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Leukotrienes (LTs) are pro-inflammatory lipid mediators that belong to the group of eicosanoids, which are oxygenated metabolites of one common precursor, the aracidonic acid (AA). This polyunsaturated fatty acid is esterified at the sn-2 position of cellular membrane phospholipids and can be released by cytosolic phospholipase A2 alpha (cPLA2alpha) enzymatic deacylation. AA can be converted into LTs by the catalytic reaction of 5-lipoxygenase (5-LO). Enzymatic activation of cPLA2alpha as well as of 5-LO is regulated by similar determinants. In response to cellular stimuli that elevate the intracellular Ca2+ level and/or activate MAP kinase pathways, cPLA2alpha and 5-LO comigrate from a soluble cell compartment (mainly the cytosol) to the nuclear membrane, where AA is released und converted into LTs. LTs play a significant role in promoting inflammatory reactions and immune processes. They have been shown to be released from leukocytes in response to bacterial and viral infections and substantially contribute to an effective immune reaction for host defense. Innate immune pathogen recognition is mediated to a substantial part by the Toll-like receptor (TLR) family. So far, 10 human TLR subtypes have been identified, all of which detect distinct highly conserved microbial structures and trigger the induction of signaling pathways that lead to the expression of numerous immune and inflammatory genes. TLR signaling culminates in the activation NF-kappaB and/or MAP kinases, which as well are known to be involved in the regulation of cellular LT biosynthesis. In this regard, it seemed conceivable that the release of LTs might be regulated by TLR activation. Present studies were undertaken in order to verify and characterize a possible influence of TLR activation on the LT biosynthesis, and furthermore to identify the involved signaling pathways and underlying mechanisms. First experiments revealed that pre-incubation of differentiated Mono Mac 6 (MM6) cells with a TLR4 ligand, a TLR5 ligand, as well as with different TLR2 ligands led to an about 2-fold enhancement of Ca2+ ionophore induced LT biosynthesis. Ligands of other TLR subtypes did not show any influence. These observations could also be confirmed in primary human monocytes stimulated with ionophore or fMLP. With focus on TLR2 ligands, further studies were carried out to characterize the observed enhancement of LT biosynthesis in MM6 cells. It was demonstrated that the extent of LT formation was dependent on the ligand concentration used, but was also dependent on the duration of pre-incubation. Ligand pre-incubation of 15 minutes was optimal to maximally enhance LT formation and further prolongation of pre-incubation decreased LT formation again. Moreover, simultaneous addition of TLR2 ligands with ionophore did also not enhance LT formation. These results indicated that TLR2 ligands seemed to prime human monocytes for an enhanced response upon ionophore stimulation, but did not act as costimuli, which per se were not capable of directly stimulating the biosynthesis of LTs. To analyze the underlying mechanism, the impact of TLR2 ligands on the two key enzymes of the LT biosynthesis pathway, cPLA2alpha and 5-LO, was investigated. In this regard, 5-LO could not been shown to be positively regulated by TLR ligand priming. Neither a direct stimulation, nor an enhancement of 5-LO activity by TLR ligands was detectable in MM6 cells. Similarly, TLR2 ligands did also not enhance ionophore induced 5-LO translocation to the nuclear membrane. However, it was shown that TLR2 ligands enhanced ionophore induced release of AA in MM6 cells, which occurred with a similar time course as LT formation, displaying a maximum at 10 minutes of pre-incubation. A direct stimulation of AA release, however, could not been detected. Inhibitor studies revealed cPLA2alpha to be essential for AA release in TLR2 ligand primed, ionophore stimulated MM6 cells, but also sPLA2 was found to be involved. However, the priming effect of TLR2 ligands was mediated exclusively by cPLA2alpha. Western Blot analyses revealed that p38 MAP kinase, as well as ERK1/2, are activated in MM6 cells in response to TLR2 ligands, and also Ser-505 phosphorylation of cPLA2alpha was detected, which is known to be mediated by MAP kinases and to increase cPLA2alpha activity in vitro. Maximal cPLA2alpha phosphorylation occurred after 5-10 minutes of TLR2 ligand incubation, slightly preceding maximal AA release at 10 minutes and maximal LT formation at 15 minutes of priming. The combined use of a specific p38 MAPK inhibitor with an inhibitor of the ERK1/2 signaling pathway resulted in a complete prevention of cPLA2alpha phosphorylation and TLR2 ligand mediated enhancement of AA release. Thus, both MAPK pathways seem to play a role for TLR2 ligand mediated priming effects on the release of AA. An impact of other kinases such as Mnk-1 and CamKII, which can also regulate cPLA2alpha by phosphorylation, was excluded. Finally, an anti-hTLR2 antibody significantly reduced enhanced AA release, confirming the priming effects to be dependent on TLR2 activation. In summary, it was concluded that the increase of LT biosynthesis by TLR2 ligand priming is considerably due to an enhanced cellular AA supply, which arises from a MAPK mediated phosphorylation and up-regulation of cPLA2alpha. TLR dependent enhancement of LT biosynthesis represents an interesting link between activation of innate immune receptors and the rapid formation of pro-inflammatory lipid mediators. On the one hand, this support the role of LTs in host defence and infectious diseases, but may also be relevant in pathophysiological processes, which involve TLRs as well as LTs, as it has been shown for the pathogenesis of atherosclerosis or allergic diseases.
IL-12-related cytokines produced by dendritic cells are considered to be major inducers of adaptive immune system activation upon innate antigen-sensing. IL-23 specifically is currently being discussed to support the differentiation of potentially auto-aggressive Th17 cells. Prostaglandins as bystander cell products are known to modulate the translation of this process. While previous studies focused therefore on IL-12, ignoring the existence of new IL-12-related cytokines IL-23 and IL-27, this study analysed effects of prostaglandin E2, D2 and 15d-PGJ2 on the secretion pattern of these subunits in the murine immature Langerhans cell line XS52 and the murine immature myeloid dendritic cell line JawsII under TLR4 (LPS) and TLR9 (CpG) stimulation as well as effects of prostaglandins on the murine Th1 cell line IF12 in coculture and upon Con A treatment. In serial semi-quantitative RT-PCR of the IL-12 related cytokines of the XS52 cell line and the JawsII cell line, the p40 subunit was upregulated in both DC cell lines upon TLR-stimulation, the IL-23p19 subunit constantly expressed in XS52 and upregulated in JawsII upon TLR-stimulation, while the IL-27p28 subunit was only weekly expressed under additional stimulating aCD40 Ab treatment. IL-12p35 could only be detected in the immature myeloid cell line. The protein expression of the p40 subunit was measured in Western blot assays following SDS-PAGE under reducing conditions in XS52. The Western blot-based antibody specification allowed the establishment of a p40-specific ELISPOT assays, where overadditive upregulation of the number of LPS-stimulated spot forming XS52 cells was observed under stimulation with PGE2 while PGD2 depressed the number of LPS-stimulated cytokine secreting cells. Contrary IL-12p40 could not be detected in supernatants of the JawsII cell line. Both DC cell lines were further tested for differential response towards different TLR stimulation described as a defining feature of DC subsets. While subunit expression on transcription level did not differ, only LPS-treatment led to constant IL-12p40 expression in supernatants of XS52. CpG-treatment of XS52 cells led to constantly high IL-12p40 levels under additional aCD40 Ab treatment. In IFN-g ELISPOT assays, prostaglandin effects were further analysed in IF12 Th1 cells upon Con A treatment or alternatively upon treatment in a coculture model with the syngeneic cell line XS52 and the T lymphocyte-specific protein ovalbumin. While PGE2 depressed the amount of activated Th1, PGD2 showed no effect. In conclusion, a coculture model has been generated that allows the analysis of DC and TC interactions. The importance of prostaglandins as differential regulators in time- and tissue-dependence in inflammatory processes has been demonstrated. These results accord with recent observations of an upregulation of IL-23 secretion upon PGE2 treatment.