Eicosanoid Profiling in an Orthotopic Model of Lung Cancer Progression by Mass Spectrometry Demonstrates Selective Production of Leukotrienes by Inflammatory Cells of the Microenvironment

Eicosanoids are bioactive lipid mediators derived from arachidonic acid1 (AA), which is released by cytosolic phospholipase A2 (cPLA2). AA is metabolized through three major pathways, cyclooxygenase (COX), lipoxygenase (LO) and cytochrome P450, to produce a family of eicosanoids, which individually have been shown to have pro- or anti-tumorigenic activities in cancer. However, cancer progression likely depends on complex changes in multiple eicosanoids produced by cancer cells and by tumor microenvironment and a systematic examination of the spectrum of eicosanoids in cancer has not been performed. We used liquid chromatography coupled with tandem mass spectrometry (LC/MS/MS) to quantitate eicosanoids produced during lung tumor progression in an orthotopic immunocompetent mouse model of lung cancer, in which Lewis lung carcinoma (LLC) cells are injected into lungs of syngeneic mice. The presence of tumor increased products of both the cyclooxygenase and the lipoxygenase pathways in a time-dependent fashion. Comparing tumors grown in cPLA2 knockout vs wild-type mice, we demonstrated that prostaglandins (PGE2, PGD2 and PGF2a) were produced by both cancer cells and the tumor microenvironment (TME), but leukotriene (LTB4, LTC4, LTD4, LTE4) production required cPLA2 expression in the TME. Using flow cytometry, we recovered tumor-associated neutrophils and 2 types of tumor-associated macrophages from tumor-bearing lungs and we defined their distinct eicosanoid profiles by LC/MS/MS. The combination of flow cytometry and LC/MS/MS unravels the complexity of eicosanoid production in lung cancer and provides a rationale to develop therapeutic strategies that target select cell populations to inhibit specific classes of eicosanoids.


Introduction
Eicosanoids represent a family of bioactive lipids produced through metabolism of arachidonic acid. Arachidonic acid (AA) is a polyunsaturated fatty acid, which is incorporated into the sn-2 position of membrane phospholipids. The family of PLA 2 enzymes hydrolyze membrane phospholipids to produce free fatty acids and lysophospholipids. While multiple forms of PLA 2 have been identified, cytosolic PLA 2 -a, designated in this study as cPLA 2 , is specific for arachidonoyl-containing phospholipids, and is the major enzyme involved in regulated release of AA in response to mitogenic or inflammatory stimuli [1]. Free AA can be metabolized through three major pathways [2]. Cyclooxygenases (COX-1, 2) produce prostaglandins, including PGE 2 and PGI 2 as well as thromboxanes, lipoxygenases produce hydroxyeicosatetraenoic acids (HETEs) and leukotrienes, and cytochrome P450 epoxygenases produce epoxygenated fatty acids (EETs). Over 100 distinct eicosanoid species have been identified [3]. The majority of these molecules are secreted from cells and act in an autocrine or paracrine fashion through a family of G-protein coupled receptors [4]. The repertoire of eicosanoids produced by a particular cell type will be governed by expression of enzymes in the pathway, including specific downstream synthases. For example, PGE 2 production will be regulated by expression of cyclooxygenase enzymes as well as prostaglandin E2 synthases, while specific leukotrienes, such as LTC 4 require expression of 5lipoxygenase, as well as LTC 4 synthase.
Lung cancer is associated with the highest number of cancer deaths in both men and women, underscoring the need for novel therapeutic and preventive approaches [5]. Studies in a variety of cancers, including lung cancer, have implicated individual eicosanoids as mediators of cancer initiation, progression and metastasis. Most extensively studied are prostaglandins, specifically PGE 2. Studies in cancer cell lines have demonstrated increased production of PGE 2 mediated through induction of COX-2 and cPLA 2 expression [6][7][8]. Inhibition of prostaglandin production via blocking either cPLA 2 or COX-2 inhibits transformed growth of non-small cell lung cancer cells (NSCLC), and the development of tumors in mice in response to chemical carcinogens [9]. We demonstrated that mice that are deficient in cPLA 2 (cPLA 2 -KO) show inhibition of lung tumor initiation using a chemical carcinogenesis model [10]. In contrast, PGI 2 , which is also produced downstream from COX enzymes, has been shown to inhibit lung cancer initiation, as well as having anti-metastatic effects [11]. Increased expression of 5-and 12-lipoxygenase has also been associated with tumors, including lung cancer [12]. In contrast, expression of 15-lipoxygenase-2 appears to be lost in lung cancer, and may play an anti-tumorigenic role [13]. Lipoxygenase products have direct effects on tumor cells, but are also regulators of angiogenesis and can modify immune function [12]. Recently epoxyeicosatrienoic acids (EETs) produced through the cytochrome P450 pathway have been implicated as regulators of metastasis, acting at least in part through endothelial-specific effects at distant organs [14]. While combinations of COX and lipoxygenase inhibitors have been used as therapeutic agents and have shown beneficial effects in NSCLC [15], effects on metastasis have not been examined. In addition to studies focused on cancer cells, several reports have implicated eicosanoids, specifically PGE 2 , as regulators of the tumor microenvironment (TME) [16,17]. PGE 2 signaling through EP3/EP4 receptors leads to recruitment of cancer associated fibroblasts [18]. PGE 2 has also been shown to be critical in promoting formation of T-regulatory lymphocytes [19]. Thus, cancer progression is likely to involve complex changes in multiple eicosanoids with potentially opposing biological effects. Both cancer cells and cells of the microenvironment are potent producers of eicosanoids, and tumor progression will depend on an integrated response to a spectrum of eicosanoids produced in a spatiotemporal fashion.
A limitation in lung cancer research is the lack of appropriate mouse models of metastatic lung cancer. We recently developed an immunocompetent orthotopic model in which murine lung cancer cells are directly implanted into the left lobe of syngeneic mice [20,21]. These cells form a primary tumor which over a period of 3-5 weeks metastasizes to lymph nodes as well as liver and brain. Using this model, we have demonstrated that tumors growing in mice globally deficient in cPLA 2 have a marked impairment in progression and metastasis [21]. Since the injected tumor cells expressed wild-type cPLA 2 , these data indicate that production of eicosanoids by cells of the tumor microenvironment  is critical for lung cancer progression and metastasis. However, the critical eicosanoids mediating these effects have not been defined. The advent of mass spectrometric analysis of lipids has allowed the measurement of multiple eicosanoid products from both cells and tissues [22]. This technique allows quantitative determination of a large number (.25) of distinct products. The goal of the present study was to apply mass spectrometric approach to systematically define changes in eicosanoids during lung cancer progression, and determine the role of distinct cell populations in creating this profile. Using immunocompetent orthotopic model in wild-type and cPLA 2 knockout mice we are able to assess the contribution of the tumor microenvironment to production of individual eicosanoids. Our results demonstrate a complex eicosanoid pattern during tumor progression, and identify specific inflammatory cells in the TME that selectively contribute to eicosanoid production.
Mice cPLA 2 knockout (cPLA 2 -KO) mice on a C57BL/6 background [21,23] and wild type C57BL/6 mice were bred and maintained in the Center for Comparative Medicine at the University of Colorado Denver. Experiments were done in 12-16 week old mice, both males and females, with mice of different age and gender equally represented in all experimental groups. All procedures were performed under protocols approved by the Institutional Animal Care and Use Committee (IACUC) at the University of Colorado Denver.

Orthotopic Mouse model
LLC-Luc cells (2610 5 ) were suspended in PBS containing 15% Matrigel (BD Biosciences) and injected into the parenchyma of the left lung lobe through the rib cage using a 30G needle. To directly visualize the lung a 4-5 mm incision was made in the skin under the left shoulder and subcutaneous fat was removed. After the procedure, the incision was closed using veterinary adhesive. Primary tumor size was measured using digital calipers.

Extraction and mass spectrometry measurement of eicosanoids
Mice were sacrificed at 2 or 3 weeks after cancer cell injection and the whole left lung lobe containing the tumor was excised, weighed and flash-frozen in liquid nitrogen. Frozen tissues were homogenized in 1 ml of ice-cold sucrose buffer (250 mM sucrose, 50 mM HEPES, 1 mM EDTA, 1 mM EGTA) containing protease inhibitors using motor-driven homogenizer. Aliquots were taken for protein measurement. The remaining homogenate was immediately mixed with 2 volumes of ice-cold methanol. Protein was measured using Bradford reagent (Bio-Rad).
Eicosanoids were extracted and analyzed essentially as described previously, with some modifications [24]. After addition of stable isotope-labeled internal standards (2 ng each, except for the cys-LTs, of which 5 ng were added) to the methanol-containing homogenates, eicosanoids were extracted using solid phase cartridges (Strata-X 33 mm Polymeric Reversed Phase, Phenomenex), eluted with methanol, dried and resuspended in 60 mL of 2 volumes of solvent A (8.3 mM ammonium acetate, pH 5.7) and 1 volume of solvent B (acetonitrile/methanol 65:35 v/v). A 25 mLaliquot was subsequently analyzed by LC-MS/MS using an Ascentis C18 HPLC column (15062 mm, 5 mm; Supelco) interfaced with the electrospray source of a triple quadrupole mass spectrometer (Sciex API 3000; PE-Sciex, Thornhill, Ontario, Canada). Samples were eluted at a flow rate of 200 mL/min with a linear gradient from 25% to 100% of solvent B, which was increased from 25% to 85% in 24 min, to 100% in 26 min, and held at 100% for a further 12 min. Mass spectrometric analysis was performed in the negative ion mode using multiple reaction monitoring of the following specific m/  [25] Preparation of single cell suspension and sorting by flow cytometry Mice were sacrificed at 2.5 weeks after cancer cell injection, the circulation was perfused with PBS/heparin (80 U/ml, Sigma), and left lung lobes containing tumors were excised. Tissues from 4 mice were pooled, mechanically dissociated, incubated at 37uC for 40 minutes with Collagenase A (1 mg/ml, Roche) and DNAse I (40 mg/ml, Sigma), and processed using GentleMACS dissociator C tubes (Miltenyi Biotec). Resulting single-cell suspensions were filtered through 70 mm cell strainers (BD), subject to red blood cells lysis using hypotonic buffer, and filtered second time through

Statistical & Computational Analyses
We used Friedman's Chi-Square test analysis to evaluate the difference between tumor-bearing lungs from WT and cPLA 2 -KO mice harvested at 3 weeks. Rank scores, instead of raw eicosanoid level measurements, were used in the test. We applied False Discovery Rate (FDR) control to the p-values obtained from Chi-Square test, in order to correct for multiple comparisons. The FDR values are considered "adjusted" p-values. We concluded that an association is significant when the FDR value is less than 0.05.

Multiple eicosanoids are increased in tumor bearing mice
Using an orthotopic immunocompetent mouse model, in which tumor cells are injected into lungs of mice, we previously showed that loss of cPLA 2 in the tumor microenvironment inhibited lung cancer metastasis [21]. These effects are presumably due to altered production of specific eicosanoids critical for tumor progression and metastasis. To define the spectrum of eicosanoids produced during lung tumor progression in orthotopic lung cancer model we used liquid chromatography coupled with tandem mass spectrometry (LC/MS/MS).
Lewis Lung Carcinoma cells (LLC-Luc: 2610 5 ), derived from a lung adenocarcinoma in a C57BL/6 mouse, were injected into the left lung lobes of syngeneic WT mice. Whole left lung lobes containing tumors were harvested at 2 and 3 weeks after injection, along with left lobes from control mice injected with PBS/ Matrigel. Eicosanoids extracted from the harvested lungs were analyzed by LC/MS/MS and normalized to the protein content of the sample. We monitored multiple products of the cyclooxygenase (COX), lipoxygenases (LO), and cytochrome P450 pathways. Additionally, we measured free arachidonic acid (AA) and docosahexaenoic acid (DHA). In WT mice levels of eicosanoids were generally increased with cancer progression, however with various degrees of induction and different temporal patterns (Table 1 and Fig.1). We differentiated a group of eicosanoids that were up-regulated 3-7 fold at the earlier 2-week time point (early eicosanoids): PGE 2 , PGF 2a , LTC 4 and LTE 4 (Fig. 1A). Levels of this subset of eicosanoids were further increased at 3 weeks. Compared to Matrigel-injected mice, PGE 2 was upregulated 45-fold, which was the highest increase of all eicosanoids. LTC 4 and LTE 4 were also highly increased, 12 and 13 fold, respectively. The levels of PGF 2a did not further increase at 3 weeks. A second group included eicosanoids that were not increased (, 2-fold) at 2 weeks, but increased significantly at 3 weeks (late eicosanoids, Fig. 1B). Some of the late eicosanoids: PGD 2 , TXB 2 (the stable metabolite of TXA 2 ) and AA became highly upregulated (7-10 fold compared to Matrigel injected), while others (5-, 12-, 15-HETE, and DHA) were upregulated moderately (3-4 fold). LTB 4 , which was undetectable at the 2 week time point, was detected in 50% of the animals at 3 weeks. Two of the eicosanoids: LTD 4 and 6-keto-PGF 1a (the stable metabolite of PGI 2 ), were unchanged or only marginally upregulated at either 2 or 3 weeks (Fig. 1C). Neither lipoxins nor the cytochrome P450 products (5,6-EET, 8,9-EET, 11,12-EET, 14,15-EET), were detected at any time points.

Deletion of cPLA 2 in the TME differentially affects eicosanoids
Since cPLA 2 is the rate-limiting enzyme in eicosanoid biosynthesis, we measured eicosanoid production in lung tumors grown in cPLA 2 -knockout mice. To this end, at the same time that the WT mice were injected, we also injected vehicle (Matrigel) or LLC-Luc cells into mice globally deficient in cPLA 2 . With this experimental strategy, cPLA 2 is deleted in all cells of tumor microenvironment, while wild-type expression is maintained in the cancer cells. Animals were sacrificed at 2 and 3 weeks after injection and eicosanoid profiles in tumor-bearing or control left lung lobes were determined by LC/MS/MS.
As shown in Fig. 2A, growth of primary tumors was not different in wild-type vs. cPLA 2 -KO mice, consistent with our previous observation [21]. Analysis of eicosanoid profiles (Table 2 and Fig. 2B) revealed that basal levels of eicosanoids in cPLA 2 -KO mice were in general slightly lower, but not statistically different from WT control mice. With lung tumor progression, eicosanoid production increased in both WT and cPLA 2 -KO mice; however, that increase was significantly blunted in tumor-bearing cPLA 2 -KO mice. The level of inhibition in cPLA 2 -KO mice varied widely among the various analytes, ranging from about 25% to over 90% inhibition. This result indicates that one can make a distinction between eicosanoids that are produced primarily by the microenvironment (completely inhibited in the setting of cPLA 2 knockout), and eicosanoids contributed both by microenvironment and the cancer cells (reduced partially). Detailed analysis of the eicosanoid profiles revealed that AA and DHA showed the slightest reduction associated with cPLA 2 deficiency, about 25% at 3 weeks (Table 2). 5-, 12-and 15-HETE were on average reduced by 50% in cPLA 2 -KO mice compared to WT mice ( Table 2). Products of COX pathway showed various degrees of inhibition in the setting of cPLA 2 deficiency. While TXB 2 and 6kPGF 1a were reduced by 80% at 3 weeks, the other prostaglandins (PGE 2 , PGD 2 and  PGF 2a ) were on average 50% lower than in WT mice ( Table 2 and Fig. 2B). The largest inhibition associated with cPLA 2 -deficiency in the microenvironment was detected in the leukotriene group (Table 2 and Fig. 2B). The increase in early leukotrienes, LTC 4 and LTE 4 , was delayed until 3 weeks in cPLA 2 -KO mice compared to WT mice, and their levels were reduced by 90% for LTC 4 and 75% for LTE 4 . Leukotriene LTB 4, which was induced in 3wk WT tumor-bearing lungs, was not detected in cPLA 2 -KO mice at any time point. The levels of LTD 4 , while not increased with tumor progression, were lower by 80% in 3-week cPLA 2 -KO tumors.

Distinct populations of inflammatory cells in the TME have different eicosanoid profiles
The TME is composed of multiple cell types, including inflammatory cells, fibroblasts and adaptive immune cells. In order to begin to define which of these cell populations are producing leukotrienes in the setting of tumor progression, we used flow cytometry to isolate inflammatory cells from lungs of tumor-bearing mice. Using markers previously employed to characterize inflammatory cells in the lung, we defined neutrophils (Neu, CD11b+/Ly6G+), as well as two populations of macrophages, designated as MacA (SigF+/CD11c+/F480+/CD11b low) and MacB (F480+/CD11b+/Ly6G-/SigF-), (Fig. 3A). Based on previous studies [26,27], MacA represent resident alveolar macrophages [27], whereas MacB is a heterogeneous population mainly composed of infiltrating monocytes and macrophages, and also contains interstitial macrophages, and CD11b+ dendritic cells [27,28]. In the setting of tumors, the number of MacB cells was markedly increased, whereas the MacA population was not significantly altered compared to control mice not injected with cancer cells (Fig. 3B).
To determine the potential for eicosanoid production by these three groups of inflammatory cells, we recovered them by flow cytometry from lungs of tumor-bearing mice, and examined mRNA expression of enzymes in the eicosanoid pathway by qRT-PCR. The analysis of mRNA revealed significant differences in the expression of eicosanoid pathway enzymes between different inflammatory cells (Fig. 4). All three populations expressed cPLA 2 , although levels were higher in MacA cells than in MacB or neutrophils. COX-1 was also expressed in all 3 cells types, and we did not detect significant differences in its levels, suggesting that all of these populations can produce prostaglandins. However, COX-2 was selectively expressed in neutrophils, with low levels in MacB and almost undetectable in MacA. Since inflammatory cytokines induce prostaglandins through increased COX-2 expression, we would predict that prostaglandin production would be mediated largely through neutrophils and MacB. Thromboxane synthase TXAS1 was also detected in all three cell types. 5-LO was highest in MacA cells, Neutrophils expressed 50-70% lower levels, and expression in MacB was 90% lower than in MacA. This would indicate that leukotriene production in the setting of tumor progression is largely derived from MacA or neutrophils, with the recruited MacB population contributing very little. LTA4H was expressed in all 3 cell types, while the expression of LTC4S was restricted only to MacA cells. All the analyzed enzymes were expressed at the same levels in WT and cPLA 2 -KO mice, with the exception of cPLA 2 , which, as expected, was undetectable in cells derived from cPLA 2 -KO. Since free AA may be released by enzymes other than cPLA 2 , such as monoacyl glycerol lipase (MAGL) [29] we measured MAGL levels in isolated cells. MacA cells demonstrated high levels of MAGL compared to either MacB cells or neutrophils (data not shown). This result leads to prediction that cPLA 2 deficiency will have less impact on eicosanoid production by MacA cells than by MacB or neutrophils.To confirm the potential for eicosanoid production by MacA, MacB and neutrophil populations, cells were recovered from tumorbearing mice by flow cytometry and stimulated with calcium ionophore A23187. Eicosanoid production was assessed by LC/ MS/MS (Fig.5). Along with the sorted cells, we examined eicosanoid production by cultured LLC-Luc cancer cells. The largest repertoire of eicosanoids was produced by MacA cells. In agreement with their high expression of 5-LO and exclusive expression of LTC4S, MacA were the only ones capable of producing cysteinyl leukotrienes, LTC 4 and LTD 4 . MacA also produced LTB 4 , albeit less than neutrophils, 5-HETE, and 5oxoETE. Despite their low expression of COX-2, but consistent with expression of COX-1, MacA cells were able to produce PGE 2 and TXB 2 . Interestingly, eicosanoid production by MacA cells from cPLA 2 -KO mice was reduced compared to WT, but only by about 50%. These data suggest that additional pathways distinct from cPLA 2 , such as MAGL act to provide AA in these cells. MacB cells produced lower levels of eicosanoids. As they lack 5-LO, MacB were not capable of producing leukotrienes. Despite expression of enzymes in the cyclooxygenase pathway, MacB produced only low levels of PGE 2 and TXB 2 , which were reduced by 80% in the setting of cPLA 2 -KO. Neutrophils, which express 5-LO, but not LTC4S, produced LTB 4 at levels 3-fold higher than MacA, but no cysteinyl leukotrienes. Consistent with their high expression of COX-2, neutrophils produced PGE 2 , at levels 4-fold higher than MacA. They also produced 5-HETE and TXB 2 , at levels lower than MacA cells. In the setting of cPLA 2 deficiency, neutrophil production of eicosanoids was reduced over 90% in comparison to WT mice. Among other metabolites, 12-HETE, PGF 2a , 15-HETE, AA, and DHA were produced by all 3 cell types. In contrast to myeloid cells recovered from the TME, LLC-Luc cells produced a limited spectrum of eicosanoids. Their major product was PGE 2 , detected at levels about 10 times higher than in myeloid cells. We also detected PGF 2a , 15-HETE and relatively low levels of DHA and AA. No leukotrienes were detected, consistent with our in vivo data indicating that leukotrienes are selectively produced by the TME.

Discussion
Eicosanoids represent a large family of bioactive signaling molecules with diverse and potentially opposing biological effects. While much work has focused on specific eicosanoids and their role in cancer, there has not been a systematic attempt to define the spectrum of these molecules in the setting of cancer. A large body of literature has defined both pro-and anti-tumorigenic roles for products of both the cyclooxygenase and lipoxygenase pathways [30,31]. Our studies used an immunocompetent orthotopic model of lung cancer progression, combined with a lipidomic mass spectrometry approach to demonstrate that lung cancer progression is associated with increases in multiple eicosanoid products derived from both the cyclooxygenase and lipoxygenase pathways. Individual eicosanoids showed different time dependencies, with a subset being increased at the earliest time point analyzed, whereas a second subset appeared to have a more delayed course of induction. Several products (e.g. 6k-PGF 1a ) were not changed, and products of the cytochrome P450 pathway or lipoxins were not detected in our model. While lung cancer initiation is mediated through regulation of oncogenic and tumor suppressor pathways, progression and metastasis involve complex interactions between the tumor cells and the TME [32]. Increased eicosanoid production during tumor progression may be a result of increasing numbers of inflammatory cells in the microenvironment. In addition, studies in many types of cancer have demonstrated that inflammatory cells undergo phenotypic modulation. Circulating monocytes/macrophages recruited to a tumor have been reported to either exhibit a tumoricidal phenotype, or upon contact with cancer cells, switch to a tumorpromoting phenotype [33,34]. The eicosanoid profiles of inflammatory cells may change during this phenotypic switch, leading to different induction of specific eicosanoids at later time points.
Since cPLA 2 is critical for eicosanoid production in most cell types, comparison of tumors grown in WT vs. cPLA 2 -KO mice allowed us to assess the contribution of the TME to eicosanoid production. In cPLA 2 -KO mice, we observed almost complete inhibition of leukotriene production, indicating that these products are largely produced by TME cells and their production is dependent on cPLA 2 . In contrast, levels of PGE 2 and other COX products were only moderately decreased (,50%) compared to tumors grown in WT mice, and were still increased compared to non-tumor bearing cPLA 2 -KO mice. This result can be attributed to continued eicosanoid production by LLC cells, which produce large amounts of PGE 2 in vitro. Thus our data demonstrate that PGE 2 is produced by both tumor cells and stromal cells. From our analysis we would conclude that production of most cyclooxygenase products involves both the tumor cells and the TME, but that leukotrienes are largely produced by the TME.
Using novel flow cytometry approaches developed for examining innate immune cells in the lung [26][27][28] we have been able to quantify changes in several distinct populations during cancer progression. Both the number of interstitial and infiltrating macrophages (MacB) and neutrophils were increased during tumor progression, whereas the number of resident alveolar macrophages (MacA) was not altered. While the contribution of a particular cell type to eicosanoid production will depend on the relative cell numbers in the setting of tumor, the in vivo stimuli, as well as on localization and timing of eicosanoid secretion, our data indicate that subtypes of inflammatory cells have different capacities for specific eicosanoids.
MacA cells, which represent resident alveolar macrophages, produced high levels and a large array of eicosanoids. Indeed, they were the only group capable of producing cysteinyl leukotrienes. Interestingly, in the setting of cPLA 2 knockout, eicosanoid production by MacA was significantly reduced, but not completely abrogated, which correlates with the reduction detected in the whole tumor-bearing lung. This result confirms critical role of cPLA 2 in eicosanoid production, but also indicates that MacA cells may use other sources of free AA, possibly monoacylglycerol lipase for eicosanoid generation [35]. Since the numbers of resident alveolar macrophages do not significantly increase during tumor progression (Fig. 3B), increased leukotriene and thromboxane levels in the whole tumor-bearing lung could be due to the activation of these cells.
Surprisingly, in MacB cells, which include mainly infiltrating monocytes/macrophages, the eicosanoid production per-cell was relatively low, despite clear expression of several enzymes in the eicosanoid pathway. Nonetheless, these cells may still significantly contribute to overall eicosanoid levels in the TME, if one considers high MacB cell infiltration during tumor progression (Fig. 3B). The low detected eicosanoid levels in MacB cells in vitro may also be due limitations of the in vitro assay. While increases in intracellular Ca 2+ as a result of exposure to ionophore will increase cPLA 2 activity, in many cells stimulation of additional pathways by growth factors or cytokines is required for maximal eicosanoid production [36,37]. In fact, stimulation of MacB cells with a combination of ionophore and phorbol ester (PMA) led to increased production of several eicosanoids, such as PGE 2 and HETEs compared to ionophore alone (not shown). Thus in vivo, MacB may be exposed to a milieu which activates these pathways. Alternatively, MacB cells may be specialized to perform functions other than eicosanoid production, such as cytokine secretion. In fact, these cells express high levels of Arginase-I and IL-1b, which in turn are very low in MacA or neutrophils (not shown). The analysis of tumor-associated neutrophils revealed that these cells had the highest per-cell production of LTB 4 and PGE 2 , and the production of these metabolites by neutrophils was wholly dependent on cPLA 2 . Our analysis focused on myeloid cells, since these cells were shown to produce high levels of eicosanoids in other settings, but full understanding of eicosanoid production in TME would require analysis of other cell types. Interestingly, we have not detected measureable levels of cytochrome P450 products in our tumors. Production of these eicosanoids by endothelial cells has been implicated in regulating distant organ metastases [14], suggesting that they may be produced in a localized fashion.
In conclusion, our studies, using an immunocompetent orthotopic model of lung cancer and combining flow cytometry and mass spectrometry technologies, define a complex profile of eicosanoid production during tumor progression, in which both cancer cells and specific cells of the microenvironment produce distinct eicosanoid products. Consequently, our studies implicate that anti-eicosanoid therapies will have differential effect on the cancer cells and on the cells of tumor microenvironment and provide a rationale to develop strategies targeting these populations to inhibit specific classes of eicosanoids.