Arachidonic acid metabolites, the eicosanoids, are key mediators of allergen-induced airway inflammation and remodeling in asthma. The availability of free arachidonate in cells for subsequent eicosanoid biosynthesis is controlled by phospholipase A2s (PLA2s), most notably cytosolic PLA2-α. 10 secreted PLA2s (sPLA2s) have also been identified, but their function in eicosanoid generation is poorly understood. We investigated the role of group X sPLA2 (sPLA2-X), the sPLA2 with the highest in vitro cellular phospholipolysis activity, in acute and chronic mouse asthma models in vivo. The lungs of sPLA2-X−/− mice, compared with those of sPLA2-X+/+ littermates, had significant reduction in ovalbumin-induced infiltration by CD4+ and CD8+ T cells and eosinophils, goblet cell metaplasia, smooth muscle cell layer thickening, subepithelial fibrosis, and levels of T helper type 2 cell cytokines and eicosanoids. These data direct attention to sPLA2-X as a novel therapeutic target for asthma.
Allergen-induced airway inflammation in asthma is characterized by eosinophil and CD4+ and CD8+ T cell infiltration of the airways and accompanied by airway structural changes (i.e., airway remodeling), including goblet cell metaplasia, increased smooth muscle mass, and subepithelial fibrosis from excessive deposition of extracellular matrix components such as collagen and laminin (for review see references 1, 2). Leukotrienes and prostaglandins are, respectively, 5-lipoxygenase and cyclooxygenase metabolites of arachidonic acid (i.e., eicosanoids) that are important in the pathogenesis of asthma. Release of 5-lipoxygenase products leukotriene B4 (LTB4), the cysteinyl leukotrienes (cysLTs) C4, D4, and E4, and cyclooxygenase products prostaglandin D2 (PGD2) and thromboxane A2 from inflamed airways leads to airway hyperresponsiveness and airflow obstruction with mucus glycoproteins. Evidence from animal models and patients with asthma suggest that these eicosanoids are key molecules that promote airway inflammation as potent chemoattractants for eosinophils, T cells, and other inflammatory cells; cause plasma extravasation and edema; modulate airway smooth muscle cell function; and induce release of extracellular matrix components (3–5).
The availability of free arachidonate in cells and, thus, the biosynthesis of leukotrienes and other eicosanoids, including prostaglandins, is tightly controlled by the regulated action of phospholipase A2s (PLA2s) that release this fatty acid by hydrolysis of the sn-2 ester of glycerophospholipids present as major components of cell membranes. Mammalian cells contain multiple types of PLA2s (6), but it is generally accepted that cytosolic group IVA PLA2-α (cPLA2-α; also known as group IVA PLA2; PLA2G4A) plays a pivotal role in agonist-mediated arachidonate release for the biosynthesis of the eicosanoids. This is based on studies with cPLA2-α inhibitors (7–10) and cPLA2-α–deficient mice (11–13). The mammalian genome also encodes 10 secreted PLA2s (sPLA2s). The role of these enzymes in eicosanoid biosynthesis is much less clear. Disruption of the group V sPLA2 gene (PLA2G5) in mice leads to ∼50% reduction in the amount of LTC4 and PGE2 production in zymosan-stimulated peritoneal macrophages (14). Group IIA, V, and X sPLA2s have been shown to coordinate with cPLA2-α to augment arachidonate release from cultured cells (15–20), but the mechanism for this coordinate action between cPLA2-α and sPLA2 is not known.
A systematic investigation of the interfacial kinetic and binding properties of the full set of mouse and human sPLA2s shows that the group X sPLA2 (sPLA2-X; PLA2G10) stands out as having the highest phospholipolysis activity when added to cultured cells (21, 22). Based on these findings and the fact that sPLA2-X is expressed in human (23, 24) and mouse lungs (this study), we investigated the possible role of sPLA2-X in a mouse asthma model by generating a sPLA2-X–deficient mouse for studies of allergen-induced airway inflammation and remodeling. In this initial study, we explored an animal disease model rather than experiments with single cell types in vitro, because sPLA2-X is a secreted enzyme and can potently act extracellularly on many, if not all, mammalian cell types to liberate arachidonic acid. Therefore, studies with cultured mammalian cells cannot shed sufficient light on the behavior of sPLA2-X in tissues. This is a different situation than with cPLA2-α that acts in the cytoplasm.
Results
Generation and characterization of the sPLA2-X−/− mouse
Mutation of the mouse sPLA2-X gene was accomplished by retroviral-mediated insertion of an exon-trapping cassette (see Materials and methods). DNA sequence analysis revealed that the trapping cassette is located in the intron between exons 3 and 4 of the sPLA2-X gene. Real-time (RT)–PCR analysis using primers hybridizing to exons 2 and 4 and cDNA made from mouse testis, colon, and stomach revealed ∼1,000-fold reduction in sPLA2-X mRNA levels in the sPLA2-X−/− mouse versus the wild-type littermate. We also looked for sPLA2-X protein in stomach extracts using a sensitive time-resolved fluorescence immunoassay (25). When 24 μg of stomach lysate protein was analyzed from a sPLA2-X+/+ mouse, 0.2 ng sPLA2-X protein was detected, whereas no sPLA2-X protein was detected when 34 μg of lysate protein from a sPLA2-X−/− mouse was used.
Allergen-induced airway inflammation and expression of sPLA2-X
Important insights into the mechanisms of chronic inflammation and remodeling in asthma have come from animal models that reproduce key morphologic and physiologic features of human asthma. To study the in vivo effects of sPLA2 deficiency on the asthma phenotype, we used OVA as a model allergen to induce allergen-specific pulmonary disease in wild-type and sPLA2-X−/− mice. In the acute asthma protocol (3), OVA-sensitized mice challenged with four doses of OVA display, by day 29, a disease strikingly similar to allergen-induced human asthma, including (a) circulating levels of allergen-specific IgE; (b) a marked influx of eosinophils and T cells into the airways; (c) increased levels of mucus glycoproteins, Th2 cell cytokines (IL-4, IL-5, and IL-13), and leukotrienes and other eicosanoids in bronchoalveolar lavage (BAL) fluid; and (d) pulmonary hyperreactivity to methacholine compared with saline-treated control mice. When the intranasal (i.n.) OVA challenges are continued periodically in the chronic asthma protocol (4, 26), by day 76 the mice have striking features of airway remodeling, including (a) goblet cell metaplasia, (b) increased smooth muscle cell layer mass, and (c) extensive subepithelial collagen deposition and airway wall thickening.
sPLA2-X expression in the lungs and the spleen of sPLA2-X−/− and wild-type mice in the acute asthma model was examined by immunocytochemistry. sPLA2-X was expressed in the airway epithelium in the lungs in saline-treated wild-type mice but not in sPLA2-X−/− mice (Fig. 1). After OVA sensitization and challenge, sPLA2-X expression greatly increased in the columnar cells lining the airways of wild-type mice but remained undetected in sPLA2-X−/− mice (Fig. 1 and Fig. S1). Confocal immunofluorescence microscopy demonstrated colocalization of sPLA2-X with airway epithelial cells expressing mucin 5AC glycoprotein (Fig. 2). Macrophages contributed to sPLA2-X expression in the airways, because alveolar macrophages, isolated from BAL fluid cells of OVA-treated wild-type mice (but not sPLA2-X−/− mice), exhibited strong reactivity for sPLA2-X by immunocytochemistry (Fig. 3). Splenic mononuclear cells also expressed sPLA2-X in sPLA2-X+/+ mice but not in sPLA-X−/− mice (Fig. S2). No staining reaction for sPLA2-X was observed when immunocytochemistry was performed with preimmune serum (Fig. S2).
Effect of sPLA2-X deficiency on allergen-induced recruitment of inflammatory cells into the lungs and hyperresponsiveness
On day 29, 24 h after the final i.n. OVA challenge in animals from each experimental group (i.e., acute asthma model), the effect of sPLA2-X deficiency on allergen-induced airway inflammation and hyperreactivity was determined. OVA-treated sPLA2-X+/+ mice had a sixfold increase in total cells recovered in BAL fluid compared with the saline group control (Fig. 4 a); ∼50% of the BAL fluid cells were eosinophils in the OVA-treated sPLA2-X+/+ mice. The total number of inflammatory cells and eosinophils in the BAL fluid of OVA-treated sPLA2-X−/− mice was significantly reduced compared with wild-type controls (Fig. 4 a). By light microscopy and morphometry, an influx of eosinophils and mononuclear cells into the lungs around the airways and blood vessels, airway goblet cell metaplasia/mucus hypersecretion, and interstitial edema were observed in OVA-treated sPLA2-X+/+ mice compared with saline controls (Fig. 4, b and c; and Fig. S3). This increased infiltration of total inflammatory cells and eosinophils, goblet cell metaplasia/mucus hypersecretion, and edema of the airway interstitium were markedly decreased in OVA-treated sPLA2-X−/− mice compared with sPLA2-X+/+ mice (Fig. 4, b and c; and Fig. S3). Using invasive plethysmography to determine lung resistance (RL), airway hyperreactivity to aerosolized methacholine was significantly increased in the OVA-treated wild-type mice compared with saline controls (Fig. 4 d). In contrast, pulmonary responses in the sPLA2-X−/− mice were not significantly different between the OVA and saline treatment groups (Fig. 4 d). In vivo airway responsiveness to aerosolized methacholine was also determined on day 29 in conscious, freely moving, spontaneously breathing mice using noninvasive whole-body plethysmography, and the same trends for Penh values were observed as for the invasive RL measurements (unpublished data).
Effect of sPLA2-X deficiency on allergen-induced airway remodeling
Wild-type mice challenged with OVA periodically over a 75-d period (i.e., chronic asthma model) had persistent airway infiltration by eosinophils and edema (Fig. 5 a; and Fig. S4 and Fig. S5), goblet cell metaplasia and mucus hypersecretion on day 76 (Fig. 5, a and b), and increased airway smooth muscle mass and collagen deposition (Fig. 6, a and b) compared with saline controls. These features of allergen-induced airway remodeling were significantly reduced in sPLA2-X−/− mice (Fig. 5, a and b; and Fig. 6, a and b).
Effect of sPLA2-X deficiency on Th2 responses
A molecular hallmark of asthma is Th2 cytokine expression. We examined the effect of sPLA2-X deficiency on Th2 cell–driven OVA-specific IgE levels, trafficking of T cells to the lungs, and pulmonary Th2 versus Th1 cytokine expression in both the acute and chronic mouse asthma models. Circulating levels of allergen-specific IgE in blood were reduced on day 29 in sPLA2-X−/− mice compared with wild-type controls after OVA treatment (Fig. 7 a). A substantial increase in the total number of T cells and also in the numbers of both CD4+ and CD8+ cells was seen in the BAL fluid of wild-type mice after OVA treatment on day 29 (Fig. 7 b). In contrast, negligible trafficking of T cells to the BAL fluid was observed in allergen-challenged sPLA2-X−/− mice (Fig. 7 b). By RT-PCR, gene expression of the Th2 cytokines IL-4, IL-5, and IL-13 was markedly increased in whole-lung tissue of OVA-sensitized/challenged sPLA2-X+/+ mice compared with saline-treated controls on day 76 (Fig. 7 c). In OVA-treated sPLA2-X−/− mice compared with wild-type controls, gene expression of IL-4, IL-5, and IL-13 was significantly reduced (Fig. 7 c). No significant change in gene expression of the Th1 cytokines IL-2 and IFN-γ, the lymphocyte-activating factor IL-1β, or the Th1-inducing cytokine IL-12 was seen in either wild-type or sPLA2-X−/− mice after OVA treatment compared with saline controls (Fig. 7 c). Significant levels of IL-4, IL-5, and IL-13 proteins were found in the BAL fluid of OVA-treated sPLA2-X+/+ mice compared with the saline control group on day 76 (Fig. 7 d). In the BAL fluid of OVA-treated sPLA2-X−/− mice, IL-4 was not detected, and IL-5 and IL-13 levels were significantly reduced compared with wild-type controls (Fig. 7 d). IL-1β, IL-2, IL-12 (p70), and IFN-γ were not detected in the BAL fluid of wild-type and sPLA2-X−/− mice after either saline or OVA treatment. Similar reductions in the pulmonary Th2 cytokine responses were observed in sPLA2-X−/− compared with wild-type mice in the acute asthma model (unpublished data).
To examine the effect of sPLA2-X deficiency on systemic CD4+ T cell–mediated production of Th2 cytokines in response to antigenic challenge, we used flow cytometric analysis to examine production of IL-4, IL-5, and IL-10, as well as the proinflammatory cytokines IFN-γ and TNF-α, upon overnight in vitro stimulation of splenic CD4+ T cells from OVA-immunized and unimmunized mutant and wild-type mice in the presence of OVA. Comparable antigen-specific production of IL-5 (Fig. 8 a) and IL-10 (Fig. 8 a) was detected in both mutant and wild-type T cells, as indicated by ∼2–2.5-fold increase in the percentage of cytokine- producing CD4+ T cells in the presence versus absence of OVA. In contrast to IL-5 and IL-10, antigen-specific production of IL-4, IFN-γ, and TNF-α was not detected using intracellular cytokine staining, suggesting that the frequency of OVA-specific CD4+ T cells producing these cytokines was below the detection level (unpublished data). Therefore, we used a single-cell immunospot assay (ELISPOT) to measure their OVA-stimulated production of IL-4 and IFN-γ. In agreement with flow cytometric analyses of IL-5 and IL-10 production, we found no difference in their ability to produce IL-4 (Fig. 8 c) and IFN-γ (Fig. 8 d). Further, there was a comparable ability to produce IL-4 by splenic CD4+ T cells from sPLA2-X−/− mice and wild-type controls in response to anti-CD3/anti-CD28 stimulation (Fig. 8 e). Thus, sPLA2-X deficiency does not result in a general repression of Th2 or Th1 cytokine production.
Effect of sPLA2-X deficiency on eicosanoid release
To assess the effect of sPLA2-X deficiency on arachidonic acid release, we used an acute asthma model to measure the levels of eicosanoids that are derived from this fatty acid, specifically via the cyclooxygenase pathway leading to PGD2 and PGE2 and via the 5-lipoxygenase pathway leading to LTB4 and cysLTs C4, D4, and E4 (i.e., total cysLTs). Because of its chemical instability (27), PGD2 was converted to a stable methoxime (MOX) derivative to prevent its further chemical degradation, and PGD2-MOX was assayed to determine PGD2 levels. Because PGE2 is rapidly and extensively metabolized in vivo (28), both native PGE2 and its 13,14-dihydro-15-keto metabolite were assayed to determine the total PGE2 levels produced. In an acute asthma model, PGD2 (Fig. 9 a), PGE2 (Fig. 9 b), LTB4 (Fig. 9 c), and cysLT (Fig. 9 d) levels were each significantly increased in the BAL fluid of sPLA2-X+/+ mice after OVA treatment compared with saline controls with cysLTs≫PGE2>LTB4>PGD2. The 13,14-dihydro-15-keto-PGE2 metabolite represented 91% of total PGE2 levels in the OVA-treated wild-type mice. As determined by liquid chromatography–electrospray tandem mass spectrometry, the fractional distribution of LTC4, LTD4, and LTE4 was similar in the BAL fluid of OVA- and saline-treated wild-type mice, with LTE4 the predominant cysLT recovered (i.e., the respective fractional distributions of LTC4:LTD4:LTE4 in OVA- and saline-treated sPLA2-X+/+ mice were 0.11:0.26:0.63 and 0.10:0.25:0.65, respectively). The levels of PGD2, PGE2, LTB4, and cysLTs in the BAL fluid of allergen-challenged sPLA2-X−/− mice were not significantly different than those of saline-controls (Fig. 9, a–d). The fractional distribution of LTC4, LTD4, and LTE4 in the BAL fluid of OVA- and saline-treated sPLA2-X−/− mice was the same as that observed for wild-type controls (0.11:0.26:0.63 for OVA-treated sPLA2-X−/− mice and 0.10:0.25:0.65 for saline-treated sPLA2-X−/− mice). On day 76 compared with saline controls (chronic model), both cyclooxygenase (i.e., PGE2) and 5-lipoxygenase (i.e., cysLTs) products of arachidonic acid were substantially increased in the BAL fluid of wild-type but not sPLA2-X−/− mice after OVA treatment (unpublished data).
Discussion
Our results suggest that sPLA2-X plays a critical role in the pathogenesis of the asthma phenotype. The major findings of this study are that deficiency of sPLA2-X in mice substantially reduces allergen-induced (a) airway eosinophil and CD4+ and CD8+ T cell trafficking, mucus hypersecretion, and hyperresponsiveness to methacholine in an acute model of asthma; (b) airway remodeling (i.e., goblet cell metaplasia, smooth muscle cell layer thickening, and subepithelial fibrosis in the lungs) in a chronic asthma model; and (c) Th2 cytokine and eicosanoid levels in these models of human asthma.
Our data suggest that sPLA2-X plays a role in eicosanoid generation and that the reduction in eicosanoid generation seen in the sPLA2-X−/− mice leads to a decrease in Th2 responses. The Th2 cell subset of CD4+ T cells has been recognized as pivotal in the development of this allergen-induced airway eosinophilic infiltration, mucus hypersecretion, fibrosis, and hyperreactivity through the secretion of IL-4, IL-5, and IL-13 cytokines. More recently, CD8+ T cells have been demonstrated to substantially contribute to these allergen- induced responses by their trafficking to the lungs and local generation of IL-13 (29). We found that sPLA2-X deficiency resulted in a marked decrease in movement of both CD4+ and CD8+ T cells to the airway lumen that was associated with diminished pulmonary Th2 cytokine gene and protein expression. Splenic T cells from the sPLA2-X−/− mice showed normal induction of Th2 and Th1 cytokines with ex vivo stimulation. Thus, the marked impairment in the ability of the mutant mice to recruit allergen-specific T cells to the lungs likely accounts for the observed diminution in pulmonary Th2 cytokine production and inflammation. Among other key effects on the asthma phenotype, IL-13 induces secretion of mucin 5AC glycoprotein, differentiation of ciliated epithelial cells into goblet cells (30), and release of TGFβ, leading to fibrosis (31) in the airways of mice after allergen challenge. IL-4, in the absence of other Th2 cytokines, can also induce typical Th2 responses, including airway goblet cell metaplasia, in a mouse asthma model (32). IL-5 promotes growth and maturation of eosinophil precursors and stimulates the chemotaxis of mature eosinophils, prolonging their survival in allergic inflammatory tissue sites by inhibition of apoptosis (2). In both wild-type and sPLA2-deficient mice, Th1 cytokines remained low after OVA stimulation.
We found that in sPLA2-X–deficient mice, there is a reduction in elevated levels of eicosanoids found in OVA-treated wild-type mice, and this likely leads to an amelioration of the asthma phenotype. In mouse models of asthma, specific inhibitors of 5-lipoxygenase, or leukotriene receptor antagonists, considerably reduce indices of allergic airway inflammation, including Th2 cytokine levels (3, 4). The cysLT1 receptor antagonist montelukast inhibits Th2 cytokine gene and protein expression in the lungs of sensitized mice chronically challenged with OVA (4). Further, established and persistent airway eosinophilia, goblet cell metaplasia, increased airway smooth muscle mass, and subepithelial fibrosis in a mouse model of allergen-induced airway remodeling are reversible by cysLT1 receptor blockade (26). The cysLTs promote growth of eosinophil progenitors from the blood and bone marrow of atopic individuals (33), stimulate eosinophil chemotaxis, and increase their survival in tissue sites of allergic inflammation. Bronchial smooth muscle cells, with increased cysLT1 receptor expression after TGFβ and IL-13 treatment, proliferate in response to LTD4 (34). cysLTs also induce the release of mucus by airway goblet cells (3) and collagen by TGFβ-transformed lung myofibroblasts (35). In IL-13–induced airway inflammation and remodeling in mice, 5-lipoxygenase inhibitors, as well as cysLT1 and LTB4 receptor antagonists, reduce eosinophil infiltration, mucus cell metaplasia, and collagen deposition in the airways, indicating that both LTB4 and cysLTs C4, D4, and E4 substantially contribute to the effects of IL-13 on the lung (5).
Recent studies have indicated an important role for LTB4 and PGD2 in directing T cells to the airways in asthma. Using mice deficient in the LTB4 receptor BLT1, a requirement of the LTB4–BLT1 pathway, has been demonstrated as crucial for the early recruitment of CD4+ and CD8+ T cells to the airways after allergen challenge (36). The T cell–mediated allergen-induced airway hyperresponsiveness in this model is dependent on BLT1 and is associated with IL-13 production by the T cells (37, 38). Increased numbers of BLT1+ T cells are found in the airways of allergic individuals with asthma (39). Mice deficient in DP1, one of the receptors for PGD2, have decreased airway Th2 cytokines, eosinophil infiltration, and mucus hypersecretion compared with wild-type controls after allergen sensitization and challenge (40). PGD2 induces preferential generation of Th2 cytokines by its interaction with the chemoattractant receptor–like molecule expressed on Th2 cells (41).
Over the past decade, it has generally been considered that cPLA2-α is the master regulator of arachidonate release from cellular phospholipids. Early reports showed that group IIA sPLA2 (PLA2G2A) rises to high levels in serum and synovial fluid in patients suffering from inflammatory disorders, including acute pancreatitis and rheumatoid arthritis (42, 43), but there was no evidence showing that group IIA sPLA2 is directly responsible for the liberation of arachidonate from phospholipids for the biosynthesis of eicosanoids. More recent work has shown that sPLA2s can augment the action of cPLA2-α in cells to liberate arachidonate. Peritoneal macrophages from group V sPLA2-deficient mice produce ∼50% as much free arachidonate compared with wild-type cells after stimulation with zymosan, a fungal cell wall–derived agonist (14), yet there is essentially no arachidonate released in this system when macrophages from cPLA2-α–deficient mice are used (13). Earlier studies with antisense technology to knock down the level of group V sPLA2 also support a role for a joint action of group V sPLA2 and cPLA2-α in macrophages (16). Thus, cPLA2-α and group V sPLA2 work together by an unknown mechanism leading to maximal arachidonate release. Because both enzymes are PLA2s that can hydrolyze arachidonyl-containing phospholipids, it is not possible at this point to know which enzyme is directly responsible for most of the phospholipid sn-2 lipolysis leading to arachidonate release.
In rat gastric epithelial cells (RGM1) and in rat fibroblasts (3Y1), cytokine-induced arachidonate release and PGE2 production coincide with up-regulation and secretion of group IIA sPLA2 into the culture medium, and studies with cPLA2-α and sPLA2 inhibitors support a coordinate role for both enzymes in arachidonate release (15, 17). Coordinate action of cPLA2-α and sPLA2s has also been recently reported in transfected cells (18, 19). There are no reports showing that endogenous sPLA2-X is directly involved in arachidonic acid release from mammalian cells in culture. Nevertheless, we decided to explore the sPLA2-X−/− mouse in an animal model of asthma because of the high activity that this enzyme shows when added to mammalian cells in culture (21, 22). The results of the present study showing a clear role for sPLA2-X in mediating airway inflammation in a mouse model of allergic asthma are thus important and novel. Our study is the first to demonstrate an important role for an sPLA2 in an animal model of asthma. It remains to be seen if other mammalian sPLA2s play a role in airway inflammation and hyperreactivity.
In OVA-treated wild-type mice, a strong signal in immunohistochemical detection of sPLA2-X in mouse lung sections was seen in airway epithelial cells and alveolar macrophages. sPLA2-X colocalized with airway epithelial cells expressing mucin 5AC, a major gel-forming mucin of mouse (44) and human (45) airway epithelial cells. Studies using in situ hybridization for mRNA detection have shown that human lung epithelial cells also express sPLA2-X, along with sPLA2-V (24). It is generally thought that airway epithelial cells lack the lipoxygenases and cyclooxygenases needed to convert free arachidonate into leukotrienes and prostaglandins. However, in vitro cell co-culture studies have shown that arachidonate released from stimulated airway epithelial cells can be transferred to nearby macrophages and eosinophils for oxygenation leading to eicosanoids (46, 47). Thus, a reasonable working hypothesis for the results seen in the current study is that airway epithelial cell sPLA2-X generates free arachidonate, which is converted into proinflammatory eicosanoids by nearby leukocytes. Studies are underway to test this hypothesis by selectively disrupting the sPLA2-X gene in airway epithelial cells.
Our data demonstrating a profound effect of sPLA2-X deficiency on Th2 cell–driven airway inflammation and remodeling in a mouse model of human asthma bring a new dimension to the PLA2 field. These findings point to sPLA2-X as a potential target for the development of novel antiasthma drugs.
Materials And Methods
Generation of the sPLA2-X–deficient mouse.
Embryonic stem cells (129SvEvBrd-derived) containing a mutated sPLA2-X gene were prepared by a high throughput gene trapping technique and used at Lexicon Genetics Inc. to generate a chimeric mouse in the 129SvEvBrd/C57BL/6J mixed background, as previously described (48, 49). This approach uses a multiplicity of infection with virus that disfavors multiple insertions of the trapping cassette. The sPLA2-X−/− mouse was generated by breeding, and the genotype was verified by PCR using the primers LTR2, upper, and lower (primer sequences and PCR conditions are provided in Table S1). LTR2 and lower give the mutant band of 320 bp, and upper and lower give the wild-type band of 392 bp. Two lines of evidence indicate that the trapping cassette is present as a single copy in the genome: (a) rapid amplification of cDNA ends sequencing on the 3′ fusion transcript revealed only a single sequence, and (b) quantitative PCR on the neomycin cassette demonstrated only a single copy in heterozygote mice.
Analysis of sPLA2-X mRNA and protein.
We used primers to exons 2 and 4 for PCR analysis of cDNA isolated from mouse tissues. Mouse testis was ground in RNA lysis buffer (600 μl/100 mg of tissue; Promega) on ice, and RNA was isolated from 175 μl of suspension using a kit (Z3100; Promega). A 5-μl aliquot of the resultant 100 of RNA solution in water was converted to 20 μl of cDNA solution using a kit (Marligen Biosciences, Inc.). 1 μl of cDNA was used in a 25-μl PCR reaction with primers directed at the mouse glyceraldehyde-3–phosphate dehydrogenase mRNA sequence and predicted to form a 500-bp product spanning more than one exon. From the results of agarose gel electrophoresis on 5 μl of the PCR product after 23, 27, and 31 cycles of PCR, the amount of cDNA required just to show a perceptible band at 500 bp after 23 cycles was estimated. This amount was used in a second PCR reaction with the primers sPLA2-X–F4 (from exon 2) and sPLA2-X–RC (from exon 4). These primers gave an sPLA2-X band of the correct size (480 bp) on a 2% agarose gel after 27 cycles of PCR with cDNA derived from testis from a sPLA2-X+/+ mouse, whereas 39 cycles of PCR were required to see this same band from the same amount of cDNA derived from testis from the sPLA2-X−/− mouse, corresponding to ∼1,000-fold reduction in sPLA2-X mRNA. No PCR band was seen in a blank control after 39 PCR cycles.
To examine sPLA2-X protein expression, stomachs from sPLA2-X−/− and sPLA2-X+/+ littermate mice were flash frozen in liquid nitrogen and lyophilized. Each stomach was soaked in 200 μl of saline, mixed by vortexing, and incubated at 4°C for 30 min. Samples were centrifuged at 16,000 g for 10 min, and the supernatants were assayed for protein by the Bradford assay and for sPLA2-X using time-resolved immunoassay, as previously described (25).
Allergen challenge in mice.
All animal use procedures were approved by the University of Washington Animal Care Committee. sPLA2-X−/− C57BL/129 mice and their wild-type sPLA2-X+/+ littermates received i.p. injections of 100 μg OVA (0.2 ml of 0.5 mg/ml; Pierce Chemical Co.) complexed with aluminum potassium sulfate (alum; Sigma-Aldrich) on days 0 and 14. Mice were anesthetized i.p. with 130 mg/kg ketamine and 8.8 mg/kg xylazine in normal saline before receiving an i.n. dose of 100 μg OVA (0.05 ml of 2 mg/ml) on day 14, and 50 μg OVA (0.05 ml of 1 mg/ml) on days 26, 27, and 28 (acute asthma model) or days 26, 27, 28, 47, 61, 73, 74, and 75 (chronic asthma model). Control groups received 0.2 ml of normal saline with alum i.p. on days 0 and 14, and 0.05 ml of saline without alum i.n. on days 14, 26, 27, and 28 or days 14, 26, 27, 28, 47, 61, 73, 74, and 75. Mouse plasma samples were obtained on day 29 from the OVA- and saline-treated groups and assayed for OVA-specific IgE (50). For eicosanoid analysis studies, mice were immunized i.p. with 10 μg OVA and 1.125 mg alum in 0.2 ml of normal saline on days 0, 7, and 14 and exposed to 1% aerosolized OVA, as previously described by Myou et al. (51) for 40 min on days 21, 22, and 23. Control groups received 0.2 ml of normal saline with alum i.p. on days 0, 7, and 14, and saline by aerosol on days 21, 22, and 23.
Pulmonary function testing.
On day 29, invasive pulmonary mechanics were measured in mice in response to methacholine in the same manner as previously described (3), with the following modifications: (a) the thorax was not opened; (b) mice were ventilated with a tidal volume of 200 μl and a respiratory rate of 120 breaths per minute using a MiniVent Ventilator for Mice (Harvard Apparatus); (c) mice received aerosolized solutions of methacholine (0, 3.125, 6.25, 12.5, 25, and 50 mg/ml in normal saline) via a nebulizer aerosol system (AER 1021; Buxco Electronics) with a 2.5–4-μm aerosol particle size generated by a nebulizer head (NEB0126; Nektar Therapeutics); and (d) a commercial plethysmography system consisting of a plethysmograph (model PLY4111), amplifier and pressure transducer system (MAX II), and Biosystem XA software (all obtained from Buxco Electronics) was used to determine RL as calculated from the measures of pressure and flow and expressed as cm H2O/ml/s. Noninvasive plethysmography was also assessed on day 29, as described in Supplemental materials and methods .
BAL.
After tying off the left lung at the mainstem bronchus, the right lung was lavaged three times with 0.5 ml of normal saline either 1 h (for eicosanoid assays) or 24 h (for cytokine assays) after the final OVA or saline treatment. The BAL fluid was centrifuged at 250 g, and the supernatant was processed for eicosanoid assays, as described in detail in Supplemental materials and methods. Total BAL fluid cells were counted with eosinophils stained with 0.05% eosin (3), and the number of CD3+, CD4+, and CD8+ T cells was determined by cytofluorimetry. On day 29, alveolar macrophages were isolated from the BAL fluid cells by adherence to Esco Fluro slides (Erie Scientific Company) for 2 h in RPMI 1640 with l-glutamate (Cellgro; Mediatech, Inc.) in humidified 5% CO2/95% air at 37°C, as previously described (52). To remove nonadherent cells, the slides were washed six times in PBS, and adherent cells were stained for sPLA2-X expression.
Cytofluorimetry.
BAL fluid cells were preincubated with 1 μg Fc Block (anti–mouse CD16/CD32 [FcγIII/II receptor]; BD Biosciences) per 106 cells in 50 μl of staining buffer (BD Biosciences) for 15 min at 4°C to reduce nonspecific immunostaining. After washing in PBS containing 1% FBS, pH 7.4 (Sigma-Aldrich), ∼106 cells were incubated with 50 μl PBS + 1% FBS buffer containing 1 μg each of the following antibodies purchased from BD Biosciences: PE–anti–mouse CD3e (CD3ε chain; 145-2C11), allophycocyanin –anti–mouse CD4 (L3T4; RM4-5), and FITC–anti–mouse CD8a (Ly-2; 53-6.7) for 20 min at 4°C. Cells were fixed in 1% paraformaldehyde in PBS for 16 h at 4°C, and cytofluorimetry was performed with a flow cytometry system (Cytomics FC500; Beckman Coulter).
RT-PCR.
Total RNA was isolated from the right lung using an RNeasy mini kit (QIAGEN), and mRNA levels for IL-1β, IL-2, IL-4, IL-5, IL-12α (IL-12 p35 subunit), IL-12β (IL-12 p40 subunit), IL-13, IFN-γ, and GAPDH were determined by RT-PCR. A PCR System (7900HT Fast Real-Time; Applied Biosystems) was used, and SYBR green PCR master mix was used (Applied Biosystems. 0.2 μg RNA was used to synthesize first-strand cDNA with the first-strand synthesis system (SuperScript III; Invitrogen). All primers were designed using primer 3 and crossed large expanses of the intronic sequence (Table S1). PCR sizes were ∼100 bp and were confirmed by gel electrophoresis. RT-PCR readings had to be within the range of the standard curve. Sample cDNAs were diluted to 20 ng/μl.
Lung and spleen histopathology.
The trachea, upper and lower lobes of the left lung, and spleen were fixed for 24 h in 10% neutral buffered formalin solution. The tissues were embedded in paraffin and cut into 5-μm sections. For lung morphometry, 10 airways (0.4–0.7 mm in diameter and surrounded by smooth muscle cells) per mouse were randomly selected and examined by individuals blinded to the protocol design (3). The sections were stained with hematoxylin and eosin to evaluate airway edema (i.e., alveolar flooding by amorphous material) on a semiquantitative 0–4+ scale (0 = 0–10% alveoli with edema; 1 = 10–20% alveoli with edema; 2 = 20–30% alveoli with edema; 3 = 30–40% alveoli with edema; and 4 = 40–50% alveoli with edema) (50) and total inflammatory cell infiltration (3) on a semiquantitative scale ranging from 0–4+ and eosinophil numbers per unit of lung tissue area (2,200 μm2). Each field, at magnification of 400 using a micrometer disc (Whipple; Bausch & Lomb), represented 2,200 μm2 of tissue area. The smooth muscle mass of the smooth muscle cell layer beneath the airway epithelial cell basement membrane was assessed on a 0–4+ scale at three sites tangential to each airway cross-section examined (4). The sections were stained with alcian blue/periodic acid Schiff (PAS) reaction to identify airway goblet cells and mucus (3). The number of goblet cells was determined as the percentage of total airway epithelial cells in each airway examined. Mucus occlusion of the airway diameter was assessed on a 0–4+ scale. Each airway section was assigned a score for airway diameter occlusion by mucus based on the following criteria: 0 = 0–10% occlusion; 1 = 10–30% occlusion; 2 = 30–60% occlusion; 3 = 60–90% occlusion; and 4 = 90–100% occlusion (3). To determine subepithelial collagen deposition/fibrosis in the airways, the sections were stained with Masson's trichrome stain (4). The intensity of the collagen deposition (0–4+ scale) was assessed in the immediate region beneath the epithelium containing the contractile elements and extracellular matrix associated with the airways, as described by Leigh et al. (53)
Immunocytochemistry.
sPLA2-X expression in mouse lung and spleen was localized by immunocytochemistry using light microscopy (54). Tissues were fixed in methyl Carnoy's solution and embedded in paraffin, and 5-μm sections were cut, placed on slides (Super Frost Plus; VWR Scientific), deparaffinized, hydrated, and rinsed in PBS. All immunolabeling procedures were performed at 24°C. Endogenous peroxidase was inactivated by incubating the tissue sections in 0.75% hydrogen peroxide for 30 min. After rinsing in PBS, the sections were incubated with the primary antibody, polyclonal rabbit anti–sPLA2-X–specific antisera (55), at a 1:50 dilution for 25 min, followed by rinsing in PBS and incubation with the secondary antibody, goat anti– rabbit antibody conjugated to horseradish peroxidase (Vector Laboratories), at a 1:20 dilution for 25 min. The controls were either PBS or normal rabbit IgG (Vector Laboratories) used in place of the primary antibody. After rinsing in PBS, the sections were incubated with 0.5% 3′,3′-diaminobenzidine tetrachloride (Sigma-Aldrich) in PBS and 0.15% hydrogen peroxide for 15 min for detection of peroxidase. The sections were rinsed in PBS, and nuclei were counterstained with 1% methyl green in distilled water for 3 min. The sections were dehydrated in ethanol, cleared in xylene, and mounted on glass slides with Permount (Fisher Scientific). BAL fluid alveolar macrophages, isolated by overnight adherence to microscope slides, were also stained for sPLA2-X by immunocytochemistry.
Immunofluorescence confocal microscopy.
For immunofluorescence double staining of mucin 5AC and sPLA2-X, lung tissue was frozen in liquid nitrogen immediately after collection, embedded in OCT compound (Tissue-Tek; Sakura Finetek USA, Inc.), and cut into 10-μm-thick cryostat sections. After rinsing in PBS, the slides were fixed in acetone for 5 min, washed three times in PBS, and blocked in 2% dry milk for 30 min at room temperature. The sections were incubated with the primary antibodies (both at a dilution of 1:100 in PBS), rabbit anti–mouse sPLA2-X (55) and goat anti–mouse mucin 5AC (K-20; Santa Cruz Biotechnology, Inc.), for 40 min at room temperature, washed three times in PBS, and incubated with the secondary antibodies (both at a dilution of 1:100 in PBS; Invitrogen), Alexa Fluor 594 (i.e., red fluorophore) donkey anti–rabbit IgG and Alexa Fluor 488 (i.e., green fluorophore) donkey anti–goat IgG, for 30 min at room temperature. After washing in PBS, coverslips were placed with IMMU-MOUNT (Shandon Inc.), and slides were stored in the dark at 4°C. Sections were examined on a confocal microscope (LSM510Meta; Carl Zeiss MicroImaging, Inc.) running software version 4.0. Fluorescence excitation was provided using an argon laser line (488 nm) and a helium–neon laser line (543 nm).
Cytokine and eicosanoid analyses.
Lincoplex multiplexed biomarker immunoassays of BAL fluid for IL-1β, IL-2, IL-4, IL-5, IL-12 (p70), and IFN-γ were performed using Luminex instrumentation (3.2 pg/ml detection limit; LINCO Research) according to the manufacturer's instructions. IL-13 (1.5 pg/ml detection limit; R&D Systems), LTB4 (13 pg/ml detection limit; Cayman Chemical), cysLTs (LTC4/LTD4/LTE4, 13 pg/ml detection limit; Cayman Chemical), PGD2 (measured as the stable MOX derivative PGD2-MOX after treatment of the samples with methoxylamine hydrochloride; 3.1 pg/ml detection limit using a PGD2-MOX enzyme immunoassay (EIA) kit; Cayman Chemical), and PGE2 (measured as the total of PGE2 [15 pg/ml detection limit using a PGE2 kit–monoclonal; Cayman Chemical] and its 13,14,dihydro-15-keto metabolite [2 pg/ml detection limit using a PGE2 metabolite EIA kit; Cayman Chemical]) were determined by EIA. The fraction of cysLTs that are LTC4, LTD4, and LTE4, was determined by combined liquid chromatography–electrospray tandem mass spectrometry using a modification of the method of Kita et al. (56). Full details of eicosanoid analyses are provided in Supplemental materials and methods.
For flow cytrometric analysis of intracellular cytokines, total splenic cell populations from experimental and control mice were plated in 24- well plates (4 × 106 cells per well) and activated with 200 μg/ml OVA (Pierce Chemical Co.) overnight. The samples were stained with pericinin-chlorophyll-a-protein–conjugated anti-CD4, allophycocyanin-conjugated anti-CD8, and PE-conjugated antibodies against the following cytokines: IL-4, IL-5, IL-10, TNF-α, and IFN-γ (antibodies were obtained from BD Biosciences and eBioscience). The intracellular staining for cytokines was performed using the manufacturer's standard protocol (BD Biosciences). Samples were analyzed using a flow cytometer (FACSCanto; BD Biosciences), and the data were analyzed using FlowJo software (TreeStar Inc.).
For enzyme-linked IL-4 and IFN-γ immunospot (ELISPOT) assays (BD Biosciences), total spleen cells from OVA- and saline-treated sPLA2-X−/− mice and wild-type controls were collected, plated in 96-well plates (2 × 105 cells/well), and incubated in triplicate in 5% CO2/95% air at 37°C in the absence or presence of 5 ng/ml PMA (Sigma-Aldrich) and 500 ng/ml ionomycin (Sigma-Aldrich) for 24 h or 500 μg/ml OVA (Pierce Chemical Co.) for 5 d according to the manufacturer's protocol (BD Biosciences). CD4+ T cells were isolated from the spleen cells using Dynabeads Mouse CD4 (L3T4) and DETACHsBEAD Mouse CD4 (Dynal), according to the manufacturer's instructions. 4 × 104 CD4+ T cells/well were incubated in triplicate in 5% CO2/95% air at 37°C in the absence or presence of 1 μg/ml of hamster anti–mouse CD3ε/2 μg/ml of hamster anti–mouse CD28 monoclonal antibodies (BD Biosciences) for 5 d, and IL-4 immunospot was performed.
Statistical analysis.
Data are reported as the mean ± SEM. Differences were analyzed for significance (P < 0.05) by analysis of variance using the least significant difference method.
Online supplemental material.
Fig. S1 shows sPLA2-X expression in airway cells of OVA-treated sPLA2-X+/+ mice by immunocytochemistry. Fig. S2 shows that sPLA2-X expression is seen in splenic mononuclear cells in sPLA2-X+/+ mice but is absent in sPLA2-X−/− mice by immunocytochemistry. Fig. S3 shows decreased goblet cell metaplasia and mucus release in the lungs of sPLA2-X−/− mice after allergen challenge in an acute asthma model. Fig. S4 shows reduced levels of eosinophils in BAL fluid of OVA-treated sPLA2-X−/− mice in a chronic asthma model. Fig. S5 shows reduced allergen-induced airway inflammatory cell infiltration and edema in sPLA2-X−/− mice in a chronic asthma model. Table S1 provides the sequence of PCR primers and PCR conditions used. Supplemental materials and methods contains details of the procedure for BAL fluid eicosanoid analysis by liquid chromatography–electrospray tandem mass spectrometry and EIA and pulmonary function testing by noninvasive plethysmography.
Acknowledgments
We thank Lexicon Genetics Inc. for generation of the sPLA2-X–deficient mouse, Yoshihara Kita and Takao Shimizu and Nilda Muñoz for assistance with eicosanoid analysis, and Ronald Seifert for help with the confocal microscopy.
This work was funded by National Institutes of Health grants RO1 AI 42989 and HL 73722 (to W.R. Henderson Jr.) and HL 36235 (to M.H. Gelb).
The authors have no conflicting financial interests.
References
Abbreviations used: BAL, bronchoalveolar lavage; cysLT, cysteinyl leukotriene; cPLA2-α, cytosolic group IVA PLA2; EIA, enzyme immunoassay; i.n., intranasal; LTB4, LTC4, LTD4, and LTE4, leukotriene B4, C4, D4, and E4, respectively; MOX, methoxime; PAS, periodic acid Schiff; PGD2 and PGE2, prostaglandin D2 and E2, respectively; PLA2, phospholipase A2; RL, lung resistance; RT, real time; sPLA2, secreted PLA2; sPLA2-X, group X sPLA2.