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Deciphering the role of n-3 polyunsaturated fatty acid-derived lipid mediators in health and disease

Published online by Cambridge University Press:  02 September 2013

Matthew Spite*
Affiliation:
Diabetes and Obesity Center, University of Louisville School of Medicine, Louisville, KY 40202, USA Division of Cardiovascular Medicine, Institute of Molecular Cardiology, University of Louisville School of Medicine, Louisville, KY 40202, USA Department of Microbiology and Immunology, University of Louisville School of Medicine, Louisville, KY 40202, USA
*
Corresponding author: Dr Matthew Spite, email [email protected]
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Abstract

Accumulating evidence indicates that, analogous to n-6 PUFA, n-3 PUFA are enzymatically converted into diverse families of bioactive mediators that play numerous roles in physiology. These mediators, which include the resolvins, protectins and maresins, are particularly important in resolving acute inflammation and also appear to play a role in enhancing host defence. Given the protective actions of n-3 PUFA in human subjects and in animal models of disease, active generation of bioactive mediators may in part underlie these protective effects. Several studies have demonstrated that bioactive autacoids generated from n-3 PUFA have direct anti-inflammatory and pro-resolution actions, and the structures of many of these endogenous mediators have been elucidated. The diverse roles of these lipid mediators in health and disease, regulation of their biosynthesis, as well as identification of specific receptors and cellular targets, are emerging. This brief review will highlight the biosynthesis of resolvins, protectins and maresins, and discuss their receptor-mediated biological actions in promoting the resolution of inflammation. Their potential use as a new class of pro-resolution therapeutics, as well as gaps in knowledge and challenges for future research, will also be discussed. Overall, the identification of these novel families of lipid mediators has yielded insight into the protective actions of n-3 PUFA and may lead to the development of an entirely new class of therapeutics aimed at regulating inflammation and host defence.

Type
Conference on ‘Polyunsaturated fatty acid mediators: implications for human health’
Copyright
Copyright © The Author 2013 

PUFA of both the n-6 and n-3 classes are essential to health and must be obtained in the diet. The concept that certain types of fat are essential in the diet was put forth initially in studies of rodents consuming a fat-depleted diet, which was associated with a marked appearance of dry skin, brittle hair and skin rashes; effects that were reversed by fat replenishment( Reference Burr and Burr 1 ). A similar phenotype is apparent in human subjects with essential fatty acid deficiency, with symptoms appearing rapidly (< 1 week) in infants when their essential fatty acid levels are < 5% of total energy intake( Reference Le, Meisel and de Meijer 2 ). More than 80 years of research has now defined that essential fatty acids, which are components of major lipid classes including phospholipids, TAG and cholesterol esters, serve numerous roles in physiology( Reference Fritsche 3 , Reference Harbige 4 ). These diverse functions include the regulation of cell membrane dynamics and cell signalling, providing a source of energy (through β-oxidation), and serving as the precursors to bioactive lipid mediators( Reference Harbige 4 Reference Serhan, Chiang and Van Dyke 6 ).

While mammals have the ability to elongate and desaturate both n-3 and n-6 PUFA, the biosynthetic starting materials for these pathways, namely α-linolenic acid (18∶3n-3) and linoleic acid (18∶2n-6), respectively, must be obtained in the diet( Reference London, Albert and Anderson 7 Reference Sprecher 9 ). Linoleic acid can be further converted into arachidonic acid (20∶4n-6) through a series of elongation and desaturation reactions, whereas α-linolenic acid is similarly converted into EPA (20∶5n-3) and DHA (22∶6n-3)( Reference Sprecher 9 ). As such, EPA and DHA are not considered essential in the diet, but it should be noted that the conversion of α-linolenic acid into EPA and DHA is very low in human subjects and thus nutritional strategies designed to address deficiencies in n-3 PUFA generally utilise marine-based sources that are naturally high in EPA and DHA( Reference Le, Meisel and de Meijer 2 , Reference Calder 8 , Reference Sprecher 9 ). Importantly, studies of the biological role of n-3 PUFA in health and disease have been aided by the generation of transgenic mice that express an n-3 desaturase gene (denoted fat-1) not normally found in mammals that enables endogenous generation of n-3 PUFA from n-6 PUFA( Reference Hudert, Weylandt and Lu 10 ). These mice show substantial increases in tissue levels of both EPA and DHA and are protected from inflammation and tissue injury in a myriad of animal models of disease, including colitis, cancer and pathologic angiogenesis( Reference Hudert, Weylandt and Lu 10 Reference Xia, Lu and Wang 12 ).

While both n-6 and n-3 PUFA are essential for health, it is well-documented that the typical Western-type diet is substantially enriched in n-6 PUFA, shifting the balance from the optimal n-6:n-3 ratio of 1–2:1 to approximately 20:1( Reference DeFilippis and Sperling 13 ). This altered ratio of PUFA is associated with the development of numerous chronic diseases, including CVD and rheumatoid arthritis, potentially because of an imbalance between bioactive lipid mediators that are involved in regulating inflammation( Reference Calder 8 ) (see later). Indeed, several clinical studies have determined that enriching the diet in n-3 PUFA improves outcomes in diseases such as rheumatoid arthritis( Reference Fritsche 3 , Reference Calder 8 ). n-3 PUFA are important during fetal and infant development and may be effective in preventing essential fatty acid deficiency in infants requiring parenteral nutrition( Reference Le, Meisel and de Meijer 2 ). The protective effects of n-3 PUFA are particularly convincing for CVD, such as atherosclerosis and its associated cardiac manifestations including acute myocardial infarction and heart failure( Reference Thies, Garry and Yaqoob 14 , Reference De Caterina 15 ). Building upon observational studies demonstrating a low incidence of CVD in Greenland Eskimos, who have a diet rich in n-3 PUFA from marine sources, interventional studies have shown that dietary supplementation with purified fish oil extracts reduces the incidence of CVD( Reference De Caterina 15 ). In particular, the Gruppo Italiano per lo Studio della Sopravvivenza nell'Infarto miocardico Prevenzione trial, which enrolled patients with a history of myocardial infarction, demonstrated reduced risk of cardiovascular death with fish oil supplementation( 16 ). A similar improvement in survival was also seen in heart failure patients( Reference Tavazzi, Maggioni and Marchioli 17 ). As a testament to these and related clinical studies, the American Heart Association currently recommends eating fish rich in n-3 PUFA for the prevention of CVD (www.americanheart.org).

Although several epidemiological and interventional studies have established a beneficial role for n-3 PUFA in health and disease, the specific mechanisms whereby they exert protective actions are still emerging. Certainly, anti-arrhyrthmogenic effects via direct membrane incorporation of n-3 PUFA have been demonstrated and this may be related to the protective effects of n-3 PUFA in the context of sudden cardiac death( Reference London, Albert and Anderson 7 ). Other mechanisms include the generation of less-potent inflammatory mediators (i.e. 3-series prostanoids and 5-series leukotrienes) that compete for arachidonic acid metabolism and pro-inflammatory effects of eicosanoids( Reference Harbige 4 , Reference Calder 8 ). However, over the last decade, it has also emerged that n-3 PUFA, including both EPA and DHA, are converted into novel families of bioactive lipid mediators that are potent immunomodulatory agonists. This short review will highlight the biosynthesis and biological actions of these mediators, which include the resolvins, protectins and maresins, and discuss the potential for targeted therapeutics based on these specific mediators.

Bioactive lipid mediators generated from n-3 PUFA: biosynthetic pathways

It is well established that bioactive lipid autacoids are generated from PUFA in an enzymatic manner. Prominent examples include the generation of prostanoids and leukotrienes derived from cyclooxygenase (COX)- and lipoxygenase (LOX)-mediated conversion of arachidonic acid (20∶4, n-6). Similarly, arachidonic acid is also a substrate for monoxygenases (i.e., cytochrome P450) that give rise to epoxyeicosatrienoic acids. Collectively, these mediators play numerous physiologic roles, including regulation of haemodynamics, inflammatory cell trafficking and blood coagulation( Reference Samuelsson, Dahlen and Lindgren 5 , Reference Samuelsson 18 Reference Hata and Breyer 20 ). More recently, it has been demonstrated that, like n-6 PUFA, n-3 PUFA, including EPA and DHA, can also serve as substrates for both COX and LOX enzymes and give rise to several new families of bioactive mediators( Reference Serhan, Chiang and Van Dyke 6 , Reference Serhan and Petasis 21 ).

Resolvins

Resolvins are a family of lipid mediators generated in an enzymatic manner from EPA (E-series) or DHA (D-series)( Reference Serhan and Petasis 21 Reference Serhan, Hong and Gronert 24 ). They are so named because they were originally identified during the resolution phase of inflammation and were found to potently regulate this critical process( Reference Serhan, Clish and Brannon 23 ) (see later). While EPA can serve as a substrate for COX-2 to give rise to 3-series prostanoids, acetylation of COX-2 by aspirin permits the generation of 18-HEPE( Reference Arita, Bianchini and Aliberti 25 , Reference Arita, Clish and Serhan 26 ). Of note, 18-HEPE can also be formed through a P450-dependent route( Reference Arita, Clish and Serhan 26 ). This product can be further converted by 5-LOX to 5S,12R,18R-trihydroxy-6Z,8E,10E,14Z,16E-EPA, which was later coined resolvin E1 (RvE1; Fig. 1a)( Reference Serhan, Clish and Brannon 23 , Reference Arita, Bianchini and Aliberti 25 ). This latter biosynthetic route is similar to that of leukotriene B4, in that the 5,6 epoxide formed by 5-LOX can be enzymatically hydrolysed by leukotriene A4 hydrolase to yield RvE1( Reference Oh, Pillai and Recchiuti 27 ). More recent studies using chiral chromatography demonstrated that both 18S-HEPE and 18R-HEPE are generated by acetylated COX-2 and are associated with the generation of 18S-RvE1 and 18R-RvE1, respectively( Reference Oh, Pillai and Recchiuti 27 ). Importantly, both mediators are bioactive and share the same specific receptor (see later). While the formation of an epoxide group and enzymatic hydrolysis mediates RvE1 biosynthesis, the 5-hydroperoxy (Hp) group can also be directly reduced to give rise to 5S,18R-dihydroxy-6E,8Z,11Z,14Z,16E-EPA, which is denoted RvE2( Reference Oh, Dona and Fredman 28 , Reference Tjonahen, Oh and Siegelman 29 ). This structurally unique mediator is also bioactive. More recently, a third member of the E-series resolvin family was discovered and its structure was determined. Like RvE2, resolvin E3 is a dihydroxy-containing product generated from EPA by a 12/15-LOX pathway as opposed to the 5-LOX pathway involved in RvE1 and RvE2 biosynthesis( Reference Isobe, Arita and Matsueda 30 ). This new pathway, which is operative in eosinophils, generates two distinct stereoisomers, namely 17R, 18S-diHEPE and 17R, 18R-diHEPE, both of which are bioactive in murine models of acute inflammation( Reference Isobe, Arita and Matsueda 30 ).

Fig. 1. (colour online) Biosynthesis of pro-resolving lipid mediators from EPA and DHA. (a) EPA serves as the substrate precursor for the E-series resolvins. In the presence of aspirin, acetylated cyclooxygenase (COX)-2 utilises EPA as a substrate and produces 18-HEPE. This intermediate, which can also be generated by a P450 route, can serve as a substrate for 5-lipoxygenase (LOX) to give rise to 5-hydroperoxy (Hp)-18-HEPE. Epoxidation and enzymatic hydrolysis generates resolvin E1 (RvE1), whereas 5-Hp, 18-HEPE can also be directly reduced to generate resolvin E2 (RvE2). (b) DHA is converted to 17-HpDHA by 15-LOX, which, through the formation of an epoxide intermediate, can form protectin D1 (PD1). Conversely, 17-HpDHA can be further converted by 5-LOX to generate resolvin D1 (RvD1). In addition to 15-LOX, DHA can also serve as a substrate for 12-LOX, giving rise to 14-HpDHA, which through enzymatic epoxidation and hydrolysis, gives rise to maresin 1 (MaR1).

Like EPA, DHA can also be converted into a family of bioactive lipid mediators generated during the resolution phase of inflammation, which are denoted D-series resolvins( Reference Serhan, Chiang and Van Dyke 6 ). The common biosynthetic intermediate in D-series resolvin biosynthesis is 17-Hp DHA, which can be generated by either 15-LOX or acetylated COX-2 (Fig. 1b). However, while 15-LOX generates predominately 17S-HpDHA, acetylated COX-2 generates 17R-HpDHA and thus gives rise to ‘aspirin-triggered’ resolvins( Reference Spite and Serhan 31 ). In either case, transcellular biosynthesis of D-series resolvins proceeds through 5-LOX, which generates a series of distinct compounds denoted resolvins D1 (RvD1)–RvD6. RvD1–D4 are trihydroxy-containing regioisomers generated via enzymatic hydrolysis of either a 7, 8 epoxide (RvD1 and RvD2) or a 4, 5 epoxide (RvD3 and RvD4)( Reference Serhan and Petasis 21 , Reference Dalli, Winkler and Colas 32 ). In contrast, RvD5 and RvD6 are dihydroxy-containing mediators that arise through a peroxidase mechanism in which the C4 or C7 hydroperoxide formed prior to epoxidation is converted into a hydroxyl group at position 4 in the case of RvD6 or position 7 in the case of RvD5( Reference Serhan and Petasis 21 ). For a detailed description of the precise stereochemistry, total organic synthesis and biosynthetic pathways giving rise to D-series resolvins, the reader is referred to a recent review by Serhan and Petasis( Reference Serhan and Petasis 21 ). In all cases, these diverse biosynthetic routes giving rise to D-series resolvins generate mediators with distinct stereochemistry and double-bond geometry that in turn dictate their biological actions.

Protectins

The protectins, or neuroprotectins when generated in neural tissues, are so named because they were initially documented to have tissue protective actions in the context of neural injury associated with ischemic stroke( Reference Hong, Gronert and Devchand 33 Reference Mukherjee, Marcheselli and Serhan 35 ). The main member of this family is protectin D1 (PD1), which like D-series resolvins, is generated from DHA (Fig. 1b). The biosynthesis of PD1 proceeds via 15-LOX-mediated conversion of DHA to 17-HpDHA that, in the absence of 5-LOX (which enables biosynthesis of D-series resolvins), forms a 16,17 epoxide that is hydrolysed to 10R, 17S-diHDHA through the conjugated triene system( Reference Serhan and Petasis 21 ). Analogous to the leukotriene biosynthetic pathway, an isomer of PD1 can be generated from 17-HpDHA via double dioxygenation( Reference Serhan, Gotlinger and Hong 36 , Reference Chen, Fenet and Michaud 37 ). This isomer has an E,Z,E double-bond geometry, in contrast to the E,E,Z geometry of the conjugated triene system in PD1 and the stereochemistry of the hydroxyl group at position 10 is in the S configuration. Although less potent than PD1, this double-dioxygenation product reduced polymorphonuclear neutrophil (PMN) infiltration in an acute model of sterile inflammation and also appears to regulate platelet activation( Reference Serhan, Gotlinger and Hong 36 , Reference Chen, Fenet and Michaud 37 ).

Maresins

The maresins are the newest family of pro-resolving lipid mediators generated from DHA and are so named because they are generated by macrophages (macrophage mediators in resolving inflammation)( Reference Serhan, Yang and Martinod 38 ). Maresin-1 (MaR1) is the first member of this family and is generated from DHA by a LOX-dependent mechanism (Fig. 1b)( Reference Serhan, Yang and Martinod 38 ). While 15-LOX forms predominately 17-HpDHA when DHA is the substrate, the murine isoform of 15-LOX, namely 12/15-LOX, also generates a 14-hydroperoxide. Similarly, this product is also generated by 12-LOX, which is likely involved in the biosynthesis of 14-HpDHA in human subjects. This 14-HpDHA product can undergo epoxidation to form a 13,14 epoxide, which similar to the biosynthesis of PD1, can be hydrolysed to generate 7R, 14S dihydroxyDHA (MaR1) through the conjugated double-bond system (Fig. 1b)( Reference Serhan, Yang and Martinod 38 Reference Serhan, Dalli and Karamnov 40 ). Of note, 14-HpDHA can also serve as a substrate for 5-LOX to generate double-dioxygenation product, 7S, 14S-diHDHA, which is markedly less potent than MaR1 in resolving acute inflammation in vivo ( Reference Serhan, Yang and Martinod 38 ).

Resolving inflammation and n-3 PUFA derived mediators

Complete resolution is the normal outcome of acute inflammation and is required to re-establish tissue homoeostasis. Key checkpoints in the resolution of inflammation include the termination of PMN infiltration into the injured tissue, the timely apoptosis of PMN, active clearance of apoptotic PMN, microbes and other dead tissue by macrophages, and the efflux of phagocytes from the injured area( Reference Buckley, Gilroy and Serhan 41 , Reference Serhan, Brain and Buckley 42 ). If these events are not precisely controlled, inadvertent tissue damage can occur and the later events of the wound healing response, such as angiogenesis and re-epithelialisation are impaired. It is these cell-mediated events in active resolving inflammation that are regulated by specialised pro-resolving lipid mediators (SPM), which include the resolvins, protectins and maresins.

As detailed earlier, these lipid mediators are generated in an enzymatic manner by enzymes expressed primarily in leucocytes, although other cell types, such as epithelial and endothelial cells could also be involved in transcellular SPM biosynthesis. While our current understanding of the precise mechanisms governing a switch from pro-inflammatory lipid mediator to SPM biosynthesis is incomplete, it should be noted that LOX and COX enzymes are subject to dynamic transcriptional regulation. For example, it is well documented that engagement of pattern recognition receptors initiates inflammatory signalling pathways giving rise to increased transcriptional regulators of 5-LOX and COX-2 enzymes, such as the NF-κB and activator protein-1 pathways( Reference Kang, Mbonye and DeLong 43 , Reference Silverman and Drazen 44 ). Moreover, cytokines generated during a type 2 inflammatory response, such as IL-4 regulate 15-LOX expression in mononuclear leucocytes( Reference Conrad, Kuhn and Mulkins 45 ). Indeed, Th2-skewed peripheral blood mononuclear cells generate SPM and alternatively activated macrophages (M2) generate more SPM in total than classically activated (M1) macrophages( Reference Ariel, Li and Wang 46 , Reference Dalli and Serhan 47 ). It should be noted that engulfment of apoptotic cells by macrophages is also a stimulus for SPM generation. Thus, SPM biosynthesis is regulated in a temporal manner and is dependent on the particular leucocyte subsets and enzymatic pathways operative at specific points in time. Interestingly, different types of inflammation are associated with specific SPM signatures. For example, bacterial infection biases production of RvD5, while viral infection regulates PD1 biosynthesis( Reference Chiang, Fredman and Backhed 48 , Reference Morita, Kuba and Ichikawa 49 ).

Once generated, SPM act locally to promote resolution of inflammation and they have multiple cellular targets. Most SPM identified to date block PMN infiltration into sites of inflammation. Mechanisms involved include the down-regulation of adhesion receptors (i.e. CD11b), cytoskeletal structural rearrangements, and endothelial production of anti-adhesive mediators, such as nitric oxide( Reference Serhan and Petasis 21 , Reference Spite and Serhan 31 , Reference Spite, Norling and Summers 50 ). Modulation of this phase of the acute inflammatory response is essential to prevent excessive PMN accumulation in tissues. Next, some SPM, including RvE1, override PMN survival signalling to allow timely apoptosis to occur( Reference El Kebir, Gjorstrup and Filep 51 ). Like aberrant PMN infiltration, prolonged PMN survival can delay resolution of inflammation( Reference Serhan, Brain and Buckley 42 ). One of the most prominent defining features of actively resolving inflammation is the macrophage-dependent clearance of apoptotic cells( Reference Serhan, Brain and Buckley 42 ). As alluded to, this process is required to prevent post-apoptotic secondary necrosis of lingering apoptotic cells. Like the regulation of PMN chemotaxis, most SPM identified to date actively promote macrophage efferocytosis. Controlling both the magnitude of PMN infiltration, while also stimulating their removal by macrophages is a characteristic ‘dual action’ of SPM( Reference Spite and Serhan 31 ). In addition to the clearance of apoptotic cells, SPM also promote macrophage phagocytosis of bacteria and promote the efflux of phagocytes from sites of inflammation( Reference Chiang, Fredman and Backhed 48 , Reference Spite, Norling and Summers 50 , Reference Schwab, Chiang and Arita 52 ). This was shown in animal models of peritonitis and sepsis, in which treatment with SPM, such as PD1 and RvD2, was shown to enhance the appearance of phagocytes in the spleen and lymph nodes( Reference Spite, Norling and Summers 50 , Reference Schwab, Chiang and Arita 52 ).

In addition to these well-defined endpoints in leucocyte trafficking, SPM also regulate other processes that allow for resolution of inflammation. For example, SPM, including PD1, stimulate the up-regulation of chemokine receptors on apoptotic cells, which promotes scavenging of soluble chemokines in inflammatory exudates( Reference Ariel, Fredman and Sun 53 ). Moreover, RvE1 was shown to stimulate the up-regulation of CD55 on epithelial cells to promote PMN clearance( Reference Campbell, Louis and Tomassetti 54 ). The stimulatory actions of SPM distinguish them from other n-3 PUFA-derived mediators, such as the 3-series prostanoids or the 5-series leukotrienes, which are primarily less potent pro-inflammatory mediators or potentially endogenous receptor antagonists( Reference Calder 8 ). While discussion of all documented biological roles of SPM are beyond the scope of this review, the key biological roles of SPM in the resolution of inflammation have identified them as a new class of mediators and have helped to study the process of resolution itself.

Pro-resolving lipid mediators: identification of specific receptors

The biological actions of most lipid mediators, including the leukotrienes and prostaglandins, are mediated primarily by G-protein coupled receptors (GPCR). Initial studies interrogating the mechanisms whereby certain SPM elicit their biological actions demonstrated that pertussis toxin abolished the effects of SPM in many cases. Indeed, stimulation of macrophage phagocytosis by RvD1 is completely blocked by pertussis toxin, as is the stimulation of nitric oxide and prostacyclin production in endothelial cells stimulated by RvD2( Reference Spite, Norling and Summers 50 , Reference Krishnamoorthy, Recchiuti and Chiang 55 ). This suggested that SPM may bind to specific GPCR that couple to Gαi. The first SPM demonstrated to bind a specific GPCR was RvE1. Based on the fact that RvE1 reduced PMN recruitment during acute inflammation in vivo and that this process is both promoted and counter-regulated by other lipid mediators such as leukotriene B4 and lipoxin A4, a search for an RvE1 receptor began by screening receptors closely related to GPCR for these other lipid mediators. Using this unbiased approach, it was determined that RvE1 inhibited TNF-α-stimulated activation of NF-κB in cells transfected with a GPCR-denoted ChemR23( Reference Arita, Bianchini and Aliberti 25 ). Radioligand binding studies demonstrated that RvE1 specifically binds ChemR23 with high affinity (K d∼11 nm). In peripheral blood monocytes and ChemR23-transfected HEK293 cells, RvE1 stimulated phosphorylation of extracellular-signal-regulated kinase ( Reference Ohira, Arita and Omori 56 ). Similarly, stimulation of macrophage phagocytosis by RvE1 is blocked by an extracellular-signal-regulated kinase inhibitor, providing further evidence for receptor-mediated pro-resolving actions of RvE1. In vivo, RvE1 inhibited PMN infiltration in a murine model of peritonitis and the doses of RvE1 required to elicit such actions was log-orders of magnitude lower in mice with transgenic overexpression of ChemR23( Reference Gao, Faibish and Fredman 57 ).

Further studies on the receptor-mediated biological actions of RvE1 demonstrated that direct receptor crosstalk is an important mechanism whereby RvE1 elicits its effects. In human platelets, RvE1 blocks activation, aggregation and ADP-stimulated P-selectin mobilisation( Reference Dona, Fredman and Schwab 58 , Reference Fredman, Van Dyke and Serhan 59 ). While direct binding of ADP receptor, P2Y12 was ruled out, it was demonstrated that ChemR23-dependent activation by RvE1 inhibits P2Y12 signalling. Indeed, co-transfection of P2Y12 expressing cells with ChemR23 blocked ADP-stimulated calcium mobilisation in the presence of RvE1, whereas RvE1 failed to block P2Y12 signalling in mock-transfected cells( Reference Fredman, Van Dyke and Serhan 59 ). Of interest, ChemR23 is not highly expressed on PMN and later studies demonstrated that in addition to serving as an agonist of this receptor, RvE1 also blocks leukotriene B4-induced activation of PMN in a B leukotriene receptor-1-dependent manner( Reference Arita, Ohira and Sun 60 ). While a specific GPCR for RvE2 has not yet been identified, it is noteworthy that RvE2 shows the specific binding with human PMN( Reference Oh, Dona and Fredman 28 ).

In addition to RvE1, other SPM have also been recently shown to bind specific GPCR. In human subjects, two GPCR have been shown to mediate the pro-resolving actions of D-series resolvin, RvD1( Reference Krishnamoorthy, Recchiuti and Chiang 55 ). Building upon observations that regulation of actin polymerisation and adhesion receptor expression by RvD1 in human PMN was sensitive to pertussis toxin, a screening approach revealed that RvD1 binds both GPR32 (a previous orphan receptor) as well as the lipoxin A4 receptor, FPR2 (also denoted ALX). Radioligand binding studies demonstrated that RvD1 binds human leucocytes with high affinity (K d = 0·17 nm) and binding was observed on both PMN and monocytes. In macrophages, stimulation of phagocytosis by RvD1 was blocked by shRNA-mediated knock-down of FPR2 and GPR32, establishing the involvement of receptor-mediated signalling( Reference Krishnamoorthy, Recchiuti and Chiang 55 ). The effects of RvD1 in regulating PMN infiltration during acute inflammation in vivo were enhanced in mice with transgenic overexpression of human FPR2, whereas the regulation of PMN trafficking by RvD1 is abolished in mice deficient in the closely related murine homolog of FPR2( Reference Krishnamoorthy, Recchiuti and Chiang 61 , Reference Norling, Dalli and Flower 62 ). Collectively, these results unequivocally demonstrate that the pro-resolving actions of RvD1 are mediated by specific binding to GPCR. Lastly, while no specific GPCR for DHA product, PD1, has been identified, specific binding studies using radiolabelled PD1 have documented that PD1 specifically binds both retinal pigment epithelial cells and human PMN( Reference Marcheselli, Mukherjee and Arita 63 ). Importantly, PD1 binding was displaced in homoligand displacement assays, whereas its isomer, 10S, 17S-diHDHA was less effective in competing for PD1 binding, and a Δ15-trans isomer of PD1 was essentially inactive( Reference Marcheselli, Mukherjee and Arita 63 ). Future studies are likely to reveal important new insights into the specific receptors that mediate the biological actions of SPM and open up exciting new avenues for targeted pro-resolution therapeutics.

Pro-resolving lipid mediators and animal models of disease

Consistent with the potent actions of SPM on human leucocytes, these novel mediators have beneficial actions that have been demonstrated in several distinct animal models of disease. As resolvins were originally identified during the resolution phase of acute inflammation in mice, initial studies into the biological role of these mediators aimed to determine why they are generated during this specific phase and whether they are active mediators of resolution. Moving from HPLC isolates to geometrically and stereochemically pure compounds prepared by total organic synthesis, SPM including E-series resolvins, D-series resolvins, protectins and maresins, have been shown to promote resolution of acute inflammation in vivo ( Reference Serhan, Chiang and Van Dyke 6 , Reference Serhan and Petasis 21 , Reference Zhang and Spite 22 , Reference Spite and Serhan 31 ). Specifically, these SPM shorten the resolution interval, the time during which PMN decline from their maximum value by 50%( Reference Serhan, Chiang and Van Dyke 6 ). This parameter, which is indicative of reduced PMN infiltration and enhanced removal of apoptotic PMN by macrophages, is a critical defining feature of pro-resolving mediators. Moving beyond acute models of sterile inflammation, multiple studies have now reported that SPM also combat bacterial infection by controlling leucocyte trafficking and actively promoting both PMN and macrophage-mediated phagocytosis and bacterial killing. This translates into improved survival in multiple distinct models of infection, including polymicrobial sepsis induced by caecal ligation and puncture, as well as direct instillation of live Gram-negative bacteria( Reference Chiang, Fredman and Backhed 48 , Reference Spite, Norling and Summers 50 ). In the latter case, SPM were shown to lower the threshold of antibiotic therapy, suggesting that they may be effective adjunctive therapeutics in the context of infection( Reference Chiang, Fredman and Backhed 48 ). By selectively enhancing effector functions of leucocytes and at the same time preventing overzealous inflammatory cytokine production and leucocyte recruitment, SPM have been shown to be tissue protective in several other distinct models of inflammation as well, including colitis, cancer, periodontal disease, diabetes, stroke and pathological angiogenesis. The reader is referred to more in-depth reviews regarding the role of SPM in animal models of inflammation and disease( Reference Serhan, Chiang and Van Dyke 6 , Reference Serhan and Petasis 21 , Reference Zhang and Spite 22 , Reference Spite and Serhan 31 ).

More recent studies on isolated SPM have shown that in addition to promoting bacterial containment and preventing excessive leucocyte accumulation in tissues, these resolution agonists may be particularly important for later phases of wound healing (i.e. tissue repair). For example, studies in diabetic rodents, which are used as a model of the delayed wound healing that occurs in human diabetics, have demonstrated that treatment with RvD1 increases the rate of wound closure and promotes granulation tissue formation( Reference Tang, Zhang and Hellmann 64 ). In the context of diabetes, the time to wound closure is critical to prevent secondary infection. Moreover, RvD2 prevents tissue necrosis in rodent models of burn injury by preventing thrombosis and PMN sequestration and thereby enhancing microvascular access to the healing dermis( Reference Bohr, Patel and Sarin 65 , Reference Kurihara, Jones and Yu 66 ). Other SPM, such as RvD1, have been shown to stimulate keratinocyte migration in vitro, indicating that SPM probably have other diverse cellular targets within wounds and that they may promote other phases of wound repair beyond regulating leucocyte trafficking( Reference Norling, Spite and Yang 67 ). Finally, the newest member of the SPM genus, namely MaR1, directly stimulates tissue regeneration in brown planaria (D. tigrina) subject to surgical injury( Reference Serhan, Dalli and Karamnov 40 ). Given that MaR1 was also biosynthesised during the tissue regeneration process and rescued altered regeneration induced by LOX inhibition, MaR1 may also be a critical endogenous mediator of the regeneration process.

Animal models of disease have also been important to determine the endogenous role of SPM in the protective actions of n-3 PUFA. In particular, feeding a diet rich in n-3 PUFA (particularly EPA and DHA), increases endogenous production of SPM in acute sterile peritonitis, obesity, non-alcoholic fatty liver disease and pathologic retinal angiogenesis( Reference Serhan, Chiang and Van Dyke 6 , Reference Connor, SanGiovanni and Lofqvist 11 , Reference Serhan and Petasis 21 , Reference Claria, Dalli and Yacoubian 68 Reference Gonzalez-Periz, Horrillo and Ferre 71 ). Moreover, genetic manipulation of mice to increase endogenous production of EPA and DHA via fat-1 transgenesis (discussed earlier), also increases production of SPM in the context of inflammation associated with colitis, melanoma growth and pathologic angiogenesis( Reference Hudert, Weylandt and Lu 10 Reference Xia, Lu and Wang 12 ). In these studies, isolated SPM largely recapitulate the actions of increasing n-3 PUFA, suggesting that, not only are they generated endogenously from n-3 PUFA, but that they may in part underlie the protective actions of n-3 PUFA in these scenarios. Future studies designed to establish this cause–effect relationship using specific SPM-receptor knock-out mice for example, are likely to lend important insights into the role of n-3 PUFA in different disease states.

Human clinical studies: are resolvins a new class of pro-resolution therapeutics?

A myriad of studies in rodents and isolated human leucocytes have unequivocally established that SPM are generated from n-3 PUFA and that they have potent immunomodulatory actions that are consistent with the protective effects of n-3 PUFA. That generation of SPM could underlie the beneficial effects of n-3 PUFA supplementation have been strengthened by recent studies in human subjects. In healthy human volunteers taking a fish oil supplement for just 3 weeks (4 g/d; 35% EPA, 25% DHA), SPM including RvD1, RvD2, PD1 and SPM biosynthetic precursors, 17-HDHA and 18-HEPE, were identified( Reference Mas, Croft and Zahra 72 ). Moreover, the levels of these mediators identified using a specific liquid chromatography-tandem MS based approach, were found to be within the range at which they are biologically active (e.g. about 20–40 pg/ml for RvD1 and RvD2). In addition, other studies have established that 18-HEPE and RvE1 are generated in healthy human subjects within 3–4 h of EPA and aspirin administration( Reference Arita, Bianchini and Aliberti 25 , Reference Oh, Pillai and Recchiuti 27 ).

In contrast to the generation of SPM in healthy volunteers given n-3 PUFA supplements, other human studies suggest that SPM generation may be deficient in the context of certain diseases associated with chronic, unresolved inflammation. For instance, PD1 and 17-HDHA were identified in exhaled breath condensates from healthy individuals, whereas only trace amounts were detected in human subjects with clinical exacerbation of asthma( Reference Levy, Kohli and Gotlinger 73 ). Similarly, SPM, including RvD1, RvD2 and PD1 were identified in human subcutaneous adipose tissue samples obtained from healthy individuals, whereas the levels of PD1 and 17-HDHA were significantly reduced in subcutaneous adipose tissue obtained from patients with peripheral vascular disease( Reference Claria, Nguyen and Madenci 70 ). This result is similar to deficiencies observed in other pro-resolving lipid mediators, such as lipoxin A4, observed in asthma and other chronic inflammatory diseases including peripheral artery disease( Reference Ho, Spite and Owens 74 , Reference Sanak, Levy and Clish 75 ). Finally, our recent studies in a rodent model of diabetic wound healing also demonstrated a reduced SPM biosynthetic capacity despite similar levels of DHA in the wounds of diabetic and non-diabetic mice( Reference Tang, Zhang and Hellmann 64 ). Given that n-3 PUFA improve disease outcomes in some diseases but not others (e.g. asthma, diabetes and inflammatory bowel disease), it is possible that impaired downstream metabolism of n-3 PUFA could in part underlie this lack of efficacy and the development of a comprehensive understanding of the mediators of the protective actions of n-3 PUFA may help to identify responders v. non-responders( Reference Calder 8 ). Further human clinical studies will be required to elucidate these relationships fully.

Building upon evidence that the generation of SPM may in part be responsible for the protective actions of n-3 PUFA in human subjects, clinical studies have begun to determine whether SPM might be effective targeted therapeutics. Resolvyx (www.resolvyx.com) has been at the forefront of this effort, initiating the first clinical studies with n-3 PUFA-derived SPM, including RvE1. The company's product pipeline includes a synthetic RvE1 analogue, denoted RX-10045, which has been successfully used in a phase 2 clinical study for the treatment of dry eye. In 2009, Resolvyx reported positive results of the 28-d, randomised, placebo-controlled trial, which enrolled 232 patients (www.clinicaltrials.gov). The primary endpoint of the trial was the Worst Symptom Score, which is a composite indicator of dryness, ocular discomfort, stinging, burning and grittiness. Patients treated with RX-10045 showed significant improvements in this primary endpoint compared with placebo and RX-10045 was safe and well-tolerated. This particular analogue and clinical programme has now been licensed to Celtic Therapeutics for further clinical development. In addition to RX-10045, Resolvyx is also developing a programme around synthetic RvE1 (RX-10001) and PD1 (RX-20001) for other indications, such as asthma, inflammatory bowel disease and rheumatoid arthritis, and Phase 1 studies have been initiated to assess safety, tolerability, pharmacodynamics and pharmacokinetics (see www.clinicaltrials.gov).

In addition to treating chronic inflammatory pathologies, there is also considerable potential for SPM as a new genus of pain management therapeutics( Reference Ji, Xu and Strichartz 76 ). Recent studies have demonstrated that certain SPM, such as RvE1, RvD1 and RvD2, are potent analgesics in animal models of inflammatory pain. In particular, intrathecal or intraplantar administration of SPM have been shown to decrease pain induced by a variety of stimuli, including formalin, complete Freund's adjuvant, TNF-α and capsaicin without affecting basal pain perception( Reference Ji, Xu and Strichartz 76 Reference Xu, Zhang and Liu 78 ). These SPM, such as RvE1, were more potent than morphine or non-steroidal anti-inflammatory drugs in vivo. Mechanistically, SPM have been shown to regulate activation of transient receptor potential villinoid subtype-1 and transient receptor potential ankyryn 1 in primary sensory neurons with IC50 values in the low nanomolar range, suggesting that these SPM may be endogenous regulators of pain( Reference Ji, Xu and Strichartz 76 Reference Xu, Zhang and Liu 78 ). Although clinical studies have not yet evaluated the efficacy of SPM in regulating pain, this particular therapeutic area holds great promise as chronic pain management continues to be a challenging area of clinical medicine.

Concluding remarks

Studies over the last 10–15 years have defined that n-3 PUFA are enzymatically converted into a diverse array of bioactive autacoids that have potent immunomodulatory and tissue protective actions. These mediators bind specific receptors, have multiple cellular targets and their biosynthesis and actions have been demonstrated in both rodents and human subjects. The elucidation of these new pathways has provided a mechanistic understanding of the protective roles of n-3 PUFA in health and disease and may lead to the development of effective targeted therapeutics aimed at treating chronic inflammatory diseases.

Acknowledgement

None.

Financial Support

The support of National Institutes of Health grants HL106173 and GM103492 is gratefully acknowledged. The National Institutes of Health had no role in the design, analysis or writing of this article.

Conflicts of Interest

None.

Authorship

M. S. wrote and edited the manuscript.

References

1. Burr, GO & Burr, MM (1973) Nutrition classics from The Journal of Biological Chemistry 82:345–67, 1929. A new deficiency disease produced by the rigid exclusion of fat from the diet. Nutr Rev 31, 248249.Google Scholar
2. Le, HD, Meisel, JA, de Meijer, VE et al. (2009) The essentiality of arachidonic acid and docosahexaenoic acid. Prostaglandins Leukot Essent Fatty Acids 81, 165170.Google Scholar
3. Fritsche, K (2006) Fatty acids as modulators of the immune response. Annu Rev Nutr 26, 4573.CrossRefGoogle ScholarPubMed
4. Harbige, LS (2003) Fatty acids, the immune response, and autoimmunity: a question of n-6 essentiality and the balance between n-6 and n-3. Lipids 38, 323341.Google Scholar
5. Samuelsson, B, Dahlen, SE, Lindgren, JA et al. (1987) Leukotrienes and lipoxins: structures, biosynthesis, and biological effects. Science 237, 11711176.Google Scholar
6. Serhan, CN, Chiang, N & Van Dyke, TE (2008) Resolving inflammation: dual anti-inflammatory and pro-resolution lipid mediators. Nat Rev Immunol 8, 349361.Google Scholar
7. London, B, Albert, C, Anderson, ME et al. (2007) Omega-3 fatty acids and cardiac arrhythmias: prior studies and recommendations for future research: a report from the National Heart, Lung, and Blood Institute and Office Of Dietary Supplements Omega-3 Fatty Acids and their Role in Cardiac Arrhythmogenesis Workshop. Circulation 116, e320e335.Google Scholar
8. Calder, PC (2013) Omega-3 polyunsaturated fatty acids and inflammatory processes: nutrition or pharmacology? Br J Clin Pharmacol 75, 645662.Google Scholar
9. Sprecher, H (2000) Metabolism of highly unsaturated n-3 and n-6 fatty acids. Biochim Biophys Acta 1486, 219231.CrossRefGoogle ScholarPubMed
10. Hudert, CA, Weylandt, KH, Lu, Y et al. (2006) Transgenic mice rich in endogenous omega-3 fatty acids are protected from colitis. Proc Natl Acad Sci USA 103, 1127611281.Google Scholar
11. Connor, KM, SanGiovanni, JP, Lofqvist, C et al. (2007) Increased dietary intake of omega-3-polyunsaturated fatty acids reduces pathological retinal angiogenesis. Nat Med 13, 868873.Google Scholar
12. Xia, S, Lu, Y, Wang, J et al. (2006) Melanoma growth is reduced in fat-1 transgenic mice: impact of omega-6/omega-3 essential fatty acids. Proc Natl Acad Sci USA 103, 1249912504.Google Scholar
13. DeFilippis, AP & Sperling, LS (2006) Understanding omega-3's. Am Heart J 151, 564570.CrossRefGoogle ScholarPubMed
14. Thies, F, Garry, JM, Yaqoob, P et al. (2003) Association of n-3 polyunsaturated fatty acids with stability of atherosclerotic plaques: a randomised controlled trial. Lancet 361, 477485.Google Scholar
15. De Caterina, R (2011) n-3 fatty acids in cardiovascular disease. N Engl J Med 364, 24392450.CrossRefGoogle ScholarPubMed
16. GISSI-prevenzione Investigators (1999) Dietary supplementation with n-3 polyunsaturated fatty acids and vitamin E after myocardial infarction: results of the GISSI-Prevenzione trial. Gruppo Italiano per lo Studio della Sopravvivenza nell'Infarto miocardico. Lancet 354, 447455.Google Scholar
17. Tavazzi, L, Maggioni, AP, Marchioli, R et al. (2008) Effect of n-3 polyunsaturated fatty acids in patients with chronic heart failure (the GISSI-HF trial): a randomised, double-blind, placebo-controlled trial. Lancet 372, 12231230.Google Scholar
18. Samuelsson, B (2012) Role of basic science in the development of new medicines: examples from the eicosanoid field. J Biol Chem 287, 1007010080.Google Scholar
19. Capdevila, JH, Harris, RC & Falck, JR (2002) Microsomal cytochrome P450 and eicosanoid metabolism. Cell Mol Life Sci 59, 780789.Google Scholar
20. Hata, AN & Breyer, RM (2004) Pharmacology and signaling of prostaglandin receptors: multiple roles in inflammation and immune modulation. Pharmacol Ther 103, 147166.Google Scholar
21. Serhan, CN & Petasis, NA (2011) Resolvins and protectins in inflammation resolution. Chem Rev 111, 59225943.Google Scholar
22. Zhang, MJ & Spite, M (2012) Resolvins: anti-inflammatory and proresolving mediators derived from omega-3 polyunsaturated fatty acids. Annu Rev Nutr 32, 203227.CrossRefGoogle ScholarPubMed
23. Serhan, CN, Clish, CB, Brannon, J et al. (2000) Novel functional sets of lipid-derived mediators with antiinflammatory actions generated from omega-3 fatty acids via cyclooxygenase 2-nonsteroidal antiinflammatory drugs and transcellular processing. J Exp Med 192, 11971204.Google Scholar
24. Serhan, CN, Hong, S, Gronert, K et al. (2002) Resolvins: a family of bioactive products of omega-3 fatty acid transformation circuits initiated by aspirin treatment that counter proinflammation signals. J Exp Med 196, 10251037.Google Scholar
25. Arita, M, Bianchini, F, Aliberti, J et al. (2005) Stereochemical assignment, antiinflammatory properties, and receptor for the omega-3 lipid mediator resolvin E1. J Exp Med 201, 713722.Google Scholar
26. Arita, M, Clish, CB & Serhan, CN (2005) The contributions of aspirin and microbial oxygenase to the biosynthesis of anti-inflammatory resolvins: novel oxygenase products from omega-3 polyunsaturated fatty acids. Biochem Biophys Res Commun 338, 149157.CrossRefGoogle Scholar
27. Oh, SF, Pillai, PS, Recchiuti, A et al. (2011) Pro-resolving actions and stereoselective biosynthesis of 18S E-series resolvins in human leucocytes and murine inflammation. J Clin Invest 121, 569581.CrossRefGoogle ScholarPubMed
28. Oh, SF, Dona, M, Fredman, G et al. (2012) Resolvin E2 formation and impact in inflammation resolution. J Immunol 188, 45274534.Google Scholar
29. Tjonahen, E, Oh, SF, Siegelman, J et al. (2006) Resolvin E2: identification and anti-inflammatory actions: pivotal role of human 5-lipoxygenase in resolvin E series biosynthesis. Chem Biol 13, 11931202.Google Scholar
30. Isobe, Y, Arita, M, Matsueda, S et al. (2012) Identification and structure determination of novel anti-inflammatory mediator resolvin E3, 17,18-dihydroxyeicosapentaenoic acid. J Biol Chem 287, 1052510534.Google Scholar
31. Spite, M & Serhan, CN (2010) Novel lipid mediators promote resolution of acute inflammation: impact of aspirin and statins. Circ Res 107, 11701184.Google Scholar
32. Dalli, J, Winkler, JW, Colas, RA et al. (2013) Resolvin D3 and aspirin-triggered resolvin D3 are potent immunoresolvents. Chem Biol 20, 188201.Google Scholar
33. Hong, S, Gronert, K, Devchand, PR et al. (2003) Novel docosatrienes and 17S-resolvins generated from docosahexaenoic acid in murine brain, human blood, and glial cells. Autacoids in anti-inflammation. J Biol Chem 278, 1467714687.Google Scholar
34. Marcheselli, VL, Hong, S, Lukiw, WJ et al. (2003) Novel docosanoids inhibit brain ischemia-reperfusion-mediated leucocyte infiltration and pro-inflammatory gene expression. J Biol Chem 278, 4380743817.Google Scholar
35. Mukherjee, PK, Marcheselli, VL, Serhan, CN et al. (2004) Neuroprotectin D1: a docosahexaenoic acid-derived docosatriene protects human retinal pigment epithelial cells from oxidative stress. Proc Natl Acad Sci USA 101, 84918496.Google Scholar
36. Serhan, CN, Gotlinger, K, Hong, S et al. (2006) Anti-inflammatory actions of neuroprotectin D1/protectin D1 and its natural stereoisomers: assignments of dihydroxy-containing docosatrienes. J Immunol 176, 18481859.Google Scholar
37. Chen, P, Fenet, B, Michaud, S et al. (2009) Full characterization of PDX, a neuroprotectin/protectin D1 isomer, which inhibits blood platelet aggregation. FEBS Lett 583, 34783484.Google Scholar
38. Serhan, CN, Yang, R, Martinod, K et al. (2009) Maresins: novel macrophage mediators with potent antiinflammatory and proresolving actions. J Exp Med 206, 1523.Google Scholar
39. Dalli, J, Zhu, M, Vlasenko, NA et al. (2013) The novel 13S,14S-epoxy-maresin is converted by human macrophages to maresin1 (MaR1), inhibits leukotriene A4 hydrolase (LTA4H), and shifts macrophage phenotype. FASEB J.Google Scholar
40. Serhan, CN, Dalli, J, Karamnov, S et al. (2012) Macrophage proresolving mediator maresin 1 stimulates tissue regeneration and controls pain. FASEB J 26, 17551765.Google Scholar
41. Buckley, CD, Gilroy, DW, Serhan, CN et al. (2013) The resolution of inflammation. Nat Rev Immunol 13, 5966.CrossRefGoogle ScholarPubMed
42. Serhan, CN, Brain, SD, Buckley, CD et al. (2007) Resolution of inflammation: state of the art, definitions and terms. FASEB J 21, 325332.Google Scholar
43. Kang, YJ, Mbonye, UR, DeLong, CJ et al. (2007) Regulation of intracellular cyclooxygenase levels by gene transcription and protein degradation. Prog Lipid Res 46, 108125.Google Scholar
44. Silverman, ES & Drazen, JM (1999) The biology of 5-lipoxygenase: function, structure, and regulatory mechanisms. Proc Assoc Am Physicians 111, 525536.Google Scholar
45. Conrad, DJ, Kuhn, H, Mulkins, M et al. (1992) Specific inflammatory cytokines regulate the expression of human monocyte 15-lipoxygenase. Proc Natl Acad Sci U S A 89, 217221.Google Scholar
46. Ariel, A, Li, PL, Wang, W et al. (2005) The docosatriene protectin D1 is produced by TH2 skewing and promotes human T cell apoptosis via lipid raft clustering. J Biol Chem 280, 4307943086.Google Scholar
47. Dalli, J & Serhan, CN (2012) Specific lipid mediator signatures of human phagocytes: microparticles stimulate macrophage efferocytosis and pro-resolving mediators. Blood 120, e60e72.CrossRefGoogle ScholarPubMed
48. Chiang, N, Fredman, G, Backhed, F et al. (2012) Infection regulates pro-resolving mediators that lower antibiotic requirements. Nature 484, 524528.Google Scholar
49. Morita, M, Kuba, K, Ichikawa, A et al. (2013) The lipid mediator protectin d1 inhibits influenza virus replication and improves severe influenza. Cell 153, 112125.Google Scholar
50. Spite, M, Norling, LV, Summers, L et al. (2009) Resolvin D2 is a potent regulator of leucocytes and controls microbial sepsis. Nature 461, 12871291.Google Scholar
51. El Kebir, D, Gjorstrup, P & Filep, JG (2012) Resolvin E1 promotes phagocytosis-induced neutrophil apoptosis and accelerates resolution of pulmonary inflammation. Proc Natl Acad Sci USA 109, 1498314988.Google Scholar
52. Schwab, JM, Chiang, N, Arita, M et al. (2007) Resolvin E1 and protectin D1 activate inflammation-resolution programmes. Nature 447, 869874.Google Scholar
53. Ariel, A, Fredman, G, Sun, YP et al. (2006) Apoptotic neutrophils and T cells sequester chemokines during immune response resolution through modulation of CCR5 expression. Nat Immunol 7, 12091216.Google Scholar
54. Campbell, EL, Louis, NA, Tomassetti, SE et al. (2007) Resolvin E1 promotes mucosal surface clearance of neutrophils: a new paradigm for inflammatory resolution. FASEB J 21, 31623170.CrossRefGoogle ScholarPubMed
55. Krishnamoorthy, S, Recchiuti, A, Chiang, N et al. (2010) Resolvin D1 binds human phagocytes with evidence for proresolving receptors. Proc Natl Acad Sci USA 107, 16601665.Google Scholar
56. Ohira, T, Arita, M, Omori, K et al. (2010) Resolvin E1 receptor activation signals phosphorylation and phagocytosis. J Biol Chem 285, 34513461.Google Scholar
57. Gao, L, Faibish, D, Fredman, G et al. (2013) Resolvin E1 and chemokine-like receptor 1 mediate bone preservation. J Immunol 190, 689694.Google Scholar
58. Dona, M, Fredman, G, Schwab, JM et al. (2008) Resolvin E1, an EPA-derived mediator in whole blood, selectively counter regulates leukocytes and platelets. Blood 112, 848855.Google Scholar
59. Fredman, G, Van Dyke, TE & Serhan, CN (2010) Resolvin E1 regulates adenosine diphosphate activation of human platelets. Arterioscler Thromb Vasc Biol 30, 20052013.Google Scholar
60. Arita, M, Ohira, T, Sun, YP et al. (2007) Resolvin E1 selectively interacts with leukotriene B4 receptor BLT1 and ChemR23 to regulate inflammation. J Immunol 178, 39123917.Google Scholar
61. Krishnamoorthy, S, Recchiuti, A, Chiang, N et al. (2012) Resolvin D1 receptor stereoselectivity and regulation of inflammation and proresolving microRNAs. Am J Pathol 180, 20182027.Google Scholar
62. Norling, LV, Dalli, J, Flower, RJ et al. (2012) Resolvin D1 limits polymorphonuclear leukocyte recruitment to inflammatory loci: receptor-dependent actions. Arterioscler Thromb Vasc Biol 32, 19701978.CrossRefGoogle ScholarPubMed
63. Marcheselli, VL, Mukherjee, PK, Arita, M et al. (2010) Neuroprotectin D1/protectin D1 stereoselective and specific binding with human retinal pigment epithelial cells and neutrophils. Prostaglandins Leukot Essent Fatty Acids 82, 2734.Google Scholar
64. Tang, Y, Zhang, MJ, Hellmann, J et al. (2013) Proresolution therapy for the treatment of delayed healing of diabetic wounds. Diabetes 62, 618627.Google Scholar
65. Bohr, S, Patel, SJ, Sarin, D et al. (2013) Resolvin D2 prevents secondary thrombosis and necrosis in a mouse burn wound model. Wound Repair Regen 21, 3543.Google Scholar
66. Kurihara, T, Jones, CN, Yu, YM et al. (2013) Resolvin D2 restores neutrophil directionality and improves survival after burns. FASEB J 6, 22702281.Google Scholar
67. Norling, LV, Spite, M, Yang, R et al. (2011) Cutting edge: humanized nano-proresolving medicines mimic inflammation-resolution and enhance wound healing. J Immunol 186, 55435547.Google Scholar
68. Claria, J, Dalli, J, Yacoubian, S et al. (2012) Resolvin D1 and resolvin D2 govern local inflammatory tone in obese fat. J Immunol 189, 25972605.Google Scholar
69. Claria, J, Gonzalez-Periz, A, Lopez-Vicario, C et al. (2011) New insights into the role of macrophages in adipose tissue inflammation and fatty liver disease: modulation by endogenous omega-3 fatty acid-derived lipid mediators. Front Immunol 2, 49.Google Scholar
70. Claria, J, Nguyen, BT, Madenci, A et al. (2013) Diversity of lipid mediators in human adipose tissue depots. Am J Physiol Cell Physiol (In the Press).CrossRefGoogle ScholarPubMed
71. Gonzalez-Periz, A, Horrillo, R, Ferre, N et al. (2009) Obesity-induced insulin resistance and hepatic steatosis are alleviated by omega-3 fatty acids: a role for resolvins and protectins. FASEB J 23, 19461957.Google Scholar
72. Mas, E, Croft, KD, Zahra, P et al. (2012) Resolvins D1, D2, and other mediators of self-limited resolution of inflammation in human blood following n-3 fatty acid supplementation. Clin Chem 58, 14761484.CrossRefGoogle Scholar
73. Levy, BD, Kohli, P, Gotlinger, K et al. (2007) Protectin D1 is generated in asthma and dampens airway inflammation and hyperresponsiveness. J Immunol 178, 496502.CrossRefGoogle ScholarPubMed
74. Ho, KJ, Spite, M, Owens, CD et al. (2010) Aspirin-triggered lipoxin and resolvin E1 modulate vascular smooth muscle phenotype and correlate with peripheral atherosclerosis. Am J Pathol 177, 21162123.Google Scholar
75. Sanak, M, Levy, BD, Clish, CB et al. (2000) Aspirin-tolerant asthmatics generate more lipoxins than aspirin-intolerant asthmatics. Eur Respir J 16, 4449.Google Scholar
76. Ji, RR, Xu, ZZ, Strichartz, G et al. (2011) Emerging roles of resolvins in the resolution of inflammation and pain. Trends Neurosci 34, 599609.Google Scholar
77. Park, CK, Xu, ZZ, Liu, T et al. (2011) Resolvin D2 is a potent endogenous inhibitor for transient receptor potential subtype V1/A1, inflammatory pain, and spinal cord synaptic plasticity in mice: distinct roles of resolvin D1, D2, and E1. J Neurosci 31, 1843318438.Google Scholar
78. Xu, ZZ, Zhang, L, Liu, T et al. (2010) Resolvins RvE1 and RvD1 attenuate inflammatory pain via central and peripheral actions. Nat Med 16, 592597.Google Scholar
Figure 0

Fig. 1. (colour online) Biosynthesis of pro-resolving lipid mediators from EPA and DHA. (a) EPA serves as the substrate precursor for the E-series resolvins. In the presence of aspirin, acetylated cyclooxygenase (COX)-2 utilises EPA as a substrate and produces 18-HEPE. This intermediate, which can also be generated by a P450 route, can serve as a substrate for 5-lipoxygenase (LOX) to give rise to 5-hydroperoxy (Hp)-18-HEPE. Epoxidation and enzymatic hydrolysis generates resolvin E1 (RvE1), whereas 5-Hp, 18-HEPE can also be directly reduced to generate resolvin E2 (RvE2). (b) DHA is converted to 17-HpDHA by 15-LOX, which, through the formation of an epoxide intermediate, can form protectin D1 (PD1). Conversely, 17-HpDHA can be further converted by 5-LOX to generate resolvin D1 (RvD1). In addition to 15-LOX, DHA can also serve as a substrate for 12-LOX, giving rise to 14-HpDHA, which through enzymatic epoxidation and hydrolysis, gives rise to maresin 1 (MaR1).