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Open Access

Peer-reviewed

Research Article

Expression of DP2 (CRTh2), a Prostaglandin D2 Receptor, in Human Mast Cells

Correction

17 Dec 2014: The PLOS ONE Staff (2014) Correction: Expression of DP2 (CRTh2), a Prostaglandin D2 Receptor, in Human Mast Cells. PLOS ONE 9(12): e116246. https://doi.org/10.1371/journal.pone.0116246 View correction

Abstract

PGD2 has long been implicated in allergic diseases. Recent cloning of a second PGD2 receptor, DP2 (also known as CRTh2), led to a greater understanding of the physiological and pathophysiological implications of PGD2. PGD2 signaling through DP1 and DP2 mediates different and often opposite effects in many cell types of the immune system. Although mast cells (MC) are the largest source of PGD2 in the body, there is little information about their potential expression of DP2 and its functional significance. In this study, we show that tissue MC in human nasal polyps express DP2 protein, and that human MC lines and primary cultured human MC express mRNA as well as protein of DP2. By immunohistochemistry, we detected that 34% of MC in human nasal polyps expressed DP2. In addition, flow cytometry showed that 87% of the LAD2 human MC line and 98% of primary cultured human MC contained intracellular DP2. However, we could not detect surface expression of DP2 on human MC by single cell analysis using imaging flow cytometry. Blocking of endogenous PGD2 production with aspirin did not induce surface expression of DP2 in human MC. Two DP2 selective agonists, DK-PGD2 and 15R-15-methyl PGD2 induced dose-dependent intracellular calcium mobilization that was abrogated by pertussis toxin, but not by three DP2 selective antagonists. MC mediator release including degranulation was not affected by DP2 selective agonists. Thus, human MC express DP2 intracellularly rather than on their surface, and the function of DP2 in human MC is different than in other immune cells such as Th2 cells, eosinophils and basophils where it is expressed on the cell surface and induces Th2 cytokine and/or granule associated mediator release. Further studies to elucidate the role of intracellular DP2 in human MC may expand our understanding of this molecule and provide novel therapeutic opportunities.

Citation: Moon TC, Campos-Alberto E, Yoshimura T, Bredo G, Rieger AM, Puttagunta L, et al. (2014) Expression of DP2 (CRTh2), a Prostaglandin D2 Receptor, in Human Mast Cells. PLoS ONE 9(9): e108595. https://doi.org/10.1371/journal.pone.0108595

Editor: Roland Seifert, Medical School of Hannover, Germany

Received: May 28, 2014; Accepted: August 23, 2014; Published: September 30, 2014

Copyright: © 2014 Moon et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: The authors confirm that all data underlying the findings are fully available without restriction. All relevant data are within the paper.

Funding: This study was supported by the Canadian Institutes of Health Research (CIHR, 7034, 111267). TCM received a CIHR-Rx&D/Canadian Lung Association/GlaxoSmithKline (GSK) research program fellowship (XCL-81974) and Alberta Heritage Foundation for Medical Research (now Alberta Innovates - Health Solutions, AIHS) fellowship (200501397). TY received a fellowship from Tokyo Jikei Medical University. EC received an AllerGen/Canadian Allergy, Asthma and Immunology Foundation (CAAIF)/Merck International Clinician-Scientist and Post-Doctoral Research Fellowship. LC received a salary award from AIHS and held a GSK-CIHR Chair in Airway Inflammation, and these were competitive peer reviewed grant competitions. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The funding from “GlaxoSmithKline” as a CIHR-Rx&D/Canadian Lung Association/GSK research program fellowship (XCL-81974) to TCM is a post-doctoral fellowship administered by the Canadian Institutes of Health Research (CIHR) in partnership with the Canadian Lung Association, GlaxoSmithKline and CIHR Rx&D Collaborative Research Program. There is no competing interest with GlaxoSmithKline with this fellowship award. The funding from “Merck” as an AllerGen/Canadian Allergy, Asthma and Immunology Foundation (CAAIF)/Merck International Clinician-Scientist and Post-Doctoral Research Fellowship to EC is administered by AllerGen, a government funded National Centre of Excellence. There is no competing interest with Merck with this salary award. The funding from “GlaxoSmithKline” as a GSK-CIHR Chair in Airway Inflammation and from AIHS to LC are salary awards scholarships. Therefore there is no competing interest with GlaxoSmithKline. AIHS is not a commercial source but is a publicly funded, board-governed corporation that operates under an Act of the Alberta provincial legislature. Cover Letter The “AstraZeneca Canada Inc.” in ADB's title is to acknowledge his chair position as a courtesy, but ADB has no commercial relationship with them. In 1991, Astra Canada endowed a Chair in Asthma Research to the University of Alberta; Astra merged with Zeneca much later and the name of the endowment/chair was altered. This endowment is under the full control of the University and there is no formal affiliation with AstraZeneca. Therefore there is no competing interest with AstraZeneca Canada Inc. This does not alter our adherence to PLOS ONE policies on sharing data and materials.

Introduction

Mast cells (MC) are tissue-resident cells derived from bone marrow progenitors. They are widely distributed throughout the body, performing multiple tasks in different locations and functional settings. MC are primary effector cells of allergic inflammation following IgE cross-linking and they also have diverse roles in angiogenesis, wound healing, tissue remodeling, regulation of inflammation, host defense, and innate and adaptive immune responses [1][4]. Along with mediators such as histamine and proteases in the granules, and de novo synthesized cytokines and chemokines, activated MC produce an abundance of prostaglandin (PG) D2 and leukotriene (LT) C4 [5], [6]. These lipid mediators have bronchoconstricting and vasoactive properties, but also participate in host defense, inflammation, and allergic diseases through diverse activities such as effector cell trafficking, antigen presentation, immune cell activation and fibrosis [6][8].

PGD2 is a key mediator produced by activated MC [5], [9] and antigen presenting cells [10] following allergen exposure in patients with asthma, atopic dermatitis or allergic rhinitis [11][13]. PGD2 contributes directly to smooth muscle contraction [14], [15], vascular leak and vasodilation [16] that typically occur in type I hypersensitivity, and also potentiates cellular responses to other physiologically relevant mediators (eg., histamine) released during these allergic reactions [17]. It modulates dendritic cell migration and maturation [18] and induces migration and activation of human Th2 cells [19], [20], eosinophils [21], [22], basophils [20], [23], and macrophages [24]. PGD2 mediates its effects via activation of D prostanoid receptors (DPs). DP1, a member of the prostanoid family of G protein-coupled receptors (GPCR), uses pertussis toxin (PTX)-resistant Gs proteins for its signaling that stimulates adenylate cyclase and elevates intracellular levels of cyclic adenosine monophosphate (cAMP). Recently, DP1 was shown to play a role in MC maturation toward an anaphylaxis-sensitive phenotype [25]. DP2 [also known as CRTh2 (chemoattractant receptor-homologous molecule expressed on Th2 cells), GPR44, and CD294] is a GPCR of the formylmethionylleucylphenylalanine receptor subfamily with a primary amino acid sequence homology to chemokine receptors. It signals with PTX-sensitive Gi proteins that suppress adenylate cyclase and decrease intracellular cAMP levels, but induces intracellular Ca2+ mobilization in response to PGD2 [20], [26], [27]. Although DP2 was first discovered in human Th2 cells and is a specific marker for human Th2 compared to human Th1 cells, this differs in the mouse where both Th1 and Th2 cells express DP2 [28]. Human and/or mouse eosinophils, basophils, macrophages and dendritic cells express DP2, and DP2 signaling causes chemotaxis and activation of these cells [18][24], [26], [29], [30].

Although MC are a major source of PGD2, little is known about DP2 expression in human MC except for an immunohistochemical study which shows DP2 expression in human nasal mucosa MC [30]. In mouse, DP2 transcripts have been identified in MC lines (P815, MC/9) [28] and bone-marrow derived primary cultured MC [31]. Boehme et al reported that DP2 in murine bone marrow-derived MC is involved in chemotaxis, down-regulation of CD62L, and up-regulation of CD23 and CD30 [31]. However, given differences between human and mouse in structure of the DP2 gene [32] and in expression of DP2 in Th2 and Th1 cells, the functions of DP2 in human and mouse MC might differ. Thus, we examined for the first time whether DP2 is expressed on human MC and if ligation of DP2 influences human MC activation.

Materials and Methods

Cell culture

HMC-1 (human mast cell line-1), an immature MC line derived from a patient with MC leukemia (a gift from Dr. J.H. Butterfield, Rochester, MN) [33], and LAD2 (laboratory of allergic diseases 2), developed from human bone marrow mononuclear cells (generously provided by Drs. D.D. Metcalfe and A. Kirshenbaum, National Institutes of Health, Bethesda, MD) [34] were cultured as previously described [35].

Human peripheral blood-derived primary cultured MC (hPBDMC) and cord blood-derived primary cultured MC (hCBDMC) were developed from CD34+ progenitors as previously described with minor modifications [35][38]. Briefly, approximately 100 mL of peripheral blood drawn from healthy donors into 10 mL heparinized Vacutainer tubes (BD Canada, Oakville, ON, Canada), or EDTA-treated umbilical cord blood from placentae obtained within 45 min of delivery were used. Ethics about the studies using human peripheral blood from healthy donor and cord blood from placentae after delivery were approved by the Human Ethics Research Committee, University of Alberta and Capital Health Region, and written informed consent for the use of donated peripheral blood or cord blood from placentae was obtained from each donor. The blood was diluted with the same volume of 10 mM phosphate buffer (pH 7.4) containing 150 mM NaCl [phosphate-buffered saline (PBS)] and then layered on Histopaque 1077 (Sigma-Aldrich Canada Ltd., Oakville, ON, Canada). The mononuclear cell fraction was obtained after centrifugation at 450×g for 30 min. After washing the mononuclear cells twice with PBS, CD34+ progenitors were isolated using the EasySep human CD34 positive selection kit (StemCell Technologies, Vancouver, BC, Canada). CD34+ cells from peripheral blood were cultured at 5×104 cells/mL in StemSpan SFEM (StemCell Technologies) supplemented with 100 ng/mL rhSCF (PeproTech Inc., Rocky Hill, NJ) and 100 ng/mL rhIL-6 (PeproTech Inc.) for 8 wk, with 30 ng/mL rhIL-3 (PeproTech Inc.) used for the first wk only for hPBDMC cultures. CD34+ cells from cord blood were cultured in AIM-V (Life Technologies) supplemented with 100 ng/mL rhSCF for 8 wk to develop hCBDMC. The StemSpan SFEM or AIM-V was hemidepleted twice a wk. At 4 wk, the entire volume of old media was replaced once by fresh media and then hemidepleted twice a wk until 8 wk. Primary MC cultures were used after 8 wk and confirmed as> 99% MC by tryptase/chymase staining before use [38], [39].

The DP2-transfected line K562/B19 and its control line K562/neo was generously provided by Dr. K. Nagata (BML, Inc., Saitama, Japan) and cultured as previously described [40].

Reverse transcription-polymerase chain reaction (RT-PCR)

Total RNA was extracted with RNAqueous-4PCR kit (Life Technologies) according to manufacturer's instructions and quantified by measuring optical density at 260 nm. Purity and integrity of extracted RNA were assessed by 260/280 nm ratio and applying to 1.2% formaldehyde-agarose gels, respectively. RT-PCR was carried out using SuperScript III First-Strand Synthesis System for RT-PCR (Life Technologies). Five µg of total RNA from each sample was used as template for reverse transcription reaction. The RNA/primer mixture (5 µg total RNA, 5 µM oligo(dT)20 primers and 1 mM dNTP mixture in 10 µL DEPC-treated water) was incubated for 5 min at 65°C, then placed on ice for at least 1 min. Ten µL cDNA synthesis mixture (200 U SuperScript III reverse transcriptase, 40 units RNaseOUT, 20 mM DTT, 10 mM MgCl2, in 2× RT buffer) was added and incubated for 50 min at 50°C, 5 min at 85°C and chilled on ice. Before proceeding to PCR, 2 U of RNase H were added and incubated for 20 min at 37°C. Two µL of the above cDNA was used for PCR with 1 U Red Taq DNA Polymerase (Sigma). PCR was carried out with Mastercycler Gradient (Eppendorf, Mississauga, ON, Canada). The specific primers were designed based on published sequence data: human DP2 (301 bp) forward 5′-CCT CTG TGC CCA GAG CCC CAC GAT GTC GGC-3′, reverse 5′-CAC GGC CAA GAA GTA GGT GAA GAA G-3′ [41]; DP1 (635 bp) forward 5'-CTT CTA CCG ACG GCA CAT CAC C-3', reverse 5'-TGC ACC GGC TCC TGT ACC TAA G-3' [42]; β-actin (326 bp) forward 5'-GGC ATC CTC ACC CTG AAG TA-3', reverse 5'-AGG GCA TAC CCC TCG TAG AT-3' [43]. We optimized the cycle number to be within the exponential phase of amplification. PCR with 2 µL of DNase/RNase free water (Sigma) instead of cDNA was run as a negative control and cDNA from human Th2 cells (CRTh2+/CD4+ T cells differentiated in vitro by culturing in Th2-polarizing conditions [44]) was used as a positive control for DP2. The PCR products were analyzed by 1% agarose gel electrophoresis with ethidium bromide staining and confirmed by sequencing (DNA Core Services Lab, University of Alberta).

Immunostaining of mast cells

To study potential surface expression of DP2, 2.5×105 cells in culture media were washed with PBS-FACS buffer (1× PBS containing 0.5% BSA, 0.1% NaN3 and 3% FBS) then resuspended with 100 µL PBS-FACS buffer. After blocking FcR with 1 µL human FcR blocking reagent (Miltenyi Biotec, Auburn, CA) and 50.1 µg normal mouse IgG (Life Technologies) for 30 min at room temperature (RT), cells were incubated with specific Ab and isotype matched control Ab directly conjugated with fluorophore at 4°C for 30 min: APC-conjugated mouse anti-human DP2 IgG2A (R&D Systems Inc., Minneapolis, MN) and APC-conjugated mouse IgG2A (R&D Systems Inc.); FITC-conjugated mouse anti-human FcεRIα IgG2b (eBioscience, San Diego, CA) and FITC-conjugated mouse IgG2b (eBioscience). Stained cells were washed with 1 mL PBS-FACS buffer, fixed with 200 µL PBS-FACS containing 2% paraformaldehyde and 0.54% sucrose, and fluorescence read using a FACSCalibur (BD Biosciences, Mississauga, ON, Canada), FACSCanto II (BD Biosciences) or an ImageStream Mark II (Amnis Co., EMD Millipore, Seattle, WA) [45]. For ImageStream Mark II analyses, nuclei were also stained with 30 µM 4',6-diamidino-2-phenylindole (DAPI, Life Technologies).

For total expression (surface and intracellular) of DP2, cells were fixed with 100 µL 4% paraformaldehyde for 10 min on ice, permeabilized using 0.4% saponin for 10 min on ice, and FcR were blocked with 1 µL human FcR blocking reagent (Miltenyi Biotec) and 50.1 µg normal mouse IgG for 30 min at RT before staining with Ab. Data were analyzed with WinMDI ver. 2.9 (developed by Joe Trotter), FlowJo ver. 10.0.5 (Tree Star, Inc., Ashland, OR) or IDEAS software (Amnis).

Immunohistochemical staining of human nasal polyp mast cells

Nasal polyps were obtained from endoscopic sinus surgery from patients with chronic rhinosinusitis at the University of Alberta Hospital, Canada, from archives of 2007 to 2009 (n = 15) [39]. All studies were approved by the Human Ethics Research Committee, University of Alberta. Written informed consent for the use of tissues was obtained from each patient by a surgical release form signed before surgery, explaining that any tissue removed from the patient may be used for diagnosis, research, or disposal. After excision, tissue samples were placed in 10% neutral buffered formalin and then 4 µm sections were generated from each tissue block after dehydration and paraffin embedding. After heat-induced epitope retrieval (20 min at 90–95°C) using Target Retrieval Solution (Citrate pH 6.0, Dako, Burlington, ON, Canada), deparaffinized sections were incubated with 4% hydrogen peroxide in methanol for 20 min to reduce endogenous peroxidase activity. Sections were incubated in blocking solution (5% normal goat serum in PBS) for 30 min before incubation in primary Ab [rabbit anti-human DP2 IgG (Abcam Inc., Toronto, ON, Canada) and alkaline phosphatase–conjugated mouse anti-human MC tryptase (G3) IgG1 (EMD Millipore, Billerica, MA)] or isotype matched control Ab [normal rabbit IgG (AbD Serotec, Raleigh, NC) and alkaline phosphatase–conjugated mouse IgG (Abcam Inc.)] overnight at 4°C. Sections were washed 3 times with PBS, incubated for 30 min at RT with biotin-conjugated goat anti-rabbit IgG (Vector Laboratories Inc., Burlingame, CA), washed 3 times with PBS, and incubated for 1 h at RT with horseradish peroxidase (HRP)-conjugated streptavidin (Vector Laboratories Inc.) for DP2 staining. The sections were developed using the NovaRED peroxidase substrate kit (Vector Laboratories Inc.) and alkaline phosphatase substrate kit III (Vector Laboratories Inc.), respectively. Coverslips were placed on the slides with mounting medium (Cytoseal-XYL, Richard-Allan Scientific, Kalamazoo, MI). For morphometric analyses of the abundance of DP2 positive cells and of MC, three high-powered fields (HPF) distant from the edge of the section on each slide were randomly selected, and either single or double positive cells were counted using a microscope (magnification 10×40, HPF = 0.196 mm2). Total cell numbers (excluding epithelial cells) in a field were determined by counting nuclei. Photography was taken using DXM1200C digital camera (Nikon Canada Inc., Mississauga, ON, Canada) attached to Eclipse E600W microscope (Nikon Canada Inc.).

Intracellular calcium (Ca2+) flux

Intracellular Ca2+ flux was measured using Fluo-4 NW Calcium Assay kit (Life Technologies) according to manufacturer's instructions. After measuring baseline fluorescence of Fluo-4 AM loaded MC (1.25×105 cells in 50 µL/well) for 100 sec, 100 nM to 10 µM of DP2 agonist [PGD2 (Cayman Chemical, Ann Arbor, MI), 15R-15-methyl PGD2 (Cayman Chemical), or 13,14-dihydro-15-keto PGD2 (Cayman Chemical)] was added and intracellular Ca2+ response was measured using fluorescence plate reader (FLx800, Bio-Tek Instruments Inc., Winooski, VT) with excitation and emission wavelengths of 485 nm and 516 nm, respectively. To antagonize DP2, DP2 selective antagonists [1 µM CAY10471 (Cayman Chemical) or 100 nM CAY10595 (Cayman Chemical)] or DP2/TP dual antagonist [1 µM ramatroban (Cayman Chemical)] was added 5 min before agonist treatment. Cells were pretreated with 10 nM PTX for 2 h to inhibit Gαi before loading Fluo-4 AM. Cytosolic free Ca2+ was presented by one of the following calculations: Fluorescence ratio (fluorescence unit at each time point/baseline fluorescence unit), Δfluorescence ratio (fluorescence ratio of agonist treated MC – fluorescence ratio of sham treated MC), integral (area under the curve during indicated time period) or Δintegral (integral of agonist treated MC – integral of sham treated MC).

Assay of β-hexosaminidase release

β-hexosaminidase (β-hex) secretion, a marker of MC degranulation was quantitated by fluorometric analysis of the hydrolysis of 4-methylumbelliferyl-N-acetyl-β-D-glucosaminide (Sigma Chemical Co.) as previously described [46]. The percentage of β-hex released into the supernatant was calculated by the following formula: [S/(S+P)]×100, where S and P are the β-hex contents of supernatant and cell pellet.

Statistical Analysis

All experiments were performed at least three times. Data were analyzed using GraphPad Prism (version 5) and presented as mean ± SEM. p<0.05 was considered significant. Details of the statistical analyses used are indicated in figure legends.

Results

Expression of PGD2 receptors in human MC

Despite increasing evidence for DP2, also known as CRTh2, expression and function in various cell types (eg., human Th2 cells, eosinophils, basophils, dendritic cells) [27], [40], [41], little is known about expression and function of DP2 in MC [5]. We first examined expression of DP2 in MC in situ in human nasal polyp tissue. We previously reported that tryptase-positive MC were the dominant (> 99%) MC phenotype in human nasal polyp tissue (Fig 1A, black triangle in insert) [39]. As shown in Fig. 1A, DP2 positive cells in the nasal polyps included tryptase positive MC (double positive; white arrow in insert) and non MC (DP2 single positive; white triangle in insert). Using semiquantitative morphometric analyses of total nucleated cells below the epithelium, 1.5±0.2% were DP2 positive MC (double positive), and 9.2±0.8% were DP2 positive non-MC (DP2 single positive) (Fig 1B). In the nasal polyps, 33.9±4.8% of tryptase+ MC expressed DP2 (Fig 1C).

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Figure 1. Immunohistochemical staining of DP2 in human nasal polyp mast cells.

(A) Tissue sections from nasal polyps (n = 15) were double stained with rabbit anti-human DP2 and mouse anti-human MC tryptase antibodies or isotype matched control antibodies. DP2 staining is shown in dark red and MC tryptase is shown in blue. Insert shows the cellular staining with examples of single- (white triangle for DP2 single+, black triangle for tryptase single+) and double-positive cells (open arrow). (B) Percentage of DP2+ MC and non MC from total nucleated non epithelial cells (C) Percentage of DP2 positive MC among tryptase+ MC. The percentage of DP2 positive MC among MC was calculated by [number of double positive cells/(number of double positive cells + number of tryptase single positive cells)]×100.

https://doi.org/10.1371/journal.pone.0108595.g001

We next examined expression of DP1 and DP2 in various human MC cultures. Two human MC lines, HMC-1 and LAD2, and two in vitro differentiated primary human MC, peripheral blood-derived MC (hPBDMC) and cord blood-derived MC (hCBDMC) expressed DP2 mRNA (Fig 2). The level of DP2 mRNA was higher in primary human MC than human MC lines. DP1 mRNA was also detected in human Th2 cells and in primary cultured human MC but not in human MC lines. In flow cytometry analysis, DP2 protein was detected by immunostaining after permeabilization in 97.9±0.8% and 87.0±2.4% of hPBDMC and LAD2, respectively (Fig 3A, B). However, surface expression of DP2 was observed only in 4.5±0.6% of hPBDMC and 11.4±2.4% of LAD2 (Fig 3C, D), and similar results were obtained using an independently generated rat anti-human DP2 antibody (IgG2a, clone BM16, Miltenyi Biotec) (Fig S1). Although DP2 expression on MC surface was low, it was comparable to FcεRI (3.3±1.2%, Fig 3E) on hPBDMC, a level that is functional in IgE-mediated mediator secretion (Fig 7B).

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Figure 2. mRNA expression of PGD2 receptors in human mast cells.

Expression of DP2 and DP1 mRNA in human MC lines (HMC-1 and LAD2) and primary cultured MC [peripheral blood-derived MC (hPBDMC) and cord blood-derived MC (hCBDMC)]. Three different cultures were shown for hPBDMC and hCBDMC. Human DP2+/CD4+ T cells cultured in Th2-polarizing conditions were used for a positive control of DP2 and dH2O instead of cDNA was used as a negative control.

https://doi.org/10.1371/journal.pone.0108595.g002

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Figure 3. Flow cytometry analysis of DP2 and FcεRI expression on human mast cells.

Expression of DP2 and FcεRI on hPBDMC and LAD2 were examined by flow cytometry. A representative result of dot plot (left) and MFI (Mean Fluorescent Intensity, right) from five to eight independent experiments calculated using WinMDI ver.2.9 software (mean±SEM) are shown. (A) Total expression of DP2 in hPBDMC (n = 8). (B) Total expression of DP2 in LAD2 (n = 5). (C) Surface expression of DP2 in hPBDMC (n = 8). (D) Surface expression of DP2 on LAD2 (n = 5). (E) Surface expression of FcεRI on hPBDMC (n = 15–21). (F) Surface expression of FcεRI (n = 5) on LAD2. (G) Surface expression of DP2 on DP2 transfectant, K562/B19 (n = 3) was examined as a control. In dot plot, the percentage of positive cells was shown inside, and gray, black and red dots represent unstained, stained with isotype control and specific antibody, respectively. p<0.05, ††p<0.01, †††p<0.001 compared with unstained; **p<0.01, ***p<0.001 compared with isotype control by repeated measures ANOVA followed by the Tukey post-test.

https://doi.org/10.1371/journal.pone.0108595.g003

These results show that DP2 is expressed by human MC, and provided a rationale to examine the function of DP2 in human MC.

DP2 agonist-induced cytosolic Ca2+ flux in human MC; sensitive to pertussis toxin but not to DP2 antagonists

To determine whether DP2 in MC is functional, cytosolic Ca2+ flux known to be downstream of DP2 signaling was assessed after treatment with DP2 agonists. Selective DP2 agonists, both physiologic and synthetic, DK-PGD2 (Fig 4A, C) and 15R-15-methyl PGD2 (Fig 4B, D) [47] respectively, induced a dose-dependent (100 nM to 10 µM) cytosolic Ca2+ flux in LAD2 cells. As DP2 receptors are coupled to Gαi proteins for their signaling [20], we tested if the Ca2+ flux in MC induced by DP2 agonists was Gαi mediated. LAD2 cells were pretreated with 10 nM pertussis toxin (PTX), which prevents Gi complex from interacting with receptors by ribosylation of Gαi [48], [49]. As shown in Fig. 5, DP2 agonist-induced cytosolic Ca2+ flux was significantly diminished by PTX pretreatment. When cytosolic free Ca2+ was calculated by integral for 3 min, 10 nM PTX pretreatment inhibited 48.9±3.1% (p<0.05), 58.9±7.9% (p<0.05), and 55.1±5.2% (p<0.01) of 1 µM PGD2-, DK-PGD2-, and 15R-15methyl PGD2-induced cytosolic Ca2+ flux, respectively (Fig 5D). PTX treatment did not affect either cell viability, as reported previously [50], [51], or Gi-independent Ca2+ flux induced by thapsigargin (Fig S2).

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Figure 4. DP2 agonist-induced Ca2+ flux in human mast cells.

After measuring baseline fluorescence of Fluo-4 AM loaded MC (1.25×105 cells in 50 µL/well), (A, C) DK-PGD2 or (B, D) 15R-15-methyl PGD2 was given to the MC and intracellular Ca2+ flux was assessed by measuring fluorescence change. (A, B) Cytosolic free Ca2+ changes induced by DP2 agonists are presented as ΔFluorescence ratio (fluorescence ratio of agonist treatment – fluorescence ratio of sham treatment), where fluorescence ratio is fluorescence unit at each time point/baseline fluorescence unit. Arrow indicates the time when agonist was given. (C, D) Cytosolic free Ca2+ changes induced by DP2 agonist treatment are presented as ΔIntegral for 3 min from ΔFluorescent ratio curves shown in A and B. Results are expressed as mean ± SEM for three separate experiments. *p<0.05, **p<0.01 compared with 100 nM agonist treatment by repeated measures ANOVA followed by the Bonferroni post-test.

https://doi.org/10.1371/journal.pone.0108595.g004

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Figure 5. Pertussis toxin abolished DP2 agonist-induced Ca2+ flux in human mast cells.

LAD2 were pretreated with 10 nM pertussis toxin (PTX) for 2 h then Fluo-4 AM was loaded. After measuring baseline fluorescence of Fluo-4 AM loaded MC (1.25×105 cells in 50 µL/well), (A) 1 µM PGD2, (B) 1 µM DK-PGD2 or (C) 1 µM 15R-15-methyl PGD2 was added and intracellular Ca2+ flux was assessed by measuring fluorescence change. (A–C) Cytosolic free Ca2+ changes by DP2 agonists were presented as Fluorescence ratio (fluorescence unit at each time point/baseline fluorescence unit). Arrow indicates the time when agonist was given. (D) Cytosolic free Ca2+ changes in A–C are presented as integral for 3 min. Results are expressed as mean ± SEM for three separate experiments. p<0.05; ††p<0.01; †††p<0.001 compared with each sham treatment (sham vs agonist, PTX vs PTX/agonist), *p<0.05; **p<0.01 compared with each agonist treatment (agonist vs PTX/agonist) by repeated measures ANOVA followed by the Tukey post-test.

https://doi.org/10.1371/journal.pone.0108595.g005

We next examined if this agonist-induced Ca2+ flux could be inhibited by DP2 selective antagonists. When MC were pretreated with either DP2 antagonists (1 µM CAY10471 or 100 nM CAY10595) or DP2/TP dual antagonist (1 µM ramatroban) for 5 min, there was no significant effect on DP2 agonist-induced Ca2+ flux in human MC (Fig 6).

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Figure 6. DP2 antagonists did not abolish DP2 agonist-induced intracellular Ca2+ flux.

After measuring baseline fluorescence of Fluo-4 AM loaded LAD2, a DP2 selective antagonist (1 µM CAY10471 or 100 nM CAY10595) or DP2/TP dual antagonist (1 µM ramatroban) was added. After 5 min, 1 µM 15R-15-methyl PGD2 was added and intracellular Ca2+ flux was assessed by measuring fluorescence change. Relative Ca2+ flux was calculated from ΔIntegral for 3 min after addition of 15R-15-methyl PGD2, where sham treatment instead of antagonist considered as 100%. Results are expressed as mean ± SEM for three (ramatroban and CAY10471) and five (CAY10595) separate experiments. There was no statistical difference between sham and antagonist treatment. Note: Higher concentrations of each antagonist could not be used as they caused Ca2+ flux by themselves.

https://doi.org/10.1371/journal.pone.0108595.g006

These results suggest that intracellular Ca2+ flux by DP2 agonists occurs through a PTX-sensitive signaling pathway, but it cannot be unequivocally established that it is DP2-dependent.

Effect of DP2 agonist, 15R-15 methyl PGD2 on mediator release of human MC

Because DP2 activation induces degranulation of basophils [23] and eosinophils [21], we examined if a DP2 agonist could affect human MC degranulation. The DP2 selective agonist, 15R-15methyl PGD2 alone or in combination with IgE-crosslinking did not significantly alter degranulation (β-hex release) of LAD2 (Fig 7A) and hPBDMC (Fig 7B). Moreover, the DP2 selective agonist did not affect PGD2 and LTC4 release after IgE-crosslinking (Fig S3). Since PGD2 has been shown to induce Th2 cytokines from Th2 cells, we also examined IL-5 and IL-13 levels, but they were undetectable in both LAD2 and hPBDMC by DP2 agonist or IgE-crosslinking in the presence or absence of DP2 agonist (Table S1).

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Figure 7. No effects of DP2 agonist on human mast cell degranulation induced by IgE-crosslinking.

LAD2 or hPBDMC were sensitized with 100 ng/mL biotinylated human IgE overnight. Cells were washed and resuspended (2×105 cells/200 µL) in HEPES-Tyrode's buffer (HTB), and stimulated with 100 ng/mL streptavidin in the presence or absence of indicated dose of 15R-15-methyl PGD2 for 30 min. The cells were centrifuged, and the percent release of β-HEX into the supernatant was calculated. β-HEX release (%) are expressed as mean ± SEM for 8–9 separate experiments of LAD2 (A), and 8–10 separate experiments of hPBDMC (B) with five different hPBDMC cultures. **p<0.01, ***p<0.001 compared with sham (0 nM 15R-15-methyl PGD2 without IgE cross-linking), and no statistical significant difference was found between 15R-15-methyl PGD2 treatment group by one-way ANOVA followed by the Tukey post-test.

https://doi.org/10.1371/journal.pone.0108595.g007

Intracellular expression of DP2 in human MC

Since DP2 selective antagonists failed to inhibit DP2 agonist induced Ca2+ flux (Fig 6) and DP2 selective agonists did not affect MC degranulation (Fig 7) or release of other mediators that we tested (Fig S3, Table S1), it is unclear whether the effect, although significantly inhibited by PTX (Fig 5), is actually due to DP2 activation. Moreover, although we confirmed that our methodology detects surface expression on the DP2 transfectant (Fig 3G), few MC (Fig 3C, D) showed surface expression of DP2, despite a high proportion of the MC expressing intracellular DP2. Thus, we examined MC expression of DP2 in further detail via imaging flow cytometry, a technique which merges fluorescence microscopy with flow cytometry allowing for robust quantitation of population-level morphological features based on single cell images [45]. In concordance with the conventional flow cytometry result shown in Fig 3, we detected extracellular staining for DP2 on 15.8±5.6% of LAD2 and 2.6±1.0% of PBDMC, and intracellular staining in 94.7±1.0% and 78.9±13.3% of permeabilized LAD2 and PBDMC, respectively. Surprisingly, however, by analyzing DP2+ cell images, we established that positive signals detected after surface staining were from inside MC (Fig 8A, C, open triangles), rather than on the surface. The ImageStream data also revealed that punctate staining for DP2 was observed in both LAD2 and PBDMC (Fig 8B, D, arrows) compared to DP2 transfected cells where DP2 was observed primarily on the cell surface (Fig 8E, F, closed triangle). Collectively, these data indicate that the majority of DP2 staining in human MC is found inside the cell.

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Figure 8. Single cell analysis of DP2 expression on human mast cells with ImageStream.

Expression of DP2 on LAD2 and hPBDMC were examined with ImageStream after staining live cells for surface expression (A, C) or with fixed and permeabilized cells for total expression (B, D). (A, C) After surface staining, DP2 signals were detected from inside MC (open triangle) rather than on the surface. (B, D) Intracellular punctate staining for DP2 (arrow) was observed in fixed and permeabilized MC before staining. (E, F) K562/B19 (DP2 transfectant) was used as a control for surface expression of DP2 (closed triangle). Representative images of cells stained with isotype matched control Ab (left) and DP2 positive cells (right) from three independent experiments are shown.

https://doi.org/10.1371/journal.pone.0108595.g008

Effect of constitutive PGD2 on DP2 surface expression

Because we detected low surface expression of DP2 on human MC (Fig 3C, D and 8) and it has been shown that DP2 is internalized when it binds its ligand [52], [53], we hypothesized that constitutive PGD2 produced by SCF-induced MC activation in cultures [54] might provide an explanation for the low DP2 surface expression in MC. To determine whether expression of DP2 on the surface of MC might be enhanced by blocking constitutive PGD2 production, we incubated LAD2 with 10 µg/mL aspirin and then examined expression of DP2 by flow cytometry. However, as shown in Fig. 9, blocking constitutive PGD2 production did not affect surface expression of DP2. This result suggests that expression of DP2 inside of MC, rather than on the surface, is not a result of ongoing internalization due to constitutive PGD2 production in our cultures.

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Figure 9. Effect of intrinsic PGD2 on DP2 expression in human mast cells.

LAD2 were incubated for indicated time periods in the presence or absence of 10 µg/mL aspirin and then any change of surface and total DP2 expression was examined by flow cytometry. ΔRelative MFI [Relative mean fluorescent intensity (MFI) from stained cells with DP2 Ab - Relative MFI from stained cells with isotype Ab], where relative MFI is [(MFI from stained cells with Ab - MFI from unstained cells)/MFI from unstained cells], from five independent experiments was calculated using WinMDI ver.2.9 software (mean ± SEM). No statistical significance difference was found between sham and aspirin treatment groups by Two-way ANOVA followed by the Bonferroni post-test.

https://doi.org/10.1371/journal.pone.0108595.g009

In an effort to stimulate surface expression of DP2 on MC, we also tried several other approaches, including treatment with IFNγ and/or TNF, both which increase surface DP2 expression in eosinophils [55], treatment with IL-4, which induce DP2 expression in T cells [56] and SCF depletion from culture media to prohibit SCF-mediated MC activation [54]. However, all were unsuccessful (Fig S4). Collectively, this suggests that surface expression of DP2 in human MC is regulated differently than in other cell types (eg., eosinophils and Th2 cells).

Discussion

PGD2 is the predominant prostanoid produced by activated MC and plays important roles in regulation of allergic inflammation, host defense, and innate and adaptive immune responses. However, there is a lack of understanding regarding expression of DP2 and its functional significance in human MC. In this study, we showed for the first time that human MC express DP2 (Figs 13, 8 and 9). Interestingly, DP2 expression was almost exclusively intracellular in human cultured MC (Figs 3, 8 and 9). We were unable to induce surface expression using several approaches including culture MC in surface DP2 increasing condition in eosinophils [55] or blocking constitutive PGD2 production (Fig 9). This suggests that surface expression of DP2 in human MC is regulated differently than in other cell types (eg., eosinophils).

Dose dependent cytosolic Ca2+ flux was detected in human MC after treatment with DP2 selective agonists (DK-PGD2 and 15R-15-methyl PGD2) in a range of 100 nM – 10 µM (Fig 4) and this was significantly depressed by PTX (Fig 5). However, human MC required significantly higher doses (1–10 µM) of DP2 agonists to induce Ca2+ flux than eosinophils [57][59] or Th2 cells (100 nM) [20], [60]. Moreover, DP2 selective antagonists did not inhibit DP2 agonist-induced Ca2+ flux in human MC, although we used higher dose than their IC50 shown previously in different experimental system [61][63]. However, we could not test higher doses of antagonists than shown in Fig 6, because these doses caused Ca2+ flux by themselves. Given these results, it is not clear whether the intracellular Ca2+ flux is DP2 dependent or not. The predominant intracellular expression of DP2 rather than on the cell surface of human MC may explain the need for a high dose of agonist to induce the Ca2+ signal through intracellular DP2. PGD2 and DK-PGD2 have poor permeability of the cell membrane, although there is no information about PGD2 uptake in human MC and there is no direct evidence that human MC express the prostaglandin transporter on the cell surface [64][67]. The synthetic DP2 agonist (15R-15-methyl PGD2) and DP2 antagonists have not been characterized in terms of their cell permeability. Further study of the permeability of DP2 agonists and antagonists will help to clarify DP2 dependency of intracellular Ca2+ flux shown in this study.

Although DP2 signaling can induce Th2 cytokine production [19], degranulation [21], [23] and leukotriene production [29], [68] in other immune cells, we could not detect any of these responses in human MC stimulated with DP2 agonists. The lack of effect of DP2 agonists on MC mediator release suggest that the role of intracellular DP2 in MC is different than its role on the surface of other immune cells such as Th2 cells [19], eosinophils [21], [29], [68], and basophils [23]. Our results about the high dose of DP2 agonist required for Ca2+ mobilization and the lack of effect of DP2 agonists on MC degranulation and cytokine release are consistent with those shown in mouse MC [31].

With advances in analytical methods that enable imaging at subcellular resolution, there is increasing evidence of intracellular expression of GPCRs, and this reveals distinct functions and signal transduction mechanisms inside cells as compared with the plasma membrane location [69], [70]. For example, β2-adrenoreceptor, a prototypical GPCR, signaling occurs intracellularly in the endosome, as well as in the plasma membrane [69], and more recently, Binda et al [70] showed that the intracellular expression of DP1 is associated with intracrine/autocrine signaling of DP1 mediated by ERK1/2 in the perinuclear region. Although further study is needed to define the intracellular location of DP2 in human MC, we observed punctate staining of DP2 in human MC (Fig 8), typical of endosomal or granular expression. Therefore, intracellular DP2 in human MC may play an unknown role in MC function, distinct from the functions of cell surface DP2. Given the recent finding of a role for lipocalin-type prostaglandin D synthase (L-PGDS) and heat shock proteins in trafficking of DP1 to the cell membrane [70], cell surface trafficking of DP2 may also be regulated by other proteins. Although L-PGDS did not mediate trafficking of other GPCRs, including DP2 [70], they did not test hematopoietic PGDS (H-PGDS), the relevant PGDS in MC. The study of trafficking mechanisms of DP2 will help determine the role of different cellular locations of this receptor in different cell types.

In this study we showed intracellular expression of DP2 in human MC. Although DP2 agonists induced Ca2+ flux and this was abolished with PTX, DP2 antagonists failed to inhibit Ca2+ flux induced by agonist. Therefore DP2 dependency or not of agonist-induced Ca2+ flux needs further clarification. DP2 agonists neither induced nor augmented β-HEX release, or eicosanoids (PGD2 and LTC4) and cytokine (IL-5 and IL-13) production in the presence or absence of FcεRI crosslinking. This may be related with its location inside the cell rather than on the surface, and permeability of DP2 agonists and antagonists. Despite all our efforts, we were unable to induce surface expression or translocation of DP2 from inside to the surface. Further study is needed to understand trafficking and functional significance of DP2 in human MC. Understanding its functional significance in human MC and their responses may help inform development and application of DP2 antagonists for therapeutic intervention.

Supporting Information

Figure S1.

Flow cytometry analysis of DP2 expression on human mast cells. Expression of DP2 on hPBDMC and LAD2 were examined by flow cytometry using rat anti-human DP2 antibody (IgG2a, clone BM16). Percentage of positive cells (left) and MFI (Mean Fluorescent Intensity, right) from three to four independent experiments calculated using WinMDI ver.2.9 software (mean±SEM) are shown. (A) Surface expression of DP2 in hPBDMC (n = 3). (B) Surface expression of DP2 on LAD2 (n = 4). (C) Total expression of DP2 on LAD2 (n = 1, triplicate). *p <0.05, **p <0.01 compared with isotype control by one-tailed paired t-test.

https://doi.org/10.1371/journal.pone.0108595.s001

(TIF)

Figure S2.

PTX pretreatment did not affect thapsigargin induced Ca2+ flux and viability of human mast cells. A–C. LAD2 were pretreated with 10 nM pertussis toxin (PTX) for 2 h then Fluo-4 AM was loaded. After measuring baseline fluorescence of Fluo-4 AM loaded MC (1.25×105 cells in 50 µL/well), 10 µM 15R-15-methyl PGD2 (A) or 1 µM thapsigargin (Sigma) (B) was added and intracellular Ca2+ flux was assessed by measuring fluorescence change. Cytosolic free Ca2+ changes by stimulation were presented as Fluorescence ratio (fluorescence unit at each time point/baseline fluorescence unit). Arrow indicates the time when stimulus was given. Cytosolic free Ca2+ changes in A and B are presented as integral for 3 min (C). Results are expressed as mean ± SEM for three separate experiments with duplication. ††p<0.01; †††p<0.001 compared with each sham treatment (sham vs stimulus, PTX vs PTX/stimulus), **p<0.01 compared with each stimulus treatment; NS, not significant (stimulus vs PTX/stimulus) by one-way ANOVA followed by the Tukey post-test. D. Cell viability after PTX treatment was measured with WST-1 according to manufacturer's instruction (Roche Applied science, 68298 Mannheim, Germany). LAD2 (5×104 cells in 100 µL/well) were treated with 10 nM PTX for 2 h and then 10 µL of WST-1 was added to the well. After 2 h incubation, absorbance at 440 nm and 690 nm were measured and results are expressed as mean ± SEM of background subtracted A440–A690 values from triplicated experiment. NS, not significant by one-tailed t-test.

https://doi.org/10.1371/journal.pone.0108595.s002

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Figure S3.

DP2 agonist did not affect FcεRI-mediated PGD2 and LTC4 production of human mast cell. hPBDMC or LAD2 were sensitized with 100 ng/mL biotinylated human IgE overnight. Cells were washed and stimulated with 100 ng/mL streptavidin in the presence or absence of indicated dose of 15R-15-methyl PGD2 or PGD2 for 30 min. The cells were centrifuged, and the release of PGD2 or LTC4 into the supernatant was measured by ELISA (Cayman Chemical). A. Effect of 15R-15-methyl PGD2 on FcεRI-mediated PGD2 release from hPBDMC (n = 1). Note that 15R-15-methyl PGD2 did not cross-react with PGD2 ELISA. PGD2 detected in the presence of 1000 ng/mL 15R-15-methyl PGD2 was 0.8 ng/ml. B. Effect of 15R-15-methyl PGD2 on FcεRI-mediated LTC4 release from hPBDMC. **p<0.01 compared with unstimulated control, but not significant (NS) in the presence or absence of 15R-15-methyl PGD2 by repeated measures ANOVA followed by the Tukey post-test (n = 4). C. Effect of 15R-15-methyl PGD2 on FcεRI-mediated LTC4 release from LAD2 (n = 1). D. Effect of PGD2 on FcεRI-mediated LTC4 release from hPBDMC (n = 2).

https://doi.org/10.1371/journal.pone.0108595.s003

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Figure S4.

IL-4, SCF starvation, and IFNγ and/or TNF did not affect surface expression level of DP2 on human mast cells. hPBDMC (A, n = 2) and LAD2 (B, n = 3–4) were cultured in the presence or absence of 100 ng/ml rhIL-4 for 7 days then expression of DP2 on their surface were examined by flow cytometry. FcεRI expression was examined as internal control for IL-4 effect. C. Expression of DP2 on the surface of LAD2 was examined after 1 day starvation of SCF. CD117 expression was examined as internal control for SCF starvation (n = 1). D. DP2 expression was examined after 1 day of LAD2 culture in the presence or absence of IFNγ and/or TNF (n = 2). Relative MFI was calculated by MFI of stained cells with antibody/MFI of stained cells with isotype control.

https://doi.org/10.1371/journal.pone.0108595.s004

(TIF)

Table S1.

DP2 agonist did not induce IL-5 and IL-13 production from human mast cells in the presence or absence of FcεRI-crosslinking.

https://doi.org/10.1371/journal.pone.0108595.s005

(DOCX)

Acknowledgments

The authors thank Dr. Erin Wright at the University of Alberta for their help and advice with tissue sample collection and preparation for immunohistochemistry. We thank Dr. Kinya Nagata at the BML, Inc., Japan for DP2-transfected line (K562/B19) and its control line (K562/neo).

Author Contributions

Conceived and designed the experiments: TCM DRB ADB LC. Performed the experiments: TCM EC TY GB AMR. Analyzed the data: TCM TY GB AMR LP. Wrote the paper: TCM. Interpretation of data: TCM TY AMR LP DRB ADB LC. Revised the manuscript critically for important intellectual content: EC TY GB AMR LP DRB ADB LC.

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