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. 2018 Feb;50:48–54. doi: 10.1016/j.coi.2017.10.007

Immunoresolvents signaling molecules at intersection between the brain and immune system

Jesmond Dalli 1, Charles N Serhan 2
PMCID: PMC5869050  PMID: 29154174

Highlights

  • The vagus nerve regulates ILC-3 and macrophage trafficking to the peritoneum.

  • Vagotomy reduces peritoneal PCTR concentrations and alters tissue resolution tone.

  • Resection of the vagus nerve impairs resolution responses to sterile and infectious insults.

Abstract

Understanding mechanisms that control immunity is central in the quest to gain insights into the etiopathology of many of the diseases that afflict modern societies. New results implicate the nervous system as a central player in controlling many aspects of both the innate and adaptive arms of the immune response. Furthermore it is now well appreciated that a novel group of autacoids termed as specialized proresolving mediators, which are enzymatically produced from essential fatty acids, orchestrate the immune response promoting the termination of inflammation as well as tissue repair and regeneration. The present brief review discusses evidence for the crosstalk between the nervous system and leukocytes in regulating SPM production. We will also discuss the impact that this has on controlling tissue resolution tone and the resolution of both infectious and sterile inflammation.

Current Opinion in Immunology 2018, 50:48–54

This review comes from a themed issue on Innate immunity

Edited by Gwendalyn J Randolph

For a complete overview see the Issue and the Editorial

Available online 16th November 2017

https://doi.org/10.1016/j.coi.2017.10.007

0952-7915/© 2017 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).

Introduction

The nervous system integrates signals from the periphery to ensure homeostatic control and host survival. Increasing evidence demonstrates that in addition to regulating sensory and motor functions the nervous system is also essential in regulating the host immune response [1]. This crosstalk between the immune and nervous systems is a primordial defense mechanism where, for example, in the nematode Caenobacter elegans the nervous system is central in controlling innate immunity via the modulation of the non-canonical unfolded protein response [2]. In mammals the nervous system is also important in controlling both the innate and adaptive arms of the immune responses [1, 3, 4]. Recent studies demonstrate that the vagus nerve orchestrates host responses to both sterile, including sterile peritonitis [5], arthritis [6], colitis [7] and cancer [4] as well as infectious insults, for example, polymicrobial sepsis [8] and Escherichia coli infections [3]. These observations have been extended to humans where in patients with arthritis stimulation of the vagus system leads to a significant reduction in disease activity and in circulating markers of inflammation [9].

Efforts to identify signals that control the termination of inflammation recently uncovered a genus of mediators that are produced via the stereoselective conversion of essential fatty acids. These autacoids activate cognate receptors and regulate the biological actions of both innate and adaptive immune cells [10]. Given their potent actions and unique structures these mediators are coined as specialized pro-resolving mediators (SPM). This super-family of mediators is composed of four main families: the arachidonic acid derived lipoxins, the eicosapentaenoic acid (EPA), n−3 docosapentaenoic acid (DPA) and docosahexaenoic acid (DHA)-derived resolvins (Rv) and the n−3 DPA and DHA-derived protectins (PD) and maresins (MaR) (see [11, 12] for a detailed review of their biosynthetic pathways). The production of these mediators is regulated in both a temporal and tissue dependent manner. Recent studies demonstrate that the biological actions of RvD1 (see Table 1 for complete stereochemistry), a DHA-derived SPM, are additive to those of antibiotics reducing the required doses to clear both gram positive and negative infections [13]. These mediators also regulate tissue repair and regeneration by controlling leukocyte trafficking, phenotype, the expression of genes that are involved in the regeneration of damaged tissues and the re-establishment of barrier function [14, 15, 16]. Impaired LXA4 production is associated with dysregulated T-cell response in dry eye disease [17]. RvD1, RvD2 and MaR1 also regulate T-cell phenotype, down-regulating the production of effector cytokines, including IFNγ, in both CD4 and CD8 positive T-cells. They also promote the expression of FoxP3 in CD4 cells [18]. The RvD series precursor 17-HDHA regulates B-cell responses to viral infections, up-regulating antibody production and protecting against influenza infections [19] and pain [20, 21]. The EPA derived RvE1 regulates the responses of antigen presenting cells, including those of dendritic cells reducing the expression of IL-12 [22, 23]. Together these findings emphasize the role of this new super-family of autacoids in the maintenance of homeostasis and re-establishment of function following challenge, whether this is sterile or infective in nature.

Table 1.

Lipid mediator metabolomes, abbreviations and complete stereochemistry.

Metabolome Mediator Abbreviation Stereochemistry
DHA Resolvin D1 RvD1 7S, 8R, 17S-trihydroxy-4Z, 9E, 11E, 13Z, 15E, 19Z-docosahexaenoic acid
Resolvin D2 RvD2 7S, 16R, 17S-trihydroxy-4Z, 8E, 10Z, 12E, 14E, 19Z-docosahexaenoic acid
Resolvin D3 RvD3 4S, 11R, 17S-trihydroxy-5Z, 7E, 9E, 13Z, 15E, 19Z-docosahexanoic acid
Resolvin D4 RvD4 4S, 5R, 17S-trihydroxy-6E, 8E, 10Z, 13Z, 15E, 19Z-docosahexaenoic acid
Resolvin D5 RvD5 7S, 17S-dihydroxy-4Z, 8E, 10Z, 13Z, 15E, 19Z-docosahexaenoic acid
Maresin 1 MaR1 7R, 14S-dihydroxy-4Z, 8E, 10E, 12Z, 16Z, 19Z-docosahexaenoic acid
Protectin conjugate in tissue regeneration 1 PCTR1 16R-glutathionyl, 17S-hydroxy-4Z, 7Z, 10Z, 12E, 14E, 19Z-docosahexaenoic acid
Protectin conjugate in tissue regeneration 2 PCTR2 16-cysteinylglycinyl, 17S-hydroxy-4Z, 7Z, 10Z, 12, 14, 19Z-docosahexaenoic acid
Protectin conjugate in tissue regeneration 3 PCTR3 16-cysteinyl, 17S-hydroxy-4Z, 7Z, 10Z, 12, 14, 19Z-docosahexaenoic acid



EPA Resolvin E1 RvE1 5S, 12R, 18R-trihydroxy-6Z, 8E, 10E, 14Z, 16E-eicosapentaenoic acid



AA Lipoxin A4 LXA4 5S, 6R, 15S-trihydroxy-7E, 9E, 11Z, 13E-eicosatetraenoic acid
Leukotriene B4 LTB4 5S, 12R-dihydroxy-6Z, 8E, 10E, 14Z-eicosatetraenoic acid
Prostaglandin E2 PGE2 9-oxo-11R, 15S-dihydroxy-5Z, 13E-prostadienoic acid
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Several mechanisms are now implicated in the regulation of SPM biosynthesis; regulation of micro RNA 219 controls 5-LOX expression [24]. Post-translation modification of 5-LOX leads to a switch in the product profile of the enzyme from the pro-inflammatory leukotriene (LT) B4 to the pro-resolving mediator LXA4 [25]. Sex hormones also play an important role in regulating SPM production, an action that is also tissue dependent, where for example in murine systems estrogen down-regulates LXA4 production in the eye [17]. In humans this hormone is associated with an increased derman and systemic SPM production including RvD, LX and RvE [26]. Recent results also demonstrate that the nervous system is essential in controlling local SPM formation, during both infectious and sterile inflammation [3, 5]. The present review highlights the recent evidence underpinning the role of the nervous system in regulating tissue SPM production and the role of this response in controlling innate immune responses to both sterile and infectious insults.

Neuronal regulation of tissue lipid mediator profiles

Increasing evidence indicates that the initial response by resident leukocytes to both injury and infections has a significant bearing on outcome of the ensuing inflammation and whether this resolves or becomes chronic [27]. Given the roles that the vagus nerve plays in regulating host immune responses [1, 8, 9], we recently queried whether this nerve was also involved in the tempering of tissue leukocyte phenotype and responses. Using a systematic approach we found that cervical disruption of the vagus nerve lead to a shift in peritoneal concentrations of both pro-resolving as well as inflammation initiating eicosanoids [3]. Peritoneal prostaglandin concentrations were increased in vagotomised mice whereas concentrations of several pro-resolving mediators including the recently uncovered immunoresolvents Protectin Conjugates in Tissue Regeneration (PCTR) were decreased. Of note, cervical disruption of the left vagus did not significantly perturb peritoneal PCTR levels suggesting that the neuro-immune plexus was in this organ was associated with the right vagus. These changes in peritoneal lipid mediator concentrations point to a significant alteration in the ability of the host to mount a protective immune response given the increase in inflammation-initiating eicosanoids and a decrease in the tissue protective mediators; a lipid mediator profile associated with delayed/non-resolving inflammation [10, 28, 29].

Vagus regulates PCTR biosynthesis in peritoneal ILC-3 and macrophages

Changes in peritoneal levels of these mediators were also associated with an alteration peritoneal leukocyte composition, phenotype and functions. Loss of vagal signaling impacted group 3 innate lymphoid cells (ILC-3). The observation that ILC-3 numbers were significantly decreased in the peritoneum of vagotomised mice demonstrates that the biological actions of these cells are not solely restricted to the gastro-intestinal epithelium. Our studies demonstrated that these cells are also found in milky spots within the greater omenutm in proximity to macrophages as well as neuronal bodies arising from the gastroepiploic nerve; a nerve that is linked to the right vagus nerve via the gastroepiploic plexus [30]. This highlights a role for neuronal signaling in controlling ILC-3 trafficking to organs, given the decreased peritoneal cell counts observed following resection of the vagal trunk [3]. These findings are in accord with recent studies demonstrating a role of the neuronal system in regulating ILC-3 responses. Disruption of vagal signaling also impacted the peritoneal macrophage population. Peritoneal macrophage numbers were increased in vagotomise mice, with a shift in both the expression of lineage markers, including arginease-1 and major histocompatibility complex II, as well as lipid mediator profiles. Of note, the biosynthesis of PCTRs in these peritoneal macrophages was altered indicating that vagal signaling controls macrophage lipid mediator biosynthesis. The role of ILC-3 in regulating both peritoneal PCTR concentrations as well as macrophage phenotype was highlighted by the observation that both were altered in Rag1−/− mice when ILC-3 were depleted using an anti-CD90 antibody. In both WT and Rag1−/− mice loss of ILC-3 also lead to a delay in resolution responses to Escherichia coli infections and an impaired ability of peritoneal leukocytes to clear bacteria [3]. Recent studies have also demonstrated an interaction between components of the neuronal system and ILC-3 [31, 32] as well as other immune cells including macrophages [33, 34] in controlling host response to both sterile and infectious insults in the gut mucosa. Thus these findings underscore a central role for neuronal control of immune responses in regulating in the maintenance of tissue homeostasis and the re-establishment of function following an inflammatory episode.

In the lamina propria ILC-3 are central in regulating tissue macrophage responses by producing regulatory factors such as GM-CSF, a mechanism that can be either protective [35] or pathogenic [36]. These cells also express 15-LOX type 1 (mouse cells express the homologous enzyme: 12/15-LOX), the initiating enzyme in the PCTR biosynthetic pathway, and the activity of this enzyme is upregulated by the neurotransmitter acetylcholine [3]. PCTRs are a newly uncovered family of pro-resolving mediators that control neutrophil and macrophage responses to both sterile and infectious stimuli. This family of mediators is biosynthesized via the insertion of molecular oxygen by 15-liopxygenase at carbon 17 of DHA to yield 17S-hydro(peroxy)-4Z,7Z,10Z,13Z,15E,19Z-docosahexaenoic acid. This is subsequently converted to an allylic epoxide intermediate via 15-LOX mediated abstraction of hydrogen from carbon 14 yielding 16S, 17S-epoxy-4Z,7Z,10Z,12E,14E,19Z-docosahexaenoic acid (16S, 17S-epoxy-PD; Figure 1). The epoxide is substrate for conversion by glutathione-S-transferases to the peptide–lipid conjugated mediator 16R-glutathionyl, 17S-hydroxy-4Z,7Z,10Z,12E,14E,19Z-docosahexaenoic acid (PCTR1) that is precursor to 16-cysteinylglycinyl, 17S-hydroxy-4Z,7Z,10Z,12,14,19Z-docosahexaenoic acid (PCTR2) and 16-cysteinyl, 17S-hydroxy-4Z,7Z,10Z,12,14,19Z-docosahexaenoic acid (PCTR3). Each of these mediators promotes the phagocytosis of bacteria by neutrophils and macrophages as well as macrophage efferocytosis [37, 38, 39]. PCTR1 downregulates the production of inflammatory cytokines by macrophages including tumor necrosis factor-α, Interleukin (IL)-3, IL-8, and IL-12(p40) and regulate leukocyte trafficking increasing monocyte/macrophage trafficking and limiting neutrophil recruitment to the site of inflammation [39]. In addition, each of the PCTRs accelerates tissue regeneration in planaria [37, 38].

Figure 1.

Figure 1

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The PCTR biosynthetic pathway and biological actions. In the production of PCTRs DHA is oxygenated at carbon 17 to yield 17S-hydro(peroxy)-4Z,7Z,10Z,13Z,15E,19Z-docosahexaenoic acid. This is subsequently converted to an allylic epoxide intermediate via 15-LOX mediated abstraction of hydrogen from carbon 14 yielding 16S,17S-epoxy-4Z,7Z,10Z,12E,14E,19Z-docosahexaenoic acid (16S, 17S-epoxy-PD). In murine systems these reactions are catalyzed by the 12/15-LOX exnyme. The epoxide is substrate for conversion to the peptide–lipid conjugated mediator 16R-glutathionyl,17S-hydroxy-4Z,7Z,10Z,12E,14E,19Z-docosahexaenoic acid (PCTR1) that is precursor to 16-cysteinylglycinyl,17S-hydroxy-4Z,7Z,10Z,12,14,19Z-docosahexaenoic acid (PCTR2) which in turn is precursor to 16-cysteinyl,17S-hydroxy-4Z,7Z,10Z,12,14,19Z-docosahexaenoic acid (PCTR3). The PCTRs carry potent biological actions in promoting the resolution of infectious inflammation by regulating leukocyte trafficking and the uptake and killing of bacteria as well as tissue repair and regeneration.

Given that leukocytes are central in SPM biosynthesis, loss of PCTRs in mice following the disruption of peritoneal neuronal signaling indicates that the neuro-immune plexus is essential for controlling PCTR biosynthesis in peritoneal leukocytes. In this context production of SPM, in particular PCTR1, by ILC-3 is central in regulating peritoneal macrophage phenotype and responses whereby co-incubations of peritoneal macrophages with either ILC-3 or PCTR1 restores their lipid mediator profiles and their ability to uptake bacteria (Figure 2). This was of biological relevance in infections since reconstitution of vagotomised mice with either ILC-3 or PCTR1 also lead to a restoration of host responses following E. coli inoculation, significantly reducing the number of leukocytes recruited to the peritoneal cavity, shortening the resolution interval (i.e. the time it takes for recruited neutrophils to traffic out of the peritoneum) and upregulated the ability of peritoneal leukocytes to phagocytose and kill bacteria [3]. Furthermore, it rectified LM-SPM biosynthesis during the course of the inflammatory response. Given the role that different SPM play in regulating distinct aspects of the host immune response during select stages of infectious-inflammation this is critical for the re-establishment of function (see [28] for a detailed review and Figure 3). Therefore these findings underscore the role of ILC-3 in orchestrating peritoneal macrophage responses and tissue resolution tone. They also highlight that dysregulation in SPM production alters leukocyte phenotype and consequently function.

Figure 2.

Figure 2

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PCTR mediate neuronal control of tissue resolution tone. Neuronal singling in the peritoneum regulates ILC-3 PCTR production that controls macrophage phenotype, upregulating macrophage SPM biosynthesis and regulating host responses to bacterial infection.

Figure 3.

Figure 3

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Temporal regulation of exudate SPM biosynthesis during self-limited infections. Under ideal conditions neuronal signal regulates tissue PCTR biosynthesis. This controls tissue resident macrophage phenotype and function. Infectious challenge activates resident leukocytes, primarily macrophages, and upregulates maresin (MaR)1 biosynthesis, this mediator promotes the uptake and clearance of apoptotic cells and bacteria and antagonizes the signaling of the leukocyte chemoattractant LTB4 by acting as a partial agonist/antagonist to the LTB4 receptor (BLT1). This regulatory action is also shared with the MaR1 further metabolite 22-OH-MaR1 [43]. As inflammatory exudate matures neutrophil numbers reach a maximum and a shift in the lipid mediator profile occurs with an upregulation in RvD5 and PD1 concentrations that denotes the onset of resolution [13]. This shift in lipid mediator profile is also associated with an increased recruitment of monocytes to the peritoneum and an increase in the number of resolution phase macrophages. During these late stages of inflammation-resolution there is also the formation of tissue-reparative and regenerative mediators termed as maresin conjugates in tissue regeneration (MCTRs) [15]. The biosynthesis of these mediators in human macrophages is initiated via the 14-lipoxygenation of DHA, to yield three novel peptide–lipid conjugated mediators namely MCTR1, MCTR2 and MCTR3 [15].

SPM regulation by the vagus in sterile inflammation

The regulation of lipid mediators by neuronal circuits is also central in the control of inflammation to sterile injury. The vagus nerve regulates the expression of the axonal guidance molecule netrin 1, a protein that in addition to regulating neuronal development also controls immune responses [5, 40, 41]. Incubation of netrin 1 with primary human monocytes upregulates the biosynthesis of several pro-resolving mediators including RvD1 and LXA4. Netrin 1 also increases SPM production in vivo during acute-self limited inflammation, were this protein upregulates exudate RvD5 and PD1 concentrations during zymosan initiated peritonitis. Loss of netrin 1 expression in both vagotomized mice and netrin 1 heterozygote mice lead to dysregulated LM production following sterile challenged, including a reduction in exudate RvD1 and an increase in the inflammation initiating eicosanoids LTB4 and PGE2 [5]. This was also associated with a disruption of resolution processes, increased neutrophil recruitment to the peritoneum, delayed resolution of inflammation and an increase in the exudate levels of several pro-inflammatory cytokines including TNF-α, IL-6 and MIP-1α [5]. Of note, netrin 1 also regulates macrophage efferocytosis, an action that was dependent on the ability of these cells to produce SPM, given that this action was lost in macrophages from 12/15-LOX deficient mice (see Figure 2). In addition, administration of RvD1 to netrin deficient mice restored resolution responses, reducing the amplitude as well as the duration of the inflammatory response [5].

Concluding remarks

The biological actions of SPM are now appreciated to be relevant to many experimental as well as human settings where they regulate the cardinal signs of resolution that include remotio infectiones agens (clearance of infective agents), remotio obruta (clearance of debris), avaritiam ex munere (gain of function) and indolentia (analgesia) [37, 38]. Dysregulation in the production of these mediators is also associated with the development of disease [11, 12, 14, 29, 37, 38, 42] with the mechanisms leading to this impaired production remaining of interest. Thus, the appreciation that the neuro-immune synapse is important in regulating tissue levels of these mediators, with neurotransmitters such acetylcholine being important in controlling local SPM biosynthesis, may provide new leads in the understanding of disease mechanisms. Moreover, these new links to neural immune networks represent new leads in the development of approaches that harness the potent biological actions of SPM and do not carry the many side effects associated with current therapeutics.

Conflict of interest

The authors declare that they have no competing interests.

Acknowledgments

Studies in the authors’ laboratories were supported by a Sir Henry Dale Fellowship jointly funded by the Wellcome Trust and the Royal Society (Grant number: 107613/Z/15/Z), the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (Grant number: 677542) and the Barts Charity (Grant number: MGU0343) to JD as well as National Institutes of Health (grant numbers R01GM38765 and P01GM095467) to CNS.

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