The Fgf9-Nolz1-Wnt2 axis regulates morphogenesis of the lung.

Morphological development of the lung requires complex signal crosstalk between the mesenchymal and epithelial progenitors. Elucidating the genetic cascades underlying signal crosstalk is essential to understanding lung morphogenesis. Here, we identified Nolz1 as a mesenchymal lineage-specific transcriptional regulator that plays a key role in lung morphogenesis. Nolz1 null mutation resulted in a severe hypoplasia phenotype, including a decreased proliferation of mesenchymal cells, aberrant differentiation of epithelial cells and defective growth of epithelial branches. Nolz1 deletion also downregulated Wnt2, Lef1, Fgf10, Gli3 and Bmp4 mRNAs. Mechanistically, Nolz1 regulates lung morphogenesis primarily through Wnt2 signaling. Loss-of-function and overexpression studies demonstrated that Nolz1 transcriptionally activated Wnt2 and downstream ß-catenin signaling to control mesenchymal cell proliferation and epithelial branching. Exogenous Wnt2 could rescue defective proliferation and epithelial branching in Nolz1 knockout lungs. Finally, we identified Fgf9 as an upstream regulator of Nolz1. Collectively, Fgf9-Nolz1-Wnt2 signaling represents a novel axis in the control of lung morphogenesis. These findings are relevant to lung tumorigenesis, in which a pathological function of Nolz1 is implicated.

Potential interactions between the TBX4-FGF10 and SHH-FOXF1 signaling during human lung development revealed using ChIP-seq.

BACKGROUND: The epithelial-mesenchymal signaling involving SHH-FOXF1, TBX4-FGF10, and TBX2 pathways is an essential transcriptional network operating during early lung organogenesis. However, precise regulatory interactions between different genes and proteins in this pathway are incompletely understood. METHODS: To identify TBX2 and TBX4 genome-wide binding sites, we performed chromatin immunoprecipitation followed by next-generation sequencing (ChIP-seq) in human fetal lung fibroblasts IMR-90. RESULTS: We identified 14,322 and 1,862 sites strongly-enriched for binding of TBX2 and TBX4, respectively, 43.95% and 18.79% of which are located in the gene promoter regions. Gene Ontology, pathway enrichment, and DNA binding motif analyses revealed a number of overrepresented cues and transcription factor binding motifs relevant for lung branching that can be transcriptionally regulated by TBX2 and/or TBX4. In addition, TBX2 and TBX4 binding sites were found enriched around and within FOXF1 and its antisense long noncoding RNA FENDRR, indicating that the TBX4-FGF10 cascade may directly interact with the SHH-FOXF1 signaling. CONCLUSIONS: We highlight the complexity of transcriptional network driven by TBX2 and TBX4 and show that disruption of this crosstalk during morphogenesis can play a substantial role in etiology of lung developmental disorders.

New insights into small-cell lung cancer development and therapy.

Small-cell lung cancer (SCLC) accounts for approximately 15% of lung cancer cases; however, it is characterized by easy relapse and low survival rate, leading to one of the most intractable diseases in clinical practice. Despite decades of basic and clinical research, little progress has been made in the management of SCLC. The current standard first-line regimens of SCLC still remain to be cisplatin or carboplatin combined with etoposide, and the adverse events of chemotherapy are by no means negligible. Besides, the immunotherapy on SCLC is still in an early stage and novel studies are urgently needed. In this review, we describe SCLC development and current therapy, aiming at providing useful advices on basic research and clinical strategy.

Lung morphogenesis is orchestrated through Grainyhead-like 2 (Grhl2) transcriptional programs.

The highly conserved transcription factor Grainyhead-like 2 (Grhl2) exhibits a dynamic expression pattern in lung epithelium throughout embryonic development. Using a conditional gene targeting approach to delete Grhl2 in the developing lung epithelium, our results demonstrate that Grhl2 plays multiple roles in lung morphogenesis that are essential for respiratory function. Loss of Grhl2 leads to impaired ciliated cell differentiation and perturbed formation of terminal saccules. Critically, a substantial increase in Sox9-positive distal tip progenitor cells was observed following loss of Grhl2, suggesting that Grhl2 plays an important role in branching morphogenesis. Gene transcription profiling of Grhl2-deficient lung epithelial cells revealed a significant down regulation of Elf5, a member of the Ets family of transcription factors. Furthermore, ChIP and comparative genomic analyzes confirmed that Elf5 is a direct transcriptional target of Grhl2. Taken together, these results support the hypothesis that Grhl2 controls normal lung morphogenesis by tightly regulating the activity of distal tip progenitor cells.

Crucial requirement of ERK/MAPK signaling in respiratory tract development.

The mammalian genome contains two ERK/MAP kinase genes, Mek1 and Mek2, which encode dual-specificity kinases responsible for ERK/MAP kinase activation. In order to define the function of the ERK/MAPK pathway in the lung development in mice, we performed tissue-specific deletions of Mek1 function on a Mek2 null background. Inactivation of both Mek genes in mesenchyme resulted in several phenotypes, including giant omphalocele, kyphosis, pulmonary hypoplasia, defective tracheal cartilage and death at birth. The absence of tracheal cartilage rings establishes the crucial role of intracellular signaling molecules in tracheal chondrogenesis and provides a putative mouse model for tracheomalacia. In vitro, the loss of Mek function in lung mesenchyme did not interfere with lung growth and branching, suggesting that both the reduced intrathoracic space due to the dysmorphic rib cage and the omphalocele impaired lung development in vivo. Conversely, Mek mutation in the respiratory epithelium caused lung agenesis, a phenotype resulting from the direct impact of the ERK/MAPK pathway on cell proliferation and survival. No tracheal epithelial cell differentiation occurred and no SOX2-positive progenitor cells were detected in mutants, implying a role for the ERK/MAPK pathway in trachea progenitor cell maintenance and differentiation. Moreover, these anomalies were phenocopied when the Erk1 and Erk2 genes were mutated in airway epithelium. Thus, the ERK/MAPK pathway is required for the integration of mesenchymal and epithelial signals essential for the development of the entire respiratory tract.

Wnt/ß-catenin signaling links embryonic lung development and asthmatic airway remodeling.

Embryonic lung development requires reciprocal endodermal-mesodermal interactions; mediated by various signaling proteins. Wnt/ß-catenin is a signaling protein that exhibits the pivotal role in lung development, injury and repair while aberrant expression of Wnt/ß-catenin signaling leads to asthmatic airway remodeling: characterized by hyperplasia and hypertrophy of airway smooth muscle cells, alveolar and vascular damage goblet cells metaplasia, and deposition of extracellular matrix; resulting in decreased lung compliance and increased airway resistance. The substantial evidence suggests that Wnt/ß-catenin signaling links embryonic lung development and asthmatic airway remodeling. Here, we summarized the recent advances related to the mechanistic role of Wnt/ß-catenin signaling in lung development, consequences of aberrant expression or deletion of Wnt/ß-catenin signaling in expansion and progression of asthmatic airway remodeling, and linking early-impaired pulmonary development and airway remodeling later in life. Finally, we emphasized all possible recent potential therapeutic significance and future prospectives, that are adaptable for therapeutic intervention to treat asthmatic airway remodeling.

PTEN regulates lung endodermal morphogenesis through MEK/ERK pathway.

Pten is a multifunctional tumor suppressor. Deletions and mutations in the Pten gene have been associated with multiple forms of human cancers. Pten is a central regulator of several signaling pathways that influences multiple cellular functions. One such function is in cell motility and migration, although the precise mechanism remains unknown. In this study, we deleted Pten in the embryonic lung epithelium using Gata5-cre mice. Absence of Pten blocked branching morphogenesis and ERK and AKT phosphorylation at E12.5. In an explant model, Pten(Δ/Δ) mesenchyme-free embryonic lung endoderm failed to branch. Inhibition of budding in Pten(Δ/Δ) explants was associated with major changes in cell migration, while cell proliferation was not affected. We further examined the role of ERK and AKT in branching morphogenesis by conditional, endodermal-specific mutants which blocked ERK or AKT phosphorylation. MEK(DM/+); Gata5-cre (blocking of ERK phosphorylation) lung showed more severe phenotype in branching morphogenesis. The inhibition of budding was also associated with disruption of cell migration. Thus, the mechanisms by which Pten is required for early endodermal morphogenesis may involve ERK, but not AKT, mediated cell migration.

Gpr177 regulates pulmonary vasculature development.

Establishment of the functional pulmonary vasculature requires intimate interaction between the epithelium and mesenchyme. Previous genetic studies have led to inconsistent conclusions about the contribution of epithelial Wnts to pulmonary vasculature development. This discrepancy is possibly due to the functional redundancy among different Wnts. Here, we use Shh-Cre to conditionally delete Gpr177 (the mouse ortholog of Drosophila Wntless, Wls), a chaperon protein important for the sorting and secretion of Wnt proteins. Deletion of epithelial Gpr177 reduces Wnt signaling activity in both the epithelium and mesenchyme, resulting in severe hemorrhage and abnormal vasculature, accompanied by branching defects and abnormal epithelial differentiation. We then used multiple mouse models to demonstrate that Wnt/ß-catenin signaling is not only required for the proliferation and differentiation of mesenchyme, but also is important for the maintenance of smooth muscle cells through the regulation of the transcription factor Kruppel-like factor 2 (Klf2). Together, our studies define a novel mechanism by which epithelial Wnts regulate the normal development and maintenance of pulmonary vasculature. These findings provide insight into the pathobiology of congenital lung diseases, such as alveolar capillary dysplasia (ACD), that have abnormal alveolar development and dysmorphic pulmonary vasculature.

Assessment of inhibited alveolar-capillary membrane structural development and function in bronchopulmonary dysplasia.

Bronchopulmonary dysplasia (BPD) is a chronic lung disease of extreme prematurity and is defined clinically by dependence on supplemental oxygen due to impaired gas exchange. Optimal gas exchange is dependent on the development of a sufficient surface area for diffusion. In the mammalian lung, rapid acquisition of distal lung surface area is accomplished in neonatal and early adult life by means of vascularization and secondary septation of distal lung airspaces. Extreme preterm birth interrupts secondary septation and pulmonary capillary development and ultimately reduces the efficiency of the alveolar-capillary membrane. Although pulmonary health in BPD infants rapidly improves over the first few years, persistent alveolar-capillary membrane dysfunction continues into adolescence and adulthood. Preventative therapies have been largely ineffective, and therapies aimed at promoting normal development of the air-blood barrier in infants with established BPD remain largely unexplored. The purpose of this review will be: (1) to summarize the histological evidence of aberrant alveolar-capillary membrane development associated with extreme preterm birth and BPD, (2) to review the clinical evidence assessing the long-term impact of BPD on alveolar-capillary membrane function, and (3) to discuss the need to develop and incorporate direct measurements of functional gas exchange into clinically relevant animal models of inhibited alveolar development.

Disruption of Cdyl gene impairs mouse lung epithelium differentiation and maturation.

CDYL is a chromodomain protein that has been identified as a transcriptional co-repressor that is primarily involved in the formation of repressor complexes which coordinate histone modifications to repress gene transcription. However, most functions and mechanisms of action of the CDYL protein are unknown. In this study, we show that Cdyl-/- mice died of respiratory distress immediately at birth because of distinct abnormalities in distal lung morphogenesis which was characterized by thickened septal and expiratory alveolus atelectasis. Furthermore, Cdyl deletion in mice led to excessive proliferation of immature epithelial cells and an arrest in alveolar epithelium cell differentiation in late gestation which were associated with decreased secretion of mature surfactant proteins in alveolus. Microarray analysis showed that Cdyl gene deletion influenced the expression of genes regulating neuroactive ligand-receptor interactions, cell adhesion, and cell cycle. We validated that Cdyl repressed the transcriptional activity of Cks1 in vitro. In conclusion, Cdyl gene participates in the perinatal respiratory epithelium differentiation and maturation that is important for normal lung function at birth.

The mechanosensitive ion channel TRPV4 is a regulator of lung development and pulmonary vasculature stabilization.

INTRODUCTION ­: Clinical observations and animal models suggest a critical role for the dynamic regulation of transmural pressure and peristaltic airway smooth muscle contractions for proper lung development. However, it is currently unclear how such mechanical signals are transduced into molecular and transcriptional changes at the cell level. To connect these physical findings to a mechanotransduction mechanism, we identified a known mechanosensor, TRPV4, as a component of this pathway. METHODS ­: Embryonic mouse lung explants were cultured on membranes and in submersion culture to modulate explant transmural pressure. Time-lapse imaging was used to capture active changes in lung biology, and whole-mount images were used to visualize the organization of the epithelial, smooth muscle, and vascular compartments. TRPV4 activity was modulated by pharmacological agonism and inhibition. RESULTS ­: TRPV4 expression is present in the murine lung with strong localization to the epithelium and major pulmonary blood vessels. TRPV4 agonism and inhibition resulted in hyper- and hypoplastic airway branching, smooth muscle differentiation, and lung growth, respectively. Smooth muscle contractions also doubled in frequency with agonism and were reduced by 60% with inhibition demonstrating a functional role consistent with levels of smooth muscle differentiation. Activation of TRPV4 increased the vascular capillary density around the distal airways, and inhibition resulted in a near complete loss of the vasculature. CONCLUSIONS ­: These studies have identified TRPV4 as a potential mechanosensor involved in transducing mechanical forces on the airways to molecular and transcriptional events that regulate the morphogenesis of the three essential tissue compartments in the lung.

The putative tumor suppressor gene EphA3 fails to demonstrate a crucial role in murine lung tumorigenesis or morphogenesis.

Treatment of non-small cell lung cancer (NSCLC) is based on histological analysis and molecular profiling of targetable driver oncogenes. Therapeutic responses are further defined by the landscape of passenger mutations, or loss of tumor suppressor genes. We report here a thorough study to address the physiological role of the putative lung cancer tumor suppressor EPH receptor A3 (EPHA3), a gene that is frequently mutated in human lung adenocarcinomas. Our data shows that homozygous or heterozygous loss of EphA3 does not alter the progression of murine adenocarcinomas that result from Kras mutation or loss of Trp53, and we detected negligible postnatal expression of EphA3 in adult wild-type lungs. Yet, EphA3 was expressed in the distal mesenchyme of developing mouse lungs, neighboring the epithelial expression of its Efna1 ligand; this is consistent with the known roles of EPH receptors in embryonic development. However, the partial loss of EphA3 leads only to subtle changes in epithelial Nkx2-1, endothelial Cd31 and mesenchymal Fgf10 RNA expression levels, and no macroscopic phenotypic effects on lung epithelial branching, mesenchymal cell proliferation, or abundance and localization of CD31-positive endothelia. The lack of a discernible lung phenotype in EphA3-null mice might indicate lack of an overt role for EPHA3 in the murine lung, or imply functional redundancy between EPHA receptors. Our study shows how biological complexity can challenge in vivo functional validation of mutations identified in sequencing efforts, and provides an incentive for the design of knock-in or conditional models to assign the role of EPHA3 mutation during lung tumorigenesis.

ErbB4 Regulates the Timely Development of Late Fetal Lung Function and Structure / Шинэ санаа Шинэ нээлт

ErbB4 receptor has an important function in fetal lung cell maturation. Deletion of ErbB4 leads to alveolar simplification and airway hyperreactivity in adult mice. We aimed to study the effects of ErbB4 deletion on the fetal lung. The pulmonary structure, surfactant protein (SP) expression, surfactant synthesis and secretion in fetal ErbB4-deleted IIER4hc*r1 mice were studied at El6, El7, and El8. Morphometry at EIX showed a decrease in the size of saccules in HER4hc"1 lungs. At E17, the structural development of the ErbB4-deleted lungs was delayed, keeping these lungs in the canalicular stage. Expression of SP-B and SP-I) were both decreased at El8 in HER4hc"1 lungs. Surfactant phospholipid synthesis and secretion were both reduced at El8, but at El 7, only synthesis was decreased. Pulmonary ErbB4 deletion results in a structural and functional developmental delay, indicating a crucial regulatory role of F.rbB4 in the timely progression of fetal lung development.

ErbB4 Regulates the Timely Development of Late Fetal Lung Function and Structure / Шинэ санаа Шинэ нээлт

ErbB4 receptor has an important function in fetal lung cell maturation. Deletion of ErbB4 leads to alveolar simplification and airway hyperreactivity in adult mice. We aimed to study the effects of ErbB4 deletion on the fetal lung. The pulmonary structure, surfactant protein (SP) expression, surfactant synthesis and secretion in fetal ErbB4-deleted IIER4hc*r1 mice were studied at El6, El7, and El8. Morphometry at EIX showed a decrease in the size of saccules in HER4hc"1 lungs. At E17, the structural development of the ErbB4-deleted lungs was delayed, keeping these lungs in the canalicular stage. Expression of SP-B and SP-I) were both decreased at El8 in HER4hc"1 lungs. Surfactant phospholipid synthesis and secretion were both reduced at El8, but at El 7, only synthesis was decreased. Pulmonary ErbB4 deletion results in a structural and functional developmental delay, indicating a crucial regulatory role of F.rbB4 in the timely progression of fetal lung development.