Airway hyperresponsiveness (AHR), goblet cell metaplasia, and mucus overproduction are important features of bronchial asthma. To elucidate the molecular mechanisms behind these pulmonary pathologies, we examined for genes preferentially expressed in the lungs of a murine model of allergic asthma by using suppression subtractive hybridization (SSH). We identified a gene called gob-5 that had a selective expression pattern in the airway epithelium with AHR. Here, we show that gob-5, a member of the calcium-activated chloride channel family, is a key molecule in the induction of murine asthma. Intratracheal administration of adenovirus-expressing antisense gob-5 RNA into AHR-model mice efficiently suppressed the asthma phenotype, including AHR and mucus overproduction. In contrast, overexpression of gob-5 in airway epithelia by using an adenoviral vector exacerbated the asthma phenotype. Introduction of either gob-5 or hCLCA1, the human counterpart of gob-5, into the human mucoepidermoid cell line NCI-H292 induced mucus production as well as MUC5AC expression. Our results indicated that gob-5 may play a critical role in murine asthma, and its human counterpart hCLCA1 is therefore a potential target for asthma therapy.
p53R2, which is regulated by tumor suppressor p53, is a small subunit of ribonucleotide reductase. To determine whether it is involved in DNA repair by supplying deoxyribonucleotides (dNTPs) for resting cells in vivo, we generated a strain of mice lacking Rrm2b (encoding p53R2). These mice developed normally until they were weaned but from then on had growth retardation and early mortality. Pathological examination indicated that multiple organs had failed, and all Rrm2b-null mice died from severe renal failure by the age of 14 weeks. TUNEL staining showed a greater number of apoptotic cells in kidneys of 8-week-old Rrm2b-/- mice relative to wild-type mice. p53 was activated in kidney tissues of Rrm2b-/- mice, leading to transcriptional induction of p53 target genes. Rrm2b-/- mouse embryonic fibroblasts (MEFs) became immortal much earlier than Rrm2b+/+ MEFs. dNTP pools were severely attenuated in Rrm2b-/- MEFs under oxidative stress. Rrm2b deficiency caused higher rates of spontaneous mutation in the kidneys of Rrm2b-/- mice. Our results suggest that p53R2 has a pivotal role in maintaining dNTP levels for repair of DNA in resting cells. Impairment of this pathway may enhance spontaneous mutation frequency and activate p53-dependent apoptotic pathway(s) in vivo, causing severe renal failure, growth retardation and early mortality.
Mucus overproduction is a clinical feature of asthma. Ca2+-activated Cl- channel 1 (CaCC1) has been identified as a protein that is expressed in intestinal epithelia and that plays an important role in fluid and electrolyte transport. Recently, its mouse counterpart, gob-5, was identified as a key molecule in the induction of murine asthma through mucus overproduction. To elucidate the relationship of CaCC1 to human asthma, we examined CaCC1 expression using real-time quantitative polymerase chain reaction analysis in bronchial tissues from patients with asthma and normal control subjects. The expression of CaCC1 was significantly upregulated in patients with bronchial asthma compared with control subjects. In situ hybridization and immunohistochemical analysis demonstrated that CaCC1 is located in the bronchial epithelium, especially in mucus-producing goblet cells. In vitro transfection of a CaCC1 expression vector into the human mucoepidermoid cell line, NCI-H292, increased mucus production and induced the MUC5AC gene. These results suggest that CaCC1 plays a direct role in mucus production and differentiation in goblet cells and may contribute to the pathogenesis of asthma through its mucus-inducing activity.
Airway hyperresponsiveness (AHR) is an important feature of bronchial asthma. Although the incidence of AHR has genetic and environmental components, the mechanism of AHR in asthma remains unclear. The identification of genes that are preferentially expressed in a murine model of AHR could help elucidate the molecular mechanisms of this pulmonary pathology. Suppressive subtractive hybridization analysis revealed that eosinophil chemotactic factor by T lymphocytes (ECF-L), a mouse chitinase family protein, was selectively expressed in the lungs of mice with AHR. Induction of ECF-L expression was observed soon after allergen exposure but before the onset of airway inflammation. Cell-specific ECF-L expression was examined by in situ hybridization using digoxigenin-labeled antisense RNA probes and immunofluorescence staining. The assay revealed that the ECF-L-expressing cells in the lungs of the AHR-model mice are alveolar macrophages. Intratracheal administration of an adenoviral vector that expressed antisense ECF-L RNA (Ad-ECF-L-AS) suppressed AHR and eosinophil infiltration. These results indicate that ECF-L may play a critical role in allergic inflammation and bronchial asthma.
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