Membrane localization and topology of leukotriene C4 synthase

Leukotriene C(4) (LTC(4)) synthase conjugates LTA(4) with GSH to form LTC(4). Determining the site of LTC(4) synthesis and the topology of LTC(4) synthase may uncover unappreciated intracellular roles for LTC(4), as well as how LTC(4) is transferred to its export carrier, the multidrug resistance protein-1. We have determined the membrane localization of LTC(4) synthase by immunoelectron microscopy. In contrast to the closely related five-lipoxygenase-activating protein, LTC(4) synthase is distributed in the outer nuclear membrane and peripheral endoplasmic reticulum but is excluded from the inner nuclear membrane. We have combined immunofluorescence with differential membrane permeabilization to determine the topology of LTC(4) synthase. The active site of LTC(4) synthase is localized in the lumen of the nuclear envelope and endoplasmic reticulum. These results indicate that the synthesis of LTB(4) and LTC(4) occurs in different subcellular locations and suggests that LTC(4) must be returned to the cytoplasmic side of the membrane for export by multidrug resistance protein-1. The differential localization of two very similar integral membrane proteins suggests that mechanisms other than size-dependent exclusion regulate their passage to the inner nuclear membrane.

Covalent linkage of prosthetic heme to CYP4 family P450 enzymes

An extensive body of research on the structural properties of cytochrome P450 enzymes has established that these proteins possess a b-type heme prosthetic group which is noncovalently bound at the active site. Coordinate, electrostatic, and hydrogen bond interactions between the protein backbone and heme functional groups are readily overcome upon mild acid treatment of the enzyme, which releases free heme from the protein. In the present study, we have used a combination of HPLC, LC/ESI-MS, and SDS-PAGE techniques to demonstrate that members of the mammalian CYP4B, CYP4F, and CYP4A subfamilies bind their heme in an unusually tight manner. HPLC chromatography of CYP4B1 on a POROS R2 column under mild acidic conditions caused dissociation of less than one-third of the heme from the protein. Moreover, heme was not substantially removed from CYP4B1 under electrospray or electrophoresis conditions that readily release the prosthetic group from other non-CYP4 P450 isoforms. This was evidenced by an intact protein mass value of 59,217 +/- 3 amu for CYP4B1 (i.e., apoprotein plus heme) and extensive staining of this approximately 60 kDa protein with tetramethylbenzidine/H(2)O(2) following SDS-PAGE. In addition, treatment of CYP4B1, CYP4F3, and CYP4A5/7 with strong base generated a new, chromatographically distinct, polar heme species with a mass of 632.3 amu rather than 616.2 amu. This mass shift is indicative of the incorporation of an oxygen atom into the heme nucleus and is consistent with the presence of a novel covalent ester linkage between the protein backbone of the CYP4 family of mammalian P450s and their heme catalytic center.

Alternative splicing determines the function of CYP4F3 by switching substrate specificity

Diversity of cytochrome P450 function is determined by the expression of multiple genes, many of which have a high degree of identity. We report that the use of alternate exons, each coding for 48 amino acids, generates isoforms of human CYP4F3 that differ in substrate specificity, tissue distribution, and biological function. Both isoforms contain a total of 520 amino acids. CYP4F3A, which incorporates exon 4, inactivates LTB4 by omega-hydroxylation (Km = 0.68 microm) but has low activity for arachidonic acid (Km = 185 microm); it is the only CYP4F isoform expressed in myeloid cells in peripheral blood and bone marrow. CYP4F3B incorporates exon 3 and is selectively expressed in liver and kidney; it is also the predominant CYP4F isoform in trachea and tissues of the gastrointestinal tract. CYP4F3B has a 30-fold higher Km for LTB4 compared with CYP4F3A, but it utilizes arachidonic acid as a substrate for omega-hydroxylation (Km = 22 microm) and generates 20-HETE, an activator of protein kinase C and Ca2+/calmodulin-dependent kinase II. Homology modeling demonstrates that the alternative exon has a position in the molecule which could enable it to contribute to substrate interactions. The results establish that tissue-specific alternative splicing of pre-mRNA can be used as a mechanism for changing substrate specificity and increasing the functional diversity of cytochrome P450 genes.

Differential localization of 5- and 15-lipoxygenases to the nuclear envelope in RAW macrophages

Leukotriene formation is initiated in myeloid cells by an increase in intracellular calcium and translocation of 5-lipoxygenase from the cytoplasm to the nuclear envelope where it can utilize arachidonic acid. Monocyte- macrophages and eosinophils also express 15-lipoxygenase, which converts arachidonic acid to 15(S)-hydroxyeicosatetraenoic acid. Enhanced green fluorescent 5-lipoxygenase (5-LO) and 15-lipoxygenase (15-LO) fusion proteins were expressed in the cytoplasm of RAW 264.7 macrophages. Only 5-lipoxygenase translocated to the nuclear envelope after cell stimulation, suggesting that differential subcellular compartmentalization can regulate the generation of leukotrienes versus 15(S)-hydroxyeicosatetraenoic acid in cells that possess both lipoxygenases. A series of truncation mutants of 5-LO were created to identify putative targeting domains; none of these mutants localized to the nuclear envelope. The lack of targeting of 15-LO was then exploited to search for specific targeting motifs in 5-LO, by creating 5-LO/15-LO chimeric molecules. The only chimera that could sustain nuclear envelope translocation was one which involved replacement of the N-terminal 237 amino acids with the corresponding segment of 15-LO. Significantly, no discrete targeting domain could be identified in 5-LO, suggesting that sequences throughout the molecule are required for nuclear envelope localization.

Expression of the CYP4F3 gene. tissue-specific splicing and alternative promoters generate high and low K(m) forms of leukotriene B(4) omega-hydroxylase

Cytochrome P450 4F3 (CYP4F3) catalyzes the inactivation of leukotriene B(4) by omega-oxidation in human neutrophils. To understand the regulation of CYP4F3 expression, we analyzed the CYP4F3 gene and cloned a novel isoform (CYP4F3B) that is expressed in fetal and adult liver, but not in neutrophils. The CYP4F3 gene contains 14 exons and 13 introns. The cDNAs for CYP4F3A (the neutrophil isoform) and CYP4F3B have identical coding regions, except that they contain exons 4 and 3, respectively. Both exons code for amino acids 66-114 but share only 27% identity. When expressed in COS-7 cells, the K(m) of CYP4F3B was determined to be 26-fold higher than the K(m) of CYP4F3A using leukotriene B(4) as a substrate. 5'-Rapid amplification of cDNA end studies reveal that the CYP4F3A and CYP4F3B transcripts have 5'-termini derived from different parts of the gene and are initiated from distinct transcription start sites located 519 and 71 base pairs (bp), respectively, from the ATG initiation codon. A consensus TATA box is located 27 bp upstream of the CYP4F3B transcription start site, and a TATA box-like sequence is located 23 bp upstream of the CYP4F3A transcription start site. The data indicate that the tissue-specific expression of functionally distinct CYP4F3 isoforms is regulated by alternative promoter usage and mutually exclusive exon splicing.

Glutathione conjugates recognize the Rossmann fold of glyceraldehyde-3-phosphate dehydrogenase

Leukotriene (LT) C4 and other glutathione conjugates are synthesized intracellularly and then move to the plasma membrane for export. The intracellular proteins that bind these molecules and the significance of these interactions are poorly understood. To identify the binding sites of membrane-associated proteins that recognize these molecules, we utilized photoaffinity probes to label the inner leaflet of erythrocytes. The predominant molecule labeled with S-(p-nitrobenzyl)glutathione-[125I]4-azidosalicylic acid (PNBG-[125I]ASA) or LTC4-[125I]4-azidosalicylic acid (LTC4-[125I]ASA) was 38 kDa. The protein was labeled with PNBG-[125I]ASA, electroblotted to polyvinylidene difluoride membranes, digested in situ with lysyl endopeptidase, and two radiolabeled peptides isolated by reverse phase-high performance liquid chromatography. These contained an identity of 7/11 with amino acids 119-129, and 11/11 with amino acids 67-77 of human liver glyceraldehyde-3-phosphate dehydrogenase (GAPDH), respectively. Photoaffinity labeling with PNBG-[125I]ASA was blocked completely by 100 microM ATP and greater than 50% with 100 microM NAD+. LTC4-[125I]ASA binding to the NAD+ site was confirmed by V8 protease digestion of purified GAPDH labeled with LTC4-[125I]ASA or PNBG-[125I]ASA, with both labels localized to the 6.8-kDa N-terminal fragment. Photoaffinity labeling of HL-60 cells with LTC4-125I-ASA identified GAPDH as the predominant cytoplasmic binding protein in these cells. These data indicate that GAPDH is a membrane-associated and cytoplasmic protein which binds glutathione conjugates including LTC4.

Purification of human leukotriene C4 synthase

Leukotriene (LT) C4 synthase, the enzyme that catalyzes the conjugation of LTA4 with reduced glutathione to form LTC4, was purified to homogeneity from the KG-1 myeloid cell line after solubilization of the microsomes utilizing a combination of 0.4% sodium deoxycholate and 0.4% Triton X-102. The solubilized enzyme was then applied to an S-hexyl-glutathione-agarose column that was eluted by the use of 7.5 mM probenecid. After removal of the probenecid by sequential concentration and dilution in an Amicon concentrator, the enzyme was additionally purified and concentrated by binding to and elution from approximately 75 mg of S-hexyl-glutathione-agarose. The enzyme was further resolved by electrophoresis with a nondenaturing Tris-glycine gel, and the LTC4 synthase activity was localized to slices 3 and 4. When the remainder of the eluate from the nondenaturing gel was precipitated by acetone and analyzed by 14% SDS/PAGE with silver staining, a single protein band of 18 kDa was associated with LTC4 synthase activity and was not present in the eluates of slices lacking activity. The overall recovery was 12.5%. In a separate preliminary purification, in which the yield was only approximately 1%, the eluates of the nondenaturing gel had also revealed a single protein of 18 kDa by SDS/PAGE, which was present only in the eluates with LTC4 synthase activity. These data identify LTC4 synthase as a protein of 18 kDa, a size consistent with its membership in the microsomal glutathione S-transferase family.

The mechanism of leukotriene B4 export from human polymorphonuclear leukocytes

Recently, we characterized the export of leukotriene (LT) C4 from human eosinophils as a carrier-mediated process (Lam, B. K., Owen, W. F., Jr., Austen, K. F., and Soberman, R. J. (1989) J. Biol. Chem. 264, 12885-12889). To determine whether a similar mechanism regulates the release of leukotriene B4 (LTB4), human polymorphonuclear leukocytes (PMN) were preloaded with LTB4 by incubation with 25 microM leukotriene A4 (LTA4) at 0 degrees C for 60 min. PMN converted LTA4 to LTB4 in a time-dependent manner as determined by resolution of products by reverse-phase high performance liquid chromatography and quantitation by integrated optical density. When PMN preloaded with LTB4 were resuspended in buffer at 37 degrees C for 0-90 s, there occurred a time-dependent release of LTB4 but little formation or release of 20-hydroxy-LTB4 and 20-carboxy-LTB4. When PMN were preloaded with increasing amounts of intracellular LTB4 by incubation with 3.1-50.0 microM LTA4 and were then resuspended in buffer at 37 degrees C for 20 s, there occurred a concentration-dependent and saturable release of LTB4 with a Km of 798 pmol/10(7) cells and a Vmax of 383 pmol/10(7) cells/20 s. The release of LTB4 was temperature-sensitive with a Q10 of 3.0 and an energy of activation of 19.9 kcal/mol. The rate of LTB4 release at 37 degrees C is about 50 times the rate of 20-carboxy-LTB4 release. PMN preloaded with LTB4 and resuspended at 0 degree C for 1-60 min in the presence of 30 microM LTA5 progressively converted LTA5 to LTB5. The rate of LTB4 release at 0 degree C was inhibited over the entire time period, peaking at about 50% at 30 min. These results indicate that the release of LTB4 from PMN is a carrier-mediated process that is distinct from its biosynthesis.

A morphometric study of normodense and hypodense human eosinophils that are derived in vivo and in vitro

Hypodense eosinophils were obtained from two patients with the idiopathic hyperosinophilic syndrome (IHES), and hypodense eosinophils were derived by culturing normodense human eosinophils from control donors in the presence of endothelial cells alone, granulocyte/macrophage-colony-stimulating factor (GM-CSF) alone, or GM-CSF and fibroblasts. These eosinophils were examined ultrastructurally and stereologically for alterations in the volume density (Vv) of their electron-dense granules, the Vv of their lucent granules, the Vv of their lipid droplets, the numerical density of their granules with respect to cytoplasm (Nv), and the plasma membrane surface area-to-cell volume ratio (Sv) that might account for their decreased sedimentation density. The hypodense eosinophils that were obtained from the two patients with IHES exhibited a one-third reduction in granule Vv relative to normodense eosinophils from control donors, primarily because of a decrease in granule size. The culture-derived hypodense eosinophils exhibited 10% to 16% decreases in their granule Vv, significant increases in their lucent granules, and a approximately 7.5% decrease in their Sv. Calculation of the cell volume from cross-sectional area measurements showed that the eosinophils that had been cocultured with fibroblasts in the presence of GM-CSF increased their volume by approximately 15%. The eosinophils that had been cocultured with endothelial cells exocytosed some of their granules. In conclusion, a composite of factors including cell swelling, a decrease in the volume of the cytoplasm occupied by granules, and an increase in granule lucency contributes to the hypodense phenotype in vitro, but only cell swelling and hypogranulation are seen in cells from patients with IHES. The latter could reflect the response of 'primed' hypodense eosinophils in vivo to pertinent tissue ligands.

Docosahexaenoic acid, a constituent of rodent fetal serum and fish oil diets, inhibits acquisition of macrophage tumoricidal function

Macrophage (M phi) activation is deficient in the fetus and neonate, at times when the serum concentration of docosahexaenoic acid (DHA; 22:6n3) is approximately 10-fold higher than in the adult. We tested the effects of highly purified DHA on M phi activation in vitro. M phi were stimulated with rIFN-gamma plus either of two second or "triggering" signals, LPS or heat-killed Listeria monocytogenes. M phi activation was assayed as the lysis of P815 mastocytoma cells, which are resistant to TNF-alpha. DNA inhibited the activation of peritoneal M phi and the M phi line RAW264.7 in a dose-dependent manner at concentrations between 20 and 160 microM. These concentrations are found in fetal and neonatal rodent sera. Another polyunsaturated fatty acid, arachidonic acid (20:4n6), was much less inhibitory. In contrast to its profound effect on tumoricidal activation, DHA did not inhibit phagocytosis and catabolism of 125I-heat-killed Listeria monocytogenes. Increasing the rIFN-gamma or second signals reduced the inhibition of tumoricidal activation by DHA but not M phi incorporation of 14C-DHA. When the rIFN-gamma and second signals were separated in time, DHA was far more inhibitory if delivered with the triggering signal than if delivered with the rIFN-gamma. However, the incorporation of 14C-DHA was the same under these two conditions. In M phi treated with DHA during LPS stimulation, the inhibition was time-dependent, requiring more than 2 h. Although DHA inhibits cyclooxygenase activity, its inhibition of M phi activation was not reversed with the following cyclooxygenase products: PGE2, a stable TXA2 analog (U-46, 619) or a stable PGI2 analog (Iloprost). Although DHA is metabolized by lipoxygenases, the inhibition was not reversed by the lipoxygenase inhibitors 5, 8, 11, 14-eicosatetraynoic acid and nordihydroguaiaretic acid. Altogether, the data indicate that DHA, at concentrations present in fetal and neonatal sera, inhibits M phi activation and may contribute to the previously observed deficits in M phi function in the fetus and neonate.

Docosahexaenoic acid, a constituent of rodent fetal serum and fish oil diets, inhibits acquisition of macrophage tumoricidal function

Macrophage (M phi) activation is deficient in the fetus and neonate, at times when the serum concentration of docosahexaenoic acid (DHA; 22:6n3) is approximately 10-fold higher than in the adult. We tested the effects of highly purified DHA on M phi activation in vitro. M phi were stimulated with rIFN-gamma plus either of two second or "triggering" signals, LPS or heat-killed Listeria monocytogenes. M phi activation was assayed as the lysis of P815 mastocytoma cells, which are resistant to TNF-alpha. DNA inhibited the activation of peritoneal M phi and the M phi line RAW264.7 in a dose-dependent manner at concentrations between 20 and 160 microM. These concentrations are found in fetal and neonatal rodent sera. Another polyunsaturated fatty acid, arachidonic acid (20:4n6), was much less inhibitory. In contrast to its profound effect on tumoricidal activation, DHA did not inhibit phagocytosis and catabolism of 125I-heat-killed Listeria monocytogenes. Increasing the rIFN-gamma or second signals reduced the inhibition of tumoricidal activation by DHA but not M phi incorporation of 14C-DHA. When the rIFN-gamma and second signals were separated in time, DHA was far more inhibitory if delivered with the triggering signal than if delivered with the rIFN-gamma. However, the incorporation of 14C-DHA was the same under these two conditions. In M phi treated with DHA during LPS stimulation, the inhibition was time-dependent, requiring more than 2 h. Although DHA inhibits cyclooxygenase activity, its inhibition of M phi activation was not reversed with the following cyclooxygenase products: PGE2, a stable TXA2 analog (U-46, 619) or a stable PGI2 analog (Iloprost). Although DHA is metabolized by lipoxygenases, the inhibition was not reversed by the lipoxygenase inhibitors 5, 8, 11, 14-eicosatetraynoic acid and nordihydroguaiaretic acid. Altogether, the data indicate that DHA, at concentrations present in fetal and neonatal sera, inhibits M phi activation and may contribute to the previously observed deficits in M phi function in the fetus and neonate.

Identification of an aldehyde dehydrogenase in the microsomes of human polymorphonuclear leukocytes that metabolizes 20-aldehyde leukotriene B4

We have previously reported that cytochrome P-450LTB in the microsomes of human polymorphonuclear leukocytes (PMN) catalyzes three omega-oxidations of leukotriene B4 (LTB4), leading to the sequential formation of 20-OH-LTB4, 20-CHO-LTB4, and 20-COOH-LTB4 (Soberman, R.J., Sutyak, J.P., Okita, R.T., Wendelborn, D.F., Roberts, L.J., II, and Austen, K. F. (1988) J. Biol. Chem. 263, 7996-8002). The identification of the novel final intermediate, 20-CHO-LTB4, allowed direct analysis of its metabolism by PMN microsomes in the presence of adenine nucleotide cofactors. Microsomes in the presence of 100 microM NAD+ or 100 microM NADP+ converted 1.0 microM 20-CHO-LTB4 to 20-COOH-LTB4 with a Km of 2.4 +/- 0.8 microM (mean +/- S.E., n = 4) and a Vmax of 813.9 +/- 136.6 pmol.min-1.mg-1, for NAD+, as compared to 0.12 microM and 5.0 pmol.min-1.mg-1 (n = 2) for NADPH as a cofactor. The conversion of 1.0 microM of 20-CHO-LTB4 to 20-COOH-LTB4 in the presence of saturating concentrations (1.0 mM) of both NAD+ and NADP+ was not greater than the reaction in the presence of 1.0 mM of each cofactor separately, indicating that NAD+ and NADP+ were cofactors for the same enzyme. Antibody to cytochrome P-450 reductase did not inhibit the conversion of 20-CHO-LTB4 to 20-COOH-LTB4. When 1.0 microM 20-OH-LTB4 was added to microsomes in the presence of NADPH, approximately three-fourths of the product formed (63.7 +/- 5.1 pmol; mean +/- S.E., n = 3) was 20-CHO-LTB4 and approximately one-fourth (21.3 +/- 3.9 pmol; mean +/- S.E., n = 3) was 20-COOH-LTB4. In the presence of both NADPH and NAD+, only 20-COOH-LTB4 (85.5 +/- 9.9 pmol; mean +/- S.E., n = 3) was formed. PMN microsomes also contain an NADH-dependent aldehyde reductase which converts 20-CHO-LTB4 to 20-OH-LTB4, a member of the LTB4 family of molecules with biological activity. Based upon kinetic, cofactor and inhibition data, microsomal aldehyde dehydrogenase preferentially regulates the final and irreversible inactivation step in the LTB4 metabolic sequence.

The identification of a distinct export step following the biosynthesis of leukotriene C4 by human eosinophils

We have examined the requirements for the export of leukotriene C4 (LTC4) from cultured human eosinophils. To define saturability and kinetics of LTC4 export, eosinophils were interacted with leukotriene A4 (LTA4) at 37 degrees C, and the methanolic extracts of the cell-associated and extracellular compartments were then analyzed for LTC4 content by reverse phase high performance liquid chromatography with on-line monitoring of absorbance at 280 nm. When LTA4 was added at concentrations from 0 to 100 microM for 10 min at 37 degrees C, the amount of LTC4 released extracellularly became constant at an LTA4 concentration of 7.5 microM or greater even though the amount of intracellular LTC4 continued to increase. When eosinophils were incubated with 50 microM LTA4 for 0-60 min at 37 degrees C and then held at 0 degrees C for the remainder of the 60-min interval, 54.2 and 77.3% (n = 3), respectively, of the total LTC4 was released extracellularly after 15 and 30 min of incubation at 37 degrees C. Eosinophils incubated with 50 microM LTA4 at 0 degrees C for 1 h synthesized 290 pmol of LTC4 (n = 3) which was approximately half-maximal, all of which was retained intracellularly. We utilized the time and temperature dependence of LTC4 export to preload eosinophils with both LTC4 and leukotriene C5 (LTC5) by sequentially supplying them with specific substrates. With increasing concentrations of intracellular LTC5, there was dose-dependent inhibition of the subsequent release of LTC4 at 37 degrees C, with the sum of the released glutathionyl leukotrienes remaining constant. In addition, only minimal competition for LTC4 release occurred when cells were preloaded with both LTC4 and the conjugate of 1-chloro-2,4-dinitrobenzene and reduced glutathione, S-(dinitrophenyl)glutathione. The criteria of saturability, time dependence of LTC4 release at 37 degrees C, competition of LTC4 with LTC5 for release, and the inhibition of LTC4 release at 0 degrees C establish the export of LTC4 from cells as a novel and specific biochemical step distinct from both LTA4 uptake and the conjugation of LTA4 with reduced glutathione by LTC4 synthase to form LTC4.

Interleukin 5 and phenotypically altered eosinophils in the blood of patients with the idiopathic hypereosinophilic syndrome

We report that the hypodense eosinophil population in three patients with corticosteroid-unresponsive IHES was uniquely long lived ex vivo in the absence of exogenous cytokines. Serum or plasma from these patients conferred prolonged viability ex vivo to normodense eosinophils from reference donors and converted them to a functionally activated hypodense phenotype. In that antibody against IL-5 neutralized this activity in IHES serum, excessive quantities of this cytokine may account for the characteristic eosinophilia and long-lived, functionally augmented eosinophil phenotype in this disorder.