Isabel Mandeville scite author profile

The involvement of genes controlling embryonic processes in the etiology of diseases often escapes attention because of the focus given to their inherent developmental role. Hoxa5 belongs to the Hox gene family encoding transcription factors known for their role in skeletal patterning. Hoxa5 is required for embryonic respiratory tract morphogenesis. We now show that the loss of Hoxa5 function has severe repercussions on postnatal lung development. Hoxa5؊/؊ lungs present an emphysema-like morphology because of impaired alveogenesis. Chronic inflammation characteristics, including goblet cell hyperplasia, mucus hypersecretion, and recruitment of inflammatory cells, were also observed. Altered cell specification during lung morphogenesis triggered goblet cell anomalies. In addition, the defective motility of alveolar myofibroblast precursors in the embryonic lung led to the mispositioning of the alveolar myofibroblasts and to abnormal elastin deposition postnatally. Both goblet cell hyperplasia and elastic fiber abnormalities contributed to the chronic physiopathological features of Hoxa5 ؊/؊ lungs. They constituted an attractive stimulus to recruit activated macrophages that in turn generated a positive feedback loop that perpetuated macrophage accumulation in the lung. The present work corroborates the notion that altered Hox gene expression may predispose to lung pathologies. Lung morphogenesis relies on finely orchestrated processes that initiate from the outpocketing and the elongation of the foregut endoderm into the surrounding mesenchyme. The lung bud then branches extensively giving rise to saccules that expend and subdivide to ultimately produce alveoli. In the mouse, the main stem bronchi form at approximately embryonic day (E) 9.5, and ramification organized by signaling centers shapes the respiratory tree during the pseudoglandular period that extends from E14.0 to E16.5. At late gestational stages, saccules are found at the end of each terminus of the pulmonary tree. The last step of lung morphogenesis occurs between postnatal day (P) 5 and P30, and it aims at multiplying the respiratory surface for vital gas exchanges after birth by modifying the distal lung architecture through the process of alveogenesis. During each step of lung development, the concerted action of transcriptional regulators, signaling molecules, their associated receptors and downstream effectors governs branching morphogenesis and lung maturation by integrating cellular proliferation, differentiation, apoptosis, and migration.

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Inflammatory cytokines, goblet cell hyperplasia and altered lung mechanics in Lgl1 +/- mice

Lan

Ribeiro

Mandeville

et al. 2009

Respir Res

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BackgroundNeonatal lung injury, a leading cause of morbidity in prematurely born infants, has been associated with arrested alveolar development and is often accompanied by goblet cell hyperplasia. Genes that regulate alveolarization and inflammation are likely to contribute to susceptibility to neonatal lung injury. We previously cloned Lgl1, a developmentally regulated secreted glycoprotein in the lung. In rat, O2 toxicity caused reduced levels of Lgl1, which normalized during recovery. We report here on the generation of an Lgl1 knockout mouse in order to determine whether deficiency of Lgl1 is associated with arrested alveolarization and contributes to neonatal lung injury.MethodsAn Lgl1 knockout mouse was generated by introduction of a neomycin cassette in exon 2 of the Lgl1 gene. To evaluate the pulmonary phenotype of Lgl1+/- mice, we assessed lung morphology, Lgl1 RNA and protein, elastin fibers and lung function. We also analyzed tracheal goblet cells, and expression of mucin, interleukin (IL)-4 and IL-13 as markers of inflammation.ResultsAbsence of Lgl1 was lethal prior to lung formation. Postnatal Lgl1+/- lungs displayed delayed histological maturation, goblet cell hyperplasia, fragmented elastin fibers, and elevated expression of TH2 cytokines (IL-4 and IL-13). At one month of age, reduced expression of Lgl1 was associated with elevated tropoelastin expression and altered pulmonary mechanics.ConclusionOur findings confirm that Lgl1 is essential for viability and is required for developmental processes that precede lung formation. Lgl1+/- mice display a complex phenotype characterized by delayed histological maturation, features of inflammation in the post-natal period and altered lung mechanics at maturity. Lgl1 haploinsufficiency may contribute to lung disease in prematurity and to increased risk for late-onset respiratory disease.

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Respiratory Adaptations to Lung Morphological Defects in Adult Mice Lacking Hoxa5 Gene Function

et al. 2004

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