Mast cells contain spleen-type prostaglandin D synthetase

Prostaglandin D synthetase activity in the cytosol (100,000 x g, 1-h supernatant) fraction of peritoneal mast cells of adult rats (105.0 nmol/min/mg protein) was the highest among such activities in various rat tissues and cells. As judged by the absolute requirement for glutathione for the reaction (Km = 300 microM), the Km value for prostaglandin H2 (200 microM), and insensitivity of the activity to 1 mM 1-chloro-2,4-dinitrobenzene, the enzyme in mast cells was similar to rat spleen prostaglandin D synthetase and differed from rat brain prostaglandin D synthetase or glutathione S-transferase, all of which catalyze the isomerase reaction from prostaglandin H2 to prostaglandin D2. In immunotitration analyses, the activity in mast cells showed a titration curve exactly identical with that of the purified spleen-type enzyme and almost completely absorbed by an excess amount of antibody against this enzyme, but it remained unchanged after incubation with antibodies against the brain-type enzyme and glutathione S-transferase isozymes thus far purified. In Western blot after two-dimensional electrophoresis of crude extracts of mast cells, a single immunoreactive spot was observed with antibody against the spleen-type enzyme at the same position as that of the purified enzyme (Mr = 26,000, pI = 5.2). Furthermore, the immunoreactive protein obtained from mast cells showed the same peptide fingerprints as those of the purified spleen-type enzyme, after partial digestion with Staphylococcus aureus V8 protease or trypsin. In immunoperoxidase staining, the immunoreactivity of the spleen-type enzyme was found in the cytosol of tissue mast cells in various organs such as thymus, intestine, stomach, and skin of adult rats. These findings indicate that prostaglandin D2 is produced by the spleen-type synthetase in mast cells of various tissues.     

9 alpha,11 beta-prostaglandin F2 formation in various bovine tissues. Different isozymes of prostaglandin D2 11-ketoreductase, contribution of prostaglandin F synthetase and its cellular localization

9 alpha,11 beta-prostaglandin F2 was formed from prostaglandin D2 by its 11-ketoreductases in 100,000 x g supernatants of various bovine tissues in the presence of an NADPH-generating system. The reductase activities were high in liver (51.09 nmol/h/mg of protein), lung (24.99), and spleen (14.20); moderate in heart and pancreas (3.09-3.61); weak in stomach, intestine, colon, kidney, uterus, adrenal gland, and thymus (0.11-2.63); and undetectable in brain, retina, carotid artery, and blood (less than 0.10). No formation of prostaglandin F2 alpha from prostaglandin D2 was detected in all tissues. In immunotitration analyses with a polyclonal antibody specific for prostaglandin F synthetase, the reductase activities in lung and spleen showed identical titration curves to that of the purified synthetase and decreased to less than 15% of the initial activity under the condition of antibody excess. Prostaglandin F synthetase-immunoreactive protein in these two tissues showed peptide fingerprints identical to that of the purified enzyme after partial digestion with Staphylococcus aureus V8 protease. The antibody was partially cross-reactive to the reductase in liver (about 20% of that to the synthetase) but not to the reductase(s) in other tissues. The Km value for prostaglandin D2 of the reductase activity was the same in lung and spleen as that of the purified prostaglandin F synthetase (120 microM) but differed in liver (6 microM), heart, and pancreas (15 microM). The predominant distribution of prostaglandin F synthetase in lung and spleen was confirmed by radioimmunoassay (2.8 and 1.0 micrograms/mg protein, respectively) and Northern blot analyses. In immunoperoxidase staining, this enzyme was localized in alveolar interstitial cells and nonciliated epithelial cells in lung, histiocytes and/or dendritic cells in spleen, and a few interstitial cells in kidney and adrenal cortex.     

Isolation and properties of enzymes involved in prostaglandin biosynthesis.

Prostaglandin (PG) endoperoxide synthetase was purified until homogeneity had been attained. The pure enzyme displays both cyclooxygenase and peroxidase activity, in accordance with the work of MIYAMOTO et al. (J. biol. Chem. 252, 2629--2636 (1976)). This enzyme therefore converts arachidonic acid into PGH2. Glutathione S-transferases, in the presence of glutathione, convert PGH2 into a mixture of PGF2alpha, PGE2 and PGD2. A new transferase in sheep lung gives mainly PGF2alpha and PGD2. Isolation and properties of these enzymes will be discussed. Finally, progress will be reported on the isolation of a soluble enzyme from various rat organs such as lung and spleen, which forms almost exclusively prostaglandin D.     

Biochemical and immunological characterization of rat spleen prostaglandin D synthetase

Rat spleen prostaglandin D synthetase (Christ-Hazelhof, E., and Nugteren, D. H. (1979) Biochim. Biophys. Acta 572, 43-51) is very similar to rat brain prostaglandin D synthetase (Urade, Y., Fujimoto, N., and Hayaishi O. (1985) J. Biol. Chem. 260, 12410-12415) as judged by their pI (4.7-5.2), Mr (26,000-27,000), and self-inactivation during the isomerase reaction from prostaglandin H2 to prostaglandin D2. However, the amino acid compositions of these two enzymes were quite different. Furthermore, the spleen enzyme was associated with the glutathione S-transferase activity, differing from the brain enzyme. The synthetase and transferase activities of the spleen enzyme showed almost identical pH and glutathione dependencies, the optimum pH = 8.0 and Km for glutathione = 300 microM. The Km values for prostaglandin H2 and 1-chloro-2,4-dinitrobenzene (a substrate for the transferase) were about 200 microM and 5 mM, respectively. The synthetase activity was dose-dependently inhibited by 1-chloro-2,4-dinitrobenzene (IC50: approximately 5 mM) and more strongly by nonsubstrate ligands, such as bilirubin and indocyanine green (IC50: 150 and 2 microM, respectively). Both the synthetase and transferase activities of the purified enzyme dose-dependently decreased and showed identical immunotitration curves by incubation with antibody against this enzyme, but remained unchanged when treated with antibody against the brain enzyme. The antibody specific for the spleen enzyme absorbed almost all of the synthetase activity and about 10% of the transferase activity in the spleen, but not the transferase activity in the liver, heart, and testis. These results show that the two types of prostaglandin D synthetase are similar but different enzymes and that the spleen enzyme is a unique glutathione S-transferase differing from other isozymes and their subunits reported previously.     

Prostaglandin D2 formation and characterization of its synthetases in various tissues of adult rats

When the amounts of primary prostaglandins formed from endogenous arachidonic acid were determined in homogenates of various tissues of adult rats, prostaglandin D2 was the major prostaglandin found in most tissues. It was formed actively in the spleen (3100 ng/g tissue/5 min at 25 degrees C), intestine (2600), bone marrow (2400), lung (1100), and stomach (630); moderately in the epididymis, skin, thymus, and brain (140-340); and weakly in other tissues (less than 100). Addition of exogenous arachidonic acid (1 mM) accelerated the formation of prostaglandin D2 in all tissues as follows: spleen (15,000); bone marrow, intestine, thymus, liver, and lung (1600-5200); stomach, adrenal gland, epididymis, brain, salivary gland, skin, spinal cord, and seminal vesicle (380-1000); and other tissues (80-310). The activity of prostaglandin D synthetase (prostaglandin-H2 D-isomerase) was detected in 100,000g supernatants of almost all tissues. As judged by glutathione requirement for the reaction, inhibition of the activity by 1-chloro-2,4-dinitrobenzene, and immunotitration or immunoabsorption analyses with specific antibodies, the enzyme in the epididymis, brain, and spinal cord (1.8-9.2 nmol/min/mg protein) was glutathione-independent prostaglandin D synthetase (Y. Urade, N. Fujimoto, and O. Hayaishi (1985) J. Biol. Chem. 260, 12410-12415). The enzyme in the spleen, thymus, bone marrow, intestine, skin, and stomach (2.0-57.1) was glutathione-requiring prostaglandin D synthetase (Y. Urade, N. Fujimoto, M. Ujihara, and O. Hayaishi (1987) J. Biol. Chem. 262, 3820-3825). The activity in the kidney and testis (3.7-4.5) was catalyzed by glutathione S-transferase. The activity in the liver, lung, adrenal gland, salivary gland, heart, pancreas, and muscle (0.6-5.1) was due to both the glutathione-requiring synthetase and the transferase.     

Purification and characterization of rat brain prostaglandin D synthetase

Prostaglandin D synthetase was purified 2,600-fold from rat brain to apparent homogeneity, as judged by polyacrylamide gel electrophoresis and ultracentrifugation. The purified enzyme was a monomeric protein with a molecular weight of 27,000 +/- 1,000. The pI value, sedimentation coefficient, and partial specific volume were 4.6, 4.1 s, and 0.73 ml/g, respectively. The enzyme was stable between pH 4 and 11 at the temperature lower than 25 degrees C and resistant to a heat treatment under alkaline conditions (pH 8-11). About 50% of the activity was detected after a heat treatment at 100 degrees C for 5 min at pH 10. However, the enzyme was readily inactivated by the isomerase reaction of prostaglandin H2 to prostaglandin D2. The enzyme required sulfhydryl compounds such as dithiothreitol, glutathione, beta-mercaptoethanol, cysteine, and cysteamine for the reaction, but stoichiometric oxidation of these sulfhydryl compounds was not observed. The optimum pH, Km value for prostaglandin H2, and the turnover number were 9.5, 14 microM, and 170 min-1, respectively. The antibody was raised against the purified enzyme in a rabbit, which showed only one positive band in immunoblotting after gel electrophoresis of crude extracts of the brain at the same position as that of the purified enzyme. More than 90% of the prostaglandin D synthetase activity in the brain was absorbed by an excess amount of the antibody, indicating that our preparation is a major component of the enzyme responsible for the biosynthesis of prostaglandin D2 in the brain.     

Inhibition of rat brain prostaglandin D synthase by inorganic selenocompounds

Various inorganic selenocompounds dose-dependently inhibited the rat brain prostaglandin (PG) D synthase, both in the purified enzyme preparation and in the crude brain supernatant. All of the quadrivalent selenium compounds tested had a very limited range of IC50 values in the purified enzyme (11-12 microM) and in the brain supernatant (9-15 microM). A divalent selenium compound was also inhibitory, but a hexavalent selenium compound was ineffective. In contrast, organic selenocompounds such as selenomethionine and selenourea had no effect on the PGD synthase activity. Furthermore, sodium sulfate and sodium sulfite up to 10 mM did not inhibit the activity. The inhibition by selenium required the preincubation of the metal with sulfhydryl compounds such as dithiothreitol (DTT), indicating that the formation of selenotrisulfide or some other adduct(s) is essential for the inhibition. Furthermore, the inhibition was reversed by an excess amount of dithiothreitol, suggesting that the selenotrisulfide derivative of DTT binds to the SH group of the PGD synthase. The kinetic analysis revealed the inhibition by selenite to be noncompetitive with a Ki value of 10.1 microM. On the other hand, glutathione-dependent PGD synthase from rat spleen was much less inhibited, and PGF synthase and PGD2 11-ketoreductase activities were not inhibited by the selenium compound.     

Deoxyuridine triphosphate nucleotidohydrolase: distribution of the enzyme in various rat tissues

The distribution of deoxyuridine triphosphate nucleotidohydrolase (dUTPase) [EC 3.6.1.23] in the cytosol of various rat tissues was investigated by measuring the enzyme activity and by immunochemical analyses. Among nine rat tissues, thymus, and spleen showed the highest activities of the enzyme per gram of tissue, while intestine, stomach, lung and liver showed very low levels. Rabbit antibodies directed against purified dUTPase of anemic rat spleen showed reactivity with partially purified dUTPases from other rat tissues such as thymus, testis, or regenerating liver. Immunotitration and immunoblot experiments also indicated that the dUTPases in various rat tissues had very similar antigenicity and apparently the same subunit molecular size (Mr = 19,500), suggesting that the enzyme lacks organ-specificity. Immunoblot analysis of dUTPase protein with crude extracts from various rat tissues showed a similar distribution to that of the enzyme activity. No immuno-reactive band corresponding to the dUTPase was detected in intestine, although intestinal mucosa has been recognized as an actively proliferating tissue.     

Basal level of prostaglandin D2 in rat brain by a solid-phase enzyme immunoassay

A solid-phase enzyme immunoassay for prostaglandin D2 (PGD2) was developed in which PGD2 was labeled with horseradish peroxidase. After competitive binding to the immobilized antibody between enzyme-labeled and free PGD2, the activity of the enzyme bound to the antibody was assayed fluorometrically using 3-(p-hydroxyphenyl)-propionic acid and hydrogen peroxide as substrates. The procedure allowed determinations of 3-100 pg for PGD2. The IC50 value for PGD2 in the solid-phase enzyme immunoassay was about 25 pg and the sensitivity was improved about 10 times compared to those in radioimmunoassay and in solution-phase enzyme immunoassay. The solid-phase enzyme immunoassay was applied to the measurement of PGD2 content in rat brain and thereby an octadecylsilyl silica cartridge and a reversed-phase HPLC were sequentially used for sample preparations. Heads were immediately frozen in liquid nitrogen after decapitation to avoid a postmortem formation of PGD2. PGD2 contents measured by solid-phase enzyme immunoassay correlated well with the values obtained by radioimmunoassay (r = 0.966) after raising its contents by intravenous administration of PGD2. The in vivo level of PGD2 in rat brain was extremely low but determined to be 0.11 +/- 0.03 ng/g tissue (mean +/- S.E.M.) with this enzyme immunoassay. The result was equal to the value extrapolated to zero time from the postmortem change.     

Inhibition of brain prostaglandin D synthetase and prostaglandin D2 dehydrogenase by some saturated and unsaturated fatty acids

The activities of rat brain prostaglandin D synthetase and swine brain prostaglandin D2 dehydrogenase were inhibited by some saturated and unsaturated fatty acids. Myristic acid was most potent among saturated straight-chain fatty acids so far tested. The IC50 values of this acid were 80 microM for prostaglandin D synthetase and 7 microM for prostaglandin D2 dehydrogenase, respectively. Little inhibition was found with methyl myristate and myristyl alcohol. The IC50 values of these derivatives were more than 200 microM for both enzymes, suggesting that the free carboxyl group was essential for the inhibition. The effects of cis double bond structure of fatty acids on the inhibition potency were examined by the use of the carbon 18 and 20 fatty acids. The inhibition potencies for both enzymes increased with the number of cis double bonds; the IC50 values of stearic, oleic, linoleic and linolenic acid were, respectively, more than 200, 60, 30 and 30 microM for prostaglandin D synthetase, and 20, 10, 8.5 and 7 microM for prostaglandin D2 dehydrogenase. Arachidonic acid also inhibited the activities of both enzymes with respective IC50 values of 40 microM for prostaglandin D synthetase and 3.9 microM for prostaglandin D2 dehydrogenase, while arachidic acid showed little inhibition. The kinetic studies with myristic acid and arachidonic acid demonstrated that the inhibition by these fatty acids was competitive and reversible for both enzymes. Myristic acid and other fatty acids also inhibited the activities of several enzymes in prostaglandin metabolism, although to a lesser extent. The IC50 values of myristic acid for prostaglandin E isomerase, thromboxane synthetase and NAD-linked prostaglandin dehydrogenase (type I) were 200, 700 and 100 microM, respectively. However, this fatty acid showed little inhibition on fatty acid cyclooxygenase (20% at 800 microM), glutathione-requiring prostaglandin D synthetase from rat spleen (20% at 800 microM), and NADP-linked prostaglandin dehydrogenase (type II) (no inhibition at 200 microM).     

Immunochemical characterization of rat testicular asparagine synthetase.

We studied immunochemical properties of rat testicular asparagine synthetase. Western blot analysis of testis extract with polyclonal antibody raised against purified asparagine synthetase revealed an immunoreactive band at 62 kDa. The pancreas, brain, thymus, and spleen also showed 62-kDa bands. The intensities of these bands were roughly proportional to the specific activities of the enzyme in these tissues. The antibody showed some degree of cross-reactivity to asparagine synthetases from human, beef, pig, mouse, guinea pig, chicken, and frog, but not carp. But the enzyme from human HL-60 cells and lower vertebrates reacted with the antibody less strongly than enzyme from rats. The N-terminal amino acid sequence of the enzyme, determined by the Edman degradation method, in 10 recovered residues was identical to that of human asparagine synthetase deduced from corresponding cDNA (I.L. Andrulis et al., 1987, Mol. Cell. Biol. 7, 2435-2443). Immunohistochemical staining of the testis showed the presence of asparagine synthetase mainly in Sertoli cells in the seminiferous tubules.     

The purification and properties of aldose reductase from rat ovary

Aldose reductase has been highly purified from rat ovary to apparent homogeneity, as assessed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purified enzyme proved to be a monomeric protein with a molecular weight of about 39,900. The enzyme catalyzed the NADPH-dependent reduction of a number of aromatic and aliphatic aldehydes as well as aldo-sugars. The enzyme was potently inhibited by p-chloro-mercuribenzoate and a commercially developed aldose reductase inhibitor, M79175. The result of an immunoinhibition study, using antibody against the purified enzyme, indicated that the enzyme was responsible for more than 50% of the overall catalytic activity of D-glucose reduction in rat ovarian cytosol. Western blotting analysis revealed that immunoreactive proteins to anti-ovarian aldose reductase antibody were present in adrenal gland, various reproductive tissues, brain, lung, and heart of rats. Furthermore, ovarian tissues of various species contained immunoreactive proteins, though in small amounts. The enzyme was primarily localized in the granulosa cells and oocytes of all stages of follicular development during the estrous cycle, though it was also found in the corpora lutea cells in the pregnant rats.     

Enzymatic formation of prostaglandin F2 alpha from prostaglandin H2 and D2. Purification and properties of prostaglandin F synthetase from bovine lung

Prostaglandin F synthetase from bovine lung was purified 540-fold to apparent homogeneity, as assessed by polyacrylamide gel electrophoreses and ultracentrifugation. The purified enzyme proved to be a monomeric protein with a molecular weight of about 30,500. The enzyme catalyzed not only the reduction of the 11-keto group of prostaglandin D2 but also the reduction of 9,11-endoperoxide of prostaglandin H2 and various carbonyl compounds (e.g. phenanthrenequinone). Experiments using column chromatography, polyacrylamide gel electrophoreses, immunotitration using antibody against the purified enzyme, and heat treatment indicated that three enzyme activities resided in a single protein. Although phenanthrenequinone and prostaglandin D2 competitively inhibited the prostaglandin D2 and phenanthrenequinone reductase activities, respectively, these two substrates were all but ineffective on the prostaglandin H2 (at the Km value) reductase activity up to 14-fold of those Km values. These results suggest that a single enzyme protein purified from the bovine lung catalyzes the reduction of prostaglandin D2, prostaglandin H2, and various carbonyl compounds and that prostaglandin D2 and prostaglandin H2 are metabolized at two different active sites, yielding prostaglandin F2 alpha as the reaction product.     

Localization and identity of adenosine deaminase-positive cells in tissues of the young rat and calf

Rabbit antibody to calf adenosine deaminase (ADA) was used to localize this enzyme in tissues of the young rat and calf by the immunoperoxidase method. The distribution patterns of ADA in most tissues were similar for both species. Within the thymus gland, the enzyme was strongly expressed predominantly in cortical lymphocytes. In the spleen and lymph nodes, most lymphocytes of T-cell areas stained weakly for ADA, whereas only a small number of ADA-positive cells were found in B-cell areas. Clumps of strongly ADA-positive mononuclear blastoid and plasma cells were observed in the medullary regions of lymph nodes, around peri-arteriolar lymphocyte sheaths and in the red pulp of the spleen, and in the lamina propria of the intestine. Double immunofluorescence staining studies in the rat showed that some of these blastoid cells contained both ADA and immunoglobulins and appeared to be plasmablasts. Strong staining for ADA was also found, in both the rat and calf, in as yet unidentified mononuclear blastoid cells in the interstitium of non-lymphoid organs (kidney, heart, lung), in endothelial cells of some arterioles and capillaries, and in Kupffer cells of the liver. In addition, ADA was strongly expressed in calf bile canaliculi. These studies define areas in rat and calf tissues which contain ADA-positive cells and provide a model system for investigations of the relationship between ADA and the function and development of these cells.     

A particle concentration fluorescence immunoassay for prostaglandin D synthase in the rat central nervous system

A solid phase, particle concentration fluorescence immunoassay (PCFIA) was developed for the measurement of prostaglandin (PG) D synthase in the 100,000g supernatant of various regions of the rat central nervous system. In this assay, the enzyme (in the range of 1-25 micrograms protein of brain supernatant or 1-100 ng of the purified enzyme) is attached to submicrometer carboxypolystyrene beads coated with polyclonal anti-rat brain PGD synthase IgG. The total particle-bound enzyme is assayed with fluorescein isothiocyanate (FITC)-conjugated monoclonal anti-PGD synthase IgG after incubation for 1 h. The optimum assay condition was obtained when carboxyl particles coated with ca. 500 micrograms/ml of polyclonal IgG at pH 5.0 and 5 micrograms/ml of FITC-IgG were used. No significant fluorescence was observed when FITC conjugates or carboxyl particles were prepared using IgG from nonimmunized rabbits. Heat treatment of the brain supernatant decreased the specific binding of the enzyme in parallel with the loss of enzyme activity, indicating that the denatured enzyme is not recognized by this assay method. The PGD synthase immunoreactivity was widely distributed in the brain regions and was highest in the paraflocculus. Although slight discrepancy was observed between the concentration by PCFIA and the enzyme activity measured by using [14C]PGH2 in some brain regions, there is a considerable correlation (0.727) between the values by both methods in the same brain regions. The PCFIA now developed showed higher sensitivity (around 10 times), greater reliability, and larger number of samples measurable at once than the radio-TLC assay using [14C]PGH2. This method could provide valuable information concerning the regulatory mechanisms of PGD synthase.     

Immunological cross-reactivity between large and small (2'-5')oligoadenylate synthetases from pig cells

Using glycerol gradient centrifugation, the molecular sizes of porcine (2'-5')oligoadenylate synthetases (2-5A synthetases) were estimated. The 2-5A synthetase purified from pig spleen was about 150 kDa, while the enzyme extracted from nuclei of Newcastle disease virus-infected pig epithelial cells (SK-h) was about 20-40 kDa. The nuclear 2-5A synthetase was selectively adsorbed to Protein A-Sepharose beads conjugated with anti-spleen 2-5A synthetase antibody. Thus, the smaller 2-5A synthetase in nuclei of pig cells shares a protein structure with the larger enzyme from pig spleen.     

Erythroblast antigen expression in murine hematopoietic and nonhematopoietic cells. 2. An immunofluorescent study in pre- and postnatal ontogeny using monoclonal antibodies

The expression of erythroblast antigen (Ag-Eb) in cell membranes during pre- and postnatal mouse development was studied by immunofluorescence using the monoclonal antibody MAE-15. Ag-Eb was detected in embryonic liver, spleen, epithelia of intestine, various glands and skin, as well as in extraembryonic tissues (yolk sac and trophoblast). In pregnant mice positive immunofluorescence was observed in placenta and on the surface of decidual cells in uterus. In adult non-pregnant mice Ag-Eb expression was detected not only in membranes of erythroid cells, but also in non-hemopoietic tissues, such as epithelia of various glands, intestine, kidney and testis, brain endothelium, basal layer of epidermis, and intercalated discs of the heart muscle. A possible role of Ag-Eb in processes of cell transport is discussed.     

Acetoacetyl-CoA synthetase specific activity and concentration in rat tissues

An antibody against acetoacetyl-CoA synthetase purified from rat liver was raised in rabbits. Utilizing the binding of antibody-antigen complexes to a nitrocellulose membrane, a sensitive enzyme-linked immunosorbent assay was developed to estimate the enzyme concentration in rat tissues. The enzyme concentration (microgram immunoreactive protein/mg protein) in rat liver cytosol was increased about 3-, 1.8- and 7-fold by feeding rats diets containing 5% cholestyramine, 0.2% ML-236B (compactin), and 5% cholestyramine plus 0.2% ML-236B for 4 days, respectively, and decreased about 1.8-fold by fasting the animals or 1.3-fold by feeding them a diet containing 5% cholesterol. Changes in the enzyme activity were almost parallel to those in the enzyme concentration, suggesting the physiological role of this enzyme in cholesterol biosynthesis. Immunoblotting of the hepatic cytosol also confirmed that the increase in enzyme concentration on cholestyramine and/or ML-236B feeding was due to an increase in an enzyme protein the same as the purified enzyme and not the isozymic protein. Among various rat tissues examined, the concentrations of immunologically crossreactive enzyme were higher in lipogenic tissues, such as brain, adipose tissue and liver, than in other tissues. The enzymes in these three tissues were identical in molecular weight determined by gel filtration and immunoblotting.     

Cellular communication inside the liver. Binding, conversion and metabolic effect of prostaglandin D2 on parenchymal liver cells.

The major eicosanoid produced within the rat liver, prostaglandin (PG) D2, wa studied for its ability to interact with the various liver cell types. It appeared that PGD2 bound specifically to parenchymal liver cells, whereas the binding of PGD2 to Kupffer and endothelial liver cells was quantitatively unimportant. Maximally 700 pg of PGD2/mg of parenchymal-cell protein could be bound by a high-affinity site (1 x 10(6) PGD2-binding sites/cell). The recognition site for PGD2 is probably a protein because trypsin treatment of the cells virtually abolished the high-affinity binding. High-affinity binding of PGD2 was a prerequisite for the induction of a metabolic effect in isolated parenchymal liver cells, i.e. the induction of glycogenolysis. High-affinity binding of PGD2 by parenchymal cells was coupled to the conversion of PGD2 into three metabolites, whereas no conversion of PGD2 by Kupffer and endothelial liver cells was noticed. The temperature-sensitivity of the conversion of PGD2 was consistent with a conversion of PGD2 on or in the vicinity of the cell membrane. One of the PGD2 metabolites could be identified as 9 alpha, 11 beta-PGF2. It can be calculated that the conversion rate of PGD2 by parenchymal liver cells exceeds the production rate of PGD2 by Kupffer plus endothelial liver cells, indicating that PGD2 is meant to exert its activity within the liver. The present finding that PGD2 formed by the non-parenchymal liver cells is recognized by a specific receptor on parenchymal liver cells and that binding, conversion and metabolic effect of PGD2 are interlinked by this receptor provides further support for the specific role of PGD2 in the intercellular communication in the liver.     

Purification and properties of prostaglandin D synthetase from rat brain.

The prostaglandin D synthetase system was isolated from rat brain. Prostaglandin endoperoxide synthetase solubilized from a microsomal fraction catalyzed the conversion of arachidonic acid to prostaglandin H2 in the presence of heme and tryptophan. Prostaglandin D synthetase (prostaglandin endoperoxidase-D isomerase) catalyzing the isomerization of prostaglandin H2 to prostaglandin D2 was found predominantly in a cytosol fraction and was purified to apparent homogeneity with a specific activity of 1.7 mumol/min/mg of protein at 24 degrees C. The enzyme also acted upon prostaglandin G2 and produced a compound presumed to be 15-hydroperoxy-prostaglandin D2. Glutathione was not required for the enzyme reaction, but the enzyme was stabilized by thiol compounds including glutathione. The enzyme was inhibited by p-chloromercuribenzoic acid in a reversible manner. The purified enzyme was essentially free of the glutathione S-transferase activity which was found in the cytosol of brain.