An activated form of beta-catenin [Catnb(Delta(ex3))] was expressed in respiratory epithelial cells of the developing lung. Although morphogenesis was not altered at birth, air space enlargement and epithelial cell dysplasia were observed in the early postnatal period and persisted into adulthood. The Catnb(Delta(ex3)) protein caused squamous, cuboidal, and goblet cell dysplasia in intrapulmonary conducting airways. Atypical epithelial cells that stained for surfactant pro protein C (pro-SP-C) and had morphological characteristics of alveolar type II cells were observed in bronchioles of the transgenic mice. Catnb(Delta(ex3)) inhibited expression of Foxa2 and caused goblet cell hyperplasia associated with increased staining for mucins and the MUC5A/C protein. In vitro, both wild type and activated beta-catenin negatively regulated the expression of the Foxa2 promoter. Catnb(Delta(ex3)) also caused pulmonary tumors in adult mice. Activation of beta-catenin caused ectopic differentiation of alveolar type II-like cells in conducting airways, goblet cell hyperplasia, and air space enlargement, demonstrating a critical role for the Wnt/beta-catenin signal transduction pathway in the differentiation of the respiratory epithelium in the postnatal lung.
Following injury, bronchiolar cells undergo rapid squamous metaplasia, followed by proliferation and re-establishment of the complex columnar epithelium that is characteristic of the normal airway. Mechanisms that regulate the repair of bronchiolar epithelium are of considerable relevance for understanding the pathogenesis of both acute and chronic lung diseases associated with airway remodeling. This study was designed to identify the role of the GP130-STAT3 signaling pathway during repair of the bronchiolar epithelium. STAT3 ( The respiratory epithelium is recurrently subject to injury by pathogens, particles, and toxicants. Following extensive bronchiolar injury, remaining cells undergo squamous metaplasia to maintain the epithelial barrier. Thereafter, epithelial cell proliferation and differentiation restore the normal populations of ciliated and nonciliated cells lining the bronchioles. Since acute and chronic airway injuries are associated with many pulmonary diseases, the mechanisms and cellular processes regulating repair of the respiratory epithelium are of considerable interest. Repair of the bronchiolar epithelium has been studied using various agents to cause epithelial cell injury, including naphthalene, respiratory pathogens, and inhaled toxicants (see review 1 ). Naphthalene has been used to selectively kill nonciliated bronchiolar cells in the mouse lung in vivo.2-4 Within 24 hours after naphthalene exposure, Clara cells are sloughed from the bronchiolar surface. Remaining cells, consisting primarily of ciliated cells and nonciliated, naphthalene-resistant cells, undergo squamous metaplasia and spread to maintain the epithelial lining. Dynamic changes in cell shape are accompanied by the expression of a number of transcription factors and cellular markers that are also associated with the differentiation of respiratory epithelial cells during
Tumor suppressor phosphatase and tensin homolog deleted on chromosome 10 (PTEN) is a lipid phosphatase that regulates multiple cellular processes including cell polarity, migration, proliferation, and carcinogenesis. In this work, we demonstrate that conditional deletion of Pten (Pten D/D ) in the respiratory epithelial cells of the developing mouse lung caused epithelial cell proliferation and hyperplasia as early as 4 to 6 weeks of age. While bronchiolar cell differentiation was normal, as indicated by b-tubulin and FOXJ1 expression in ciliated cells and by CCSP expression in nonciliated cells, cell proliferation (detected by expression of Ki-67, phospho-histone-H3, and cyclin D1) was increased and associated with activation of the AKT/mTOR survival pathway. Deletion of Pten caused papillary epithelial hyperplasia characterized by a hypercellular epithelium lining papillae with fibrovascular cores that protruded into the airway lumens. Cell polarity, as assessed by subcellular localization of cadherin, b-catenin, and zonula occludens-1, was unaltered. PTEN is required for regulation of epithelial cell proliferation in the lung and for the maintenance of the normal simple columnar epithelium characteristics of bronchi and bronchioles.
Based on the role of retinoblastoma (Rb) in lens development and in the cell cycle reentry of muscle cells during limb regeneration, we have analyzed expression or Rb patterns in intact and lens regeneration-undergoing newt eyes. We find that in intact newt eye Rb is expressed in the retina as a gradient with higher levels in the photoreceptor layer and virtually no expression in the ganglion layer. In addition, a second gradient was detected within the photoreceptor layer with expression diminishing at the dorsal and ventral regions. In the intact lens, Rb is expressed in the lens epithelium and in the differentiating lens fibers at the bow region. During lens regeneration, Rb is expressed very strongly in the differentiating lens fibers, but not in the lens epithelium. Using an antibody specific to the hyperphosphorylated form of Rb, we detected the inactive protein only in the pigment epithelial cells of the iris. These distinct patterns might be related to the regenerative potential of the lens in the newt. Anat Rec Part
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