Th2 but not Th1 immune bias results in altered lung functions in a murine model of pulmonary Cryptococcus neoformans infection.

Changes in airway dynamics have been reported in the rat model of pulmonary cryptococcosis. However, it is not known if Cryptococcus neoformans-induced changes in lung functions are related to the immunophenotype that develops in response to cryptococcal infection in the lungs. In this study we performed a parallel analysis of the immunophenotype and airway resistance (standard resistance of the airways [SRAW]) in BALB/c mice infected with highly virulent C. neoformans strain H99 and moderately virulent strain 52D. H99 infection evoked a Th2 response and was associated with increased SRAW, while the SRAW for 52D infection, which resulted in a predominantly Th1-skewed response, did not differ from the SRAW for uninfected mice. We found that an altered SRAW in mice did not positively or negatively correlate with the pulmonary fungal burden, the magnitude of inflammatory response, the numbers of T cells, eosinophils or eosinophil subsets, neutrophils, or monocytes/macrophages, or the levels of cytokines (interleukin-4 [IL-4], IL-10, gamma interferon, or IL-13) produced by lung leukocytes. However, the level of a systemic Th2 marker, serum immunoglobulin E (IgE), correlated significantly with SRAW, indicating that the changes in lung functions were proportional to the level of Th2 skewing in this model. These data also imply that IgE may contribute to the altered SRAW observed in H99-infected mice. Lung histological analysis revealed severe allergic bronchopulmonary mycosis pathology in H99-infected mice and evidence of protective responses in 52D-infected mice with well-marginalized lesions. Taken together, the data show that C. neoformans can significantly affect airflow physiology, particularly in the context of a Th2 immune response with possible involvement of IgE as an important factor.

Pneumocystis murina infection and cigarette smoke exposure interact to cause increased organism burden, development of airspace enlargement, and pulmonary inflammation in mice.

Chronic obstructive pulmonary disease (COPD) is characterized by the presence of airflow obstruction and lung destruction with airspace enlargement. In addition to cigarette smoking, respiratory pathogens play a role in pathogenesis, but specific organisms are not always identified. Recent reports demonstrate associations between the detection of Pneumocystis jirovecii DNA in lung specimens or respiratory secretions and the presence of emphysema in COPD patients. Additionally, human immunodeficiency virus-infected individuals who smoke cigarettes develop early emphysema, but a role for P. jirovecii in pathogenesis remains speculative. We developed a new experimental model using immunocompetent mice to test the interaction of cigarette smoke exposure and environmentally acquired Pneumocystis murina infection in vivo. We hypothesized that cigarette smoke and P. murina would interact to cause increases in total lung capacity, airspace enlargement, and pulmonary inflammation. We found that exposure to cigarette smoke significantly increases the lung organism burden of P. murina. Pulmonary infection with P. murina, combined with cigarette smoke exposure, results in changes in pulmonary function and airspace enlargement characteristic of pulmonary emphysema. P. murina and cigarette smoke exposure interact to cause increased lung inflammatory cell accumulation. These findings establish a novel animal model system to explore the role of Pneumocystis species in the pathogenesis of COPD.