Nongenomic estrogen action in human lung myofibroblasts.

Recent studies have suggested that the antiproliferative effects of E2 may be mediated through a nongenomic action. Herein, we asked whether nongenomic estrogen action regulates phosphorylation of Raf1 and ERK1/2 mitogen-activated protein (MAP) kinase in lung myofibroblasts. We demonstrated that lung myofibroblasts, incubated in the presence of E2, showed a rapid phosphorylation on serine-259 of Raf1 and tyrosine-204 of ERK1/2 MAP kinase at 15 min, by approximately 3- and 5-fold, respectively. This phosphorylation was followed by dephosphorylation between 30 and 60 min. Western blot analysis showed that E2 regulates tyrosine phosphorylation of four main cytoplasmic proteins in lung myofibroblasts, of 42, 44, 70 and 100 kDa. Furthermore, our results indicated that E2 inhibits cell proliferation (BrdU index) in lung myofibroblasts by approximately 30% (P < 0.01). These data provide evidence that nongenomic action of E2, regulates both serine and tyrosine phosphorylation of cytoplasmic proteins in lung myofibroblasts, including Raf1 and ERK1/2 MAP kinase, which may regulate proliferation in lung myofibroblasts.

The molecular basis of lung morphogenesis.

To form a diffusible interface large enough to conduct respiratory gas exchange with the circulation, the lung endoderm undergoes extensive branching morphogenesis and alveolization, coupled with angiogenesis and vasculogenesis. It is becoming clear that many of the key factors determining the process of branching morphogenesis, particularly of the respiratory organs, are highly conserved through evolution. Synthesis of information from null mutations in Drosophila and mouse indicates that members of the sonic hedgehog/patched/smoothened/Gli/FGF/FGFR/sprouty pathway are functionally conserved and extremely important in determining respiratory organogenesis through mesenchymal-epithelial inductive signaling, which induces epithelial proliferation, chemotaxis and organ-specific gene expression. Transcriptional factors including Nkx2.1, HNF family forkhead homologues, GATA family zinc finger factors, pou and hox, helix-loop-helix (HLH) factors, Id factors, glucocorticoid and retinoic acid receptors mediate and integrate the developmental genetic instruction of lung morphogenesis and cell lineage determination. Signaling by the IGF, EGF and TGF-beta/BMP pathways, extracellular matrix components and integrin signaling pathways also directs lung morphogenesis as well as proximo-distal lung epithelial cell lineage differentiation. Soluble factors secreted by lung mesenchyme comprise a 'compleat' inducer of lung morphogenesis. In general, peptide growth factors signaling through cognate receptors with tyrosine kinase intracellular signaling domains such as FGFR, EGFR, IGFR, PDGFR and c-met stimulate lung morphogenesis. On the other hand, cognate receptors with serine/threonine kinase intracellular signaling domains, such as the TGF-beta receptor family are inhibitory, although BMP4 and BMPR also play key inductive roles. Pulmonary neuroendocrine cells differentiate earliest in gestation from among multipotential lung epithelial cells. MASH1 null mutant mice do not develop PNE cells. Proximal and distal airway epithelial phenotypes differentiate under distinct transcriptional control mechanisms. It is becoming clear that angiogenesis and vasculogenesis of the pulmonary circulation and capillary network are closely linked with and may be necessary for lung epithelial morphogenesis. Like epithelial morphogenesis, pulmonary vascularization is subject to a fine balance between positive and negative factors. Angiogenic and vasculogenic factors include VEGF, which signals through cognate receptors flk and flt, while novel anti-angiogenic factors include EMAP II.

Laminin 2 attachment selects myofibroblasts from fetal mouse lung.

Laminins (LNs) are extracellular matrix glycoproteins that are involved in cell adhesion, proliferation, and differentiation. So far, 11 LN variants (LN1 to LN11) have been described. In the lung, at least six LN variants have been identified. However, only the role of LN1 has been characterized to any extent. In this study, we hypothesized that the LN2 variant may play a role during lung development. We identified, by RT-PCR analysis, that the alpha2-chain mRNA of LN2 is expressed during mouse lung development. LN2 adhesion assays were then performed with cells from fetal mouse lung primary cultures. Our results showed that a specific subpopulation of fetal lung cells that expressed vimentin, alpha-smooth muscle actin, and desmin attached onto LN2, whereas the cells that did not adhere to LN2 as well as the total cell population were able to adhere readily on fibronectin. Cell attachment onto LN2 was inhibited by EDTA. In addition, we demonstrated, by RT-PCR and Western analysis, that the LN2-adherent cells autoexpressed the alpha2-chain of LN2. In the late pseudoglandular period, LN2 was localized by immunohistochemistry in the basement membrane of airways and blood vessels and around mesenchymal cells. We conclude that LN2 is expressed during lung development and that a specific subpopulation of fetal lung mesenchymal cells expressing a myofibroblastic phenotype can be selected by attachment to LN2 in primary culture. These findings lead us to speculate that LN2 may play a key role in the cell biology of myofibroblasts during lung development.

Commitment and differentiation of lung cell lineages.

To form a large diffusible interface capable of conducting respiratory gases to and from the circulation, the lung must undergo extensive cell proliferation, branching morphogenesis, and alveolar saccule formation, to generate sufficient surface area. In addition, the cells must differentiate into at least 40 distinct lung cell lineages. Specific transcriptional factors, peptide growth factor receptor-mediated signaling pathways, extracellular matrix components, and integrin-signaling pathways interact to direct lung morphogenesis and lung cell lineage differentiation. Branching mutants of the respiratory tracheae in Drosophila have identified several functionally conserved genes in the fibroblast growth factor signaling pathway that also regulate pulmonary organogenesis in mice and probably also in man. Key transcriptional factors including Nkx2.1, hepatocyte nuclear factor family forkhead homologues, GATA family zinc finger factors, pou and homeodomain proteins, as well as basic helix-loop-helix factors, serve as master genes to integrate the developmental genetic instruction of lung morphogenesis and cell lineage determination. Lung mesenchyme serves as a 'compleat' inducer of lung morphogenesis by secreting soluble peptide growth factors. In general, peptide growth factors signaling through cognate receptors with tyrosine kinase intracellular signaling domains such as epidermal growth factor receptor, fibroblast growth factor receptors, hepatocyte growth factor/scatter factor receptor, c-met, insulin-like growth factor receptor, and platelet-derived growth factor receptor, stimulate lung morphogenesis, while the cognate receptors with serine/threonine kinase intracellular signaling domains, such as the transforming growth factor-beta receptor family are inhibitory. The extracellular matrix also plays a key role in determining branching morphogenesis. Pulmonary neuroendocrine (PNE) cells differentiate earliest in gestation among lung epithelial cells. PNE cells are principally derived from endoderm and not neural crest. PNE cells have been proposed to function as airway chemoreceptors, while PNE cell secretory granules contain many bioactive substances such as GRP which may direct proliferation of adjacent epithelial cells. Mammalian achaete-schute homolog-1 null mutant mice do not develop PNE cells. Candidate molecular switches in the transition from a quiescent to a proliferative alveolar epithelial cell (AEC) phenotype and back again following acute hyperoxia, include autocrine peptide growth factor signaling pathways and cell cycle regulatory elements. AEC type 2 also appear capable of reversible transdifferentiation into AEC type 1 and intermediate phenotypes in response to cues from extracellular matrix and cell shape, as well as soluble factors. Evidence for expression of telomerase by alveolar epithelial stem cells, which correlates with self-renewal potential, is now beginning to emerge. Lung regeneration following lobectomy in juvenile rodents is associated with co-ordinated cell proliferation, re-expression of elastin and formation of alveoli. Retinoic acid has recently shown promise as a stimulator of alveolization in juvenile rats. Our future goal is to devise new rational and gene therapeutic strategies to stimulating lung growth and maturation, ameliorating lung injury, augmenting lung repair, and inducing lung regeneration. The ideal agent or agents would therefore mimic the instructive role of lung mesenchyme, correctly inducing the temporospatial pattern of lung cell lineages necessary to restore pulmonary gas diffusing capacity.

Fibrinolysis potentiating activity following endothelial cells-platelet interaction.

When porcine endothelial cells in culture are incubated in the presence of human platelets, a 90kDa neutral proteinase activity is generated on casein gel (PECAP-Platelet Endothelial Cell Activated Protease). This activity was undetected when platelet extract or serum free EC conditioned medium were analysed under similar conditions. The optimum pH, isoelectric point, molecular weight and inhibitory profile of this activity were similar to Glu-plasmin. However, the low plasminogen content (less than 50ng/ml) in the conditioned medium of endothelial cells incubated with platelet could not contribute alone to this activity and the presence of a plasmin potentiating factor was suggested. This factor was separated from plasminogen by lysine-Sepharose chromatography.

[Endothelial cell proteases and their modulation by platelets]. / Protéases des cellules endothéliales et leur modulation par les plaquettes.

Endothelial cells produce and secrete a large number of proteases which are implicated in various disease states. These proteases fall into two classes: serine proteases include plasminogen activators (t-PA) and urokinase (u-PA) and play a major role in fibrinolysis, tissue repair and carcinogenesis; and metalloproteases include collagenases and stromelysine, two enzymes involved in the tissue remodelling that occurs during angiogenesis and tumor growth. The authors have recently identified two other proteases in porcine aortic endothelial cell culture medium. One is an elastase-like enzyme of the metalloprotease group, whereas the other is a new protease whose molecular weight is 85 Kd and whose activity becomes apparent only after exposure of the endothelial cells to platelets. The term Platelet Endothelial Cell Activated Protease accurately describes this enzyme. PECAP degrades casein and fibrinogen. Because PECAP is not inhibited by the usual inhibitors of the various classes of proteases, it remains at present unclassified.

Endothelial proteases stimulated by blood platelets.

Endothelial cells secrete a protease which is activated in the extracellular medium by platelets. This protease PECAP, degrades casein and fibrinogen, and its characteristics differentiate it from the other known blood and vascular proteases.

Thyroid hormone stimulates adipocyte differentiation of 3T3 cells.

Triiodothyronine added at 0.1 nM to 3T3-F442A cells cultured in adipogenic medium having endogenous hormone concentrations similar to those of hypothyroid serum stimulated adipose conversion; activities of both lipogenic enzymes, glycerophosphate dehydrogenase and malic enzyme, increased with hormone treatment. The number of adipocytes was also augmented by L-T3 addition but the number of fat cell clusters remained the same as compared to non-treated cultures, suggesting that thyroid hormone increased the number of adipocytes probably through stimulating selective multiplication of precursor adipose cells. Hormone addition to cells cultured with non-adipogenic medium did not promote conversion showing that L-T3 is not an adipogenic factor by itself. Triiodothyronine added at concentrations similar to those found in hyperthyroidism, from 10 nM up to 10 microM, also increased the proportion of adipocytes without changing the number of fat cell clusters, but they decreased the activity of both lipogenic enzymes and lipid accumulation in mature adipocytes. It can be concluded that during 3T3-F442A differentiation into adipocytes L-T3 increases the number of differentiated adipocytes and, at low concentrations, also enhances lipogenic enzyme activities, whereas at the hyperthyroid hormone levels these enzyme activities are significantly reduced, remaining at levels similar to those of cells cultured with hypothyroid medium. This cloned cell line seems to be a useful model to study thyroid hormone action at both molecular and cellular level.