Murine Intraepithelial Dendritic Cells Interact With Phagocytic Cells During Aspergillus fumigatus-Induced Inflammation.

People are constantly exposed to airborne fungal spores, including Aspergillus fumigatus conidia that can cause life-threatening conditions in immunocompromised patients or acute exacerbations in allergics. However, immunocompetent hosts do not exhibit mycoses or systemic inflammation, due to the sufficient but not excessive antifungal immune response that prevent fungal invasion. Intraepithelial dendritic cells (IE-DCs) of the conducting airway mucosa are located in the primary site of the inhalant pathogen entry; these cells can sense A. fumigatus conidia and maintain homeostasis. The mechanisms by which IE-DCs contribute to regulating the antifungal immune response and controlling conidia dissemination are not understood. To clarify the role of IE-DCs in the balance between pathogen sensing and immune tolerance we investigated the A. fumigatus conidia distribution in optically cleared mouse lungs and estimated the kinetics of the local phagocytic response during the course of inflammation. MHCII+ antigen-presenting cells, including IE-DCs, and CD11b+ phagocytes were identified by immunohistochemistry and three-dimensional fluorescence confocal laser-scanning microscopy of conducting airway whole-mounts. Application of A. fumigatus conidia increased the number of CD11b+ phagocytes in the conducting airway mucosa and induced the trafficking of these cells through the conducting airway wall to the luminal side of the epithelium. Some CD11b+ phagocytes internalized conidia in the conducting airway lumen. During the migration through the airway wall, CD11b+ phagocytes formed clusters. Permanently located in the airway wall IE-DCs contacted both single CD11b+ phagocytes and clusters. Based on the spatiotemporal characteristics of the interactions between IE-DCs and CD11b+ phagocytes, we provide a novel anatomical rationale for the contribution of IE-DCs to controlling the excessive phagocyte-mediated immune response rather than participating in pathogen uptake.

Aeroallergen challenge promotes dendritic cell proliferation in the airways.

Aeroallergen provocation induces the rapid accumulation of CD11c(+)MHC class II (MHC II)(+) dendritic cells (DCs) in the lungs, which is driven by an increased recruitment of blood-derived DC precursors. Recent data show, however, that well-differentiated DCs proliferate in situ in various tissues. This may also contribute to their allergen-induced expansion; therefore, we studied DC proliferation in the airways of mice in the steady state and after local aeroallergen provocation. Confocal whole-mount microscopy was used to visualize proliferating DCs in different microanatomical compartments of the lung. We demonstrate that in the steady state, CD11c(+)MHC II(+) DCs proliferate in both the epithelial and subepithelial layers of the airway mucosa as well as in the lung parenchyma. A 1-h pulse of the nucleotide 5-ethynyl-2'-deoxyuridine was sufficient to label 5% of DCs in both layers of the airway mucosa. On the level of whole-lung tissue, 3-5% of both CD11b(+) and CD11b(-) DC populations and 0.3% of CD11c(+)MHC II(low) lung macrophages incorporated 5-ethynyl-2'-deoxyuridine. Aeroallergen provocation caused a 3-fold increase in the frequency of locally proliferating DCs in the airway mucosa. This increase in mucosal DC proliferation was later followed by an elevation in the number of DCs. The recruitment of monocyte-derived inflammatory DCs contributed to the increasing number of DCs in the lung parenchyma, but not in the airway mucosa. We conclude that local proliferation significantly contributes to airway DC homeostasis in the steady state and that it is the major mechanism underlying the expansion of the mucosal epithelial/subepithelial DC network in allergic inflammation.

Neuropeptides control the dynamic behavior of airway mucosal dendritic cells.

The airway mucosal epithelium is permanently exposed to airborne particles. A network of immune cells patrols at this interface to the environment. The interplay of immune cells is orchestrated by different mediators. In the current study we investigated the impact of neuronal signals on key functions of dendritic cells (DC). Using two-photon microscopic time-lapse analysis of living lung sections from CD11c-EYFP transgenic mice we studied the influence of neuropeptides on airway DC motility. Additionally, using a confocal microscopic approach, the phagocytotic capacity of CD11c(+) cells after neuropeptide stimulation was determined. Electrical field stimulation (EFS) leads to an unspecific release of neuropeptides from nerves. After EFS and treatment with the neuropeptides vasoactive intestinal peptide (VIP) or calcitonin gene-related peptide (CGRP), airway DC in living lung slices showed an altered motility. Furthermore, the EFS-mediated effect could partially be blocked by pre-treatment with the receptor antagonist CGRP(8-37). Additionally, the phagocytotic capacity of bone marrow-derived and whole lung CD11c(+) cells could be inhibited by neuropeptides CGRP, VIP, and Substance P. We then cross-linked these data with the in vivo situation by analyzing DC motility in two different OVA asthma models. Both in the acute and prolonged OVA asthma model altered neuropeptide amounts and DC motility in the airways could be measured. In summary, our data suggest that neuropeptides modulate key features motility and phagocytosis of mouse airway DC. Therefore altered neuropeptide levels in airways during allergic inflammation have impact on regulation of airway immune mechanisms and therefore might contribute to the pathophysiology of asthma.

Spatiotemporal and functional behavior of airway dendritic cells visualized by two-photon microscopy.

Airway mucosal dendritic cells (DCs), located beneath the epithelium of the conducting airways, are believed to be specialized for immunosurveillance via sampling of antigens from the airway luminal surface. However, the dynamics of airway DC activity has not yet been visualized. We used two-photon microscopy to illuminate the endogenous mucosal DC network in the airways of mice. To characterize DC behavior, we used lung section preparations and an intravital microscopic approach. DCs displayed a heterogeneous movement pattern according to their localization within the airway mucosa: sessile intraepithelial DCs with a dendritiform shape exhibited active probing movements and occasionally formed transepithelial extensions into the airway lumen. In contrast, DCs within the deeper layers of the mucosal tissue migrated fast in an amoeboid manner, without probing movements, and slowed down after aeroallergen challenge. Strikingly, neither of these two mucosal DC populations ingested fluorescently labeled antigens after antigen administration to the airways in the steady state, in contrast to alveolar macrophage/DC populations in the lung periphery. Our results provide a first description of the dynamic behavior of airway mucosal DCs, with their exact role in antigen sampling remaining unclear.

Dendritic cell-nerve clusters are sites of T cell proliferation in allergic airway inflammation.

Interactions between T cells and dendritic cells in the airway mucosa precede secondary immune responses to inhaled antigen. The purpose of this study was to identify the anatomical locations where dendritic cell-T cell interactions occur, resulting in T cells activation by dendritic cells. In a mouse model of allergic airway inflammation, we applied whole-mount immunohistology and confocal microscopy to visualize dendritic cells and T cells together with nerves, epithelium, and smooth muscle in three dimensions. Proliferating T cells were identified by the detection of the incorporation of the nucleotide analogue 5-ethynyl-2'-deoxyuridine into the DNA. We developed a novel quantification method that enabled the accurate determination of cell-cell contacts in a semi-automated fashion. Dendritic cell-T cell interactions occurred beneath the smooth muscle layer, but not in the epithelium. Approximately 10% of the dendritic cells were contacted by nerves, and up to 4% of T cells formed clusters with these dendritic cells. T cells that were clustered with nerve-contacting dendritic cells proliferated only in the airways of mice with allergic inflammation but not in the airways of negative controls. Taken together, these results suggest that during the secondary immune response, sensory nerves influence dendritic cell-driven T cell activation in the airway mucosa.

Neuroimmune crosstalk in asthma: dual role of the neurotrophin receptor p75NTR.

BACKGROUND: Neurotrophins have been implicated in the pathogenesis of asthma because of their ability to induce airway inflammation and to promote hyperreactivity of sensory neurons, which reflects an important mechanism in the pathogenesis of airway hyperreactivity. Neurotrophins use a dual-receptor system consisting of Trk-receptor tyrosine kinases and the structurally unrelated p75NTR. Previous studies revealed an important role of p75NTR in the pathogenesis of allergic asthma. OBJECTIVES: The aim of the study was to investigate the precise mechanisms of neurotrophins in neuroimmune interaction, which can lead to both airway inflammation and sensory nerve hyperreactivity in vivo. METHODS: Mice selectively expressing p75NTR in immune cells or nerves, respectively, were generated. After sensitization and allergen provocation, hyperreactivity of sensory nerves was tested in response to capsaicin. Airway inflammation was analyzed on the basis of differential cell counts and cytokine levels in bronchoalveolar lavage fluids. RESULTS: Allergic mice selectively expressing p75NTR in immune cells showed normal inflammation but no sensory nerve hyperreactivity, whereas mice selectively expressing p75NTR in nerve cells had a diminished inflammation and a distinct sensory nerve hyperreactivity. CONCLUSION: Our data indicate that p75NTR plays a dual role by promoting hyperreactivity of sensory nerves and airway inflammation. Additionally, our study provides experimental evidence that development of sensory nerve hyperreactivity depends on an established airway inflammation in asthma. In contrast, development of airway inflammation seems to be independent from sensory nerve hyperreactivity. CLINICAL IMPLICATIONS: Because of its dual function, antagonization of p75NTR-mediated signals might be a novel approach in asthma therapy.

Pulmonary distribution, regulation, and functional role of Trk receptors in a murine model of asthma.

BACKGROUND: Neurotrophins have been implicated in the pathogenesis of asthma because of their ability to promote hyperreactivity of sensory neurons and to induce airway inflammation. Hyperreactivity of sensory nerves is one key mechanism of airway hyperreactivity that is defined as an abnormal reactivity of the airways to unspecific stimuli, such as cold air and cigarette smoke. Neurotrophins use a dual-receptor system consisting of Trk receptor tyrosine kinases and the structurally unrelated p75 neurotrophin receptor. OBJECTIVE: The aim of this study was to characterize the distribution, allergen-dependent regulation, and functional relevance of the Trk receptors in allergic asthma. METHODS: BALB/c mice were sensitized to ovalbumin. After provocation with ovalbumin or vehicle aerosol, respectively, Trk receptor expression was analyzed in lung tissue by means of fluorescence microscopy and quantitative RT-PCR. To assess the functional relevance of Trk receptors in asthma, we tested the effects of the intranasally administered pan-Trk receptor decoy REN1826. Allergic airway inflammation was quantified and lung function was measured by using head-out body plethysmography. RESULTS: Trk receptors were expressed in neurons, airway smooth muscle cells, and cells of the inflammatory infiltrate surrounding the bronchi and upregulated after allergen challenge. Local application of REN1826 reduced IL-4 and IL-5 cytokine levels but had no effect on IL-13 levels or the cellular composition of bronchoalveolar lavage fluid cells. Furthermore, REN1826 decreased broncho-obstruction in response to sensory stimuli, indicating a diminished hyperreactivity of sensory nerves, but did not influence airway smooth muscle hyperreactivity in response to methacholine. CONCLUSION: These results emphasize the important role of Trk receptor signaling in the development of asthma. CLINICAL IMPLICATIONS: Our data indicate that blocking of Trk receptor signaling might reduce asthma symptoms.