Abstract

Platelets are well known for their role in hemostasis and are also increasingly recognized for their roles in the innate immune system during inflammation and their regulation of macrophage activation. Here, we aimed to study the influence of platelets on the production of inflammatory mediators by monocytes and macrophages. Analyzing cocultures of platelets and murine bone marrow-derived macrophages or human monocytes, we found that collagen-activated platelets release high amounts of prostaglandin E₂ (PGE₂) that leads to an increased interleukin- (IL-) 10 release and a decreased tumor necrosis factor (TNF) α secretion out of the monocytes or macrophages. Platelet PGE₂ mediated the upregulation of IL-10 in both cell types via the PGE₂ receptor EP2. Notably, PGE₂-mediated IL-10 synthesis was also mediated by EP4 in murine macrophages. Inhibition of TNFα synthesis via EP2 and EP4, but not EP1, was mediated by IL-10, since blockade of the IL-10 receptor abolished the inhibitory effect of both receptors on TNFα release. This platelet-mediated cross-regulation between PGE₂ and cytokines reveals one mechanism how monocytes and macrophages can attenuate excessive inflammatory responses induced by activated platelets in order to limit inflammatory processes.

1. Introduction

Platelets are no longer solely seen as key players in thrombosis and hemostasis. Within the past few years, novel roles of platelets in the fields of wound healing, immune defense, and inflammation have been described [1, 2]. At sites of injuries or infections, platelets are the first cells to be recruited to the vascular endothelium. There they interact with various cell types, including monocytes, neutrophils, and endothelial cells, and, thereby, regulate cellular adhesion and extravasation [3, 4]. Most platelet functions and their interactions with other cell types are restricted to events taking place within the blood vessels. Recently, we found that platelets colocalize with macrophages outside of the blood vessels in several models for cutaneous inflammation and suppress the expression of anti-inflammatory markers and enhance the synthesis of proinflammatory mediators in the associated macrophages [5]. Monocytes in the bloodstream and macrophages in tissues play central roles in various immunological reactions. When activated, these cells synthesize and release a large amount of proinflammatory cytokines and chemokines [6] but are also known to regulate inflammation by producing anti-inflammatory mediators, like IL-10 [7–9]. Platelets are known to induce contrasting answers in macrophages in regard to pro- and anti-inflammatory phenotypes, depending on the underlying pathology, site of inflammation, and experimental model employed [2]. For example, thrombin-activated platelets have been reported to bind to circulating monocytes, thereby inducing the production of proinflammatory cytokines by those cells and thus promoting a proinflammatory phenotype [2, 10] and to increase cytokine and chemokine synthesis in macrophages [11–13]. Depending on the experimental setting, microparticles released from platelets can either enhance proinflammatory effects of macrophages [14, 15] or inhibit proinflammatory cytokine/chemokine secretion [16, 17]. The mechanisms by which platelets and platelet-derived microparticles modulate monocyte or macrophage activity are not fully understood but seem to depend in part on a direct interaction, possibly mediated by adhesion receptors such as CD62P (P-selectin), and in part on the release of soluble factors from platelets [18–20]. Notably, platelets store in granules a wide variety of signaling factors (e.g., mitogenic and angiogenic factors, chemokines (i.e., CXCL4), serotonin, histamine, nucleotides, and proteases), which are released upon platelet activation and have the potential to induce or to modulate proinflammatory responses of macrophages [21]. In addition, platelets are able to synthesize lipid mediators like thromboxane A2 (TXA2) [5, 22, 23] or PGE₂ [24, 25] upon activation. Furthermore, platelets have been shown to convert human peripheral blood circulating monocytes to IL-10-producing regulatory monocytes [26]. The anti-inflammatory cytokine IL-10, which exerts its effects via binding to the IL-10 receptor (IL-10 R), is known to control the inflammatory process by suppressing the production of proinflammatory cytokines such as tumor necrosis factor alpha (TNFα) in monocytes/macrophages [27]. It has been shown that activated platelets enhance IL-10 secretion and reduce TNFα secretion by monocytes in order to counteract exaggerated proinflammatory immune responses in vivo [28]. In addition, platelet-rich plasma (PRP) has a strong anti-inflammatory capacity based on the suppression of the synthesis of TNFα [29]. In macrophages, the production of IL-10 has been shown to be upregulated by the PGE₂, another major product of monocytes/macrophages [30], which is also formed and released by platelets [24, 25]. PGE₂ exerts its effects by four specific cell membrane-associated G protein-coupled receptors, termed EP1, EP2, EP3, and EP4_, which differ in their signal transduction pathways [31]. While in bone marrow dendritic cells (BM-DCs), most effects of PGE₂ are mediated via EP2 and EP4 stimulate the production of IL-10 [32]; the involved receptors in monocytes/macrophages are not known. Thus, platelet-induced intracellular signaling in monocytes or macrophages is highly complex and only incompletely understood. Here, we observed that platelets release PGE₂ after activation with collagen, leading to an increased release of IL-10 from murine macrophages as well as human monocytes, which in turn suppress TNFα. Moreover, we identified the receptors, by which PGE₂ mediates the upregulation of IL-10 and the suppression of TNFα in monocytes/macrophages. In murine macrophages, the EP2 and EP4 receptors were proven to mediate the multi-cytokine-modulating effect of PGE₂, whereas in human monocytes solely, the EP2 receptors are involved. The TNFα-decreasing effect induced by activation of EP1 was demonstrably uncoupled from IL-10 and mediated via a separate pathway.

2. Methods

2.1. Animals

C57BL/6N mice were supplied by JANVIER LABS (Le Genest-Saint-Isle, France). COX-1-, EP2-, and EP4-deficient mice were described previously [33–35]. In all experiments, the Ethics guidelines of the Public Health Services for investigations in conscious animals were obeyed and the procedures were approved by the local Ethics Committee.

2.2. Reagents

Refludan was obtained from Pharmion (Berlin, Germany). Horm collagen was purchased from Takeda Austria GmbH (Linz, Austria). mCSF was obtained from PeproTech (Hamburg, Germany). Mouse IL-10 Rα antibody was purchased from R&D Systems (Minneapolis, USA). EP receptor-specific ligands (EP2 agonist butaprost (free acid), EP3 agonist sulprostone, and EP4 agonist L-902,688) were purchased from Cayman Chemical (Michigan, USA). EP1 agonist ONO-Di-004 was kindly provided by Dr. Maruyama (ONO Pharmaceuticals, Sekurei, Japan).

2.3. Prostanoid Measurement

Analysis of prostanoids was performed using liquid chromatography-electrospray ionization-tandem mass spectrometry (LC-ESI-MS/MS). The LC-MS/MS system consisted of a hybrid triple quadrupole linear ion trap mass spectrometer 5500 QTRAP (SCIEX, Darmstadt, Germany) equipped with a Turbo-V-source operating in negative ESI mode, an Agilent 1200 binary pump, a degasser (Agilent, Waldbronn, Germany), and an HTC Pal autosampler (Chromtech, Idstein, Germany). Data acquisition was done using Analyt V 1.6.2.

For the analysis of prostanoids, the supernatant samples were spiked with the respective isotopically labeled internal standards; mixed with 200 μl PBS, 100 μl EDTA solution (0.15 M), and 600 μl ethyl acetate; and vortexed. The organic phase was removed, and the extraction repeated with 600 μl ethyl acetate. The organic fractions were combined and evaporated at a temperature of 45°C under a gentle stream of nitrogen. The residues were reconstituted with 50 μl of acetonitrile/water/formic acid (20 : 80 : 0.0025, v/v) in glass vials. The chromatographic separation was carried out using a Synergi Hydro-RP column (150 × 2 mm I.D., 4 μm particle size, and 80 Å pore size from Phenomenex, Aschaffenburg, Germany). A linear gradient was employed at a flow rate of 300 μl/min. The mobile phase A was water/formic acid (100 : 0.0025, v/v) and mobile phase B was acetonitrile/formic acid (100 : 0.0025, v/v). The total run time was 16 min and injection volume 20 μl. Retention times of 6-keto-PGF_1α, TXB₂, PGF_2α, PGE₂, and PGD₂ were 7.2 min, 7.8 min, 8.1 min, 8.5 min, and 8.9 min, respectively. The precursor-to-product ion transitions used for quantification were m/z 351.1 → m/z 315.0 for PGE₂ and PGD₂, m/z 353.1 → m/z 291.0 for PGF_2α, m/z 369.1 → m/z 162.9 for 6-keto-PGF_1α, and m/z 369.1 → m/z 169.1 for TXB₂. The dwell time was set at 50 ms for all transitions. Calibration curves were constructed by plotting the corrected analyte areas versus the corresponding nominal analyte concentrations and performing a quadratic regression with 1/x² weighting.

2.4. Cytokine Determination in Cell Culture Medium and Cell Lysate

TNFα and IL-10 were measured by ELISA kits from R&D Systems (Minneapolis, USA) according to the manufacturer’s protocol. For cell lysis, cells were scraped, washed once with 1x PBS, and sonicated in 100 μl assay buffer. After centrifugation (10,000 ×g) for 3 min at RT, cytokine levels were determined in the supernatant.

2.5. Preparation of Murine Platelets

Murine blood was diluted in 0.106 mol/l tri-sodium citrate solution (1 : 10) and platelet-rich plasma (PRP) was generated by centrifugation (300 ×g, 5 min, RT). PRP was centrifuged for 30 min at 1300 and the pellet was resuspended in HBSS with Ca²⁺ and Mg²⁺ (Life Technologies) containing 10% citrate buffer (38 mM citrate, 88 mM sodium citrate) and modified Tyrode’s buffer 1 (137 mM sodium chloride, 2.7 mM potassium chloride, 10 mM Hepes [N-2-hydroxyethylpiperazine-N0-2-ethanesulfonic acid], 0.36 mM sodium dihydrogen phosphate, 5.5 mM dextrose, pH 6.4) supplemented with 1 U/ml refludan. Platelets were resuspended in HBSS/citrate and FCS-free RPMI medium. Collagen I (3 ng/ml) was used for platelet activation.

2.6. Preparation of Murine Bone Marrow-Derived Macrophages

Bone marrow-derived macrophages were generated as follows. The femur and tibia of the hind legs from adult mice were extracted from the muscle tissue. Bone ends were cut and bone marrow cells were extracted by centrifugation with 10,000 ×g for 10 seconds. The cells were differentiated in RPMI1640 with L-glutamine (Life Technologies), 10% FCS, 100 U/ml penicillin, and 100 μg/ml streptomycin and 20 ng/ml mCSF (PeproTech, Hamburg, Germany) for 7 days on 24 well-plates (Greiner Bio-One) Prior to their use, the platelets were incubated for 10 min at room temperature in 8 mM citrate and 88 mM sodium citrate in HBSS, with either 3 ng/ml collagen for activation. 400 μl of this medium containing 30 mio/ml platelets was added to the attached macrophages and incubated for 3 hours at 5% CO₂ and 37°C in the incubator.

2.7. Isolation of Human Platelets and Monocytes

Human platelets and monocytes were isolated using buffy coats, blood samples which are already enriched with white blood cells, and platelets. The blood was centrifuged at 120 ×g to obtain PRP (platelet-rich plasma). After the PRP supernatant was transferred into a clean conical centrifugation tube, PRP was supplemented with 111 ml ACD-A. After collecting the platelets by centrifugation at 750 ×g for 10 minutes, the resulting platelet pellet was resuspended in modified Tyrode’s buffer 1 (137 mM sodium chloride, 2.7 mM potassium chloride, 10 mM Hepes [N-2-hydroxyethylpiperazine-N0-2-ethanesulfonic acid], 0.36 mM sodium dihydrogen phosphate, 5.5 mM dextrose, pH 6.4) supplemented with 1 U/ml refludan. Platelets were resuspended in a modified Tyrode’s buffer 2 (same composition as the modified Tyrode’s buffer 1 with additional 2 mM calcium chloride, 2 mM magnesium chloride, and 0.02 U/ml apyrase; pH 7.4).

The remaining blood is layered on to Histopaque-1077 (Sigma-Aldrich) and centrifuged without break at 400 ×g for 30 minutes at room temperature. The upper layer was discarded and the interface containing mononuclear cells was transferred into a clean conical centrifugation tube. The cells were washed by adding 40 ml isotonic phosphate buffer. After centrifugation at 250 ×g for 3 minutes, the supernatant was discarded and remaining erythrocytes were lysed dissolving the cell pellet in 5 ml of erythrocyte lysis buffer (155 mM NH4Cl, 10 mM KHCO3, 0.1 mM Na-EDTA, pH 7.2) for 4 min at RT. Residual cells were collected by centrifugation (250 ×g, 3 min) and resuspended in buffer (phosphate-buffered saline (PBS), pH 7.2, 0.5% bovine serum albumin (BSA), 2 mM EDTA). Human monocytes were isolated as follows. 2 mio/ml of peripheral blood mononuclear cells were plated on 24 well-plates (Greiner Bio-One) in an appropriate amount of prewarmed Monocyte Attachment Medium from PromoCell (Heidelberg, Germany) and incubated for 45 minutes at 5% CO₂ and 37°C in the incubator. After aspirating the supernatant, the attached monocytes were washed twice with 1x PBS. 400 μl of Monocyte Base Medium from PromoCell, containing 200 mio/ml platelets was added to the attached monocytes and incubated for 3 hours at 5% CO₂ and 37°C in the incubator. Amounts of prostaglandins were measured using cell culture supernatants and obtained by centrifugation (250 ×g, 3 min).

2.8. Statistics

Experiments with two treatment groups were analyzed using Student’s t-test. Experiments with more than two groups were analyzed using ANOVA followed by post hoc tests. Significance was accepted at .

3. Results

3.1. Collagen-Activated Platelets Selectively Regulate the Synthesis of IL-10 and TNFα in Cocultures with Murine Macrophages

Since it has been previously described that thrombin receptor agonist peptide- (TRAP-) activated platelets enhance IL-10 secretion and reduce TNFα secretion by monocytes [28], we investigated whether activation with collagen exerts the same effects. Therefore, we incubated murine bone marrow-derived macrophages (BMDM) alone, with untreated platelets, or with collagen-activated platelets and determined the effect of the platelets on the cytokine release. In control experiments, no IL-10 and TNFα could be detected in supernatants of untreated as well as collagen-activated platelets (data not shown). The release of IL-10 and TNFα was only observed in cocultures with macrophages. We found that collagen-activated platelets induced a 2.82-fold stronger increase of extracellular IL-10 than untreated platelets in cocultures with BMDM (Figure 1(a)). In contrast to IL-10, both untreated and, to a lesser extent, collagen-activated platelets upregulated the secretion of TNFα (Figure 1(b)). To show that there is no relevant number of unstimulated platelets which are getting activated during the coincubation with macrophages, we have performed the coincubation with murine macrophages employing untreated as well as BAPTA-AM-inactivated platelets. In both cases, similar amounts of TNFα (Figure 1(b)/supplementary data available online at https://doi.org/10.1155/2017/1463216) were seen. To analyze the direct influence of IL-10 on the platelet-induced release of TNFα, cocultures of murine BMDM and untreated platelets were incubated with murine IL-10 (125 pg/ml) and the TNFα concentration in the medium was determined after 3 hours. IL-10 completely blocked the platelet-induced release of TNFα from murine macrophages (Figure 1(c)). Thus, we demonstrated that collagen-activated platelets enhance IL-10 secretion which in turn mediates the reduction of TNFα-secretion by murine BMDMs.

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Figure 1 

Collagen-activated platelets selectively regulate the synthesis of IL-10 and TNFα in cocultures with murine macrophages. (a), (b) Murine bone marrow-derived macrophages (BMDM) were incubated alone, with untreated platelets (untreated PLTs) or with platelets prestimulated with collagen (1 μg/ml; act. PLTs) for 3 hours and the concentrations of IL-10 and TNFα were determined by ELISA. (c) Murine BMDM were incubated with untreated platelets with or without murine IL-10 (125 pg/ml). TNFα levels were determined in the medium. Data are presented as mean ± SEM from 4 experiments. One-way ANOVA/Bonferroni , , , .

3.2. Cross-Regulation of PGE₂ and TNFα through an Induction of IL-10 by Platelet-Derived PGE₂

In macrophages, the production of IL-10 has been shown to be upregulated by the prostaglandin PGE₂, another major product of monocytes/macrophages [30], which is also formed and released by platelets [24, 25]. In cocultures of platelets and murine BMDMs, we observed that collagen-activated platelets induced a stronger PGE₂ release than untreated platelets (Figure 2(a)). In order to elucidate a possible cross-regulation of TNFα and PGE₂, we determined whether exogenous PGE₂ can decrease the release of TNFα from platelet-stimulated murine macrophages. Therefore, we coincubated murine BMDM with untreated platelets, causing a strong TNFα release (505 ± 55 pg/ml) released from the macrophages (Figure 2(b)). However, coincubation with PGE₂ (1 μM) completely abolished the platelet-induced TNFα secretion. To study whether or not the blockage of the platelet-induced TNFα release by PGE₂ is due to an inhibition of intracellular TNFα production, we analyzed the concentrations of TNFα in cell lysates of murine BMDMs preincubated with untreated platelets (Supplementary data ). We found that PGE₂ nearly completely abrogated the platelet-induced accumulation of intracellular TNFα in murine macrophages from 263 ± 55.5 pg/ml down to 33.6 pg/ml.

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Figure 2 

Cross-regulation of PGE₂ and TNFα through an induction of IL-10 in murine macrophages by platelet derived PGE₂. (a) Murine BMDM were incubated alone, with untreated platelets, or with collagen-activated platelets for 3 hours. (b), (c) Murine BMDM were incubated with untreated platelets with or without PGE₂ (1 μM) for 3 hours. (d) Murine platelets were incubated with or without collagen (1 μg/ml) for 30 minutes. (e), (f) BMDM from wild-type mice (b) or COX-1-deficient mice (c) were coincubated with BAPTA-AM-inactivated platelets (30 μM) or with collagen-activated platelets isolated from wild-type and COX-1-deficient mice for 3 hours. The concentrations of PGE₂ in the medium were determined by LC-MS/MS. IL-10 levels and TNFα levels in the medium were determined by ELISA. Data are presented as mean ± SEM from 4 experiments. One-way ANOVA/Bonferroni , , , .

For certain cell types, a cross-regulation of PGE₂ and TNFα [36, 37] through an induction of IL-10 by PGE₂ is reported [32, 38]. To investigate whether the observed IL-10 upregulation can be mediated via PGE₂, we treated a coculture of untreated platelets and BMDMs with exogenous PGE₂ (1 μM). We found that the application of PGE₂ leads to a 7.7-fold higher release of IL-10 (Figure 2(c)), implicating an interaction between PGE₂ and IL-10 signaling, both increasingly released in cocultures of murine macrophages and activated platelets.

Due to the fact that PGE₂ can be generated and released by platelets [24, 25] as well as monocytes/macrophages [36], we verified the origin of PGE₂ in our in vitro model system. Therefore, we first determined the amounts of PGE₂ within supernatants of platelets in response to collagen activation. Collagen treatments caused a significant release of PGE₂ from the isolated platelets (Figure 2(d)), revealing that activated platelets are indeed capable to provide high amounts of PGE₂. The generation of PGE₂ in platelets is catalyzed solely by the cyclooxygenase-1 (COX-1) isoform, whereas within monocytes/macrophages, a second isoform named COX-2 can lead to the production of PGE₂ during inflammatory settings [39]. Thus, we used COX-1-deficient platelets to identify the origin of extracellular PGE₂ in the cocultures of platelets and BMDM. We incubated bone marrow-derived macrophages from wild-type mice (Figure 2(e)) or COX-1-deficient mice (Figure 2(f)) with BAPTA-AM-inactivated platelets or with collagen-activated platelets isolated from wild-type and COX-1-deficient mice and determined the concentrations of PGE₂. In both wild-type and COX-1-BMDM cocultures, only collagen-activated wild-type platelets led to an increased level of PGE₂, demonstrating that platelets are the source of PGE_2, due to the fact that COX-1-deficient platelets are not capable of building any PGE₂.

In conclusion, these results suggest that PGE₂ released from collagen-activated platelets leads to the release of IL-10 from murine macrophages which in turn suppresses the intracellular accumulation and the release of TNFα.

3.3. EP2 and EP4 Receptors Induce IL-10 Release from Murine Macrophages in Response to Activated Platelets

The effects of PGE₂ on monocytes/macrophages are exerted by four subtypes of specific G protein-coupled receptors on their plasma membranes (EP1, EP2, EP3, and EP4) [32]. In order to examine which EP receptor is mediating the suppression of TNFα by PGE₂, we generated cocultures of BMDM and untreated platelets and treated them with the EP agonists for 3 h (Figure 3(a)). For all EP agonists, several different concentrations were tested (data not shown) and concentrations 10 times higher than the EC₅₀ value indicated by the provider were used in the following experiments. Treatment of BMDM cultures with untreated platelets increased the TNFα concentration in the cell culture medium from undetectable levels to 441 ± 78 pg/ml () (Figure 3(a)). The EP1 agonist ONO-Di-004 (400 nM) and the EP2 agonist butaprost (170 nM) almost completely inhibited platelet-induced TNFα release similar to the actions of PGE₂. The EP4 agonist L-902,688 (5 nM) showed the same effect but to a lesser extent. In contrast, 10 nM of the EP3 agonist sulprostone (K_i 0.6 nM) exhibited no effect on the TNFα release, which was not surprising because former reports already described the absence of an effect of sulprostone on IL-10 secretion from bone marrow cells [40, 41]. Thus, PGE₂ seems to suppress platelet-induced TNFα in murine macrophages via its receptors EP1, EP2, and EP4.

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Figure 3 

Influence of EP receptor agonists on the release of TNFα and IL-10 from platelet-stimulated murine macrophages. Murine BMDM were incubated alone or with untreated platelets and the respective EP agonist concentrations for 3 hours (400 nM ONO-Di-004, 170 nM butaprost, 10 nM sulprostone, 5 nM L-902,688, 1 μM PGE₂). TNFα (a) or IL-10 (b) were determined by ELISA. Data are presented as mean ± SEM from 4 experiments. One-way ANOVA/Bonferroni , , , .

To study whether or not these three EP receptors also induce an IL-10 release, we determined the extracellular IL-10 levels from the same cocultivated cells. Unstimulated BMDM exhibited no detectable IL-10 level, whereas the coincubation with untreated platelets only slightly elevated IL-10 in cell supernatants after 3 h up to 34.8 ± 8.3 pg/ml, while PGE₂ (1 μM) increased the IL-10 production in macrophages to 270 ± 24.5 pg/ml. The EP2 agonist butaprost and the EP4 agonist L-902,688 were nearly as potent as PGE₂ in increasing IL-10. In contrast, neither the EP1 agonist ONO-Di-004 nor the EP3 agonist sulprostone increased the IL-10 release. Thus, the suppression of TNFα by PGE₂-induced IL-10 release in murine macrophages in response to activated platelets seems to be mediated via EP2 and EP4 receptors, while EP1 activation reduces TNFα via a different pathway.

3.4. EP2 and EP4 Decrease TNFα through IL-10 and Its Receptor IL-10 R

To examine whether or not PGE₂ is mediating the inhibition of TNFα via IL-10 R, we incubated murine BMDM with untreated platelets and the different EP agonists with or without adding the murine IL-10 Rα antibody (9 μg/ml). As shown before, untreated platelets caused a significant increase in TNFα release from murine macrophages after 3 h, while the EP1 agonist ONO-Di-004, the EP2 agonist butaprost, and the EP4 agonist L-902,688 decreased the TNFα release (Figure 4). Importantly, the neutralizing antibody IL-10 Rα could not reverse the decrease in TNFα levels caused by the EP1 receptor agonist ONO-Di-004 but the TNFα-decreasing effects of butaprost (60.6%) and L-902,688 (65.5%). Thus, the data show that activated platelets release PGE₂, which increases the synthesis of IL-10 in murine macrophages via EP2 and EP4, and IL-10 then again suppresses TNFα synthesis.

Figure 4 

EP2 and EP4 decrease TNFα through IL-10 and its receptor IL-10 R. Murine BMDM were incubated alone or with untreated platelets ± IL-10 Rα antibody (9 μg/ml) 30 minutes before the application of the respective EP agonist concentrations for 3 hours (40 nM ONO-Di-004, 100 nM butaprost, 5 nM L-902,688, 30 nM PGE₂). TNFα was determined by ELISA. Data are presented as mean ± SEM from 4 preparations. One-way ANOVA/Bonferroni , , .

3.5. Ex Vivo Validation of the Cross-Regulation between Platelet PGE₂ and Macrophage IL-10 and TNFα

To examine the impact of the absence of EP2 or EP4 on the observed cross-regulation, we determined the amounts of PGE₂, TNFα, and IL-10 in supernatants of BMDM from wild-type, EP2-deficient, and EP4-deficient mice, which were coincubated for 3 hours with untreated or collagen-activated wild-type platelets. In each type of coculture, wild-type platelets released PGE₂ in response to collagen (Figure 5(a)). Similar to wild-type macrophages, EP2-deficient as well as EP4-deficient macrophages react towards platelet PGE₂ with an increased release of IL-10 (Figure 5(b)) and a suppression of TNFα (Figure 5(c)). In conclusion, the ex vivo data suggest that the genetic deletion of either the EP2 or the EP4 receptor subtypes can be compensated by the other receptor. For that reason, EP2- and EP4-deficient mice are not a suitable model for the analysis of the in vivo impact of the observed cross-regulation.

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Figure 5 

Ex vivo validation of the cross-regulation between platelet PGE₂ and IL-10 and TNFα released from EP2- and EP4-deficient macrophages. Murine BMDM from wild-type, EP2-deficient, and EP4-deficient mice were incubated alone, with untreated platelets (untreated PLTs) or with platelets prestimulated with collagen (1 μg/ml; act. PLTs) for 3 hours. The concentrations of PGE₂ (a) were determined by LC-MS/MS. IL-10 levels (b) and TNFα levels (c) were determined by ELISA. One-way ANOVA/Bonferroni , , , , ^#< 0.00008.

3.6. PGE₂ Mediates Inhibition of TNFα Release from Platelet-Stimulated Human Monocytes

To determine whether human monocytes respond to platelets similar to murine macrophages, we isolated peripheral mononuclear cells out of human blood and let the monocytes attach on cell culture plates. After 3 hours of culture, the supernatants were collected and assayed with PGE₂, TNFα, and IL-10 in the medium. We found that collagen-activated platelets induced a strong PGE₂ increase in medium (Figure 6(a)), which leads to a decreased TNFα release (Figure 6(b)) and a significant upregulation of IL-10 (Figure 6(c)). Thus, human monocytes showed the same correlation between PGE₂, IL-10, and TNFα in response to platelets as observed for murine macrophages. TNFα produced by human monocytes in the presence of untreated platelets was significantly decreased by the application of exogenous PGE₂ (Figure 6(d)) which in turn increased the amount of IL-10 (Figure 6(e)). To analyze the direct influence of IL-10 on the platelet-induced release of TNFα, we incubated the coculture of human monocytes and untreated platelets with human IL-10 (125 pg/ml) and determined the concentration of TNFα in the supernatant after 3 hours. IL-10 was able to attenuate the platelet-induced release of TNFα out of human monocytes (Figure 6(f)). Thus, as seen in murine macrophages, activated platelets release high amounts of PGE₂ leading to an increased release of IL-10.

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Figure 6 

PGE₂ mediates inhibition of TNFα release from platelet-stimulated human monocytes. (a), (b), (c) Human monocytes were incubated alone, with untreated human platelets or with collagen-activated human platelets for 3 hours and PGE₂ (a), TNFα (b), or IL-10 (c) were determined. (d), (e) Human monocytes were incubated alone or with untreated platelets with or without PGE₂ (1 μM). (f) Human monocytes were incubated with untreated platelets with or without human IL-10 (125 pg/ml). The concentrations of PGE₂, TNFα, and IL-10 within the cell-free supernatants were determined by LC-MS/MS or rather ELISA within cell-free supernatants. Data are presented as mean ± SEM from 4 experiments. One-way ANOVA/Bonferroni (a)–(e) or two-tailed t-test (f) , , .

3.7. EP2 Receptors Induce IL-10 Release from Human Monocytes in Response to Activated Platelets

To investigate which EP receptor mediates IL-10 release and inhibition of TNFα release, human monocytes were incubated with platelets in absence and presence of EP receptor agonists. EP1 receptor agonist ONO-Di-004 (400 nM) and EP2 agonist butaprost (170 nM) completely blocked the platelet-induced TNFα release (Figure 7(a)). As observed for murine macrophages, the EP3 receptor agonist sulprostone (10 nM) exhibited no inhibitory effect on platelet-mediated TNFα release from human monocytes. In contrast to murine macrophages, the EP4 agonist L-902,688 (5 nM) did not affect the release of TNFα. Thus, PGE₂ seems to inhibit platelet-induced TNFα release out of human monocytes via its receptors EP1 and EP2.

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Figure 7 

Influence of EP receptor agonists on the release of TNFα and IL-10 from platelet-stimulated human monocytes. Human monocytes were incubated alone or with untreated platelets and the respective EP agonist concentrations for 3 hours (400 nM ONO-Di-004, 170 nM butaprost, 10 nM sulprostone, 5 nM L-902,688, 1 μM PGE₂). TNFα (a) or IL-10 (b) were determined by ELISA. Data are presented as mean ± SEM from 4 experiments. One-way ANOVA/Bonferroni , , .

To investigate which of the EP receptors mediates the suppression of TNFα by PGE₂-induced IL-10, we determined the extracellular IL-10. Application of exogenous PGE₂ (1 μM) led to a 3.1-fold increase of IL-10 production in monocytes up to 212 ± 29 pg/ml and only the EP2 agonist butaprost increased the IL-10 release (Figure 7(b)). In contrast, neither the EP1 receptor agonist ONO-Di-004, the EP3 receptor agonist sulprostone, nor the EP4 receptor agonist L-902,688 affected the IL-10 release from human monocytes. Thus, in human monocytes, EP2 receptors mediate the suppression of TNFα by PGE₂-induced IL-10 in response to activated platelets, causing an anti-inflammatory reaction of monocytes towards activated platelets.

3.8. EP2 Decreases TNFα through IL-10 and Its Receptor IL-10 R

To examine whether or not the EP2 agonist butaprost is mediating the inhibition of TNFα via IL-10 and its receptor IL-10 R, we incubated cocultures of human monocytes and untreated platelets with the different EP agonists with or without adding the human IL-10 Rα antibody (22.5 μg/ml). The EP1 agonist ONO-Di-004 and the EP2 agonist butaprost decreased the TNFα release from human monocytes significantly (Figure 8). Importantly, the neutralizing antibody IL-10 Rα increased the TNFα levels only in combination with butaprost but not with the EP1 agonist. Thus, IL-10 and its receptor IL-10 R are involved in the suppression of TNFα by EP2, while EP1 activation reduces TNFα via a different pathway.

Figure 8 

EP2 decreases TNFα through IL-10 and its receptor IL-10 R. Human monocytes were incubated with untreated platelets ± IL-10 Rα antibody (22.5 μg/ml) 30 minutes before the application of the respective EP agonist concentrations for 3 hours (40 nM ONO-Di-004, 75 nM butaprost). TNFα was determined by ELISA. Data are presented as mean ± SEM from 4 preparations. One-way ANOVA/Bonferroni .

4. Discussion

Platelets interact with macrophages modulating their inflammatory functions in several inflammatory settings, such as arteriosclerosis and rheumatoid arthritis. Most platelet functions and their interactions with other cell types are restricted to events taking place within the blood vessels. Recently, we found that platelets colocalize with macrophages outside of the blood vessels in several models for cutaneous inflammation and suppress the expression of anti-inflammatory markers and enhance the synthesis of proinflammatory mediators in the associated macrophages (5). However, platelet-induced intracellular signaling in monocytes or macrophages is highly complex and still not completely understood. Our study helps to clarify how activated platelets modulate the production of inflammatory mediators by human monocytes and murine macrophages in early stages of inflammation. We observed that activated platelets selectively release PGE₂ in cocultures with murine macrophages and human monocytes, which leads to an induction of IL-10 that in turn suppresses the intracellular accumulation as well as the release of TNFα. To our knowledge, these data are the first revealing that platelets are inducing an anti-inflammatory reaction of monocytes/macrophages via a cross-regulation of PGE₂ and TNFα through IL-10.

It is not surprising that platelets influence the production of pro- as well as anti-inflammatory mediators in monocytes/macrophages, since it is known that activated platelets upregulate the production of inflammatory cytokines by human peripheral blood mononuclear cells [25] and human monocyte-derived macrophages [42]. For example, platelet-monocyte interactions promote the release of proinflammatory IL-8, TNFα, and IL-6 upon coincubation in vitro [12, 42]. On the other hand, platelets have been shown to dampen inflammatory responses by triggering IL-10 and downregulating IL-6 and TNFα release by monocytes [2] as well as macrophages [43]. From the literature, it is known that TRAP-activated platelets enhance IL-10 secretion and reduce TNFα secretion by monocytes (19). In our study, we observed three major modulatory effects induced by collagen-activated platelets as follows: (i) activated platelets led to an enhanced release of PGE₂, (ii) an attenuation of the synthesis as well as the release of TNFα, and (iii) an upregulated induction of IL-10. Whereas the actions of TNFα as a proinflammatory mediator and IL-10 as an anti-inflammatory mediator are clearly defined, PGE₂ fulfills contrasting roles in the induction of inflammatory responses. Its well-known proinflammatory properties are the reason for the clinical use of the anti-inflammatory-acting COX inhibitors [44–46], while several functions of monocytes/macrophages are not proinflammatory but rather anti-inflammatory [47]. In this regard, PGE₂ inhibits the induction of proinflammatory cytokines in monocytes/macrophages [48] and can upregulate anti-inflammatory mediators, like IL-10 in case of macrophages [30].

In the experimental model we employed, PGE₂ seems to exert anti-inflammatory effects. The release of PGE₂ from activated platelets in cocultures with monocytes/macrophages led to an induction of IL-10 that in turn suppressed the intracellular accumulation as well as the release of TNFα. Due to the fact that uncontrolled expression of TNFα would lead to serious consequences, culminating in multiorgan failure and death [11], we suggested that the observed cytokine-modulating feature of PGE₂ is contributing to the resolution of the inflammation in order to prevent serious tissue injury.

Moreover, we were able to identify the receptors, by which PGE₂ mediates the upregulation of IL-10 and the suppression of TNFα in monocytes/macrophages. In murine macrophages, the EP2 and EP4 receptors mediate the cytokine-modulating effect of PGE₂. These findings are in accordance with the current literature which reveals that most of the PGE₂ actions in monocytes/macrophages are mediated via these two receptor subtypes. An in vitro study using the monocytic cell line THP-1 revealed that PGE₂ regulates cytokine signaling via increased intracellular cAMP levels, mediated by EP2 and/or EP4 receptors [49]. Within bone marrow dendritic cells (BM-DCs), PGE₂-EP2 and EP4 signaling stimulate the production of IL-10 [32] and inhibited the release and intracellular accumulation of TNFα [37]. Our data clearly revealed a difference between monocytes and macrophages according to the receptors involved in mediating the inhibitory effect of PGE₂. Whereas PGE₂ mediates the upregulation of IL-10 in both cell types via the EP2 receptors, the EP4 receptors are additionally involved only in case of murine macrophages (Figure 9). Unfortunately, ex vivo analysis using EP2- and EP4-deficient bone marrow-derived macrophages revealed that the genetic deletion of one of these receptor subtypes can be compensated by each other, and thus, the EP2- or the EP4-deficient macrophages can react to platelet PGE₂ similar than wild-type macrophages with an increased IL-10 release which mediates the suppression of TNFα. For that reason, EP2- and EP4-deficient mice are not suitable models for the determination of in vivo effects of the PGE₂-mediated cross-regulation.

Figure 9 

Summary of the platelet-induced crosstalk between PGE₂, IL-10, and TNFα in murine macrophages and human monocytes. Activated platelets produce and release PGE₂ in cocultures with macrophages. PGE₂ binds to EP1, EP2 (orange), and in case of murine macrophages additionally to EP4 (green). The binding of PGE₂ to EP1 decreased synthesis and secretion of TNFα independently of IL-10. The activation of EP2 and EP4 in murine macrophages and EP2 in human monocytes increased the secretion of IL-10 which binds to its receptor IL-10 R, leading to an inhibition of the production and release of TNFα.

Taken together, the interplay between platelets and monocytes/macrophages during inflammation led to a PGE₂-induced IL-10 production, which in turn suppresses TNFα via EP2 and/or EP4 in order to prevent serious tissue injury. This puts specific EP2 or EP4 agonists in perspective for the anti-inflammatory therapy in inflammatory diseases. Currently, the improvement of clinical symptoms of chronic inflammatory and autoimmune diseases such as rheumatoid arthritis (RA), inflammatory bowel disease (IBD), and psoriasis is reached by the repeated administration of TNFα-sequestering antibodies, like the monoclonal antibodies infliximab, adalimumab, and the fusion protein etanercept [22], but therapeutic application is hampered by the lack of oral availability, immunogenic response, restricted distribution, and high costs. PGE₂ itself is not a therapeutic agent because of its broad biological activities resulting from the activation of all four EP receptors. Compounds that interact specifically with the EP2 receptor may allow a wider, more practical exploitation in the therapy of inflammatory diseases and may additionally act immunosuppressive [50]. Thus, the multi-cytokine-modulating feature of a specific EP2 agonist might be advantageous over the conventional clinical approach represented by the existing anti-TNFα therapy.

Abbreviations

Conflicts of Interest

The authors declare that there is no conflict of interest regarding the publication of this paper.

Authors’ Contributions

All authors were involved in the planning of the experiments, the discussion of the data, and the critical revision and approval of the manuscript. Bona Linke and Bettina Picard-Willems performed the in vitro experiments and ELISA experiments. Rolf M. Nüsing and Patrick Slattery provided the EP1 agonist. Bona Linke, Klaus Scholich, and Gerd Geisslinger wrote the manuscript.

Acknowledgments

This work was supported by the DFG (German Research Foundation) grant SCHO817/3, the SFB1039 TPA08, and the Faculty of Medicine at the Goethe University Frankfurt in the framework of the Young Investigator’s Support Program 2015.

Supplementary Materials