Mast cells are immune effector cells that are involved in allergies and inflammation through the release of mediators such as histamine, PGs, and cytokines. Uncoupling protein 2 (UCP2) is a mitochondrial protein that inhibits insulin secretion from β cells, possibly through down-regulation of reactive oxygen species production. We hypothesized that UCP2 could also regulate mast cell activation. In this study, we show that mouse bone marrow mast cells (BMMCs) and human leukemic LAD2 mast cells express UCP2. BMMCs from Ucp2/ mice exhibited greater histamine release, whereas overexpression of UCP2 in LAD2 cells reduced histamine release after both allergic and nonallergic triggers. Ucp2/ BMMCs also had elevated histamine content and histidine decarboxylase expression. Histamine content was reduced by overexpression of UCP2 or treatment with the mitochondrial-targeted superoxide dismutase-mimetic (TBAP) tetrakis(4-benzoic acid) porphyrin manganese(III). Furthermore, Ucp2/ BMMCs also had greater production of both IL-6 and PGD2 as well as ERK phosphorylation, which is known to regulate PG synthesis. Intradermal administration of substance P, an activator of skin mast cells, and challenge with DNP-human serum albumin after passive sensitization induced significantly greater vascular permeability in the skin of Ucp2/ mice in vivo. Our results suggest that UCP2 can regulate mast cell activation.

Mast cells are critical mediators of allergic diseases, as well as innate and acquired immunity (1). Mast cells are found in areas exposed to the external environment and are activated by diverse stimuli, including IgE receptor (FcεRI) cross-linking and neuropeptides such as substance P (SP)4 that act on G protein-coupled receptors. Mast cell granules store a number of preformed mediators, including histamine and proteases that are released by degranulation; activated mast cells also de novo synthesize numerous proinflammatory eicosanoids and cytokines, many of which can be released selectively (2). These mediators cause immediate hypersensitivity reactions, characterized by vasodilation and increased vascular permeability, as well as late phase allergic inflammation (3). Despite the increasing importance of mast cells in regulating immune processes (4), little is still known about how mast cell activation is regulated.

Uncoupling proteins (UCPs) reside on the inner mitochondrial membrane where they alter the mitochondrial membrane potential and reactive oxygen species (ROS) production (5). UCP2 in particular has been implicated in control of mitochondrial ROS production. Both mitochondrial and cytosolic ROS are produced by mast cell activation (6). Inhibition of ROS production reduces degranulation, indicating that ROS may play a role in regulating exocytosis (7, 8). UCP2 activity inhibits exocytosis of insulin granules from pancreatic β cells (9) and dopamine-containing vesicles from rat PC12 cells (10). UCP2 also dampens the inflammatory response of macrophages (11, 12, 13). We, therefore, hypothesized that UCP2 could inhibit mast cell activation and decrease mast cell-mediated inflammatory responses.

In this article, we show that UCP2 is expressed in both murine and human mast cells. Ucp2−/− bone marrow-derived mast cells (BMMCs) have greater release of proinflammatory molecules after both allergic and nonallergic triggers, in addition to having increased histamine content. Ucp2−/− mice also develop significantly greater skin vascular permeability in response to SP and Ag after passive sensitization. Our results indicate that UCP2 is a novel regulator of mast cell function with implications for treatment of mast cell-mediated allergic and inflammatory diseases.

Ucp2−/− and Ucp2+/+ littermates were generated as previously described (11). Bone marrow cells were isolated from the femurs and tibias of age (8–12 wk)- and sex-matched mice. These cells were cultured in RPMI 1640 supplemented with 10% heat-inactivated FBS, 2 mM l-glutamine, 100 U/ml penicillin, 100 μg/ml streptomycin, nonessential amino acids, sodium pyruvate, 10 ng/ml murine stem cell factor (SCF), and 10 ng/ml murine IL-3 (both from PeproTech). Cells were used from 4 to 8 wk of culture. Purity was tested by staining granules with toluidine blue (1%, pH 2). Fetal skin mast cells (FSMCs) were isolated and cultured as previously described (10). Cell suspensions were prepared from excised trunk skin of day 16 fetal mice by limited trypsinization. Cells were cultured for 3 wk in medium described above and purified by Percoll density gradient centrifugation before use in experiments. LAD2 cells (supplied by Dr. A. S. Kirshenbaum, National Institutes of Health, Bethesda, MD) derived from a human mast cell leukemia (14) were cultured in StemPro-34 medium (Invitrogen) supplemented with 100 U/ml penicillin/streptomycin and 100 ng/ml recombinant human SCF, supplied by Amgen.

Age- and sex-matched mice were sacrificed and an 8-mm diameter piece of dorsal skin was immediately removed and weighed. The skin was homogenized in 10 μl/mg of 2% perchloric acid and boiled for 10 min. After centrifugation at 10,000 × g for 10 min, the supernatant was removed and neutralized with an equal volume of 2 M NaOH. Histamine levels were determined by commercial ELISA (Beckman Coulter) according to the manufacturer’s instructions.

Cells were washed once with PBS and then lysed in lysis buffer containing 20 mM Tris-HCl (pH 7.4), 1 mM EDTA, 150 mM NaCl, 1% Nonidet P-40, 1 mM PMSF, 10 μg/ml aprotinin, 10 μg/ml leupeptin, 1 mM Na3VO4, and 50 mM NaF. Equal amounts of protein were electrophoresed on 10% SDS-polyacrylamide gels (Invitrogen) and then transferred to a 0.44-μm polyvinylidene difluoride membrane (Invitrogen). After blocking with 5% milk, membranes were probed overnight at 4°C with either goat anti-UCP2 (1/400; Santa Cruz Biotechnology) or rabbit anti-histidine decarboxylase (HDC, 1/300; Abcam). For detection, the membranes were incubated with the appropriate secondary Ab conjugated to HRP (1/5000; Santa Cruz Biotechnology) and the blots were visualized with ECL. Blots were then stripped and reprobed with Abs against β-actin or porin.

BMMCs were sensitized with murine anti-DNP IgE (Sigma-Aldrich) for the indicated period of time. The cells were resuspended in PBS and blocked with 5 μg/ml FcγII/III-blocking Ab (eBioscience) for 30 min at room temperature. After two washes, cells were incubated for 30 min at room temperature with either 5 μg/ml FITC-conjugated anti-mouse IgE Ab, 1.25 μg/ml PE-conjugated anti-mouse c-kit Ab, or the appropriate isotype control Abs (all from eBioscience). Cells were then washed twice and analyzed with a FACSCalibur flow cytometer using CellQuest software (BD Biosciences).

RNA was isolated using a RNeasy minikit (Qiagen). RNA (500 ng) was reverse transcribed using an iScript cDNA synthesis kit (Ambion). PCR were performed using GoTaq Green Master Mix (Promega) with the following cycling conditions: 95°C for 10 min and 35 cycles of 95°C for 10 s and 57°C for 60 s. Products were run on a 2% agarose gel. The following primers were used: UCP2 forward, 5′-TGTCTCGTCTTGCCGATTGAAGGT-3′ and UCP2 reverse, 5′- TCTCGTGCAATGGTCTTGTAGGCT-3′; β-actin forward, 5′-TGAGCGCAAGTACTCTGTGTGGAT-3′ and β-actin reverse, 5′-TGTTTGCTCCAACCAACTGCTGTC-3′.

Quantitative PCR was performed in triplicate with an Applied Biosystems 7300 Real-Time PCR System using TaqMan gene expression master mix (Applied Biosystems) and a TaqMan murine HDC primer/probe set (Mm00456104_m1; Applied Biosystems,) and TaqMan 18S rRNA primer/probe set (Applied Biosystems). Relative mRNA abundance was determined from standard curves run with each experiment and expression was normalized to 18S rRNA expression.

Mast cells were resuspended in Tyrode’s buffer (137 mM NaCl, 2.7 mM KCl, 20 mM HEPES, 5.6 mM glucose, 1.8 mM CaCl2, 1.0 mM MgCl2, and 0.1% BSA, pH 7.4). Cells were stimulated either with SP (1 μM for LAD2 cells and 100 μM for BMMCs; Sigma-Aldrich), compound 48/80 (C48/80; 30 μg/ml), or ionomycin (1 μM; Sigma-Aldrich) for 10 min. BMMCs were sensitized overnight with anti-DNP IgE (100 ng/ml; Sigma-Aldrich) and stimulated with DNP-human serum albumin (HSA) (10 ng/ml; Sigma-Aldrich) for 20 min. LAD2 cells were sensitized overnight with human myeloma IgE (2 μg/ml; Chemicon International) and stimulated with anti-human IgE (10 μg/ml; DakoCytomation) for 20 min. Histamine levels in the supernatant and pellet were measured using an LS-50B Luminescence Spectrometer (PerkinElmer) as previously described (15, 41). Histamine release was expressed as percentage of the total cellular histamine content = (histamine in supernatant)/(histamine in supernatant + histamine in pellet) × 100.

For IL-6 release, BMMCs (5 × 104 cells/500 μl) were distributed in 48-well microtiter assay plates and stimulated in complete culture medium with the indicated concentrations of stimulus for 24 h. IL-6 content was determined in cell-free supernatants with commercial ELISA kits (R&D Systems) according to the manufacturer’s instructions. For PG production, BMMCs (2 × 105 cells/500 μl) were stimulated in Tyrode’s buffer for 30 min. Commercial ELISAs for PGD2 (PGD2-MOX kit; Cayman Chemical) were performed according to the manufacturer’s instructions.

Cells were loaded with 5 μM dihydroethidium (Sigma-Aldrich) for 30 min at 37°C. The cells were washed twice, resuspended in Tyrode’s buffer, and stimulated as described. After 5 min of stimulation, cells were placed on ice until being analyzed using a FACSCalibur flow cytometer.

Lentiviral vectors were generated as previously described (16). UCP2-encoding or pWPI vector with expression vectors encoding VSV-G gag-pol and env proteins were transiently transfected into 293T cells using Lipofectamine 2000 (Invitrogen). Supernatants were collected at 24 and 48 h, filtered through 0.45-μm filters, and centrifuged at 50,000 × g for 2 h at 4°C to pellet the virus. Viral pellets were resuspended in 300 μl of culture medium and frozen at −80°C until use. Cells were infected by spinoculation: 5 × 105 cells were resuspended in 200 μl of fresh medium and 50 μl of viral suspension with 8 μg/ml polybrene (Sigma-Aldrich) in 12-well plates and spun at 1500 × g for 90 min at 30°C. Afterward, 1 ml of medium was added and the next day the cells were resuspended in fresh medium. Cells were used for experiments 5 days after infection.

EB extravasation was performed as previously described (17). Sex- and age-matched mice were administered 1% EB in sterile normal saline (0.1 ml) via tail vein injection. They were then anesthetized by an i.p. injection (0.1 ml) of ketamine (100 mg/kg)/xylazine (10 mg/kg), after which the dorsal subscapular skin was shaved and either 50 pmol of SP or 10 μg of histamine (both from Sigma-Aldrich) were injected intradermally in a total volume of 50 μl in the subscapular region with a tuberculin syringe. After 20 min, mice were sacrificed and an 8-mm diameter circular piece of skin at each injection site was removed and weighed. Alternatively, we used passive cutaneous anaphylaxis: normal saline or anti-DNP IgE (20 μg/50 μl; Sigma-Aldrich) was administered intradermally at two skin sites each. Two days later, DNP-HSA (200 μg) along with 1% EB in sterile normal saline (100 μl) was injected in the tail vein. The mice were sacrificed 30 min later and skin injection sites were cut, weighed, and placed in Eppendorf tubes. The mice were then handled the same as described above. EB was extracted in 1 ml of N,N-dimethylformamide overnight at 55°C and the OD was measured at 620 nm using a PerkinElmer Luminescence Spectrophotometer. The EB concentration was calculated using a standard curve and values were normalized to the tissue weight. Intravascular EB and nonspecific effects of injection were accounted for by subtracting the EB extracted after injection of PBS.

Data are expressed as the mean ± SD. Groups were compared with a Student’s t test using the statistical software program SigmaStat. A value of p < 0.05 was considered significant.

We used RT-PCR and immunoblotting to assess expression of UCP2 in murine BMMCs. The Ucp2 transcript could be detected by RT-PCR in BMMCs (Fig. 1,A). Immunoblotting showed that UCP2 protein was expressed in BMMCs as well as in human leukemic LAD2 mast cells (Fig. 1,B). No UCP2 was detected in lysate from Ucp2−/− BMMCs, showing the specificity of the Ab (Fig. 1 B).

FIGURE 1.

UCP2 is expressed in mouse and human mast cells. A,. RT-PCR for UCP2 and β-actin. Lane 1, cDNA from BMMCs; lane 2, pooled cDNA from mouse brown fat, liver, brain, and muscle for positive control; and lane 3, BMMC mRNA not reverse transcribed for negative control. Images are representative of three separate experiments with similar results. B, Immunoblot of lysate from wild-type BMMCs, Ucp2−/− BMMCs and LAD2 cells using Ab against UCP2. Immunoblot is representative of three experiments with similar results. C, Representative May-Grünwald-Giemsa staining of wild-type and Ucp2−/− BMMCs. Original magnification, ×100. D, Flow cytometry of the surface expression of c-kit and FcεRI in wild-type and Ucp2−/− BMMCs. Dotted lines are BMMCs incubated with isotype control Ab. Data are representative of three experiments with similar results. Pos, Positive.

FIGURE 1.

UCP2 is expressed in mouse and human mast cells. A,. RT-PCR for UCP2 and β-actin. Lane 1, cDNA from BMMCs; lane 2, pooled cDNA from mouse brown fat, liver, brain, and muscle for positive control; and lane 3, BMMC mRNA not reverse transcribed for negative control. Images are representative of three separate experiments with similar results. B, Immunoblot of lysate from wild-type BMMCs, Ucp2−/− BMMCs and LAD2 cells using Ab against UCP2. Immunoblot is representative of three experiments with similar results. C, Representative May-Grünwald-Giemsa staining of wild-type and Ucp2−/− BMMCs. Original magnification, ×100. D, Flow cytometry of the surface expression of c-kit and FcεRI in wild-type and Ucp2−/− BMMCs. Dotted lines are BMMCs incubated with isotype control Ab. Data are representative of three experiments with similar results. Pos, Positive.

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BMMCs were obtained by culturing nonadherent bone marrow progenitor cells for 4 wk in SCF- and IL-3-supplemented medium. Bone marrow from both wild-type and Ucp2−/− mice generated highly pure BMMC cultures shown to be morphologically normal with numerous distinguishable granules upon staining with May-Grünwald-Giemsa (Fig. 1,C). Expression of the mast cell markers c-kit and FcεRI was assessed by flow cytometry, which showed similar levels of these molecules in wild-type and Ucp2−/− BMMC cultures. (Fig. 1 D). Expression of FcεRI was also similar following 24 h of incubation with mouse IgE (100 ng/ml; data not shown). Collectively, these results suggest that UCP2 is not necessary for normal BMMC development.

Following overnight sensitization with DNP-specific IgE (100 ng/ml), BMMCs were stimulated for 20 min with DNP-HSA (10 ng/ml). Ucp2−/− BMMCs released significantly more histamine (1.4-fold) after challenge with 10 ng/ml DNP-HSA (Fig. 2,A); Levels of basal release were similar in wild-type and Ucp2−/− BMMCs (Fig. 2,A). We then compared the effect of three different nonimmune triggers in FSMCs: SP (100 μM) and C48/80 (30 μg/ml) as well as the calcium ionophore ionomycin (1 μM), which induces calcium influx. All of these nonimmune triggers also induced more histamine release from Ucp2−/− mast cells (Fig. 2 B), indicating that UCP2 may regulate signaling steps downstream of cytosolic calcium ion influx.

FIGURE 2.

UCP2-deficient mast cells have enhanced degranulation. A, Wild-type and Ucp2−/− BMMCs were sensitized overnight with anti-DNP IgE (100 ng/ml) and challenged for 20 min with DNP-HSA (10 ng/ml). B, Wild-type and Ucp2−/− FSMCs were stimulated for 10 min with SP (100 μM), C48/80 (30 μg/ml), or ionomycin (1 μM), after which histamine was measured in the supernatant and pellet. ∗, p < 0.05 (n = 6).

FIGURE 2.

UCP2-deficient mast cells have enhanced degranulation. A, Wild-type and Ucp2−/− BMMCs were sensitized overnight with anti-DNP IgE (100 ng/ml) and challenged for 20 min with DNP-HSA (10 ng/ml). B, Wild-type and Ucp2−/− FSMCs were stimulated for 10 min with SP (100 μM), C48/80 (30 μg/ml), or ionomycin (1 μM), after which histamine was measured in the supernatant and pellet. ∗, p < 0.05 (n = 6).

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We next examined the effect of UCP2 on degranulation of human mast cells by transducing LAD2 cells with a lentivirus encoding human UCP2 and GFP or a lentivirus expressing GFP alone as a control (16). The transduction efficiency was ∼50% as assessed by flow cytometric analysis of GFP expression; overexpression of UCP2 was confirmed by immunoblot (Fig. 3,A). IgE-sensitized UCP2-overexpressing LAD2 cells challenged with anti-IgE (10 ng/ml) had 38% less histamine release compared with control cells (Fig. 3,B). Levels of basal histamine release were similar in UCP2-overexpressing and control cells (Fig. 3,B). UCP2-overexpressing LAD2 cells stimulated with SP (1 μM) had 23% less histamine release compared with control cells (Fig. 3 C). LAD2 cells transduced with the control virus showed similar histamine release to untransduced controls (data not shown). Together, these results suggest that UCP2 down-regulates degranulation in both mouse and human cells regardless of the stimulus used.

FIGURE 3.

Overexpression of UCP2 in LAD2 cells inhibits histamine release. LAD2 cells were transduced with either a control lentivirus or UCP2-overexpression lentivirus and used for experiments 5 days after transduction. A, Immunoblot of lysate from transduced LAD2 cells showing UCP2 overexpression. B, Transduced LAD2 cells were sensitized overnight with human IgE (2 μg/ml) and challenged for 20 min with anti-IgE (10 μg/ml) or C, stimulated for 10 min with SP (1 μM). ∗, p < 0.05 (t test) vs cells transduced with control virus. All data are presented as percent histamine release and represent the mean ± SD (n = 3).

FIGURE 3.

Overexpression of UCP2 in LAD2 cells inhibits histamine release. LAD2 cells were transduced with either a control lentivirus or UCP2-overexpression lentivirus and used for experiments 5 days after transduction. A, Immunoblot of lysate from transduced LAD2 cells showing UCP2 overexpression. B, Transduced LAD2 cells were sensitized overnight with human IgE (2 μg/ml) and challenged for 20 min with anti-IgE (10 μg/ml) or C, stimulated for 10 min with SP (1 μM). ∗, p < 0.05 (t test) vs cells transduced with control virus. All data are presented as percent histamine release and represent the mean ± SD (n = 3).

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We next addressed the possibility that UCP2 may affect mast cell histamine content before stimulation. Histamine was extracted from the untreated skin of wild-type and Ucp2−/− mice and measured by ELISA. Histamine levels were 241 ± 70 nmol/g for wild-type vs 352 ± 90 nmol/g for Ucp2−/− mice (Fig. 4 A), a 60% increase over wild-type mice.

FIGURE 4.

UCP2 decreases mast cell histamine content. A, Total skin histamine of wild-type and Ucp2−/− mice quantified by ELISA. Data are normalized to the tissue weight. ∗, p < 0.05. Graph represents the mean and individual data of six to seven mice per genotype. B, Representative photomicrographs of dorsal skin from wild-type and Ucp2−/− mice stained with toluidine blue. Metachromatic mast cells are also indicated by arrows. C, Number of mast cells per mm2 in cross-section of skin. Mast cells were counted in five randomly chosen fields from three sections per mouse. Data represent the mean ± SD of five mice per genotype; p > 0.05. D, Total histamine content of wild-type and Ucp2−/− BMMCs was measured spectrophotometrically and normalized to cell number. ∗, p < 0.05 vs wild type (t test). Data are the mean ± SD of three experiments. E, Total histamine content of LAD2 cells 5 days after transduction with a control lentivirus or UCP2- overexpression lentivirus. ∗, p < 0.05 vs control cells. Data are the mean ± SD (n = 3).

FIGURE 4.

UCP2 decreases mast cell histamine content. A, Total skin histamine of wild-type and Ucp2−/− mice quantified by ELISA. Data are normalized to the tissue weight. ∗, p < 0.05. Graph represents the mean and individual data of six to seven mice per genotype. B, Representative photomicrographs of dorsal skin from wild-type and Ucp2−/− mice stained with toluidine blue. Metachromatic mast cells are also indicated by arrows. C, Number of mast cells per mm2 in cross-section of skin. Mast cells were counted in five randomly chosen fields from three sections per mouse. Data represent the mean ± SD of five mice per genotype; p > 0.05. D, Total histamine content of wild-type and Ucp2−/− BMMCs was measured spectrophotometrically and normalized to cell number. ∗, p < 0.05 vs wild type (t test). Data are the mean ± SD of three experiments. E, Total histamine content of LAD2 cells 5 days after transduction with a control lentivirus or UCP2- overexpression lentivirus. ∗, p < 0.05 vs control cells. Data are the mean ± SD (n = 3).

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Examination of the number and distribution of mast cells in the skin of Ucp2−/− mice by May-Grünwald-Giemsa and toluidine blue stains showed no differences from wild type (Fig. 4,B). The skin mast cells had a normal distribution in the superficial dermis with equal numbers in both the Ucp2−/− and wild-type skin (Fig. 4 C). Given that mast cells are the only cells in the skin to produce histamine and that mast cell density is similar in wild-type and Ucp2−/− skin, it suggests that more histamine is produced per mast cell.

We also measured histamine levels in cultured BMMCs and found that wild-type BMMCs contained 0.11 ± 0.029 pg/cell, whereas Ucp2−/− BMMCs contained 0.28 ± 0.039 pg/cell, a 155% increase over wild-type cells (Fig. 4,D). We next measured the histamine content in LAD2 cells after transduction with either the control or the UCP2-overexpression lentivirus. Transduction with the control lentivirus did not have any effect on LAD2 histamine content. LAD2 cells overexpressing UCP2 had a 27% lower histamine content 5 days after lentiviral transduction (3.63 ± 0.13 pg/cell in control cells vs 2.60 ± 0.34 pg/cell in UCP2-overexpressing cells; Fig. 4 E).

We also measured expression of HDC, the enzyme responsible for histamine synthesis, to investigate whether this could account for the difference in histamine levels. Quantitative real-time PCR and immunoblot showed that Ucp2−/− BMMCs expressed greater levels of HDC mRNA (Fig. 5,A) and protein (Fig. 5 B). The immunoblot shows both 74- and 54-kDa bands for HDC. The full-length HDC (74 kDa) is inactive until it is cleaved to the shorter form (54 kDa). Together, these data indicate that induction of HDC may be responsible for the increased histamine content observed in Ucp2−/− mast cells.

FIGURE 5.

UCP2 decreases mast cell HDC expression. A, Real-time quantitative PCR of HDC mRNA transcripts from wild-type and Ucp2−/− BMMCs normalized to 18S rRNA. ∗, p < 0.05. Data are the mean ± SD of three experiments. B, Immunoblot of lysate from wild-type and Ucp2−/− BMMCs with anti-HDC Ab. Immunoblot is representative of three independent experiments with similar results. C, Superoxide production of wild-type and Ucp2−/− BMMCs measured by dihydroethidium using flow cytometry. Histogram is representative of three experiments with similar results. D, Total histamine content of BMMCs after 5-day treatment with TBAP (20–40 μM). ∗, p < 0.05. Data are the mean ± SD (n = 3).

FIGURE 5.

UCP2 decreases mast cell HDC expression. A, Real-time quantitative PCR of HDC mRNA transcripts from wild-type and Ucp2−/− BMMCs normalized to 18S rRNA. ∗, p < 0.05. Data are the mean ± SD of three experiments. B, Immunoblot of lysate from wild-type and Ucp2−/− BMMCs with anti-HDC Ab. Immunoblot is representative of three independent experiments with similar results. C, Superoxide production of wild-type and Ucp2−/− BMMCs measured by dihydroethidium using flow cytometry. Histogram is representative of three experiments with similar results. D, Total histamine content of BMMCs after 5-day treatment with TBAP (20–40 μM). ∗, p < 0.05. Data are the mean ± SD (n = 3).

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UCP2 down-regulates superoxide production in many cell types (4, 5). It is also reported that ROS induces the HDC gene (14, 18). We therefore hypothesized that the increased histamine content in Ucp2−/− mast cells was due to increased superoxide production. We first showed enhanced ROS production in Ucp2−/− BMMCs by measuring fluorescence of cells loaded with dihydroethidium using flow cytometry. Dihydroethidium fluorescence was higher in Ucp2−/− BMMCs compared with wild-type BMMCs (Fig. 5,C). We examined the effect of mitochondrial superoxide production on histamine content by treating BMMCs with the mitochondrial-targeted superoxide dismutase (SOD)-mimetic Mn(III) tetrakis(4-benzoic acid) porphyrin (TBAP). Culture of BMMCs for 5 days with TBAP (20–40 μM) reduced histamine content by up to 58% (Fig. 5 D). Similar results were found with LAD2 cells (data not shown). Culture of LAD2 cells or BMMCs with TBAP for 5 days did not affect cell viability as shown by trypan blue staining. These data indicate that mitochondrial superoxide increases histamine content, possibly through induction of HDC.

Cells were sensitized overnight with anti-DNP IgE (100 ng/ml) and stimulated with DNP-HSA (10 ng/ml) for 24 h; IL-6 in the supernatant fluid was ∼50% higher in the Ucp2−/− BMMCs than controls (Fig. 6).

FIGURE 6.

Ucp2−/− BMMCs have augmented IL-6 release. Cells were sensitized overnight with anti-DNP IgE (100 ng/ml) and stimulated with DNP-HSA (10 mg/ml) in complete medium. After 24 h, IL-6 in the supernatant fluid was measured by ELISA (n = 3; ∗, p < 0.05).

FIGURE 6.

Ucp2−/− BMMCs have augmented IL-6 release. Cells were sensitized overnight with anti-DNP IgE (100 ng/ml) and stimulated with DNP-HSA (10 mg/ml) in complete medium. After 24 h, IL-6 in the supernatant fluid was measured by ELISA (n = 3; ∗, p < 0.05).

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PGD2 is a lipid produced primarily by mast cells that contributes to vasodilation, bronchoconstriction, and chemotaxis of eosinophils and lymphocytes (19). After stimulation with DNP-HSA (10 ng/ml), Ucp2−/− BMMCs produced more PGD2 (5866 ± 1430 vs 3274 ± 289 pg/106 cells; Fig. 7,A). A similar effect was observed with C48/80 (30 μg/ml; 7880 ± 886 vs 6348 ± 464 pg/106 cells; Fig. 7 B).

FIGURE 7.

Ucp2−/− BMMCs have augmented PGD2 release and ERK activation. A and C, PGD2 release from wild-type and Ucp2−/− BMMCs. Cells were either (A) sensitized overnight with anti-DNP IgE (100 ng/ml) and stimulated with DNP-HSA (10 ng/ml) or (C) stimulated with C48/80 (30 μg/ml); after 30 min, supernatant PGD2 was measured by ELISA. ∗, p < 0.05 vs wild type. All data represent the mean ± SD of three experiments. B and D, ERK phosphorylation in wild-type and Ucp2−/− BMMCs. Cells were treated for the indicated times as follows: B, sensitized overnight with anti-DNP IgE (100 ng/ml) and then stimulated with DNP-HSA (10 ng/ml) or D, stimulation by C48/80 (30 μg/ml). Phospho-ERK and total ERK were determined by immunoblot. Immunoblots are representative of three experiments with similar results.

FIGURE 7.

Ucp2−/− BMMCs have augmented PGD2 release and ERK activation. A and C, PGD2 release from wild-type and Ucp2−/− BMMCs. Cells were either (A) sensitized overnight with anti-DNP IgE (100 ng/ml) and stimulated with DNP-HSA (10 ng/ml) or (C) stimulated with C48/80 (30 μg/ml); after 30 min, supernatant PGD2 was measured by ELISA. ∗, p < 0.05 vs wild type. All data represent the mean ± SD of three experiments. B and D, ERK phosphorylation in wild-type and Ucp2−/− BMMCs. Cells were treated for the indicated times as follows: B, sensitized overnight with anti-DNP IgE (100 ng/ml) and then stimulated with DNP-HSA (10 ng/ml) or D, stimulation by C48/80 (30 μg/ml). Phospho-ERK and total ERK were determined by immunoblot. Immunoblots are representative of three experiments with similar results.

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ERK is a MAPK that controls early-phase PG production through activation of cytosolic phospholipase A2 (20)and may also regulate degranulation (21). Its activation is enhanced by ROS (22), raising the possibility that it may link greater ROS production to greater PG release. We, therefore, measured phospho-ERK levels by immunoblot with the hypothesis that ERK activation would be greater in Ucp2−/− BMMCs. Levels of phospho-ERK were higher in Ucp2−/− BMMCs following stimulation with both DNP-BSA (Fig. 7,C) and C48/80 (Fig. 7,D). Levels of total ERK were similar in wild-type and Ucp2−/− BMMCs (Fig. 7, B and D).

To assess the effect of UCP2 on mast cell-dependent inflammation in vivo, we performed an EB extravasation assay following intradermal injection of normal saline or SP (50 pmol) into the dorsal skin. SP mediates stress-induced inflammatory reactions in the skin by activating mast cells (23) and is also up-regulated in chronic inflammatory skin diseases such as psoriasis (24, 25). SP allows us to measure the effects of direct mast cell activation, since the cells do not need to be sensitized ahead of time. Significantly increased EB extravasation was seen in the skin of Ucp2−/− mice following SP injection compared with wild-type mice (Fig. 8,A). Similar results were observed in mice passively sensitized by i.p. injection of anti-DNP IgE and then challenged intradermally with DNP-HSA (Fig. 8,B). Capillary permeability caused by mast cell activation is primarily mediated by histamine (24). To rule out the possibility that differences in EB extravasation were due to the response of the capillaries to histamine, we assessed vascular permeability following intradermal injection of histamine (10 μg) into the dorsal skin. No difference in EB extravasation was seen between genotypes (Fig. 8,C), indicating that there is a similar response to histamine in both Ucp2−/− and wild-type mice. Furthermore, the differences seen in plasma extravasation following either SP or anti-DNP-HSA stimulation cannot be explained by an increased number of mast cells, since we showed that there were no differences in the distribution of skin mast cells in Ucp2−/− and wild-type mice (Fig. 4). These data indicate that decreased expression of UCP2 significantly increases mast cell histamine-dependent vascular permeability in vivo.

FIGURE 8.

Enhanced vascular permeability in Ucp2−/− mouse skin. A, EB extravasation following intradermal injection of either normal saline or SP (50 pmol) for 10 min. B, EB extravasation following passive sensitization with IgE and local skin challenge with DNP-HSA for 10 min. C, EB extravasation after intradermal challenge with histamine (10 μg) for 10 min. EB was extracted from the injection sites in N,N-dimethylformamide overnight, quantified by absorbance at 620 nm, and normalized to tissue weight. All results represent net extravasation after subtraction of extravasation from control saline injections. Graphs represent the mean and individual values of each mouse.

FIGURE 8.

Enhanced vascular permeability in Ucp2−/− mouse skin. A, EB extravasation following intradermal injection of either normal saline or SP (50 pmol) for 10 min. B, EB extravasation following passive sensitization with IgE and local skin challenge with DNP-HSA for 10 min. C, EB extravasation after intradermal challenge with histamine (10 μg) for 10 min. EB was extracted from the injection sites in N,N-dimethylformamide overnight, quantified by absorbance at 620 nm, and normalized to tissue weight. All results represent net extravasation after subtraction of extravasation from control saline injections. Graphs represent the mean and individual values of each mouse.

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In this study, we show that the mitochondrial protein UCP2 is expressed in both murine and human LAD2 mast cells and can regulate mast cell activation in vitro and in vivo. Expression of UCP2 negatively regulated several mast cells functions, including degranulation, histamine production, as well as IL-6 and PGD2 and release.

The increased skin plasma extravasation seen in Ucp2−/− mice can be explained by the increased release of histamine from mast cells since it occurred both after allergic challenge and stimulation with SP, a well-known trigger of mast cells (23). These findings are not due to an increased number of mast cells, because the number of mast cells in the skin of Ucp2−/− mice was similar to that of the wild-type mice. Furthermore, our findings cannot be explained by an augmented response to histamine in Ucp2−/− mice, because intradermal administration of histamine resulted in similar levels of plasma extravasation in both wild-type and Ucp2−/− mice.

We found that activation of mast cells with both Ag and FcεRI-independent stimuli (C48/80, SP, ionomycin) resulted in greater histamine release in Ucp2−/− cells, whereas overexpression of UCP2 reduced degranulation in LAD2 human mast cells. In agreement with these findings, pharmacologic uncoupling of the mitochondrial proton gradient with carbonyl cyanide p-triflurormethoxyphenylhydrazine inhibited Ag-induced mast cell degranulation (24). UCP2 was also shown to inhibit exocytosis of insulin granules in β cells (9) and dopamine-containing vesicles in rat PC12 cells (10).

One possible explanation of our findings is the increased superoxide in the Ucp2−/− mast cells. It is known that mast cells produce ROS after stimulation with Ag and non-FcεRI stimuli such as SP and C48/80 (8, 26). Inhibition of ROS production by antioxidants reduces degranulation and cytokine production (7, 27). Povidone-iodine, a superoxide scavenger, inhibited mast cell degranulation in vitro (28), and a SOD mimetic decreased mast cell degranulation in vivo in a guinea pig model of allergic asthma (29). There are several other endogenous antioxidant proteins expressed in mast cells that are reported to affect mast cell activation, including thioredoxin 1 (7) and heme oxygenase 1 (30). However, UCP2 is the first protein reported to reduce mast cell degranulation that prevents the formation of ROS rather than neutralizing it.

ROS may regulate mast cell degranulation both upstream and downstream of extracellular calcium influx (6, 31). Mast cell mitochondria are reported to be involved in the downstream regulation (6). This is in agreement with our results that Ucp2−/− mast cells have enhanced degranulation even after calcium ionophore stimulation, where all cells presumably see the same intracellular calcium levels. It is possible that UCP2 affects calcium kinetics since it is involved in mitochondrial calcium uptake (32). Another possibility is that UCP2 decreases ATP levels (33), leading to increased activation of store-operated calcium channels (34).

Increased vascular permeability in the skin of Ucp2−/− mice is likely because of increased histamine release due to both increased secretion and increased preformed histamine content. The skin of Ucp2−/− mice had histamine levels that were 60% higher than controls. Considering the similar number of mast cells, this indicates that there is more histamine stored per cell, a finding we have confirmed in BMMCs. In conjunction with elevated histamine levels, we found that Ucp2−/− BMMCs had a higher expression of HDC, the enzyme responsible for histamine synthesis. It has been reported that the HDC gene promoter is activated by oxidative stress in AGS gastric cancer cells (18). The higher ROS levels in Ucp2−/− mast cells may be responsible for induction of HDC and, therefore, increased histamine synthesis. This is consistent with our finding that the SOD-mimetic TBAP decreased histamine levels in both BMMCs and LAD2 cells.

The relation of low Ucp2 expression to increased mast cell activation was not limited only to histamine since it also permitted higher IL-6 and PGD2 production and release. Moreover, the greater PGD2 production in Ucp2−/− BMMCs was accompanied by greater ERK phosphorylation. Early PG synthesis in mast cells is controlled primarily by ERK (20). Oxidative stress is known to induce ERK activation in various cell types, including lymphocytes, possibly through an indirect effect on upstream kinases (22). In addition to PG, ERK may regulate degranulation, although there is conflicting evidence for this (20, 21).

In addition to our results, other studies have shown that UCP2 plays an important role in other immune responses. UCP2 is also expressed in lymphocytes, dendritic cells, neutrophils, and macrophages (35). Ucp2−/− mice develop more severe autoimmune encephalomyelitis (36) and autoimmune diabetes (37). Macrophages from Ucp2−/− mice have a greater inflammatory response to LPS, including increased NF-κB activation and greater cytokine production (11, 12, 13). Macrophages overexpressing UCP2 produce less ROS in response to LPS (38) and have decreased transendothelial migration (39). UCP2 deficiency also confers protection to Toxoplasma gondii and Listeria monocytogenes infection in mice, due to increased inflammatory responses (11, 35). Since there is evidence that ROS modulates activation of T and B lymphocytes (40, 41), UCP2 may also have important regulatory functions in these cells, although this has not yet been directly explored.

In conclusion, we have identified UCP2 as a novel regulator of mast cell secretion and associated inflammation. Inhibiting UCP2 has been proposed as a method to increase insulin release from β cells in type 2 diabetes (9). However, inhibition of UCP2 may worsen allergic and inflammatory diseases, making it a less attractive target for this indication. On the other hand, induction or activation of UCP2 may be a new strategy for reducing allergic and inflammatory responses.

We thank Sheila Collins for providing the UCP2-deficient breeding pairs, Dr. A. S. Kirshenbaum (National Institutes of Health) for providing the LAD2 cells, and Amgen for the generous gift of recombinant human SCF. We also thank Jessica Christian for help with word processing.

The authors have no financial conflict of interest.

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

1

This work was supported in part by the National Institutes of Health (Grant 2R01 AR047652 to T.C.T.).

4

Abbreviations used in this paper: SP, substance P; BMMCs, bone marrow mast cell; C48/80, compound 48/80; HSA, human serum albumin; EB, Evans blue; FSMC, fetal skin mast cell; HDC, histidine decarboxylase; SOD, superoxide dismutase; ROS, reactive oxygen species; UCP, uncoupling protein; SCF, stem cell factor; TBAP, tetrakis(4-benzoic acid) porphyrin.

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