Abstract
Exposure to swine dust causes intense airway inflammation with multifold increase in inflammatory cells and secretion of pro-inflammatory cytokines. This in vitro study focuses on the swine-dust activation of lymphocytes in whole blood, in phagocyte-depleted whole blood and in peripheral blood mononuclear cells (PBMC), in order to investigate whether phagocytic cells and/or soluble mediators are involved in the activation of T-cells following exposure to organic dust from a swine confinement house.
T-cell activation was analysed by flow cytometry with double staining for CD3 and the activation marker CD69.
Swine dust (50 µg) incubated (24 h) with heparinized whole blood was shown to activate 27.6% of the T-cells, while swine dust incubated with whole blood depleted from phagocytic cells or PBMC only activated 4.5% and 4.8% of the T-cells, respectively. Plasma separated from whole blood preincubated with swine dust for 24 h stimulated as much as 32.4% of PBMC T-cells and contained high levels of interleukin (IL)-12 (14 pg·mL) and interferon (IFN)-γ (2284 pg·mL−1), while plasma from PBMC incubated with swine dust contained low levels of IL-12 (2 pg·mL−1) and IFN-γ (196 pg·mL−1).
This study demonstrates that activation of T-cells by organic dust from a swine confinement building seems to require phagocytic cells, most likely acting through the release of soluble mediators. Also, conditioned plasma from swine-dust exposed whole blood, which was capable of activating T-cells, contained high concentrations of interleukin-12 and interferon-γ.
Three hours exposure to dust in a swine confinement building causes intense airway inflammation, with a multifold increase of inflammatory cells, predominantly neutrophils, in healthy volunteers 1. The exposure also induces secretion of pro-inflammatory cytokines such as tumour necrosis factor (TNF)-α, interleukin (IL)-1, IL-6, and IL-8 in the airways in vivo as assessed by bronchoalveolar lavage (BAL) 2–4. The most probable sources for these cytokines are alveolar macrophages 5 and epithelial cells 6. Previous in vivo findings have shown increased numbers of T- and B- lymphocytes in BAL fluid following exposure to dust in a swine confinement house, but the proportion of T-lymphocytes in relation to the total amount of lymphocytes, was unaltered 7. In the same study it was also demonstrated that exposure to organic dust induced activation (increased expression of the activation markers CD69, CD25 and human leukocyte antigen-DR) of T-lymphocytes in vivo 7. Furthermore, dust from swine confinement buildings activates T-cells in a dose- and time-response manner in vitro when incubated with peripheral whole blood from healthy subjects 8.
The in vivo lymphocyte activation caused by inhaled organic dust may comprise a specific activation of the T-lymphocytes through the T-cell antigen receptor. There is also a possibility that the activation of T-cells is mediated by nonspecific mechanisms in which release of T-cell activating soluble mediators from cells other than lymphocytes may be involved.
The aim of the present in vitro study thus was to elucidate whether phagocytic cells and/or soluble mediators are involved in the activation of T-cells following exposure to organic dust from a swine confinement house.
Materials and methods
Subjects
Venous blood was collected from seven (5 female), nonallergic, nonsmoking, healthy subjects, with no previous exposure for swine dust, and with a mean age of 43 (range 26–58) yrs. All subjects gave their informed consent and the study was approved by the Ethics Committee of Karolinska Institute, Stockholm, Sweden.
Stimulation with dust
Dust collected ∼1.5 m above the floor in a swine confinement building, was dissolved in Roswell Park Memorial Institute (RPMI) 1640 medium (Gibco Laboratories, Paisley, UK), sonicated for 10 min and diluted in heparinized whole blood to a final concentration of 50 µg·mL−1. The polyclonal activator, phytohaemagglutinin (PHA), used as positive control, was also dissolved in RPMI 1640 and sonicated for 10 min and diluted in whole blood to a final concentration of 10 µg·mL−1. Unstimulated whole blood containing RPMI 1640, was used as negative control. Blood samples were incubated for 24 h and then ethylenedianmine tetracetic acid (EDTA) was added to a final concentration of 5 mM. All stimulation tests were performed in duplicate during 24 h in 37°C and 5% CO2.
Blood was collected using Vacutainer® brand blood collection tubes, and Vacutainer® CPTTM, (Cell Preparation Tubes, Becton Dickinson Vacutainer Systems, Franklin Lakes, NJ, USA) containing sodium heparin anticoagulant. Peripheral blood mononuclear cells (PBMC) were selected through gradient separation. In a first experimental set-up PBMC was incubated with plasma received from whole blood previously incubated with 50 µg·mL−1 swine dust, i.e. “conditioned plasma”, 10 µg·mL−1 PHA or RPMI for 24 h. In a second experimental set-up, PBMC was resuspended in autologous plasma and incubated with 50 µg·mL−1 swine dust, 10 µg·mL−1 PHA or RPMI for 24 h.
Phagocytic cells were removed from whole blood through incubation with carbonyl iron particles (4 µg·mL−1, size 5 µg, Sigma Aldrich, Stockholm, Sweden). Blood and carbonyl iron particles were incubated for 30 min at 37°C and mixed occasionally. After incubation, the blood sample tube was placed on one of the pools of a magnet (Dynal A.S., Oslo, Norway) for 10 min at 4°C. The noniron containing i.e. the nonphagocytic cells were removed (with the tube still standing on the magnet) and transferred to a second plastic tube. Cells were resettled on the magnet for a further 10 min at 4°C and the procedure was repeated. Blood was stained with the monoclonal antibody CD14-PE/CD45-FITC (Becton Dickinson, Franklin Lakes, NJ, USA) before and after iron incubation. The nonphagocytic cells were incubated with 50 µg swine dust·mL−1, 10 µg PHA·mL−1 or with RPMI 1640 (negative control) for 24 h.
Monoclonal antibodies and flow cytometric analysis
Cells were characterized by subgroup-specific fluorochrome-conjugated monoclonal antibodies. Foranalysis of T-cell activation, double staining for CD3 and the cell-surface activation marker CD69 (Becton Dickinson) was performed. Monocyte depletion was evaluated and analysed by CD14-PE/CD45-FITC. Twenty microlitres of monoclonal antibody was added to 100 µL aliquots of either blood or PBMC samples dissolved in plasma. The samples were incubated 20 min in the dark, at room temperature. Lysing of red blood cells, was done using fluorescence-activated cell sorter (FACS) lysing solution (Becton Dickinson) and fixation was achieved by using Cellfix (Becton Dickinson). For background staining, isotypic controls were performed. Cell count percentages were calculated by flow cytometry using a FACS Calibur (Becton Dickinson).
Cytokine analyses by enzyme-linked immunosorbent assay
IL-12 in plasma samples was analysed by Human IL-12 immunoassay (R&D System Europe Ltd, Abingdon, UK). Interferon (IFN)-γ in plasma samples was analysed by OptEIATM Human IFN-γ Kit (PharMingen, San Diego, CA, USA).
Statistics
Statistical analysis was performed using StatView® programme, version 4.02 for Macintosh and Super Anova 1.11 (Abacus Concepts, Inc, Berkeley, CA, USA). Results are presented as medians (25–75th percentiles). Comparisons were performed by analysis of variance (ANOVA). P-values <0.05 were considered to be statistically significant.
Results
After 24-h incubation of whole blood in vitro 27.6% (17.3–30.8) of the CD3 positive lymphocytes (T-cells) expressed the early activation marker CD69 compared to 3.3% (2.2–4.4) of T-lymphocytes in nonstimulated whole blood (p<0.0001). Incubation with PHA and whole blood yielded 71.3% (65.3–73.4) of the T-lymphocytes to express CD69 (fig. 1⇓).
In PBMC selected from whole blood and incubated with dust for 24 h CD69 was expressed in 4.8% (4.5–7.0) of the T-cells compared to 2.2% (1.5–3.1) of T-lymphocytes from nonstimulated PBMC (not significant). PHA induced CD69 expression in 70.9% (36.0–78.8) of the T-lymphocytes in PBMC (fig. 1⇑).
Phagocytic cells were removed from whole blood through incubation with carbonyl iron, reducing the proportion of monocytes from 7 to 1% and of granulocytes from 58 to 35% (median value). In such “phagocyte reduced” whole blood, incubation with dust for 24 h induced CD69 expression in 4.5% (3.6–9.7) of the T-lymphocytes as compared to 1.5% (1.2–1.7) in T-lymphocytes of nonstimulated “phagocyte reduced” whole blood (not significant). Incubation with PHA as a positive control induced CD69 expression on 71.3% (59.1–79.2) of the T-lymphocytes (fig. 1⇑).
Plasma was transferred from dust-exposed whole blood, i.e. “conditioned plasma”, and incubated with PBMC for 24 h. Following this incubation, 32.4% (29.2-34.4) of the CD3 positive T-lymphocytes expressed CD69 compared to 3.3% (2.8–3.6) of T-lymphocytes of PBMC incubated with control plasma (p<0.0001). Plasma from whole blood stimulated with PHA induced expression of CD69 in 37.1% (30.0–52.1) of the T- lymphocytes (fig. 2⇓).
Soluble mediators in conditioned plasma
In an attempt to identify soluble mediators of importance for the T-lymphocyte stimulation, the concentration of IL-12 and IFN-γ in conditioned plasma was measured. In the dust incubated whole blood, i.e. the conditioned plasma, the IL-12 concentration was 14.1 (8.3–22.1) pg·mL−1, while the concentration was below detection limit in control plasma. Plasma from PHA stimulated whole blood contained 47.4 (25.7–73.2) pg·mL−1 IL-12. In plasma of PBMC stimulated with dust, the IL-12 concentration was 2.3 (0.1–2.8) pg·mL−1. PHA stimulated PBMC supernatant contained 5.9 (3.5–10.6) pg·mL−1, while negative controls had undetectable levels (fig. 3⇓).
IFN-γ levels in conditioned plasma were 2284.1 (1352.8–4025.9) pg·mL−1 compared to 4775.8 (3936.2–9381.8) pg·mL−1 in PHA stimulated plasma and 6.5 (0.7–32.6) pg·mL−1 in control plasma. PBMC plasma from swine dust incubations contained 195.9 (161.2–364.9) pg·mL−1 compared to 804.1 (286.7–863.0) pg·mL−1 in PHA stimulated PBMC and 6.0 (1.9–15.0) pg·mL−1 in control supernatant (fig. 3⇑).
Discussion
In line with the authors' previous findings 8 the present study demonstrates that swine dust activates T-lymphocytes in whole blood in vitro, as detected by T-cell expression of the early activation marker CD69. However, when incubating swine dust with PBMC separated from whole blood, T-lymphocytes were not activated. In contrast to whole blood, PBMC consists mainly of lymphocytes, while there are virtually no granulocytes and only few monocytes. To further investigate whether phagocytic cells such as granulocytes and monocytes could influence the dust-mediated activation of T-lymphocytes, the number of monocytes and granulocytes in whole blood were reduced, which substantially reduced the capacity of the dust to activate T-lymphocytes. Organic dust obtained from swine confinement houses is therefore capable of activating T-lymphocytes only in the presence of phagocytic cells. Moreover, plasma from swine dust exposed whole blood, i.e. conditioned plasma induced lymphocyte activation. Based on these data the present authors conclude that T-cell activation induced by dust requires phagocytic cells and that it is induced by mediator release from phagocytic rather than by a direct cell-to-cell interaction.
The present authors previously found dramatically increased numbers of inflammatory cells, especially neutrophilic granulocytes, in BAL fluid after exposure to swine dust in vivo. Increased concentrations of TNF-α, IL -1, IL-6 and IL-8 were also found in BAL fluid following exposure to swine dust in vivo 3, 4 and in supernatant of epithelial cells and alveolar macrophages following exposure to dust in vitro 9, 10. Granulocytes have also been shown to release many of these cytokines, i.e. TNF-α, IL -1, and IL-8 upon lipopolysaccharide (LPS) stimulation 11–15, and monocytes can produce TNF-α 16, IL-1, 15, 17, 18 and IL-12 19. Many of these granulocytes and monocytes derived cytokines are involved in the activation of lymphocytes, either directly (IL-1, IL-6, IL-12) or indirectly (IFN-γ). In the present study, high levels of IL-12 and IFN-γ were found in conditioned plasma following in vitro exposure of whole blood to dust. Thus phagocytic cells such as granulocytes and monocytes present in whole blood during swine dust incubation seem to release cytokines IL-12 and IFN-γ which may be of importance for the swine dust induced T-lymphocyte stimulation. It seems likely that monocytes produce cytokines such as IL-12, which may induce IFN-γ production by lymphocytes such as natural killer (NK) cells.
To conclude, phagocytic cells are necessary for the dust-activation of T-lymphocytes. The phagocytes seem to act by releasing lymphocyte-activating cytokines such as interleukin-12 and interferon-γ. To improve the understanding of immune response following exposure to organic dust, intracellular cytokine release from swine-dust activated peripheral blood cells as well as bronchoalveolar lavage cells from dust-exposed individuals will need to be studied in vivo.
- Received March 26, 2001.
- Accepted September 7, 2001.
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