Barrier Housing and Gender Effects on Allergic Airway Disease in a Murine House Dust Mite Model.

Allergic airway disease models use laboratory mice housed in highly controlled and hygienic environments, which provide a barrier between the mice and a predetermined list of specific pathogens excluded from the facility. In this study, we hypothesized that differences in facility barrier level and, consequently, the hygienic quality of the environment that mice inhabit impact the severity of pulmonary inflammation and lung function. Allergen-naive animals housed in the cleaner, high barrier (HB) specific pathogen-free facility had increased levels of inflammatory cytokines and higher infiltration of immune cells in the lung tissue but not in the bronchoalveolar lavage compared with mice housed in the less hygienic, low barrier specific pathogen-free facility. In both genders, house dust mite-induced airway disease was more severe in the HB than the low barrier facility. Within each barrier facility, female mice developed the most severe inflammation. However, allergen-naive male mice had worse lung function, regardless of the housing environment, and in the HB, the lung function in female mice was higher in the house dust mite model. Severe disease in the HB was associated with reduced lung microbiome diversity. The lung microbiome was altered across housing barriers, gender, and allergen-exposed groups. Thus, the housing barrier level impacts microbial-driven disease and gender phenotypes in allergic asthma. The housing of laboratory mice in more clean HB facilities aggravates lung immunity and causes a more severe allergic lung disease.

Dystroglycan on radial glia end feet is required for pial basement membrane integrity and columnar organization of the developing cerebral cortex.

Interactions between the embryonic pial basement membrane (PBM) and radial glia (RG) are essential for morphogenesis of the cerebral cortex because disrupted interactions cause cobblestone malformations. To elucidate the role of dystroglycan (DG) in PBM-RG interactions, we studied the expression of DG protein and Dag1 mRNA (which encodes DG protein) in developing cerebral cortex and analyzed cortical phenotypes in Dag1 CNS conditional mutant mice. In normal embryonic cortex, Dag1 mRNA was expressed in the ventricular zone, which contains RG nuclei, whereas DG protein was expressed at the cortical surface on RG end feet. Breaches of PBM continuity appeared during early neurogenesis in Dag1 mutants. Diverse cellular elements streamed through the breaches to form leptomeningeal heterotopia that were confluent with the underlying residual cortical plate and contained variably truncated RG fibers, many types of cortical neurons, and radial and intermediate progenitor cells. Nevertheless, layer-specific molecular expression seemed normal in heterotopic neurons, and axons projected to appropriate targets. Dendrites, however, were excessively tortuous and lacked radial orientation. These findings indicate that DG is required on RG end feet to maintain PBM integrity and suggest that cobblestone malformations involve disturbances of RG structure, progenitor distribution, and dendrite orientation, in addition to neuronal "overmigration."