Human milk contains nutrients and bioactive products relevant to infant development and immunological protection. Here, we investigated the proresolving properties of milk using human milk lipid mediator isolates (HLMIs) and determined their impact on resolution programs in vivo and with human macrophages. HLMIs reduced the maximum neutrophil numbers (14.6±1.2 × 106–11.0±1.0 × 106 cells per exudate) and shortened the resolution interval (Ri; 50% neutrophil reduction) by 54% compared with peritonitis. Using rigorous liquid-chromatography tandem-mass spectrometry (LC-MS-MS)-based lipid mediator (LM) metabololipidomics, we demonstrated that human milk possesses a proresolving LM-specialized proresolving mediator (LM-SPM) signature profile, containing SPMs (e.g. resolvins (Rv), protectins (PDs), maresins (MaRs), and lipoxins (LXs)) at bioactive levels (pico-nanomolar concentrations) that enhanced human macrophage efferocytosis and bacterial containment. SPMs identified in human milk included D-series Rvs (e.g., RvD1, RvD2, RvD3, AT-RvD3, and RvD4), PD1, MaR1, E-series Rvs (e.g. RvE1, RvE2, and RvE3), and LXs (LXA4 and LXB4). Of the SPMs identified in human milk, RvD2 and MaR1 (50 ng per mouse) individually shortened Ri by ∼75%. Milk from mastitis gave higher leukotriene B4 and prostanoids and lower SPM levels. Taken together, these findings provide evidence that human milk has proresolving actions via comprehensive LM-SPM profiling, describing a potentially novel mechanism in maternal–infant biochemical imprinting.
The acute inflammatory response is critical in infection and injury. The initiation and resolution of inflammation are important in host defense, each governed by bioactive lipid mediators (LMs) that drive the influx and function of immune cells, and eventually cell efflux and tissue repair.1, 2 Newly identified families of bioactive LMs, biosynthesized from essential fatty acids (EFAs), that actively stimulate resolution of inflammation were uncovered in self-resolving exudates and their structures elucidated.1 Collectively, they are coined specialized proresolving mediators (SPMs).1 SPMs comprise several families that include arachidonic acid (AA)-derived lipoxins (LXs), eicosapentaenoic acid (EPA)-derived resolvins (RvEs), and docosahexaenoic acid (DHA)-derived resolvins (RvD), protectins (PDs), and maresins (MaRs); these structurally distinct families are each host protective with defining actions in anti-inflammation (e.g., limit further neutrophil inflammation), proresolution (e.g., enhancing macrophage clearance of apoptotic cells, debris, and bacteria), pain reduction, and wound healing (reviewed in Serhan1). SPMs are evolutionarly conserved biochemical signals, as they are present in trout, salmon, and planaria (reviewed in Serhan1), and have already been identified in human organ systems, including plasma (RvD1, RvD5, RvD6, and RvE2),3 adipose tissue (RvD1, RvD2, PD1, RvE1, and LXA4),4 placenta (RvD1, AT-RvD1, RvD2, and PD1),5 and recently human milk (RvD1, RvE1, and LXA4).6 LXA4, RvE1, RvD1, and RvD2 each reduce mucosal inflammation, stimulate the innate immune response, and activate resolution of periodontal disease, colitis, and dermal inflammation.7, 8, 9
Human milk is recognized as being important for infant development, providing essential nutrients and bioactive products relevant for maternal–mucosal immune defense and immune system maturation.10 The n-3 EFA including EPA and DHA are enriched in human milk.11 For infants, and particularly premature infants, injurious and infectious insult can be detrimental.12 Hence, protective mechanisms for resolving infection and inflammation in a timely manner and educating the innate immune system in early life are critical and of general interest. In this report, we present evidence for new immunoresolving properties of human milk. Using self-limited acute inflammation and LM metabololipidomics, we found that isolates from human milk contain chemical signals with proresolving actions, namely limiting neutrophil trafficking in vivo, enhancing human macrophage phagocytosis of apoptotic polymorphonuclear neutrophil (PMN) (efferocytosis), and bacterial containment. These actions were attributed to the proresolving LM-SPM signature profile of identified bioactive mediators that included D-series resolvins (AT-RvD1, RvD2, RvD3, AT-RvD3, RvD4, RvD5, and RvD6), PDs (PD1 and AT-PD1), MaR1, E-series Rvs (RvE2 and RvE3), and LXs (AT-LXA4 and LXB4). The LM-SPM profile was altered in human milk from inflamed mammary glands (mastitis) with higher prostanoids and leukotriene B4 (LTB4) and lower SPM levels, and had reduced ability to accelerate resolution interval (Ri). Hence, the present results provide evidence for bioactive resolution signals in human milk that are linked to homeostasis, resolution of inflammation, and innate host responses.
HLMIs stimulate resolution of inflammation
To investigate whether human milk exerts proresolving actions, we used human milk chromatographic isolates with self-limited acute inflammation in vivo and mapped leukocyte trafficking. Because SPMs, including Rvs, PDs, and MaRs, stimulate resolution1 and elute within the methyl formate chromatographic fractions from C18 solid-phase extraction,3 we obtained human milk isolates from these fractions (referred to as human milk lipid mediator isolates (HLMIs)) and assessed their ability to accelerate resolution of acute inflammation in vivo. First, self-limiting acute inflammation was initiated by intraperitoneal injection of yeast cell wall particles (zymosan, 1 mg per mouse), and to quantitate resolution we used defined resolution parameters of acute inflammation.13, 14 The self-limited response reached maximal neutrophil numbers (Ψmax=14.6±1.2 × 106 cells per murine exudate) at 12 h (Tmax), which was followed by subsequent decline (Figure 1a). Administration of HLMIs immediately before inflammatory challenge gave an ∼23.1±8.9% reduction in Ψmax (11.0±1.0 × 106 cells per exudate; Figure 1a, b). Reduction in neutrophil levels was observed throughout the course of inflammation resolution in mice administered HLMIs, with 31.3±4.4% and 24.5±10.9% fewer neutrophils at 24 and 48 h, respectively, compared with peritonitis plus vehicle (Figure 1c).
To quantify the regulation of leukocyte trafficking at the site of inflammation, we investigated the Ri that quantitates the local kinetics of leukocyte infiltration, with the Ri being defined as the time interval between Tmax and T50 (the time interval when the number of infiltrated PMN drops to half of the peak number).13, 14 We found that HLMI administration gave 54% reduction in Ri from 26 to 12 h (Figure 1a, b). These results demonstrate that human milk possesses proresolving properties contained in the HLMIs.
Human milk LM-SPM signature profile: LM metabololipidomics
Because isolates from human milk accelerate resolution (Figure 1), we next sought to investigate the LM profile of human milk. Using liquid-chromatography tandem-mass spectrometry (LC-MS-MS)-based LM metabololipidomics (see Methods for details), we identified a profile signature of LMs consisting of 20 bioactive LMs (Figure 2, Table 1, and Supplementary Figure 1 online) from both lipoxygenase and cyclooxygenase pathways, including Rvs, PDs, MaRs, LXs, and prostanoids (Figure 2, Table 1, Supplementary Figure 1, and Supplementary Table 1). Each LM was identified by matching LC retention time and at least six diagnostic ions, and quantification was achieved using multiple reaction monitoring in accordance with published criteria,3 and as illustrated with representative results obtained for all identified LMs (Supplementary Figure 1b).
LM quantification, using multiple reaction monitoring, demonstrated that SPMs in healthy mature human milk (4–8 weeks postpartum) include AT-RvD1 (67.4±11.7 pg ml−1), RvD2 (82.4±28.0 pg ml−1), RvD3 (7.2±2.7 pg ml−1), AT-RvD3 (15.0±2.9 pg ml−1), RvD4 (27.4±7.5 pg ml−1), RvD5 (19.9±8.9 pg ml−1), RvD6 (6.7±2.4 pg ml−1), PD1 (4.3±2.3 pg ml−1), AT-PD1 (3.8±0.9 pg ml−1), and MaR1 (20.8±6.3 pg ml−1) from the DHA metabolome, RvE2 (321.2±129.2 pg ml−1) and RvE3 (444.9±179.8 pg ml−1) from the EPA metabolome, and AT-LXA4 (370.0±176.6 pg ml−1) and LXB4 (267.1±93.9 pg ml−1) from the AA metabolome (Table 1). These are in addition to RvD1 (147.0±47.2 pg ml−1), RvE1 (8.8±3.6 pg ml−1), and LXA4 (25.7±8.6 pg ml−1). These confirm the identification of RvD1, RvE1, and LXA4 in human milk, at values consistent with those recently reported.6 From the cyclooxygenase pathways, we also identified prostaglandin E2 (PGE2) (409.7±146.6 pg ml−1), prostaglandin D2 (PGD2) (568.3±188.9 pg ml−1), prostaglandin F2α (PGF2α) (111.1±36.2 pg ml−1), and thromboxane B2 (TxB2) (111.8±44.4 pg ml−1) in these samples in accordance with published findings.15 These results demonstrate that human milk contains SPMs at biologically relevant concentrations.
Next, we determined the contribution of each of the major bioactive metabolomes (DHA, EPA, and AA) as well as individual mediators within each metabolome to the human milk LM signature profile (Figure 2). LM metabololipidomics of human milk AA, EPA, and DHA identified bioactive metabolome demonstrated that SPMs represented ∼61.6% of the human milk LM profile (Figure 2), consisting of DHA-derived Rvs, PDs, and MaRs (13.1%), AA-derived LXs (23.5%), and EPA-derived Rvs (24.9%; Figure 2). AA-derived prostanoids amounted to ∼38.4% of the LMs identified (Figure 2), consisting primarily of PGE2 and PGD2 (∼81.5% of total prostanoids) that are key in LM mediator class switching and initiation of resolution.16 Of primary proinflammatory LM, PGF2α and TxB2, an inactive further metabolite of TxA217 combined amounted to <10% of total milk LMs (Figure 2). LTB4 is a potent proinflammatory neutrophil chemoattractant18 and was not identified in appreciable amounts in these milk samples (Table 1). This approach permitted us to assess the potential effector functions that human milk LM-SPM may endow locally within the mammary gland or on the infant during maternal–infant transfer. Taken together, these results demonstrate that human milk contains a proresolving LM-SPM signature profile, comprised predominantly of LMs and SPMs with proresolving properties at concentrations commensurate with their known bioactions.1, 17, 18
Human milk LM-SPM profile is altered in mastitis
SPMs are endogenous chemical signals that actively stimulate resolution of inflammation;1 therefore, we next sought to investigate the LM profiles of human milk from inflamed mammary glands (mastitis) and compare it with milk from healthy subjects (Figure 3). Differences in LM-SPM profiles obtained with human milk from healthy individual donors (1–6 months postpartum) and donors with mastitis (1–4 months postpartum) were assessed using principal component analysis. The two principal components, calculated using the data matrix, showed clear separation between the healthy milk cluster and mastitis milk cluster on the score plot (Figure 3a). The healthy milk cluster was characterized by higher levels of SPMs, including RvD1, RvD2, RvD3, MaR1, PD1, RvE2, and LXA4 and LXB4 as demonstrated in the loading plot (Figure 3b). Conversely, principal component analysis of the LC-MS-MS results demonstrated that the mastitis milk cluster was associated with higher levels of RvE1, LTB4, PGD2, PGF2α, and TxB2. These findings indicate that the human milk LM profile is altered in mastitis, with elevated proinflammatory LMs and reduced SPMs.
As mastitis milk had an altered LM-SPM profile, we next investigated the ability of HLMIs from mastitis milk (referred to as HLMImast) to accelerate resolution of acute inflammation. HLMI from mastitis milk was obtained as described above for HLMIs from healthy milk (see Methods for details). Administration of HLMImast immediately before challenge (1 mg zymosan per mouse) did not limit neutrophil numbers at Tmax (12.3±0.8 vs. 11.5±0.9 cells per exudate compared with peritonitis plus vehicle), and only slightly shortened the Ri by 16%, or from 19 h observed in peritonitis plus vehicle to 16 h (Figure 3c and d). Taken together, these findings indicate that mastitis milk has altered LM-SPM signature profile and reduced ability to accelerate resolution in vivo.
RvD2 and MaR1 potently accelerate resolution of acute inflammation
Because DHA is recognized to be critical for neonatal development10 and RvD2 was one of the more abundant DHA-derived SPMs identified in human milk (Figure 2 and Table 1), we sought to assess its potential contribution to the regulation of leukocyte trafficking and the Ri. Mice were administered RvD2 (50 ng per mouse, i.e., 2 μg kg−1; intraperitoneally) before initiation of a self-limited inflammatory challenge and resolution parameters quantified (Figure 4). RvD2 gave ∼40% reduction in Ψmax (10.0±0.8 × 106 vs. 17.0±2.4 × 106 cells per exudate) compared with peritonitis plus vehicle mice and shortened the Ri by 74%, or from 25 to 6.5 h (Figure 4). DHA also serves as a substrate for MaRs,1 and as MaR1 was identified in human milk at bioactive concentrations (Figure 2 and Table 1) we compared its actions on regulating leukocyte trafficking to RvD2. MaR1 (50 ng per mouse, intraperitoneally) gave a maximal PMN number of 9.9±1.3 × 106 cells per exudate and shortened the Ri to 6 h, or by 76% (Figure 4). We also assessed the ability of RvD2 and MaR1 to accelerate resolution of established peritonitis (Supplementary Figure 2a, b). RvD2 and MaR1 (50 ng per mouse) administered 12 h after zymosan challenge (1 mg per mouse) each accelerated resolution, reducing neutrophil numbers and shortening the Ri by 33% and 40%, respectively (Supplementary Figure 2a, b). Thus, both RvD2 and MaR1, at physiologic range, that is, nanograms per mouse, regulate neutrophil trafficking and shorten the Ri.
HLMIs and MaR1 stimulate resolution of infectious peritonitis
Given these in vivo findings and as HLMIs contain SPMs that enhance host-directed responses to infection, such as RvD1, RvD5, and RvD2,19, 20 we next investigated whether HLMIs enhanced resolution of infectious peritonitis (Supplementary Figure 3a, b). Mice were inoculated with a resolving dose of Escherichia coli (105 colony-forming unit and administered vehicle or HLMIs (intraperitoneally) 12 h later. HLMIs gave reduced PMN numbers at 24 h by 33% (9.8±1.1 vs. 14.6±1.8 cells per exudate compared with peritonitis plus vehicle; Supplementary Figure 3a) and enhanced leukocyte uptake of E. coli (Supplementary Figure 3b). As MaR1 potently accelerated resolution of sterile inflammation and is present in human milk, we assessed its ability to enhance resolution of infection (Supplementary Figure 3c, d). We found that MaR1 (50 ng per mouse) reduced PMN numbers at 24 h by 40% (Supplementary Figure 3c) and enhanced leukocyte uptake of E. coli (Supplementary Figure 3d). Similar results were obtained with RvD2 (n=2, data not shown) used for direct comparison.20 Taken together, these results demonstrate that HLMIs and MaR1 accelerate resolution of infection, limiting neutrophil numbers and enhancing in vivo bacterial clearance.
HLMIs enhance human macrophage phagocytosis
Given the key actions of SPMs in resolution are enhancing macrophage clearance of apoptotic cells and debris,1 we next questioned whether HLMIs have direct impact on phagocytosis with isolated human cells. Incubation of human macrophages with HLMIs gave an enhanced efferocytosis (i.e., phagocytosis of fluorescently labeled apoptotic neutrophils) compared with vehicle-treated macrophages (Figure 5a). To provide evidence whether the LMs found in HLMIs are responsible for the potent bioactions, we depleted LMs from human milk using activated charcoal21 (referred to here as HLMIAC) and compared its actions with that of HLMIs. Charcoal treatment depleted more than ∼97% of the bioactive LM content of human milk (DHA-derived SPM: 23.3 vs. 0.1 pg per 20 μl isolate; AA-derived SPM: 35.2 vs. 1.3 pg per 20 μl isolate; EPA-derived SPM: 78.5 vs. 3.3 pg per 20 μl isolate; AA-derived prostanoids: 155.8 vs. 10.6 pg per 20 μl isolate) and significantly reduced the ability of the HLMIs to stimulate macrophage efferocytosis by ∼80–95% (Figure 5a). Thus, HLMIs possess bioactive SPMs that stimulate key resolution programs in human macrophages, namely efferocytosis.
Based on these and the in vivo findings, and as SPM, including RvD1, RvD2, and RvD5, directly enhance human phagocyte containment of E. coli,19, 20 we next questioned whether HLMIs have direct impact on bacterial containment with isolated human cells. HLMIs increased human macrophage phagocytosis of fluorescent E. coli by ∼35–55% compared with vehicle-treated macrophages (Figure 5b). The ability of HLMIs to enhance macrophage containment of E. coli was significantly reduced after LM depletion with activated charcoal (Figure 5b). Taken together, these results demonstrate that HLMI possesses bioactive LMs/SPMs that enhance bacterial containment with isolated human macrophages.
In the present study, we report the human milk LM-SPM signature profile that signals resolution of inflammation and bacterial clearance. Using LC-MS-MS-based LM metabololipidomics, we identified Rvs, PDs, MaRs, and LXs at bioactive concentrations in healthy human milk. For comparison, in mastitis, milk LM-SPM levels were altered showing elevated proinflammatory LMs and lower levels of SPMs. RvD2 and MaR1 were identified in human milk, and each individually accelerated resolution of inflammation, shortening the Ri from 26 to 12 h. Also, HLMIs had infection-resolving actions in vivo, enhanced efferocytosis, and phagocytosis of E. coli with isolated human macrophages.
Human milk is a dynamic biologically active fluid that in addition to delivering essential nutrients provides passive protection for the immature mucosal immune system.10 Owing to the immaturity of the intestinal immune system in newborns, they have enhanced susceptibility to excessive inflammation and infection.12 Recently, chemical signals that actively stimulate resolution of inflammation and infection1 were identified in human milk.6 Of note, SPMs, such as Rvs, PDs, MaRs, and LXs, are endogenous LMs found in many tissues that actively counterregulate proinflammatory signals, including nuclear factor-κB,9 cytokines, and leukotrienes.1 They exert their potent actions via activating specific G-protein-coupled receptors in cell-specific and tissue-dependent manner. Several SPM receptors are identified, for example, RvE1 specifically binds both ChemR23 and BLT1, and LXA4 and RvD1 bind and activate the LX A4 receptor ALX and human GPR32, which also binds RvD3 and RvD5 (reviewed in Serhan1). RvD2 was recently found to exert its tissue-protective actions via GPR18.22 Along these lines, enterocytes express ALX23 and LXA4 stable analogs inhibit bacterial-induced interleukin-8 secretion by intestinal epithelial cells.24 Enterocytes also express ChemR23, where RvE1 induces intestinal alkaline phosphatase expression and enzyme activity that attenuates lipopolysaccharide-induced nuclear factor-κB signaling.25 Hence, together with our present results SPMs in human milk may be relevant for infant mucosal responses. Given their presence at bioactive levels in human milk (pM to nM) and their ability to engage G-protein-coupled receptors, they may activate specific and potentially additive responses in the newborn gut mucosa; such actions remain of interest.
Proresolution is a distinct process from anti-inflammation, where agonists of resolution, such as SPM, augment nonphlogistic clearance from sites of inflammation and infection, augmenting host-directed defenses including microbial containment.19, 26 In the present report, we found that human milk isolates containing SPMs accelerate resolution of acute inflammation and infection in vivo and with isolated human leukocytes. Mastitis milk gave altered SPM levels and reduced ability to accelerate resolution of acute inflammation. The higher RvE1 levels in mastitis milk may reflect an increased cytochrome P450 in the mastitis microenvironment, for example, cytochrome P450 can produce the RvE1 precursor 18-HEPE (hydroxyicosapentaenoic acid) from EPA, which in turn is converted to RvE1 by human PMN (reviewed in Serhan1), which are known to be abundant in mastitis-affected milk.27 In addition to the known beneficial properties of human milk, our current results extend its protective roles to now include proresolving properties, namely accelerating resolution of acute inflammation and infection, as well as stimulating macrophage phagocytic functions with the LC-MS-MS-based identification of human milk SPMs.
Resolution of acute inflammation can be quantitated using defined resolution indices introduced by this laboratory.13, 14 These permit direct assessment of proresolving properties of endogenous mediators (Table 2 and Supplementary Table 2). For example, RvD1 and RvD3 (50 ng per mouse, i.e., 2 μg kg−1, each) shorten Ri in murine peritonitis (Table 2). Also, RvD1, PD1, and AT-LXA4 at 300 ng per mouse (i.e., 12 μg kg−1) each reduce the Ri, whereas RvE1 accelerates the onset (Tmax) of resolution (Supplementary Table 2). In these experiments, RvD2 and MaR1 accelerate resolution of acute inflammation, reducing the magnitude of PMN infiltration (Ψmax) and shortening Ri. Of note, RvD2 and MaR1 each limit intestinal inflammation and tissue damage in experimental colitis.9, 28 Of interest, oral administration of RvD1 shortens the Ri.29 Hence, taken together with our finding that SPMs, including RvD2 and MaR1, are present in human milk at biologically relevant levels, SPMs and their pathways may have implications in the regulation of acute inflammation and resolution in maternal–infant transferred protection.
Emerging evidence indicates that breastfeeding is correlated with lower prevalence of inflammatory conditions in early life (e.g., necrotizing enterocolitis) and later life (e.g., obesity, diabetes, and cardiovascular disease).30 Human milk contains high levels of EFA, such as DHA, which are derived from maternal dietary and endogenous pools (e.g., adipose tissue).31 Increased maternal intake of n-3 EFA during gestation and lactations has been associated with beneficial outcome for infants.10 Also, DHA in breast milk is thought to have a role in early neural development,10 and some studies have found that DHA may be associated with better cognitive outcome and higher IQ; however, further investigation is needed.32 Of note, evidence in humans indicated that n-3 EFA intake can elevate RvD1, RvD2, PD1, and 17-HDHA levels in healthy individuals.33 Increases in specific SPMs after n-3 EFA intake followed by aspirin are associated with enhanced functional outcome in whole blood (i.e., increased phagocytosis) demonstrating functional metabolomic profiling.3 Omega-3 intake elevated RvD1 levels in diabetic mice34 and in patients with minor cognitive impairment and was associated with enhanced uptake of β-amyloid.35 AT-RvD1 improves postoperative cognitive decline in mice,36 and RvE1 and AT-RvD1 differentially improve functional outcome following diffuse traumatic brain injury.37 Hence, taken together with present findings that human milk contains a proresolving LM-SPM signature profile, human milk SPMs may be relevant in infant neurological development.
In summation, human milk LM metabololipidomic profiling uncovered specific LM signature with physiologically relevant levels of endogenous SPMs associated with accelerated resolution of acute inflammation in vivo. By profiling LM-SPM in human milk, we identified several potent bioactive proresolving mediators including AT-RvD1, RvD2, RvD3, AT-RvD3, RvD4, RvD5, RvD6, MaR1, PD1, AT-PD1, RvE2, RvE3, AT-LXA4, and LXB4 in human milk, as well as confirmed the earlier identification of RvD1, RvE1, and LXA4.6 Mastitis milk had higher prostanoids, lower SPM, and reduced ability to accelerate resolution. Of these newly identified SPMs herein, RvD2 and MaR1 each accelerated resolution of acute inflammation and infection (Figure 4, Table 2, and Supplementary Figure 2). With human macrophages, HLMIs stimulate efferocytosis and containment of E. coli, key actions in resolution of inflammation and infection, and accelerate resolution of infection in vivo. Hence, the present results implicate a role for SPMs in modulating inflammation, infection, and stimulating resolution during early immune development, as SPMs display potent actions in the innate immune system.
Extraction of HLMIs for murine peritonitis. Deidentified human milk from healthy donors was purchased from Biological Specialty Corporation (Colmar, PA) or from healthy and matched mastitis donors from Creative Bioarray (Shirley, NY). Two volumes of methanol were added to milk, and proteins were precipitated for 30 min on ice. Precipitate was pelleted by centrifugation (10,000 r.p.m. at 4 °C for 10 min). Supernatants were extracted using two volumes of diethyl ether, and LMs were further isolated using solid-phase extraction as in Colas et al.3 Products were eluted in methyl formate; solvent was evaporated under N2, and resuspended in ethanol. Aliquots of the ethanol fractions were taken to LC-MS-MS-based metabololipidomics for LM profiling.
Peritonitis and resolution indices. Sterile self-limited peritonitis was initiated in male FVB mice (6–8 weeks; Charles River Laboratories, Newton, MA) by intraperitoneal injection of 1 mg zymosan A (Z4250; Sigma-Aldrich, St. Louis, MO).38 For infectious peritonitis, mice were injected with self-limited inoculum of E. coli (105 colony-forming unit). Immediately before zymosan injection, mice were administered (intraperitoneally) HLMIs (levels representative of ∼1 ml human milk), RvD2 (50 ng per mouse), MaR1 (50 ng per mouse), or vehicle (saline containing 0.2% ethanol). In some experiments, mice were administered treatments at Tmax (12 h). Isolates pooled from three human milk donors were used in determining the impact on the Ri of acute peritonitis. RvD2 and MaR1 for each experiment were prepared by total organic synthesis, and matched to authentic RvD2 and MaR1.20 Physical properties of RvD2 and MaR1 were validated before each experiment according to published criteria.20 Peritoneal exudates were collected at indicated time intervals by lavaging with 5 ml PBS (phosphate-buffered saline). Exudate PMN numbers were assessed using Turk’s solution, light microscopy, and flow cytometry (FACSCanto II; BD Bioscience, San Jose, CA). PMNs were determined as Ly6G- (clone 1A8; BD Bioscience) and CD11b- (clone M1/70; eBioscience, San Diego, CA) positive events and F4/80- (clone BM8; eBioscience) negative events from events as assessed by forward scatter and side scatter. Resolution indices were calculated as in Schwab et al.13 and Bannenberg et al.,14 where Ψmax is the maximal PMN count, Tmax the time interval when PMN reaches maximum, T50 the time interval corresponding to 50% PMN reduction (or Ψ50), and the Ri is the interval between Tmax and T50. All animal experiments were approved by the Standing Committee on Animals of Harvard Medical School (protocol no. 02570) and performed in accordance with institutional guidelines.
LC-MS-MS-based LM metabololipidomics of human milk. For quantification of LM, human milk from four healthy donors (1–2 months postpartum; Lee Biosolutions, Maryland Heights, MO) or matched mastitis and healthy donors (1–6 months postpartum; Creative Bioarray, Shirley, NY) was extracted using solid-phase extraction with C18 columns (Waters, Milford, MA), following the addition of three volumes of cold methanol containing deuterated internal standards (1 ng d4-PGE2, d4-LTB4, and d8-5S-HETE, as well as d5-RvD2) and protein precipitation. LM levels were assessed by a LC-MS-MS system, QTrap 5500 and QTrap 6500 (ABSciex, Concord, Ontario, Canada) equipped with Shimadzu LC-20AD HPLC and a Shimadzu SIL-20AC autoinjector (Shimadzu, Kyoto, Japan). An Agilent Eclipse Plus C18 column (100 mm × 4.6 mm × 1.8 μm) was used with a gradient of methanol/water/acetic acid of 55:45:0.01 (vol vol−1 vol−1) to 100:0:0.01 at 0.4 ml min−1 flow rate. To monitor and identify various LM, a multiple reaction monitoring method was developed with signature ion pairs, Q1 (parent ion)–Q3 (characteristic daughter ion) optimized for each molecule. Identification was conducted using published criteria,3 where a minimum of six diagnostic ions were used in each MS-MS. The complete stereochemistry of resolvin D4 was recently determined,39 and the synthetic standard was used here for identification and quantitation from human milk. Linear calibration curves for each compound were obtained with r2 values ranging from 0.98 to 0.99. Detection limits were ∼0.1 pg.
Principal component analysis. Principal component analysis was performed using SIMCA 13.0.3 software (Umetrics, San Jose, CA) following mean centering and unit variance scaling of LM amounts. Principal component analysis is an unbiased, multivariate projection designed to identify the systematic variation in a data matrix (the overall bioactive LM profile of each sample) with lower dimensional plane using score plots and loading plots. The score plot shows the systematic clusters among the observations (closer plots presenting higher similarity in the data matrix). Loading plots describe the magnitude and the manner (positive or negative correlation) in which the measured LMs/SPMs contribute to the cluster separation in the score plot.40
Depletion of milk LMs using activated charcoal adsorption. Human milk from three healthy donors (10 ml from each donor) was combined and incubated with or without 4% activated charcoal (Sigma) for 1 h at room temperature. Activated charcoal was washed out, three volumes methanol were added to the milk, and proteins precipitated at -20 °C. Precipitate was pelleted by centrifugation (3,000 r.p.m. at 4 °C for 10 min), and LMs isolated using C18 columns and solid-phase extraction.3 Products were eluted in methyl formate, solvent was evaporated under N2, and suspended in 500 μl ethanol. For human macrophage phagocytosis, 20 μl HLMIs were dried down and resuspended in 1 ml PBS+/+ (highest dilution=1) followed by indicated dilutions (10–1,000-fold). Aliquots of the ethanol fractions were taken to LC-MS-MS-based metabololipidomics for quantification of LM profiling.
Human macrophage phagocytosis and efferocytosis. To obtain apoptotic PMN, human PMNs were isolated by density-gradient Ficoll-Histopaque from human peripheral blood. Blood was obtained from healthy volunteers giving informed consent according to Partners Human Research Committee Protocol no. 1999-P-001297. PMNs were labeled with Bisbenzimide H 33342 (Sigma-Aldrich), a fluorescent nuclear dye (10 μg ml−1 for 30 min at 37 °C) and cultured overnight (5 × 106 cells per ml in PBS+/+). Human primary macrophages were differentiated from peripheral blood monocytes19 and plated onto 96-well plates (5 × 104 cells per well). Macrophages were incubated with either HLMIs or HLMIAC at indicated dilutions (1–1,000 fold dilutions, pH 7.45, at 37 °C for 15 min), followed by a phagocytic challenge with either fluorescently labeled apoptotic PMN (3:1 PMN:macrophage) or E. coli (50:1 E. coli:macrophage). Incubations were continued for 45 min at 37 °C,19 macrophages washed, and remaining extracellular fluorescence quenched using Trypan Blue (1:15 Trypan blue:PBS+/+). Phagocytosis was assessed using a SpectraMax M3 plate reader (Molecular Devices, Sunnyvale, CA).
Statistics. Data are presented as individual values or mean±s.e.m. The criterion for statistical significance was P<0.05 using nonparametric Mann–Whitney test or two-way analysis of variance, followed by a post hoc Bonferroni test using GraphPad Prism 6 (La Jolla, CA).
Serhan, C.N. Pro-resolving lipid mediators are leads for resolution physiology. Nature 510, 92–101 (2014).
Fullerton, J.N., O'Brien, A.J. & Gilroy, D.W. Lipid mediators in immune dysfunction after severe inflammation. Trends Immunol. 35, 12–21 (2014).
Colas, R.A., Shinohara, M., Dalli, J., Chiang, N. & Serhan, C.N. Identification and signature profiles for pro-resolving and inflammatory lipid mediators in human tissue. Am. J. Physiol. Cell. Physiol. 307, C39–C54 (2014).
Claria, J., Nguyen, B.T., Madenci, A., Ozaki, C.K. & Serhan, C.N. Diversity of lipid mediators in human adipose tissue depots. Am. J. Physiol. Cell. Physiol. 304, C1141–C1149 (2013).
Keelan, J.A. et al. Effects of maternal n-3 fatty acid supplementation on placental cytokines, pro-resolving lipid mediators and their precursors. Reproduction 149, 171–178 (2015).
Weiss, G.A., Troxler, H., Klinke, G., Rogler, D., Braegger, C. & Hersberger, M. High levels of anti-inflammatory and pro-resolving lipid mediators lipoxins and resolvins and declining docosahexaenoic acid levels in human milk during the first month of lactation. Lipids Health Dis. 12, 89 (2013).
Serhan, C.N. et al. Reduced inflammation and tissue damage in transgenic rabbits overexpressing 15-lipoxygenase and endogenous anti-inflammatory lipid mediators. J. Immunol. 171, 6856–6865 (2003).
Arita, M. et al. Resolvin E1, an endogenous lipid mediator derived from omega-3 eicosapentaenoic acid, protects against 2,4,6-trinitrobenzene sulfonic acid-induced colitis. Proc. Natl. Acad. Sci. USA 102, 7671–7676 (2005).
Bento, A.F., Claudino, R.F., Dutra, R.C., Marcon, R. & Calixto, J.B. Omega-3 fatty acid-derived mediators 17(R)-hydroxy docosahexaenoic acid, aspirin-triggered resolvin D1 and resolvin D2 prevent experimental colitis in mice. J. Immunol. 187, 1957–1969 (2011).
Calder, P.C. et al. Early nutrition and immunity—progress and perspectives. Br. J. Nutr. 96, 774–790 (2006).
Peng, Y. et al. Fatty acid composition of diet, cord blood and breast milk in Chinese mothers with different dietary habits. Prostaglandins Leukot. Essent. Fatty Acids 81, 325–330 (2009).
Walker, W.A. Initial intestinal colonization in the human infant and immune homeostasis. Ann. Nutr. Metab. 63 (Suppl 2), 8–15 (2013).
Schwab, J.M., Chiang, N., Arita, M. & Serhan, C.N. Resolvin E1 and protectin D1 activate inflammation-resolution programmes. Nature 447, 869–874 (2007).
Bannenberg, G.L. et al. Molecular circuits of resolution: formation and actions of resolvins and protectins. J. Immunol. 174, 4345–4355 (2005).
Reid, B., Smith, H. & Friedman, Z. Prostaglandins in human milk. Pediatrics 66, 870–872 (1980).
Levy, B.D., Clish, C.B., Schmidt, B., Gronert, K. & Serhan, C.N. Lipid mediator class switching during acute inflammation: signals in resolution. Nat. Immunol. 2, 612–619 (2001).
Flower, R.J. Prostaglandins, bioassay and inflammation. Br. J. Pharmacol. 147, S182–S192 (2006).
Haeggstrom, J.Z. & Funk, C.D. Lipoxygenase and leukotriene pathways: biochemistry, biology, and roles in disease. Chem. Rev. 111, 5866–5898 (2011).
Chiang, N. et al. Infection regulates pro-resolving mediators that lower antibiotic requirements. Nature 484, 524–528 (2012).
Spite, M. et al. Resolvin D2 is a potent regulator of leukocytes and controls microbial sepsis. Nature 461, 1287–1291 (2009).
Chen, R.F. Removal of fatty acids from serum albumin by charcoal treatment. J. Biol. Chem. 242, 173–181 (1967).
Chiang, N., Dalli, J., Colas, R.A. & Serhan, C.N. Identification of resolvin D2 receptor mediating resolution of infections and organ protection. J. Exp. Med. 212, 1203–1217 (2015).
Gronert, K., Gewirtz, A., Madara, J.L. & Serhan, C.N. Identification of a human enterocyte lipoxin A4 receptor that is regulated by IL-13 and IFN-gamma and inhibits TNF-alpha-induced IL-8 release. J. Exp. Med. 187, 1285–1294 (1998).
Gewirtz, A.T. et al. Pathogen-induced chemokine secretion from model intestinal epithelium is inhibited by lipoxin A4 analogs. J. Clin. Invest. 101, 1860–1869 (1998).
Campbell, E.L. et al. Resolvin E1-induced intestinal alkaline phosphatase promotes resolution of inflammation through LPS detoxification. Proc. Natl. Acad. Sci. USA 107, 14298–14303 (2010).
Morita, M. et al. The lipid mediator protectin D1 inhibits influenza virus replication and improves severe influenza. Cell 153, 112–125 (2013).
Aitken, S.L., Corl, C.M. & Sordillo, L.M. Immunopathology of mastitis: insights into disease recognition and resolution. J. Mammary Gland Biol. Neoplasia 16, 291–304 (2011).
Marcon, R., Bento, A.F., Dutra, R.C., Bicca, M.A., Leite, D.F. & Calixto, J.B. Maresin 1, a proresolving lipid mediator derived from omega-3 polyunsaturated fatty acids, exerts protective actions in murine models of colitis. J. Immunol. 191, 4288–4298 (2013).
Recchiuti, A. et al. Immunoresolving actions of oral resolvin D1 include selective regulation of the transcription machinery in resolution-phase mouse macrophages. FASEB J. 28, 3090–3102 (2014).
World Health Organization Long-Term Effects of Breastfeeding: A Systematic Review. Available at http://www.who.int/maternal_child_adolescent/documents/breastfeeding_long_term_effects/en/ (2013).
Fidler, N., Sauerwald, T., Pohl, A., Demmelmair, H. & Koletzko, B. Docosahexaenoic acid transfer into human milk after dietary supplementation: a randomized clinical trial. J. Lipid Res. 41, 1376–1383 (2000).
Heaton, A.E., Meldrum, S.J., Foster, J.K., Prescott, S.L. & Simmer, K. Does docosahexaenoic acid supplementation in term infants enhance neurocognitive functioning in infancy? Front. Hum. Neurosci. 7, 774 (2013).
Mas, E., Croft, K.D., Zahra, P., Barden, A. & Mori, T.A. Resolvins D1, D2, and other mediators of self-limited resolution of inflammation in human blood following n-3 fatty acid supplementation. Clin. Chem. 58, 1476–1484 (2012).
Shevalye, H. et al. Effect of enriching the diet with menhaden oil or daily treatment with resolvin D1 on neuropathy in a mouse model of type 2 diabetes. J. Neurophysiol. 114, 199–208 (2015).
Fiala, M. et al. Omega-3 supplementation increases amyloid-beta phagocytosis and resolvin D1 in patients with minor cognitive impairment. FASEB J. 29, 2681–2689 (2015).
Terrando, N. et al. Aspirin-triggered resolvin D1 prevents surgery-induced cognitive decline. FASEB J. 27, 3564–3571 (2013).
Harrison, J.L. et al. Resolvins AT-D1 and E1 differentially impact functional outcome, post-traumatic sleep, and microglial activation following diffuse brain injury in the mouse. Brain Behav. Immun. 47, 131–140 (2015).
Sampaio, A.L.F., Dufton, N. & Perretti, M. Models of acute inflammation—air pouch, peritonitis, and ischemia–reperfusion In Fundamentals of Inflammation Serhan C.N., Ward P.A., Gilroy D.W., eds 329–337 Cambridge University Press: New York, NY, (2010).
Winkler, J. et al. Resolvin D4 potent antiinflammatory proresolving actions confirmed via total synthesis. FASEB J. 29, Suppl, 285.10 (2015).
Janes, K.A. & Yaffe, M.B. Data-driven modelling of signal-transduction networks. Nat. Rev. Mol. Cell Biol. 7, 820–828 (2006).
Arnardottir, H.H., Dalli, J., Colas, R.A., Shinohara, M. & Serhan, C.N. Aging delays resolution of acute inflammation in mice: reprogramming the host response with novel nano-proresolving medicines. J. Immunol. 193, 4235–4244 (2014).
We thank Mary Halm Small for expert assistance in the manuscript preparation and Iliyan Vlasakov for technical assistance. This work was supported in part by NIH grant P01GM095467 (CNS) and a research grant from Solutex (Madrid, Spain; to CNS). HA was supported by an Arthritis Foundation Postdoctoral Fellowship Award. SKO was supported by a Canadian Institutes of Health Research Fellowship Award.
CNS is an inventor on patents (resolvins) assigned to BWH and licensed to Resolvyx Pharmaceuticals. CNS is a scientific founder of Resolvyx Pharmaceuticals and owns equity in the company. CNS’ interests were reviewed and are managed by the Brigham and Women’s Hospital and Partners HealthCare in accordance with their conflict of interest policies. The remaining authors declare no conflicts of interest.
SUPPLEMENTARY MATERIAL is linked to the online version of the paper
About this article
Nature Reviews Cardiology (2019)
Successful Rituximab Treatment for Lymphoma, Secondary Immunodeficiency Causing Debilitating Sinusitis: Underlying Primary Immunodeficiency Disease, and Alternative Treatments to Improve the Quality of Life?
Journal of Clinical Immunology (2019)
Non-Nutritional Use of Human Milk Part 1: A Survey of the Use of Breast Milk as a Therapy for Mucosal Infections of Various Types in Poland
International Journal of Environmental Research and Public Health (2019)
Journal of the European Academy of Dermatology and Venereology (2019)
Omega-3 Fatty Acid Supplementation, Pro-Resolving Mediators, and Clinical Outcomes in Maternal-Infant Pairs