Nonredox-type 5-lipoxygenase (5-LO) inhibitors such as ZM230487 or L-739.010 potently suppress leukotriene biosynthesis at low cellular peroxide tone. Here, we show that inhibition of 5-LO product formation by nonredox-type 5-LO inhibitors in human isolated polymorphonuclear leukocytes (PMNL) depends on the activation pathway of 5-LO. Thus, compared with 5-LO product synthesis induced by the Ca2+-mobilizing agent ionophore A23187, cell stress-induced 5-LO product formation involving 5-LO kinase pathways required ~10- to 100-fold higher concentrations of ZM230487 or L-739.010 for comparable 5-LO inhibition. No such differences were observed for the iron ligand-type 5-LO inhibitor BWA4C or the novel-type 5-LO inhibitors hyperforin and 3-O-acetyl-11-keto-boswellic acid. Experiments using purified 5-LO revealed that Ca2+ is no prerequisite for potent enzyme inhibition by ZM230487, and exposure of PMNL to the combination of ionophore and cell stress did not restore potent 5-LO suppression. Intriguingly, a significant difference in the potency of nonredox-type inhibitors (but not of BWA4C) was determined between wild-type 5-LO and the mutant S271A/S663A-5-LO (lacking phosphorylation sites for ERK1/2 and MAPKAPK-2) in HeLa cells. Collectively, our data suggest that compared with Ca2+-mediated 5-LO product formation, enzyme activation involving 5-LO phosphorylation events specifically and strongly alters the susceptibility of 5-LO toward nonredox-type inhibitors in intact cells.
5-lipoxygenase (5-LO) is the key enzyme in the biosynthesis of proinflammatory leukotrienes. Here, we demonstrate that extracellular signal-regulated kinases (ERKs) can phosphorylate 5-LO in vitro. Efficient phosphorylation required the presence of unsaturated fatty acids and was abolished when Ser-663 was mutated to alanine. In intact HeLa cells stimulated with arachidonic acid (AA), impaired 5-LO product formation was evident in cells expressing the S663A-5-LO mutant compared with cells expressing wild-type 5-LO. For Mono Mac 6 cells, priming with phorbol myristate acetate (PMA) before stimulation with ionophore was required for ERK1/2 activation and efficient 5-LO phosphorylation, in parallel with substantial AA release and 5-LO product formation. Inhibition of PKC by GF109203x or MEK1/2 by U0126 (or PD98059) abolished the 5-LO up-regulation effects of PMA. In contrast, these inhibitors failed to suppress 5-LO product formation induced by stimuli such as AA plus ionophore, which apparently do not involve the ERK1/2 pathway. Based on inhibitor studies, ERKs are also involved in AA-stimulated 5-LO product formation in PMNL, whereas a role for ERKs is not apparent in 5-LO activation induced by ionophore or cell stress. Finally, the data suggest that ERKs and p38 MAPK-regulated MAPKAPKs can act in conjunction to stimulate 5-LO by phosphorylation.
We demonstrated previously that 5-lipoxygenase (5-LO), a key enzyme in leukotriene biosynthesis, can be phosphorylated by p38 MAPK-regulated MAPKAP kinases (MKs). Here we show that mutation of Ser-271 to Ala in 5-LO abolished MK2 catalyzed phosphorylation and clearly reduced phosphorylation by kinases prepared from stimulated polymorphonuclear leukocytes and Mono Mac 6 cells. Compared with heat shock protein 27 (Hsp-27), 5-LO was a weak substrate for MK2. However, the addition of unsaturated fatty acids (i.e. arachidonate 1-50 M) up-regulated phosphorylation of 5-LO, but not of Hsp-27, by active MK2 in vitro, resulting in a similar phosphorylation as for Hsp-27. 5-LO was phosphorylated also by other serine/threonine kinases recognizing the motif Arg-Xaa-Xaa-Ser (protein kinase A, Ca 2؉ /calmodulin-dependent kinase II), but these activities were not increased by fatty acids. HeLa cells expressing wild type 5-LO or S271A-5-LO, showed prominent 5-LO activity when incubated with Ca 2؉ -ionophore plus arachidonate. However, when stimulated with only exogenous arachidonic acid, activity for the S271A mutant was significantly lower as compared with wild type 5-LO. It appears that phosphorylation at Ser-271 is more important for 5-LO activity induced by a stimulus that does not prominently increase intracellular Ca 2؉ and that arachidonic acid stimulates leukotriene biosynthesis also by promoting this MK2-catalyzed phosphorylation. 5-Lipoxygenase (5-LO)1 catalyzes initial steps in formation of leukotrienes (LTs) and lipoxins, mediators and modulators of inflammatory and allergic reactions (1). In addition to phagocytes and B-lymphocytes, 5-LO was recently found also in dendritic cells, implying functions for LTs also in the adaptive part of the immune response (2, 3). Depending on the cell type, 5-LO is present in the cytosol but also in a nuclear soluble pool of resting cells. Upon cell stimulation, soluble 5-LO translocates to the nuclear membrane where it colocalizes with 5-lipoxygenase-activating protein (FLAP) and cytosolic phospholipase A 2 , and initializes the formation of LTs (for review see Ref. 4). It was recently described that an N-terminal -barrel domain of 5-LO is important for Ca 2ϩ -stimulated membrane association (5-7). It appears that phosphorylation is another determinant of cellular LT biosynthesis (8, 9); cell stimulation leading to 5-LO activity activated p38 MAPK and its downstream targets (MAPKAP kinases (MKs)), which can phosphorylate 5-LO in vitro, (10 -13). Interestingly, the p38 MAPK inhibitor SB 203580 inhibited antigen-induced LTC 4 production in sensitized mouse bone marrow-derived mast cells (14).
Nonredox type 5-lipoxygenase (5-LO) inhibitors, such as ZM 230487, its methyl analogue ZD 2138, or the Merck compound L-739,010, suppress cellular leukotriene synthesis of ionophore stimulated granulocytes with IC 50 values of about 50 nM. However, in cell homogenates or in preparations of purified enzyme, up to 150-fold higher concentrations are required for similar inhibition of 5-LO activity. This loss of 5-LO inhibition in cell homogenates was reversed by addition of glutathione or dithiothreitol, which increased the inhibitory potency of ZM 230487 or L-739,010 by about 100 to 150-fold so that 5-LO inhibition was comparable with that of intact cells. In the presence of thiols, addition of hydroperoxide [13(S)-HpODE], glutathioneperoxidase inhibition by iodacetate or selenium-deficiency lead to impaired 5-LO inhibition by ZM 230487 in cell homogenates. Moreover, addition of glutathione peroxidase was required for efficient inhibition of purified human 5-LO by ZM 230487. The data suggest that low hydroperoxide concentrations are important for efficient 5-LO inhibition by ZM 230487. The kinetic analysis revealed a noncompetitive inhibition of 5-LO by ZM 230487 at low hydroperoxide levels, whereas it acted as a competitive inhibitor with low affinity under nonreducing conditions in granulocyte homogenates. No such redox-dependent effects were observed with the 5-LO inhibitor BWA4C, the 5-LO activating protein-inhibitor MK-886 or the pentacyclic triterpene acetyl-11-keto--boswellic acid. These data suggest that physiological conditions associated with oxidative stress and increased peroxide levels lead to impaired efficacy of nonredox type 5-LO inhibitors like ZM 230487 or L-739,010. This could explain the reported lack of activity of this class of 5-LO inhibitors in chronic inflammatory processes.
B-lymphocytes express 5-lipoxygenase (5-LO) protein but cellular leukotriene production is suppressed by selenium-dependent peroxidases. Thus it was of interest to check whether reactive oxygen species (ROS) which are released under inflammatory conditions can stimulate B-lymphocyte 5-LO and counteract peroxidase-mediated suppression of cellular 5-LO activity. It was found that 5-LO in the Epstein±Barr virustransformed B-lymphocytic cell line BL41-E95-A is activated by addition of hydrogen peroxide or xanthine/ xanthine oxidase and after increasing the oxidative state of the cell by azodicarboxylic acid bis(dimethylamide). Generation of endogenous ROS from mitochondria by antimycin A also lead to a threefold upregulation of 5-LO activity in B-cells.There was almost no detectable endogenous superoxide formation in BL41-E95-A cells after stimulation with 4b-phorbol 12-myristate 13-acetate. Co-incubation experiments with BL41-E95-A cells and granulocytes demonstrated that granulocyte-derived ROS can activate B-lymphocyte 5-LO. Addition of superoxide dismutase and/or catalase to the B-lymphocyte/granulocyte co-incubations and to B-lymphocyte homogenates revealed that the 5-LO activation is due to the superoxide-derived release of hydroperoxides or hydrogen peroxide from granulocytes.The data suggest that ROS formation plays an important role in the regulation of cellular 5-LO activity in B-lymphocytes. As leukotrienes affect B-cell functions like cell proliferation, activation and maturation, this finding provides a new link between the formation of ROS and the regulation of immune responses.Keywords: B-lymphocytes; inflammation; lipid mediators; cellular activation. 5-Lipoxygenase (5-LO) catalyzes the two initial steps in leukotriene biosynthesis from arachidonic acid (AA) [1]. In crude cell homogenates, the activity of the enzyme depends on Ca 2+ and ATP [2,3]. In intact cells, 5-LO requires the presence of the membrane-bound 5-LO activating protein for leukotriene synthesis [4]. It has been shown that the enzyme activity is further regulated by the cellular redox status [5] and that a threshold level of hydroperoxides is required for the activation of the enzyme [6].In vitro, 5-LO is activated under conditions that promote lipid peroxidation [7] (e.g. by increasing the levels of hydroperoxides via depletion of glutathione [8,9] or selenium [10]). Recently, we could show that selenium-dependent peroxidases are responsible for suppression of 5-LO activity in B-lymphocytes and immature myeloid cells, and that differentiation of the myeloid cell lines HL-60 and Mono Mac 6 in the presence of transforming growth factor beta and calcitriol upregulates cellular leukotriene synthesis by the induction of peroxidase-insensitive 5-LO catalytic activity [11].Reactive oxygen species (ROS), such as hydrogen peroxide and superoxide, are generated in the cell by several pathways. In mitochondria, ROS arise from the univalent reduction of oxygen, where 1±2% of the reduced oxygen is converted to superoxide. Superoxide is also gener...
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