Publications

IL-12 modulates T cell responses between helper T cells Th2 and Th1; however, the therapeutic potential of IL-12 for allergic diseases either directly or as an adjuvant in allergen therapy has been controversial. The role of intranasal IL-12 as an adjuvant in modulating the grass pollen allergen (GAL) therapy-induced systemic immune response and lung-specific inflammation and airway reactivity was examined in this study using a mouse model of established allergic asthma. The effects of intranasal or nebulized IL-12 with or without intranasal anti-IFN-gamma antibody were examined in groups of control and allergen-sensitized or -challenged mice. T cell cytokine patterns, antibody response profiles, pulmonary inflammation and airway reactivity were examined. Intranasal IL-12 was found to be more effective in the Th2-Th1 shifting of immune response and anti-inflammatory activity in the lung compared to nebulized IL-12 at the given doses. Intranasal IL-12 significantly decreased production of IFN-gamma, eotaxin and LTC4/D4/E4 in the lung and decreased eosinophil infiltration, resulting in attenuated airway hyper-responsiveness in GAL-sensitized (GS) mice. In contrast, intranasal IL-12 significantly increased IFN-gamma production in the thoracic lymph node cultures and decreased the IL-5/IFN-gamma ratio, suggesting a Th2-Th1 shift. Also, intranasal IL-12 increased GAL-specific IgG2a antibody response, while the IgE response remained unaffected. The systemic effects of IL-12 were IFN-gamma dependent. IL-12 induces differential expression of its own receptor beta1 and beta2 subunits in the lung tissues to augment IL-12 responsiveness. Together, these results demonstrate that intranasal IL-12 is effective in shifting the systemic immune response in the direction of Th1 in IFN-gamma-dependent manner, while decreasing pulmonary inflammation and airway reactivity independent of IFN-gamma. Thus, intranasal delivery of IL-12 may provide an approach for the treatment of asthma and may be useful as an adjuvant in local nasal immunotherapy (IT) and in asthma.

A number of approaches have been used in attempts to develop a safe and effective vaccine for respiratory syncytial virus (RSV) infection. This article describes an effective prophylactic intranasal gene transfer strategy utilizing chitosan-DNA nanospheres [the mucosal gene expression vaccine (MGXV)], containing a mixture of plasmid DNAs encoding RSV antigens. In a mouse model of RSV infection, a single administration of MGXV (25 microg/mouse) results in a significant reduction of viral titers and viral antigen load after acute RSV infection of these mice. MGXV-treated mice show no significant change in airway reactivity to methacholine and no apparent pulmonary inflammation. Together these results demonstrate the potential of MGXV against acute RSV infection.

Acute respiratory syncytial virus (RSV) infection causes airway inflammation and exacerbates asthma, but the mechanism of inflammation is poorly understood. The role of the STAT-signaling pathway in RSV infection in epithelial cells was examined in this study. DNA microarray analyses of RSV-infected human alveolar type II (A549) epithelial cells identified several genes whose expression was altered from -5.5 to +56.4-fold. Four of the highly expressed genes contained STAT-binding elements. In A549 and normal human bronchial epithelial cells (NHBE), RSV induced phosphorylation and nuclear translocation of STAT-1alpha that was abrogated when RSV attachment was blocked. Treatment with a JAK-2 inhibitor or transfection with dominant-negative STAT-1alpha blocked STAT-1alpha activation and RSV infection. RSV also activated STAT-3 and IL-6 specific antibodies blocked this activation. Thus, activation of the STAT-1alpha and STAT-3 pathways play a role in RSV infection.

BACKGROUND: The mechanisms underlying epithelial cell activation by indoor inhaled antigens are poorly understood. METHODS: In this study, we investigated the role of mitogen-activated protein kinases (MAPKs) in A549 epithelial cells upon exposure to antigens of house dust mite (HDMA), German cockroach (GCA), and American cockroach (ACA). RESULTS: Each of these antigens induced a significant increase in IL-8 levels compared to the medium control. Exposure of A549 cells to these antigens induced the phosphorylation of p44/42 MAPKs within 5 minutes, which reached a peak at 25 minutes later and reached baseline levels at 1 hour after exposure. PD98059, a MEK1 inhibitor, significantly decreased phosphorylation of p44/p42 MAPKs and IL-8 production. Exposure of A549 cells with antigens, which had been preincubated with different protease inhibitors, also resulted in a reduction of both MAPK phosphorylation and IL-8 production. CONCLUSION: Thus, proteolytic antigens present in HDMA, GCA and ACA activate the p44/42 MAPKs airway epithelial cells, which lead to elevated IL-8 production and initiation of the inflammatory cascade.

BACKGROUND: Allergic subjects produce relatively low amounts of IFN-gamma, a pleiotropic Th-1 cytokine that downregulates Th2-associated airway inflammation and hyperresponsiveness (AHR), the hallmarks of allergic asthma. Adenovirus-mediated IFN-gamma gene transfer reduces AHR, Th2 cytokine levels and lung inflammation in mice, but its use would be limited by the frequency of gene delivery required; therefore, we tested chitosan/IFN-gamma pDNA nanoparticles (CIN) for in situ production of IFN-gamma and its in vivo effects. METHODS: CIN were administered to OVA-sensitized mice to investigate the possibility of using gene transfer to modulate ovalbumin (OVA)-induced inflammation and AHR. RESULTS: Mice treated with CIN exhibit significantly lower AHR to methacholine challenge and less lung histopathology. Production of IFN-gamma is increased after CIN treatment while the Th2-cytokines, IL-4 and IL-5, and OVA-specific serum IgE are reduced compared to control mice. AHR and eosinophilia are also significantly reduced by CIN therapy administered therapeutically in mice with established asthma. CIN was found to inhibit epithelial inflammation within 6 hours of delivery by inducing apoptosis of goblet cells. Experiments performed on STAT4-defective mice do not show reduction in AHR with CIN treatment, thus implicating STAT4 signaling in the mechanism of CIN action. CONCLUSION: These results demonstrate that mucosal CIN therapy can effectively reduce established allergen-induced airway inflammation and AHR.

Atrial natriuretic peptide (ANP) is a bronchodilator; however, the short half-life of ANP in vivo limited its therapeutic utility to treat asthma. The efficacy of intranasally administered plasmid DNA-expressing ANP (pANP; amino acid 99-126; Acc. No. XM131840) on the prevention of allergen-induced airway hyperresponsiveness (AHR) was examined in this study by using a mouse model of asthma. Ovalbumin-sensitized mice were treated with pANP versus control plasmids, and AHR was monitored after ovalbumin challenge for 5 weeks on 10-day intervals starting 4 days after gene transfer. Mice administered pANP demonstrated significantly less AHR for 20 days after treatment. The results demonstrate that pANP gene transfer protects against AHR and might be useful in the treatment of asthma.

Allergic asthma is associated with airway inflammation and hyperresponsiveness caused by the dysregulated production of cytokines secreted by allergen-specific helper T type 2 (Th2) cells. Allergic subjects produce relatively low amounts of interferon gamma (IFN-gamma), a pleiotropic Th1 cytokine that downregulates Th2-associated responses. In this study, we examined the possibility of modulating ovalbumin (OVA)-induced inflammation and airway hyperreactivity (AHR) by recombinant adenovirus-mediated IFN-gamma (Ad-IFN-gamma) gene transfer. OVA-sensitized mice treated with Ad-IFN-gamma exhibit significantly lower levels of Th2 cytokines interleukin 4 (IL-4) and IL-5, OVA-specific serum IgE, lung eosinophilia, and AHR in response to methacholine challenge compared with control mice. The lung sections of the treated mice show less epithelial damage, mucous plugging, and eosinophil infiltration than controls. In contrast, Ad-IFN-gamma-treated mice express significantly higher levels of IFN-gamma and IL-12 when compared with controls. Moreover, administration of Ad-IFN-gamma to mice with established AHR significantly reduced AHR, Th2 cytokines, and lung inflammation. The IFN-gamma effects were dependent on IL-12 and STAT4 (signal transducer and activator of transcription 4), as mice treated with antibodies to IL-12 and STAT4 deficient mice show attenuated Ad-IFN-gamma responses. Thus, these results demonstrate that mucosal Ad-IFN-gamma gene transfer can effectively attenuate established allergen-induced airway inflammation and AHR, predominantly through an IL-12- and STAT4-dependent mechanism.