Impact of transcription factor Sox8 on oligodendrocyte specification in the mouse embryonic spinal cord

The myelin-forming oligodendrocytes of the mouse embryonic spinal cord express the three group E Sox proteins Sox8, Sox9, and Sox10. They require Sox9 for their specification from neuroepithelial cells of the ventricular zone and Sox10 for their terminal differentiation and myelination. Here, we show that during oligodendrocyte development, Sox8 is expressed after Sox9, but before Sox10. Loss of Sox8 did not impair oligodendrocyte specification by itself, but enhanced the Sox9-dependent defect. Oligodendrocyte progenitors were still generated in the Sox9-deficient spinal cord, albeit at 20-fold lower rates than in the wildtype. Combined loss of Sox8 and Sox9, in contrast, led to a near complete loss of oligodendrocytes. Other cell types such as ventricular zone cells and radial glia remained unaffected in their numbers as well as their rates of proliferation and apoptosis. Oligodendrocyte development thus relies on the differential contribution of all three group E Sox proteins at various phases.     

Lamellar body formation precedes pulmonary surfactant apoprotein expression during embryonic mouse lung development in vivo and in vitro

Abstract. The purpose of this investigation was to determine whether lamellar inclusion body (LB) formation and surfactant apoprotein (SP-35) production are directly coordinated by temporal and positional information during development. In the present study we report a comparison between embryonic B10.A mouse lung morphogenesis and cytodifferentiation in vivo with that observed during organ culture in serumless medium. Precursor LB were first detected at embryonic day 12 (E12d), and progressively larger numbers and forms were produced during subsequent differentiation of respiratory alveolar duct epithelium. SP-35 was first detected during the canalicular period (E16.5d). Lung cultures (E12 d) showed pseudoglandular and canalicular periods of morphogenesis, and both ciliated epithelial and type II cell differentiation. Nonciliated cells produced increasing numbers of lamellar inclusion bodies throughout the culture period. SP-35 was detected at 9 days in vitro (d.i.v.). These observations indicate (i) precursor LB formation precedes SP-35 expression and is not dependent on apoprotein synthesis; (ii) E12d lung development in vitro using serumless medium proceeds at a rate equivalent to 0.5 days in vivo through 11 d.i.v.; and (iii) morphogenesis and differentiation occur in the absence of exogenous hormones and growth factors. The cell-cell interactions that play a role in morphogenesis and cell differentiation appear to be intrinsic to the developmental program for embryonic lung development and are likely to be mediated by autocrine and/or paracrine factors.     

Sox2 is important for two crucial processes in lung development: branching morphogenesis and epithelial cell differentiation

The primary lung bud originates from the foregut and develops into the bronchial tree by repetitive branching and outgrowing of the airway. The Sry related HMG box protein Sox2 is expressed in a cyclic manner during initiation and branching morphogenesis of the lung. It is highly expressed in non-branching regions and absent from branching regions, suggesting that downregulation of Sox2 is mandatory for airway epithelium to respond to branch inducing signals. Therefore, we developed transgenic mice that express a doxycycline inducible Sox2 in the airway epithelium. Continuous expression of Sox2 hampers the branching process resulting in a severe reduction of the number of airways. In addition, the bronchioli transiently go over into enlarged, alveolar-like airspaces, a pathology described as bronchiolization of alveoli. Furthermore, a substantial increase was observed of cGRP positive neuroendocrine cells and ΔNp63 isoform expressing (pre-) basal cells, which are both committed precursor-like cells. Thus, Sox2 prevents airways from branching and prematurely drives cells into committed progenitors, apparently rendering these committed progenitors unresponsive to branch inducing signals. However, Sox2 overexpression does not lead to a complete abrogation of the epithelial differentiation program.     

Numb Expression and Asymmetric versus Symmetric Cell Division in Distal Embryonic Lung Epithelium

Proper balance between self-renewal and differentiation of lung-specific progenitors is absolutely required for normal lung morphogenesis/regeneration. Therefore, understanding the behavior of lung epithelial stem/progenitor cells could identify innovative solutions for restoring normal lung morphogenesis and/or regeneration. The Notch inhibitor Numb is a key determinant of asymmetric or symmetric cell division and hence cell fate. Yet Numb proximal-distal expression pattern and symmetric versus asymmetric division are uncharacterized during lung epithelial development. Herein, the authors find that the cell fate determinant Numb is highly expressed and asymmetrically distributed at the apical side of distal epithelial progenitors and segregated to one daughter cell in most mitotic cells. Knocking down Numb in MLE15 epithelial cells significantly increased the number of cells expressing the progenitor cell markers Sox9/Id2. Furthermore, cadherin hole analysis revealed that most distal epithelial stem/progenitor cells in embryonic lungs divide asymmetrically; with their cleavage, planes are predicted to bypass the cadherin hole, resulting in asymmetric distribution of the cadherin hole to the daughter cells. These novel findings provide evidence for asymmetric cell division in distal epithelial stem/progenitor cells of embryonic lungs and a framework for future translationally oriented studies in this area.     

Cellular events associated with lung branching morphogenesis including the deposition of collagen type IV

In this study mouse lung development was examined using an in vitro model system. The culture system permitted examination of a morphogenic process that eventually led to the formation of presumptive alveoli (terminal sacs). The observations included changes in epithelial cell morphology (transition from a columnar to a spindle shape), and evidence for motile activity on the part of primitive airway epithelial cells. The importance of Type IV collagen to the cellular events associated with branching morphogenesis was investigated by immunolocalization. In addition, we assessed the similarity of normal lung development to in vitro development by comparing cultured lungs with equivalent stages of embryonic and fetal mouse lungs. The results show that cultured embryonic lung explants proceed along a morphogenic pathway that parallels normal lung development; that primitive pulmonary epithelial cells engage in motile activity and transiently acquire an extended cell shape both in vitro and in vivo; that, as suggested by others, the pattern of late branching morphogenesis is not dichotomous, but irregular; and that short wisplike fibers of Type IV collagen are present in developing embryonic and fetal lung mesenchyme. Taken together, the results show that early and late lung branching patterns differ significantly, and suggest that later stages of lung branching involve distinct epithelial cell shape transitions. The immunofluorescence data suggest that fibrous Type IV collagen may be the extracellular matrix scaffold within which early epithelial cells accomplish lung branching morphogenesis.     

Pulmonary hypoplasia in mice lacking tumor necrosis factor-alpha converting enzyme indicates an indispensable role for cell surface protein shedding during embryonic lung branching morphogenesis

Many membrane-bound protein precursors, including cytokines and growth factors, are proteolytically shed to yield soluble intercellular regulatory ligands. The responsible protease, tumor necrosis factor-alpha converting enzyme (TACE/ADAM-17), is a transmembrane metalloprotease-disintegrin that cleaves multiple cell surface proteins, although it was initially identified for the enzymatic release of tumor necrosis factor-alpha (TNF-alpha). Mammalian lung growth and development are tightly controlled by cytokines and peptide growth factors. However, the biological function of the cell shedding mechanism during lung organogenesis is not understood. We therefore evaluated the role of TACE as a "sheddase" during lung morphogenesis by analyzing the developmental phenotypes of lungs in mice with an inactive TACE gene in both in vivo and ex vivo organ explant culture. Neonatal TACE-deficient mice had visible respiratory distress and their lungs failed to form normal saccular structures. These newborn mutant lungs had fewer peripheral epithelial sacs with deficient septation and thick-walled mesenchyme, resulting in reduced surface for gas exchange. At the canalicular stage of E16.5, the lungs of TACE mutant mice were impaired in branching morphogenesis, inhibited in epithelial cell proliferation and differentiation, and delayed in vasculogenesis. Embryonic TACE knockout mouse lungs (E12) branched poorly compared to wild-type lungs, when placed into serumless organ culture. Gene expression of both surfactant protein-C and aquaporin-5 were inhibited in cultured TACE-mutant embryonic lungs, indicating defects in both branching and peripheral epithelial cytodifferentiation in the absence of TACE protein. Furthermore, both the hypoplastic phenotype and the delayed cytodifferentiation in TACE-deficient lungs were rescued by exogenous addition of soluble stimulatory factors including either TNF-alpha or epidermal growth factor in embryonic lung culture. Thus, the impaired lung branching and maturation without TACE suggest a broad role for TACE in the processing of multiple membrane-anchored proteins, one or more of which is essential for normal lung morphogenesis. Taken together, our data indicate that the TACE-mediated proteolytic mechanism which enzymatically releases membrane-tethered proteins plays an indispensable role in lung morphogenesis, and its inactivation leads to abnormal lung development.     

Conditional hypoxia inducible factor-1α induction in embryonic pulmonary epithelium impairs maturation and augments lymphangiogenesis

Hypoxia inducible factor (HIF) 1a, EPAS1 and NEPAS are expressed in the embryonic mouse lung and each isoform exhibits distinct spatiotemporal expression patterns throughout morphogenesis. To further assess the role of the HIF1a isoform in lung epithelial cell differentiation and homeostasis, we created transgenic mice that express a constitutively active isoform of human HIF-1a (HIF-1a three point mutant (TPM)), in a doxycycline-dependent manner. Expression of HIF1a TPM in the developing pulmonary epithelium resulted in lung hypoplasia characterized by defective branching morphogenesis, altered cellular energetics and impaired epithelial maturation, culminating in neonatal lethality at birth from severe respiratory distress. Histological and biochemical analyses revealed expanded glycogen pools in the pulmonary epithelial cells at E18.5, concomitant with decreased pulmonary surfactant, suggesting a delay or an arrest in maturation. Importantly, these defects occurred in the absence of apoptosis or necrosis. In addition, sub-pleural hemorrhaging was evident as early as E14.5 in HIF1a TPM lungs, despite normal patterning of the blood vasculature, consistent with defects in endothelial barrier function. Epithelial expression of HIF1a TPM also resulted in increased VEGFA and VEGFC production, an increase in the number of lymphatic vessels and indirect activation of the multiple Notch pathway components in endothelial precursor cells. Collectively, these data indicate that HIF-1a protein levels in the pulmonary epithelium must be tightly controlled for proper development of the epithelial and mesenchymal compartments.     

Role for mitogen-activated protein kinase p38 alpha in lung epithelial branching morphogenesis

In the early stages of lung development, the endoderm undergoes extensive and stereotypic branching morphogenesis. During this process, a simple epithelial bud develops into a complex tree-like system of tubes specialized for the transport and exchange of gas with blood. The endodermal cells in the distal tips of the developing lung express a special set of genes, have a higher proliferation rate than proximal part, undergo shape change and initiate branching morphogenesis. In this study, we found that of the four p38 genes, only p38α mRNA is localized specifically to the distal endoderm suggesting a role in the regulation of budding morphogenesis. Chemical inhibitors specific for the p38α and p38β isoforms suppress budding of embryonic mouse lung explants and isolated endoderm in vitro. Specific knockdown of p38α in cultured lung endoderm using shRNA also inhibited budding morphogenesis, consistent with the chemical inhibition of the p38 signaling pathway. Disruption of p38α did not affect proliferation or expression of the distal cell markers, Sox9 and Erm. However, the amount of E-cadherin protein increased significantly and ectopic expression of E-cadherin also impaired budding of endoderm in vitro. These results suggest that p38α modulates epithelial cell-cell interactions and possibly cell rearrangement during branching morphogenesis. This study provides the first evidence that p38α is involved in the morphogenesis of an epithelial organ.     

VEGF-A signaling through Flk-1 is a critical facilitator of early embryonic lung epithelial to endothelial crosstalk and branching morphogenesis

Vascular endothelial growth factor-A (VEGF-A) signaling directs both vasculogenesis and angiogenesis. However, the role of VEGF-A ligand signaling in the regulation of epithelial-mesenchymal interactions during early mouse lung morphogenesis remains incompletely characterized. Fetal liver kinase-1 (Flk-1) is a VEGF cognate receptor (VEGF-R2) expressed in the embryonic lung mesenchyme. VEGF-A, expressed in the epithelium, is a high affinity ligand for Flk-1. We have used both gain and loss of function approaches to investigate the role of this VEGF-A signaling pathway during lung morphogenesis. Herein, we demonstrate that exogenous VEGF 164, one of the 3 isoforms generated by alternative splicing of the Vegf-A gene, stimulates mouse embryonic lung branching morphogenesis in culture and increases the index of proliferation in both epithelium and mesenchyme. In addition, it induces differential gene and protein expression among several key lung morphogenetic genes, including up-regulation of BMP-4 and Sp-c expression as well as an increase in Flk-1-positive mesenchymal cells. Conversely, embryonic lung culture with an antisense oligodeoxynucleotide (ODN) to the Flk-1 receptor led to reduced epithelial branching, decreased epithelial and mesenchymal proliferation index as well as downregulating BMP-4 expression. These results demonstrate that the VEGF pathway is involved in driving epithelial to endothelial crosstalk in embryonic mouse lung morphogenesis.     

Smad1 expression and function during mouse embryonic lung branching morphogenesis

Bone morphogenetic protein (BMP) 4 plays very important roles in regulating developmental processes of many organs, including lung. Smad1 is one of the BMP receptor downstream signaling proteins that transduce BMP4 ligand signaling from cell surface to nucleus. The dynamic expression patterns of Smad1 in embryonic mouse lungs were examined using immunohistochemistry. Smad1 protein was predominantly detected in peripheral airway epithelial cells of early embryonic lung tissue [embryonic day 12.5 (E12.5)], whereas Smad1 protein expression in mesenchymal cells increased during mid-late gestation. Many Smad1-positive mesenchymal cells were localized adjacent to large airway epithelial cells and endothelial cells of blood vessels, which colocalized with a molecular marker of smooth muscle cells (alpha-smooth muscle actin). The biological function of Smad1 in early lung branching morphogenesis was then studied in our established E11.5 lung explant culture model. Reduction of endogenous Smad1 expression was achieved by adding a Smad1-specific antisense DNA oligonucleotide, causing approximately 20% reduction of lung epithelial branching. Furthermore, airway epithelial cell proliferation and differentiation were also inhibited when endogenous Smad1 expression was knocked down. Therefore, these data indicate that Smad1, acting as an intracellular BMP signaling pathway component, positively regulates early mouse embryonic lung branching morphogenesis.