromboxane receptor and thromboxane synthase in rat testis

The cellular localization of thromboxane A2 receptor (TXR) and thromboxane synthase (TXS) in rat testes was examined with an antibody against the carboxyl-terminal tail of rat TXR and anti-porcine lung TXS antibody. By light microscopy immunoreactivity for TXR was shown to be present in spermatids, whereas spermatogonia, spermatocytes, and spermatozoa lacked the immunoreactivity. Immunoelectron microscopic analysis revealed that immunostainable TXR was present in acrosomes of spermatids. In contrast, immunoreactivity for TXS was present in all stages of spermatogenic cells; spermatogonia, spermatocytes, spermatids, and spermatozoa. TX system may possibly contribute to the formation of acrosomes or have some unrecognized functions in an autocrine/paracrine fashion.

Thromboxane synthase expression in renal transplant patients with rejection

Thromboxane synthase (TS) catalyzes the formation of thromboxane (TxA2) in monocytes/macrophages, platelets, and various tissues. TxA2 is likely to play a role in graft dysfunction due to its vasoconstrictive and platelet aggregatory properties. We studied the expression of TS in 7 normal native kidneys, 29 consecutive renal allograft biopsies (performed for rising serum creatinine, n = 23, and delayed graft function, n = 6), and one transplant nephrectomy specimen with severe acute rejection. TS expression was determined by immunocytochemistry using a monoclonal antibody against human TS, Kon-7. Histologic grading of the transplant biopsy specimens was based on the Banff classification. The degree of TS staining was graded in the glomeruli, interstitium, tubules and vessels from 0 to 3+. Of 29 biopsies, 13 had chronic nephropathy (CN), 6 had acute rejection (AR) with chronic nephropathy (AR/CN), 4 had acute rejection (AR), and 6 had acute tubular necrosis (ATN). TS staining of native kidneys showed sporadic interstitial cells. The biopsy and transplant nephrectomy specimens showed significant staining, predominantly in the glomeruli and interstitium. Positively staining cells appeared to be of macrophage/monocyte lineage by morphology. The mean glomerular staining grade was significantly increased in specimens with AR (2.3 +/- 0.9) and the mean interstitial staining was increased in specimens with AR/CN (2.2 +/- 0.9). Follow-up renal function 6 months post-biopsy showed that patients with higher TS staining grades had a faster decline in graft function. In conclusion, TS expression is increased in patients with acute rejection with or without chronic nephropathy and is associated with more rapid deterioration in function.

Immunohistochemical localization of thromboxane synthase in human intrauterine tissues

Uterine tissues are known to be able to synthesize thromboxane A2 (TXA2), but there is little information about the nature of cells actually responsible for its production. In this study human placenta, fetal membranes, umbilical cord and pregnant myometrium were investigated immunohistochemically. The avidin-biotin method for a monoclonal antibody against human thromboxane synthase (Tü 300) was applied on frozen tissue sections. In placenta, fetal membranes and umbilical cord, staining was positive for Hofbauer cells and fibroblasts. Further, in sections of placenta, capillary endothelium showed antigenicity for TX synthase. Leiomyocytes in the umbilical cord vessels contained the enzyme as well. Preparations of pregnant myometrium were shown to express TX synthase in leiomyocytes, endothelial cells and connective tissue cells. Amnion, trophoblast and decidua did not possess antigenicity for this enzyme. Since TXA2 plays an important role for the regulation of vascular tone and aggregation of platelets and may stimulate myometrial contractions during parturition, the abundance of TX synthase in pregnancy-specific tissues confirms previous in vivo and in vitro observations. Further, TXA2 synthesized by Hofbauer cells may be involved in immunological reactions during pregnancy, and the number and level of activation of Hofbauer cells may be closely related to the initiation of labour. Thromboxane production by the endothelium lining the fetal vessels points to its regulatory role for the blood flow in the fetoplacental unit.

The localization of thromboxane synthase in normal and pathological human kidney tissue using a monoclonal antibody Tü 300

Thromboxane, excreted in the urine in increased amounts in glomerular, vascular and tubulo-interstitial diseases, is considered to originate from the kidney. The localization of thromboxane synthase, a key enzyme of arachidonic acid metabolism, was studied in the human kidney by immunohistology using the monoclonal antibody Tü 300. In the interstitial tissue dendritic reticulum cells surrounding the tubules expressed high concentrations of the enzyme. In glomeruli the enzyme was weakly expressed in podocytes. This was confirmed by co-localization with an antiserum directed to podocalyxin, a marker of the visceral epithelial cells. In the study of various kidney diseases, massive accumulation of thromboxane synthase containing cells was observed in interstitial diseases, whereas in glomerular diseases there were no differences from normal kidney; in a case of thrombotic microangiopathy podocytes exhibited an increase in thromboxane-synthase. The thromboxane-synthase positive infiltrating interstitial cells were shown by conventional light microscopy to be mononuclear phagocytic cells. The physiological sources of renal thromboxane are dendritic reticular cells and podocytes. In interstitial renal disease infiltrating cells of the monocyte/macrophage system constitute the major site of thromboxane synthesis. In glomerular disease, a characteristic alteration of thromboxane-synthase was not found.

Expression of thromboxane A2 receptor gene and thromboxane A2 synthase in bovine corpora lutea

Studies were undertaken to investigate the expression of thromboxane (TXA2) receptor gene, from mRNA to functional receptor protein in terms of ligand binding, along with the cellular and subcellular distribution of the enzyme that catalyzes the formation of the ligand for the receptors. Bovine corpora lutea contained a single TXA2 receptor mRNA transcript of 2.8 kb. All the cell types in bovine corpora lutea contained immunoreactive TXA2 synthase, TXB2, TXA2 receptor transcripts, and receptor protein that bound the TXA2 antagonist 9,11-dimethylmethano-11,12-methano-16 (3-iodo-4-hydroxyphenyl)-13-14-dihydro-13-aza-15 alpha beta-omega-tetranor TXA2. The large luteal cells (20-35 microns) contained more receptor transcripts, receptor protein, and immunoreactive TXA2 synthase than did the small luteal cells (12-19 microns), luteal blood vessels, and nonluteal cells (7-12 microns). After correction for the cellular area differences, small luteal cells were seen to contain more receptor protein than did large luteal cells and nonluteal cells. All the cells showed an increase of TXA2 receptors and catalytically active TXA2 synthase from mid-luteal phase to early pregnancy, suggesting the possibility that TXA2 could be a luteotropic eicosanoid. Bovine lung homogenates (a positive control), bovine luteal plasma membranes-mitochondria-lysosomes fraction, rough-smooth endoplasmic reticulum-Golgi fraction, and highly purified nuclei contained 65-kDa immunoreactive protein, presumably representing TXA2 synthase. In addition, the luteal fractions, but not bovine lung, contained other small and large molecular-size immunoreactive proteins. Immunogold electron microscopy showed that immunoreactive TXA2 synthase was present primarily in plasma membranes, rough endoplasmic reticulum, nuclear membranes, and chromatin; and immunoreactive TXB2 was present primarily in different-size vesicles and nuclear chromatin. In summary, the present studies demonstrate for the first time that primarily small and large luteal cells and secondarily blood vessels and nonluteal cells in bovine corpora lutea express TXA2 receptor gene along with the functional TXA2 synthase. The presence of functional enzyme in luteal cell nuclei suggests that the enzyme and/or its product may have previously unrecognized functions in nuclei.

Localization of thromboxane synthase in human tissues by monoclonal antibody Tü 300

Using the monoclonal antibody Tü 300 we localized thromboxane synthase, a secondary enzyme of the arachidonic acid cascade, employing the alkaline phosphatase anti-alkaline phosphatase method and indirect double labelling immunofluorescence in frozen sections of human tissues. Aside from platelets, the source of the antigen, all cells of the mononuclear phagocytic system were positive, including epithelioid cells and associated giant cells, starry sky macrophages, dendritic cells of T-cell areas, Langerhans cells and Kupffer cells. In addition, some epithelial cells such as epithelia of tonsillar crypts, reticular epithelia of the thymic cortex and ductular epithelia in liver, pancreas, female breast and salivary glands showed occasional focal reactivity for thromboxane synthase. We suggest that the mAb Tü 300 is a key marker for the macrophage system and the thromboxane generating system in normal and pathological conditions. It may detect functional activities of as yet unknown significance in some specialized epithelial cells.

The enzymes in cyclooxygenase and lipoxygenase pathways of arachidonic acid metabolism in human corpora lutea: dependence on luteal phase, cellular and subcellular distribution

Eicosanoids synthesized within corpus luteum are presumed to regulate luteal function in women. However, the potential cellular source(s) of the eicosanoids, whether small and large luteal cells differ in eicosanoid synthesis and whether eicosanoids other than prostaglandin (PG)E2, PGF2 alpha and 6-keto-PGI1 alpha can be synthesized, have not been investigated. The present immunocytochemical studies were undertaken to answer these questions using mono and polyclonal antibodies to several enzymes in arachidonic acid metabolism by cyclooxygenase and lipoxygenase pathways. Human corpora lutea from early (n = 5), mid (n = 6) and late (n = 3) luteal phases were specifically immunostained for all the enzymes. All the enzymes were present in small and large luteal cells as well as in non luteal cells. However, small luteal cells contained more immunoreactive 5-lipoxygenase, PGD2 and PGF2 alpha synthases; large luteal cells contained more TXA2 synthase and 12-lipoxygenase; small and large luteal cells contained similar amounts of cyclooxygenase and PGI2 synthase. In all the cells, immunoreactive PGD2, PGI2 and TXA2 synthases increased from early to mid luteal phase and then declined in late luteal phase. Cyclooxygenase, 5- and 12-lipoxygenases and PGF2 alpha synthase, on the other hand, increased from early to mid and mid to late luteal phases. Immunoreactive cyclooxygenase and 5- and 12-lipoxygenases were present primarily in rough endoplasmic reticulum (ER) and/or smooth ER and cytoplasm. Quite unexpectedly, all three enzymes were also found in nuclear membranes, condensed chromatin and especially at the perimeter of condensed chromatin. Dispersed chromatin contained very little or no immunoreactive enzyme. These results indicate that regulation of human luteal function by eicosanoids synthesized within the corpus luteum is complex involving perhaps a) small and large luteal as well as non luteal cells, b) eicosanoids which have not been previously considered to play a role in luteal function and c) coordinate regulation of more than one enzyme in the pathways of arachidonic acid metabolism.

Rapid increase in the activity of enzymes of eicosanoid synthesis in hepatic and extrahepatic tissues after experimental liver transplantation

Previous studies have demonstrated a marked release of prostanoids from hepatic tissue after liver grafting. In addition, eicosanoid synthesis was shown to be regulated at the level of key enzymes. The present study addressed changes of the local availability of these enzymes during and after porcine orthotopic liver transplantation. We determined kinetic parameters of cyclooxygenase (CO), the initial enzyme of prostaglandin synthesis, of prostacyclin and thromboxane synthase (PCS, TXS), two more peripheral enzymes, in microsomal preparations of hepatic and gluteal muscle biopsies, and the activity of 5-lipoxygenase (5-LO), the key enzyme of leukotriene synthesis. Maximal velocity (Vmax) of CO and PCS showed a 4-fold increase both in liver and gluteal muscle tissue 1 hr after reperfusion of the grafted liver and a more than 20-fold increase after 24 hr (P less than 0.001), whereas apparent affinities (Km) remained unchanged. In contrast, Vmax of TXS and the activity of 5-LO disclosed a striking increase only within the hepatic graft (P less than 0.001). No changes of enzymatic activity could be observed during donor operation, cold storage, and 5 min after reperfusion. Results were independent of the duration of preservation (3 hr and 20 hr with Euro-Collins) and the addition of Iloprost, a prostacyclin-analogue. These results suggest that after liver grafting, abnormalities at the level of local enzyme expression in hepatic and extrahepatic tissues might contribute to preservation damage and systemic injury of the host.

Immunoaffinity purification of human thromboxane synthase

A recently produced monoclonal antibody against human thromboxane synthase was used to purify the enzyme from platelets in a one-step procedure with good yields. The isolated protein exhibited a single band of about 58 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and contained one heme/mol. Although the visible spectrum of the oxidized enzyme displayed a peak at 418 nm like the previously isolated enzyme after dithionite reduction and CO addition, it shifted to 419 nm but not to 450 nm where only a small shoulder could be detected. Its catalytic activity was only 1-5% of the previous preparations, but with the same Km of about 10 microM and a ratio of thromboxane B2: 12-hydroxyheptadecatrienoic acid of 1:1. Studies with EPR spectrometry and inhibitors confirmed that only a minor part of the enzyme was in its native heme-thiolate conformation, whereas the major part had been converted to the inactive P420 form by the elution procedure. The amino acid analysis revealed 46% hydrophobic residues. According to the sequence of 26 amino acids from the N-terminus and two tryptic peptides no homology to one of the cytochrome P450 monooxygenases, or to cyclooxygenase, or to prostacyclin synthase was detected.

Monoclonal antibodies to thromboxane synthase from porcine lung. Production and application to development of a tandem immunoradiometric assay

Two hybridoma cell lines secreting antibodies against thromboxane synthase of porcine lung were produced. Clone TS1 secretes IgG2a antibody of lower affinity, while clone TS2 secretes IgG1 antibody of higher affinity. Both antibodies (when bound to rabbit anti-mouse IgG-Staphylococcus aureus complex) can immunoprecipitate thromboxane synthase from crude enzyme preparations in an active form suggesting that binding was not directed at the active site. Each antibody showed a distinctive pattern of cross-reactivity with thromboxane synthase from different porcine tissues. Neither of the antibodies cross-reacted with the enzyme from tissues of other species tested, indicating the heterogeneous nature of the enzyme among species. Competitive binding assay revealed that TS1 and TS2 recognized different determinants on the enzyme. The fact that two antibodies bind to separate epitopes on the same enzyme allows the development of a sensitive tandem immunoradiometric assay. The assay, based on binding of 125I-TS2 to thromboxane synthase immobilized on TS1-S. aureus complex, was linear with 7.5 approximately 75 ng of purified lung thromboxane synthase as standards and applicable to enzyme preparations regardless of their purity. The concentration of immunoreactive thromboxane synthase in porcine tissues as determined by this assay followed the order of platelet greater than colon greater than duodenum greater than lung greater than kidney greater than stomach. The fact that gastrointestinal tract is enriched with thromboxane synthase suggests that thromboxane may have significant physiological roles to be recognized in these organs.

Thromboxane synthase is preferentially conserved in activated mouse peritoneal macrophages

Resident macrophages isolated from uninfected animals produce large quantities of arachidonic acid (AA) metabolites. Immunizing animals with protein antigens or bacteria activates macrophages and causes an 80% reduction in the cyclooxygenase and lipoxygenase metabolites relative to resident cells. Since some products have been shown to modulate immune functions, we examined how the AA metabolic enzyme activities regulate the products that are synthesized. We demonstrate that the cyclooxygenase, 5-lipoxygenase, prostacyclin synthase, and probably prostaglandin (PG) endoperoxide E-isomerase activities were decreased in activated peritoneal macrophages. In sharp contrast, thromboxane synthase activity was selectively unchanged or enhanced in the activated macrophages. Thus the immune response appears to modulate the activity of the AA and PG endoperoxide-dependent enzymes, thus dictating a major shift in the profile of metabolites synthesized by macrophages.