Abstract

The local and systemic production of prostaglandin E₂ (PGE₂) and its actions in phagocytes lead to immunosuppressive conditions. PGE₂ is produced at high levels during inflammation, and its suppressive effects are caused by the ligation of the E prostanoid receptors EP₂ and EP₄, which results in the production of cyclic AMP. However, PGE₂ also exhibits immunostimulatory properties due to binding to EP₃, which results in decreased cAMP levels. The various guanine nucleotide-binding proteins (G proteins) that are coupled to the different EP receptors account for the pleiotropic roles of PGE₂ in different disease states. Here, we discuss the production of PGE₂ and the actions of this prostanoid in phagocytes from different tissues, the relative contribution of PGE₂ to the modulation of innate immune responses, and the novel therapeutic opportunities that can be used to control inflammatory responses.

1. General Considerations

Prostaglandins (PGs) are lipid mediators derived from arachidonic acid (AA) metabolism via the activation of the cyclooxygenase (COX) pathway, that regulates inflammation, immune response, hematopoiesis, tissue injury and repair, and bone resorption. PGs are found in most tissues and organs, and the variety of effects that they can elicit reflects the presence of specific PG receptors in many cell types. Upon cell activation by microbial products, cytokines, and opsonins, cytosolic phospholipase A₂ (PLA₂) is activated and recruited to hydrolase plasma cell phospholipids. Once it is released from the membrane, AA is rapidly converted into PGs by cells expressing prostaglandin H synthase (COX). At least two COX isoforms exist, the constitutive (COX-1) and inducible (COX-2) isoforms. COX-1 is expressed in many cell types distributed throughout the body, whereas COX-2 expression is highly restricted under basal conditions and upregulated during inflammation in different cell types [1] (see Figure 1). COX proteins are the major targets of nonsteroidal anti-inflammatory drugs (NSAIDs).

Figure 1 

Prostanoid biosynthesis and receptors. Upon cell stimulation, PLA2 is activated, and (AA) is released from the cellular membranes. AA is then metabolized by COX-1 or COX-2 in different cellular compartments and further metabolized by different synthases, which leads to the generation of different prostanoids. Once the product is formed, different prostanoids are transported outside the cells to bind to their respective receptors. (PG prostaglandin; Tx thromboxane; 15-deoxy-Δ12,14-prostaglandin ; Cox-1/2 cyclooxygenase-1/2; PGDS, PGES, PGFS, and PGIS prostaglandin D2/E2/F2/I2-synthase; PGIS prostacyclin synthase; TxAS thromboxane A2 synthase; PGER prostaglandin E2 9-reductase).

COX-2 is transcriptionally regulated by mediators that act through phosphatidylinositol 3-kinase (PI3K), extracellular signal-regulated kinase1/2 (ERK1/2), and p38, and the activation of COX-2 culminates in the activation of the transcription factors, nuclear factor kappa B (NFκB), activator protein (AP-1) and the cAMP response element-binding (CREB) [2, 3]. Therefore, COX-2 activity is induced by a variety of proinflammatory cytokines and growth factors and by one of its products, PGE₂. Conversely, COX-2 expression is inhibited by glucocorticoids and interleukin (IL)-4. Both COX-1 and COX-2 are present in the active state in the endoplasmic reticulum and the nuclear envelope. These enzymes convert AA to the unstable endoperoxide PGH₂, which is converted by specific synthases to the five following biologically active prostanoids: PGD₂, PGE₂, PGF_2α, PGI₂ (prostacyclin), and thromboxane A2 (TXA₂). There are several PGE synthases, and one of these synthases (mPGES-1) is a highly inducible microsomal enzyme that acts downstream of COX to catalyze the conversion of PGH₂ to PGE₂ [4–6] (Figure 1).

PGE₂ is a potent mediator of inflammation that induces both pro- and anti-inflammatory effects and signals via four different E prostanoid (EP) receptors, EP₁-EP₄. The EP receptors are member of a family of G protein-coupled receptors (GPCRs). EP₁ signals through Gα_q, which leads to increased levels of Ca²⁺. EP₂ and EP₄ signal through Gα_s, which leads to increased cAMP levels. EP₃ primarily signals through Gα_i, which leads to decreased cAMP levels [7] (Figure 2).

Figure 2 

PGE2 receptors and their actions in macrophages. PGE2 produced during inflammatory conditions binds to EP2, EP4, EP3, or EP1. EP2 and EP4 are coupled to , and the binding of PGE2 to these G protein-coupled receptors (GPCRs) induces a conformational change that results in the liberation of the subunit from the Gβ γ subunit complex. The binding of the Gα subunit to adenylyl cyclase (AC) either stimulates () or inhibits (, via EP3 signaling) the enzyme’s generation of cAMP. The production of cAMP is also regulated by microbial pathogens. Downstream cAMP signaling is mediated by its interactions with effector molecules, such as protein kinase A (PKA), or exchange proteins that are directly activated by cAMP (Epac), which have been shown to modulate phagocyte functions. Depicted here is a pattern for alveolar macrophages in which specific antimicrobial functions are differentially regulated by specific cAMP effectors.

The distribution and relative expression of these four receptor subtypes provide an elegant system that can account for the ability of PGE₂ to evoke pleiotropic and sometimes opposing bioactions that are tissue- and cell-type specific.

Although PGE₂ is commonly considered to be a potent proinflammatory mediator [8], its role as a mediator of anti-inflammatory responses is now being studied [9, 10]. The anti-inflammatory response opposes the host inflammatory response, which potentially limits collateral damage to neighboring cells and tissues and aids in the resolution of inflammation after the pathogens are contained [11]. This dual effect depends on the cell type, the tissue compartment, the state of cellular activation, and the particular expression of the signaling-EP receptors. The existence of four subtypes of receptors that signal differently and can be expressed in different combinations in a single cell explains the multiplicity of biological responses that are elicited by PGE₂ and how these responses may differ among cells and tissues. This paper reviews the recent knowledge regarding PGE₂ synthesis and its modulatory effect on innate immune responses in different tissues.

2. Lung

The synthesis of PGE₂ occurs in several different cellular types within the airways, such as epithelial cells, fibroblasts, vascular endothelial cells, and leukocytes [12]. The leukocytes that can synthesize PGE₂ include the alveolar macrophages (AMs), neutrophils, follicular dendritic cells, and T cells. The relative capacity of these cells to produce PGE₂ is shown in Table 1. The AMs represent a major source of PGE₂ during microbial infection [13], whereas alveolar epithelial cells and pulmonary fibroblasts also represent an important source of PGE₂ in the lungs [14]. High levels of PGE₂ are produced in AMs following the lipopolysaccharide (LPS)-and granulocyte/macrophage colony-stimulating factor (GM-CSF)-dependent expression of the inducible form of COX-2 [15]. Several mediators and signal transduction pathways are involved in the modulation of the synthesis and release of PGE₂ by these cells. The inhibition of endogenous rat AM-producing transforming growth factor (TGF)-β enhances PGE₂ synthesis, while the expression of LPS-induced COX-2 and PGE₂, which are released by human AMs, is upregulated following the inhibition of PI3K activity [3]. AMs also produce increased PGE₂ after bone marrow transplantation [16]. Although neutrophils are considered to be the main producers of leukotriene B₄ (LTB₄) (5-lipoxygenase-derived lipid mediator), few studies have attempted to evaluate the ability of lung neutrophils to produce prostanoids. In fact, the majority of studies is focused on the peritoneal and peripheral blood-derived neutrophils [17]. One of these studies demonstrated that lung PMNs (but not AMs) from mice that received bone marrow transplants synthesized pronounced levels of PGE₂ when compared with cells from control mice [16]. In general, the in vitro synthesis of the cytokine-induced PGE₂ by neutrophils involves the activation and novel synthesis of COX [18]. In addition, while PGE₂ synthesis is well documented in human monocyte-derived immature dendritic cells (DCs) [19], no studies to date have demonstrated the particular capacity of lung DCs to produce this mediator.

PGE₂ produced in the lungs elicits a wide variety of effects [1]. The effects vary from the induction of tissue repair and pulmonary vascular remodeling [20] to the regulation of immune inflammatory responses [21].

AMs are the primary lung cells that are involved in the protection of the alveolar-blood interface and serve as the front line of cellular defense against respiratory pathogens [22] in both murine and human cells. AMs express all four types of EP receptors [23] and contribute greatly to the amount of PGE₂ produced in infected lungs [13] (Table 1). Monick and collaborators have demonstrated that LPS induces COX-2 expression and PGE₂ release in human AMs [3, 24].

The immunomodulatory effects of PGE₂ are largely caused by its ability to increase intracellular cAMP through the stimulatory -coupled EP receptors EP₂ and EP₄ [25]. Increases in intracellular cAMP levels are transduced into cellular responses mediated by its effectors, cAMP-dependent protein kinase A (PKA), and the exchange protein directly activated by cAMP-1 (Epac-1) [26]. In phagocytes, the effects of PGE₂ are usually anti-inflammatory since PGE₂ has been demonstrated to inhibit the production of proinflammatory molecules and increase the secretion of anti-inflammatory cytokines, such as IL-10 [27]. In human AMs, PGE₂ potently inhibited LPS-induced tumor necrosis factor (TNF)-α through the activation of the EP₂ and EP₄ receptors [28]. The downmodulation of LPS-induced TNF-α by PGE₂ in rat AMs is dependent on cAMP signaling-dependent PKA activation since the selective PKA activating cAMP analog 6-Bnz-cAMP, but not the Epac-1 activating analog 8-pCPT-2-O-Me-cAMP, inhibits its production [29]. EP₂ signaling is also involved in the enhancement of LPS-induced nitric oxide (NO) by the activation of PKA rather than Epac-1 [30]. Exogenous PGE₂ can potentiate the synthesis of LPS-mediated IL-6 and IL-10 in rat AMs via AKAP10-(A-kinase anchoring protein-10-) mediated PKA signaling, while the suppression of TNF-α occurs via AKAP-8-anchored PKA-RII (PKA regulatory subunit type II) [30].

PGE₂ has also been shown to inhibit AM FcR-mediated phagocytosis by activating the EP₂ receptor, judged by the mimicked effect of the selective EP₂ agonist butaprost [23] or a specific Epac-1 agonist (8-pCPT-2′-O-Me-cAMP) [32]. Moreover, PGE₂ inhibits rat AM microbicidal activity and this effect was restored after treatment with indomethacin, EP₂, and EP₄ antagonists [31]. The role of EP₃ receptor activation-driven AMs was also studied in the context of pulmonary infection. Although the -coupled EP₃ was thought to oppose the -coupled EP₂ and EP₄ receptors, EP₃^−/− mice were protected from bacterial induced death, which corroborates the increased ability of AMs to phagocytose and kills Streptococcus pneumoniae [33]. Through EP₂, PGE₂ was also involved in the mediation of the immunosuppressive response characterized by increased IL-10 synthesis and the impairment of neutrophil recruitment to the lungs during the ingestion of apoptotic cells (efferocytosis) by phagocytes [10]. As a suppressive mediator, PGE₂ inhibits AA release and LTB₄ synthesis in rat AMs by a mechanism independent of PLA₂ [34].

Human and mouse lung DCs are localized in the airway epithelium, lung parenchyma, visceral pleura, and bronchoalveolar lavage fluid (BALF) [35]. DCs exposed to PGE₂ exhibit a decreased capability to secrete proinflammatory cytokines [36]. They are in contact with many other cells in the lungs such as the airway epithelium, type II alveolar epithelial cells, AMs, pulmonary interstitial macrophages, (myo)fibroblasts, bronchus-associated lymphoid tissue (BALT) lymphocytes, nonadrenergic, noncholinergic (NANC) nerve endings, capillary endothelium, and mast cells. Although the particularly contribution of lung DC as producer of PGE₂ is still unknown, there are several studies using bone-marrow-derived DCs (BM-DCs) showing that their immunomodulatory function is highly regulated by mediators including PGE₂, potentially produced by neighboring cells in the lungs. BM-DCs exposed to PGE₂ present decreased ability to secrete proinflammatory cytokines [36]. The importance of lung DC modulation by PGE₂ is highlighted considering DC as the mediator cell of the adaptative immune response and the lungs as an important local tissue for airway microbial defenses [37].

Lung PMNs are the primary cells recruited to the lungs during acute lung injury [38]. LPS is an important inducer of the inflammatory response by its activation of Toll-like receptor 4 (TLR4). After binding to TLR4, LPS triggers the synthesis of chemoattractants that induce PMN migration at sites of inflammation, such as the lung [39]. The overproduced PGE₂ by lung PMNs from bone marrow transplantation mice is involved to the decreased ability of PMN to kill Pseudomonas aeruginosa, an effect restored by the PG inhibition with indomethacin [16]. However, evaluation of EP signaling in the PGE₂-mediated impaired host defense by lung PMMs is much less appreciated.

Due to the low yield of murine alveolar macrophages, one plausible alternative to study PGE₂ synthesis/actions is the use of alveolar macrophage cells lines. However, a very limited number of studies have been done to identify the profile of PGE₂ synthesis and actions in this cell line. Here, we are summarizing some of the key findings regarding the expression of COX mRNA and protein in MH-S murine alveolar macrophages. MH-S is a murine alveolar macrophage cell line transformed by SV40 obtained from Balb/c mice and displays several properties of primary AM, such phagocytic capacity and expression of Mac-1 antigen, major histocompatibility complex class II, the CR3 receptor, and the Fc receptor Mbawuike and Herscowitz, 1989 to [40]. LPS-stimulated MH-S cell line promotes robust increment of COX-2 and large amounts of PGE₂ (Joo et al., 2005 to [41]; Chen et al., 2007 to [42]). Luteolin, a flavonoid that exhibits anti-inflammatory properties, is shown to inhibit COX-2 gene expression and PGE₂, IL-6, TNF-α, and iNOS production in LPS-activated MH-S cells by decreasing NF-κB and AP-1 activation Chen et al., 2007 to [42]. In this context, LPS or overexpression of IKKβ is reported to activate NF-κB signaling and COX-2 expression, which was impaired after ectopic expression of hepatitis C virus in MH-S cells Joo et al., 2005 to [41]. However, so far there are no reports regarding EP receptors expression profile and the relative role of individual receptor in MH-S cells.

3. Spleen

Splenic macrophages, DCs, and lymphocytes contribute to PGE₂ synthesis in the spleen [43]. In splenic tissues, mPGES-1 accounts for the majority of basal (COX1-dependent) PGE₂ synthesis, and the in vivo mPGES-1 deletion abolished LPS-inducible PGE₂ synthesis [44]. Normal splenic macrophages produce low levels of PGE₂ when compared with bone-marrow-derived macrophages (BMDM; Table 1), AMs, and peritoneal macrophages [45]. However, high levels of this mediator are produced by splenic macrophages in chronic inflammatory conditions, such as mycobacterial infection [46]. It has been shown that the formation of PGE₂-producing splenic macrophages is dependent on the radiosensitive bone marrow cells [47]; the precursors migrate from the bone marrow cells to the spleen to become mature cells [48]. Splenic DCs appear phenotypically immature and mature after microbial stimuli [37]. The phenotype seems to be determined by other suppressive mediators, including NO, TGF-β, 1α, 25 dihydroxyvitamin D3 (vitamin D) and PGE₂ produced by antigen-presenting cells (APCs) such as macrophages and DCs [49]. To date, no reports have described EP expression in splenic DCs; most studies are focused on bone-marrow-derived DCs (BM-DCs) [50]. These cells express all four EP receptors [51] that can induce different effects, including DC generation, migration, and maturation [52].

PGE₂-producing macrophages that are induced from mycobacterial stimuli interact closely with splenic lymphocytes to induce a shift from the Th1 to Th2 immune responses in a PGH₂ synthase-dependent manner [53]. This shift is based on the suppressive effect of the synthesis of Th1 cytokines, such as IL-1, IL-12, and interferon (IFN)-γ, but it does not affect Th2 cytokines [54]. The downmodulation of TNF-α synthesis by PGE₂ in in vitro-derived BM-DCs occurs through EP₂- and EP₄-induced signal transduction events [55]. It has also been shown that this signaling can upregulate IL-23 synthesis and downmodulate APC-produced IL-12 [56], which favors the expansion of IL-17-producing Th17 cells [57].

4. Bone

PGE₂ produced in the bone is primarily derived from osteoblasts, cells responsible for bone formation [58]. As shown in Table 1, mouse BMDMs, osteoclast precursors, and mature osteoclasts differentially express EP receptors. BMDMs express the EP₁, EP₂, EP3β, and EP₄ receptors, while mature osteoclasts only express the EP₁ receptor [59]. It was demonstrated that PGE₂ can stimulate cAMP levels in BMDMs but does not affect cAMP in mature osteoclasts; this result demonstrates that functional EP₂ and EP₄ receptors are inhibited in osteoclasts during its differentiation [59].

Osteoclasts are bone-resorbing multinucleated cells derived from the monocyte-macrophage lineage [60]. The differentiation and activation of osteoclasts are tightly regulated by osteoblasts through the release of receptor activator of NF-κB ligand (RANKL) and macrophage colony-stimulating factor (M-CSF) [61], which are required for the differentiation of osteoclast progenitors into mature osteoclasts [62]. RANKL activation induces COX-2 expression in immature osteoclast by utilizing a Rac1-dependent NK-κB activation pathway; that results in PGE₂ synthesis and contributes to accelerated osteoclast differentiation [63].

In bone, PGE₂ is known to be an important local factor in the regulation of bone formation [64] and resorption [65]. PGE₂ acts in precursors and mature osteoclasts to regulate their function. PGE₂ can directly inhibit the bone-resorbing activity of osteoclasts. This inhibitory effect was dependent on an increase of intracellular cAMP caused by activator of adenylate cyclase (forskolin) and mimicked by the EP₂ and EP₄ agonists (butaprost and AE-604). In calvaria culture from EP₄ knockout mice, PGE₂ presented an impaired role in promoting bone resorption, whereas EP₂ agonist slightly restored bone resorption and EP₄ agonist did not [66].

5. Central Nervous System (CNS)

Although the immunoprivileged status of the CNS is well known, similar to any other organ, it is connected and engaged with the immune system to maintain tissue homeostasis. An excessive inflammatory status can promote several types of brain damage, which include ischemia and neurodegenerative diseases, such as Alzheimer’s disease and Parkinson’s disease [67].

The CNS typically contains low prostanoid levels. Specifically, PGE₂, PGD₂, and PGF_2a are associated with inflammatory responses [68]. Oddly, the COX-1 and COX-2 enzymes are both constitutively expressed in the CNS (in neurons, astrocytes, microglia and endothelia) [69], and a putative COX-3 enzyme, which is a splice variant of COX-1 that is denoted as COX-1b, is described in rodent and human neural tissues [70–72]. The PGE₂ levels in the CNS are enhanced during various neurological diseases, such as multiple sclerosis, Alzheimer’s disease, and Parkinson’s disease [68].

Importantly, the proinflammatory stimuli that lead to brain injury further enhance COX-2 expression and therefore enhance PGE₂ synthesis. All three PGES isoforms are found in the CNS tissues, and the expression levels vary according to the cell type [73]. An elegant study demonstrated that brain PGE₂ synthesis is orchestrated by COX-1/COX-2/membrane-associated cPGES (cPGES-m) and by nuclear/perinuclear COX-2/mPGES-1/cPGES [74].

Because few studies have described DCs and neutrophils in the CNS, we will focus primarily on the microglia functions. It is noteworthy that although there is a close relationship between the peripheral macrophages and microglia, all of the knowledge concerning the peripheral cells cannot simply be extended to microglia cells that are inserted in a unique environment.

Initially, astrocytes were reported to be the major source of prostanoids within the CNS [75], but later studies have demonstrated that microglial cells can release higher levels of PGE₂, PGD₂, and TXB₂ than astrocytes [76]. Similar to peripheral macrophages, COX-2 is the main enzyme expressed by microglia after activation [77]. LPS induces high levels of PGE₂ synthesis by upregulating COX-2 and mPGES-1 expression [76, 78]. Additionally, activation of microglia by TLR can be modulated by further PGE₂ synthesis. Although factors such as TGF-β [79], TNF-α [80], norepinephrine [81], adenosine, and PGE₂ [82], can act as COX-2 positive regulators, other factors, such as IFN-γ [83], IL-10 [79], NO [83], and lipocortin [84] are negative regulators of COX-2 expression and activation. Interestingly, PGE₂ synthesis is rapidly augmented when microglia are treated with phosphatidylserine (PS) liposomes in a manner that is dependent on the COX-1/mPGES-2 axis [85].

From the moment that PGE₂ is released, it acts in close proximity to its production site in an autocrine or paracrine manner. In general, PGE₂ acts as a suppressive mediator of the microglia. In the CNS, PGE₂ primarily causes enhanced levels of cAMP [80], which further suggests a role for EP₂ and EP₄ in the mediation of CNS inflammation. Supporting its suppressive functions, studies of TLR4-mediated microglial activation have shown that PGE₂ can inhibit the production of TNF-α [86] and IL-12 [87], IL-18 [88], the expression of the B7-2 (CD86) co-stimulatory molecules [89], the enhancement of IL-10 and IL-6 production, and the expression of inducible nitric oxide synthase (iNOS). Additionally, a recent study has associated PGE₂ with decreased microbicidal activity by microglial cells in meningitis [90].

In addition to its inflammatory roles, PGE₂ is related to several central functions, such as fever (thermogenesis), the neuroendocrine axis, food intake, and behavior during sickness. Circulating IL-1β acts at the blood-brain barrier (BBB) to induce COX-2 expression and PGE₂ synthesis, and PGE₂ subsequently diffuses into the brain parenchyma to perform its actions [91]. Recent studies have revealed that central COX-2 inhibition did not abrogate fever induction or the increases in plasma corticosterones and anorexia, which suggests that other sources of PGE₂, such as COX-2-dependent peripherally synthesized PGE₂ or COX-1-dependent centrally produced PGE₂ [92], are involved. Interestingly, PGE₂ production in the spinal cord is elevated by peripheral inflammation through COX-2 and mPGES-1 induction, which is correlated with peripheral edema potentiation, enhanced neuron hyperexcitability, and hyperalgesia [93]. Moreover, COX-2-dependent PGE₂ is an important signaling mediator for synaptic modification [94].

The role of PGE₂ in the brain remains controversial, and its differential effects depend on its specific receptor [95]. Because the expression and timing of the EP receptors vary according to the cell type and neuronal stimuli, the specific role of each EP receptor depends on its specific context (for an extensive review, see [96]). The EP₃ receptor is likely not associated with inflammatory roles, while the EP₂ and EP₄ receptors appear to have opposing activities [96]. Although the EP₂ receptor is related to a proinflammatory neurotoxic effect in activated microglia [97], the EP₄ receptor has an anti-inflammatory, neuroprotective role [98]. These contradictory effects reflect the differential expression and timing of the EP receptors.

Consistent with the myriad activities of PGE₂ and the dependence on the expression of specific EP receptors in different cell types, studies that investigate the roles of PGE₂ in the CNS should be addressed carefully. The inflammatory effects of PGE₂ are related to its dual neuroprotective and neurotoxic roles, and unless the PGE₂ paradoxical effects are finely tuned, neurodegenerative diseases could occur. A full understanding of the roles of PGE₂ and the dynamics of EP receptors in the CNS requires the study of the restrained areas of the CNS and the endogenous PGE₂ functions relative to the different cell types and receptors that are involved.

6. Reproductive Tract

Uterine macrophages are an important source of PGs for uterine activity [99]. They are known to be potent agonists that promote contractile activity in the uterus, and either PGs or its precursor treatments initiate preterm labor throughout gestation. Therefore, LPS-induced uterine activation may be due to increased levels of proinflammatory cytokine and PGE₂. Furthermore, exogenously added PGE₂ analogs can reduce the innate immune defenses within the reproductive tract. Slama et al. provided a good example of the role of PGE2 in inhibiting innate immune response. They injected a PGE₂ analog into the maternal cervix of cows for 1 wk following calf delivery and observed an increased purulent uterine secretions, increased frequency and severity of bacterial contamination of the uterus, and reduced levels of antibodies in uterine secretions. Pharmacological PGE₂ administration facilitated the establishment of chlamydial infections of the murine female reproductive tract [100]. We have shown that the intrauterine administration of misoprostol in rats infected with Clostridium sordellii further enhanced the bacterial numbers in the uterine tract and was followed by decreased animal survival. This effect was associated with the inhibition of TNF-α and defensin secretion by decidual macrophages and uterine epithelial cells [101]. Although little is known about the potential of misoprostol to suppress the reproductive tract’s innate immunity, a study reported an increase in the rate of infections when misoprostol was administered orally, and the rate increased with intravaginal administration [102]. This may help to explain the connection between medical abortion and clostridial endometritis in contrast to infections that are caused by more commonly encountered pathogens.

7. Peritoneal Macrophages

Peritoneal macrophages are extensively used as a model to investigate macrophage function. This cell type is a standard model used to identify inflammatory responses, cellular metabolism, and apoptosis. Resident peritoneal macrophages exhibit low responsiveness to inflammatory stimuli relative to inflammatory peritoneal macrophages that are recruited by inflammatory stimuli, such as thioglycollate, peptone or glycogen. Resident peritoneal macrophages express mainly EP₄ but not EP₂ mRNA at basal levels. In the presence of LPS, the expression of EP₄ mRNA is downregulated to levels that are lower than in nonstimulated macrophages, and the expression of EP₂ mRNA is transiently increased after 3 h of stimulation [103].

Peritoneal macrophages have a greater capacity for PGE₂ synthesis than macrophages from different organs, such as alveolar macrophages or spleen macrophages. These cells have higher levels of cytosolic and membrane COX-1 expression in activated cells, which are similar to the levels of COX-2 expression after LPS treatment [104].

The effect of PGE₂ in the inhibition of inflammatory cytokines, such as TNF-α, IL-1β, and IL-6, was initially demonstrated in peritoneal macrophages upon TLR4 activation [105]. However, recent studies described that the effects of PGE₂ are due to the production of IL-10 [106]. However, the suppressive effect of PGE₂ on IL-6 production is controversial and seems to be dependent on the inflammatory stimulus used. In addition to the modulation of cytokines, exogenous PGE₂ can also modulate the expression of the cell surface receptors of peritoneal macrophages. The addition of different concentrations of PGE₂ induces an increase in CD14 on the surface of peritoneal macrophages through the activation of cAMP/PKA, which results in the activation of AP-1. The treatment of macrophages with a PKA inhibitor or with antisense c-fos and c-jun oligonucleotides in the presence of PGE₂ prevented the increase of CD14 on the surface of these cells [107].

PGE₂ modulates a broad range of cytokines in peritoneal macrophages involved in inflammatory processes. Endogenous PGE₂ production in LPS-stimulated resident peritoneal macrophages acts as a brake for TNF-α and IL-12 synthesis [103]. The activation of peritoneal macrophages with other macrophage activators, such as IFN-γ and the fungal particle zymosan, induces the synthesis of cytokines, chemokines, lipid mediators, and reactive nitrogen and oxygen species that directly or indirectly modulate the synthesis of PGE₂. Of the mediators that modulate PGE₂ synthesis in these cells, NO seems to play a key role in inhibiting PGE₂ biosynthesis by nitrosylating and preventing the activity of COX-2 and mPGES [108].

The capacity of PGE₂ to modulate cytokine production clearly influences the inflammatory response during injury and infection. The susceptibility or resistance to infection in different mice strains could be associated, at least in part, with the ability to stimulate the production of eicosanoids from phagocytes. When they are stimulated with LPS, peritoneal macrophages isolated from Balb/c mice produce approximately 3-fold more PGE₂ than the macrophages isolated from other mouse strains, such as C57BL. The higher levels of PGE₂ in the peritoneal macrophages of Balb/c mice are associated with high expression levels of sPLA2 type V and mPGES mRNA relative to the levels in the macrophages of C57BL mice. The increased capacity to produce PGE₂ by the macrophages isolated from Balb/c mice directly reflects the inhibition of cytokines, such as IL-12 and TNF-α [109].

The peritoneal site also represents a primary organ to generate macrophage cell lines, which are very often used to study macrophage behavior and functions. Below we will highlight some of the key human and murine cell lines used to study PGE2 production and actions.

8. RAW 264.7 Cells

RAW 264.7 cells are mouse macrophage-like cells established from the ascites of a tumor that was induced into a male Balb/c mouse by an intraperitoneal injection of Abselon leukemia virus (A-MuLV). These cells are extensively studied in models of inflammation, metabolism, and apoptosis, and they are used for in vitro drug screening. Currently, many reports have shown that EP₄ is the most abundant EP receptor in RAW 264.7 cells, followed by EP₂ and EP₃ but not EP₁ [110]. The expression of these receptors in RAW 246.7 cells can be modulated in a manner that is dependent on the inflammatory stimuli. TLR4 activation increases EP₂ and inhibits EP₄ receptor mRNA expression. In contrast, if these cells are stimulated only with IFN-γ, the expression of EP₂ and EP₄ decreases in a concentration-dependent manner [111].

Several inflammatory mediators, including TNF-α, IL-1 [112], and IFN-γ [113], can directly or indirectly increase the expression of COX-2 in RAW 246.7 cells. However, COX-2 expression and PGE₂ synthesis in IFN-γ-treated RAW 264.7 cells is directly regulated by TNF-α [114]. In the presence of an inflammatory stimulus, PGE₂ appears to have an autocrine effect in RAW 264.7 cells and can self-regulate the expression of COX-2. The pretreatment of cells with PGE₂ or EP₂/EP₄ agonists followed by the stimulation with LPS induced an increase in COX-2 expression, and this expression was completely inhibited in the presence of an adenylyl cyclase inhibitor [115].

9. U937

U937 is a cell line isolated from the histiocytic lymphoma of a 37-year-old male and is used to study the differentiation of monocytes into mature macrophages in the presence of different stimuli, such as IFN-γ, phorbol 12-myristate 13-acetate (PMA), and vitamin D [116]. In PMA-differentiated cells, EP₄ is the predominant receptor, while only low levels of EP₁, EP₂, and EP₃ were detected [117]. Unstimulated U937s expressed high levels of EP2 on the surface; however, when these cells were incubated with different concentrations of PMA, the expression of EP₂ and the cAMP levels that were induced by PGE₂ decreased in a manner that was dependent on PKC [118].

Undifferentiated U937 cells produce low levels of PGE₂; however, in the presence of 12-0-tetradecanoylphorbol13-acetate (TPA), these cells produce high levels of PGE₂. U937 cells express high basal levels of PLA₂, cPLA_2α, and iPLA_2β, and the presence of IFN-γ does not alter the expression of these proteins. The activation of these cells by the aggregation of FcγRI promotes the generation of PGE₂, but only iPLA_2β appears to be involved in the release of AA and the generation of this prostanoid [119]. Untreated U937 cells or differentiated U937 cells in the presence of 1,25-dihydroxyvitamin D3 express only COX-1; however, when the differentiated cells are stimulated with serum-treated zymosan (STZ), they begin to express high levels of COX-2; in the presence of exogenous AA, they produce high levels of PGE₂ [120]. U937 cells differentiated in the presence of PMA express COX-2 and high levels of PGE₂, IL-1β, and TNF-α after 6 h of stimulation with LPS. However, unlike other cell types, the increased COX-2 levels in U937 cells are independent of the presence of IL-1β and TNF-α because the treatment of these cells with the respective neutralizing antibodies does not interfere with the expression of LPS-induced COX-2 [121].

10. Therapeutic Approaches

Because PGE₂ is the major PG product of most organs and its synthesis is upregulated during inflammatory conditions, which include infections and pathophysiologic conditions, it is expected that PGE₂ plays a nonredundant role in controlling the inflammatory response and modulating phagocyte function in diverse organs. Increased plasma PGE₂ levels have been reported in murine models and in patients who have undergone bone marrow transplantation [16, 122], are infected with HIV [123], display protein-calorie malnutrition [124], are smokers, are aging [125], or have cancer [126] or cystic fibrosis [127]. In all circumstances, these conditions are associated with susceptibility to infection. More specifically, in a murine bone marrow transplantation model, high levels of PGE₂ were observed in the lung and peritoneal lavage fluid, and the overproduction of PGE₂ by multiple cell types, including AMs, PMNs, and alveolar epithelial cells, was observed [16]. Similarly, a bactericidal PMN defect in guinea pigs following thermal burn injury has been linked to increased intracellular cAMP levels and the overproduction of PGE₂ [128]. In both a murine bone marrow transplant model and also a thermal burn injury, these defects were overcome by treatment with COX inhibitors. While COX inhibition is conventionally regarded to be an “anti-inflammatory” strategy, an alternative possibility is that COX inhibitors or other nonsteroidal anti-inflammatory drugs (NSAIDs) can prevent the overproduction of immunosuppressive PGE₂, which may instead represent an “immunostimulatory” strategy. In contrast, in conditions in which PGE₂ exerts proinflammatory activities, such as in arthritis, atherosclerosis, and fever, COX inhibition is also an attractive target due to its analgesic and antipyretic properties. These drugs also have the beneficial effects of pathogen clearance. This effect has been shown that the in vivo treatment with NSAIDs enhances microbial clearance in different models of infection [26]. Although it has not been explicitly tested, we speculate that PGE₂ inhibition by NSAIDs should lead to reductions in intracellular cAMP levels, which may account for the immunostimulatory effects of NSAIDs in these models.

11. Conclusion

In summary, pharmacological inhibition or receptor genetic deletion in mice has unveiled the big diversity and distinct biological effects of PGE₂. Depending on cell-specific signaling programs and the context of injury, EP receptors can mediate either bad or protective effects in processes that mediate various diseases. The development of highly selective pharmacological agents that targets individual EP receptors should be studied in clinical trials in different disease settings.

Authors’ Contribution

Alexandra Medeiros and Camila Peres-Buzalaf are equally contributed.