Down-regulation of regulatory proteins for differentiation and proliferation in murine fetal hypoplastic lungs: altered mesenchymal-epithelial interactions.

We compared proliferation (growth) and differentiation (development) related proteins in normal and hypoplastic fetal murine lungs. The hypoplastic lungs were created in CD-1 fetal mice by nitrofen exposure (25 mg per pregnant mouse given intragastrically on gestational day 8 [Gd8]), as published earlier. The lungs were harvested at Gd14, 16, 19 and from neonates. Immunoblot analyses were carried out for transcription factors (oncogenic proteins, nuclear receptor, and transmembrane receptor proteins) in severely hypoplastic murine fetal lungs with coexistent diaphragmatic hernia, and results were compared with those derived from normal lungs of equivalent age. These proteins have proposed roles in the regulation of proliferation and differentiation processes of fetal lungs. We have shown that the product of the oncogene c-myc was reduced in hypoplastic lungs at all stages of gestation, whereas c-Fos protein levels were variable. These proteins are known to regulate transcription of various developmental proteins, such as those responsible for proliferation and differentiation. Further, the nuclear transcription factors thyroid transcription factor-1 (TITF-1) and glucocorticoid receptor (GR) were reduced, and thyroid hormone receptor (TR) and retinoic acid receptors (RARs) were inhibited in severely hypoplastic lungs compared to normal lungs of equivalent gestational stage, except in neonatal lungs, where signals for RARs were seen. TITF-1 is known to localize in bronchial epithelial cells in developing lungs. It is restricted to type II pneumocytes with gestational development in the normal lungs and regulates surfactant proteins. Earlier, we have reported that surfactant proteins are reduced in hypoplastic lungs. In the current study, reduced GR and TITF-1 proteins may play a role in reducing surfactant proteins in the hypoplastic lungs. The significant inhibition in TR and RARalpha in the severely hypoplastic lungs reflects on affected epithelial cell maturation and alveolar formation, respectively. Altered RARbeta levels correlate with affected lung growth and branching morphogenesis of nitrofen-exposed lungs. A transmembrane receptor protein EGFR was reduced in hypoplastic lungs, suggesting the involvement of altered mesenchymal-epithelial signal transduction pathways. We conclude (1) Our data suggest altered levels of various nuclear transcription factors in the murine fetal hypoplastic lungs; (2) Reduced levels TITF-1 protein in hypoplastic lungs may have caused the functional immaturity of distal lung, immature airways and thus may affect overall differentiation of lungs. These results correlated with low levels of surfactant proteins in these lungs; (3) TR and RAR inhibition indicate their roles through reduced or retarded proliferation and differentiation processes in the severely hypoplastic lungs; (4) GR down-regulation in developing fetal murine hypoplastic lungs indicate delayed development, and GR up-regulation in affected neonates may be induced by stress/stretch caused at birth due to air-breathing; (5) Down- regulation of EGFR indicate altered mesenchymal-epithelial interactions and possible influence on lung proliferation and differentiation.

Angiotensin II-induced changes in G-protein expression and resistance of renal microvessels in young genetically hypertensive rats.

Altered regulation of cAMP may contribute to enhanced renal reactivity to angiotensin II (Ang II) in spontaneously hypertensive rats (SHR). Such a phenomenon may occur in renal preglomerular arterioles and may involve changes in expression of GTP-binding regulatory proteins. We have examined the effects of Ang II on steady state levels of G(alpha i-1,2), G(alpha i-3), G(alpha s) and G(alpha q) in preglomerular arterioles from young marginally hypertensive SHR and on mean arterial pressure (MAP), renal vascular resistance (RVR) and renal cAMP excretion (UcAMP.V). Young (5-6 week old) SHR and Wistar Kyoto (WKY) rats received Ang II (35 ng/kg/min, s.c.) or vehicle for 7 days via osmotic minipumps. Urine was collected over the last 24 h. On day seven, MAP and renal blood flow were measured in anesthetized rats and RVR was determined. Preglomerular arterioles were isolated by perfusing the kidneys with iron oxide and using a series of mechanical steps coupled with the use of a magnet to retain iron-laden vessels. Membranes were prepared and the expressions of G(alpha i-1,2), G(alpha i-3), G(alpha s) and G(alpha q) were evaluated by Western immunoblotting. Baseline MAP (124 +/- 6 mmHg) was only marginally (p > 0.05) higher in SHR when compared with WKY rats (110 +/- 4 mmHg). RBF (3.04 +/- 0.16 mL/min) was significantly lower and RVR (41.10 +/- 1.37 mmHg.min/mL) was significantly higher in SHR when compared to age-matched WKY rats (4.36 +/- 0.30 mL/min and 25.79 +/- 1.58 mmHg.min/mL, respectively). Ang II significantly increased MAP in SHR (17 mmHg) but not in WKY rats. These increases in MAP were accompanied by significant increases in RVR in SHR (48% over control) but not in WKY rats. Compared to WKY rats, preglomerular arterioles from SHR exhibited significantly higher basal expression of G(alpha i-1,2) (11- fold), G(alpha 1-3) (13-fold) and G(alpha s) (3-fold). Chronic infusion of Ang II, however, downregulated the expression of G(alpha s) (by 53%; p < 0.05), G(alpha i-1,2) (by 72%; p < 0.05) and G(alpha i-3) (by 35%; p > 0.05) in SHR preglomerular arterioles but significantly upregulated the expression of these proteins in WKY by 3-, 8- and 15-fold, respectively. Basal levels of G(alpha q) were not different in preglomerular arterioles from the two strains but were downregulated by Ang II in both WKY (74% of basal) and SHR (52% of control). Baseline UcAMP.V was significantly lower in SHR (31.22 +/- 6.51 nmol/24 h) compared with WKY rats (65.33 +/- 3.60 nmol/24 h). Chronic Ang II infusion significantly increased UcAMP.V in SHR as well as WKY rats. These data clearly demonstrate that expressions of Gi isoforms as well as Gs in renal microvessels are elevated during early stages of hypertension and suggest that the elevated levels of Gi proteins may be directly associated with a blunted adenylyl cyclase-cAMP cascade in the renal microvasculature. Furthermore, Ang II appears to directly downregulate the expression of Gs in young SHR but not in young WKY renal microvessels. Such diversity in its effect on G-protein expression may be important for enhanced renal sensitivity to Ang II in SHR.

Dexamethasone enhances ras-recision gene expression in cultured murine fetal lungs: role in development.

We have shown that dexamethasone (Dex) accelerates maturation and differentiation of cultured fetal murine lungs (Cilley RE, Zgleszewski SE, Krummel TM, and Chinoy MR. Surg Forum 47: 692-695, 1996). We now demonstrate that although Dex inhibits thinning of acinar walls and secondary septa formation, it does, however, promote lung growth. CD-1 murine fetal lungs were cultured for 7 days in the presence and absence of 10 nM Dex. Dex-modulated genes were investigated and identified by differential display of mRNAs performed with specific anchor primer H-T(11)G and 24 arbitrary primers. Thirty-five differentially expressed cDNAs were isolated, subcloned, sequenced, and identified through BLAST searches. One of these cDNAs, termed Dex2, with enhanced expression in Dex-treated lungs, had 100% similarity with ras-recision gene (rrg), also known as the lysyl oxidase (LOX) gene that encodes lysyl oxidase. LOX gene is very highly conserved, with significant sequence similarity among mouse, rat, and human. Two other cDNAs, termed Dex1 and Dex4, were also identified as rrg, with 92 and 97% sequence similarity with the existing data bank sequence of rrg. LOX enzyme is known to downregulate p21(ras) protein and play a central role in the maturation of collagen and elastin in the extracellular matrix as well as modulate the cytoskeletal elements. Thus LOX may be important in lung developmental processes involving epithelial-mesenchymal interactions.

Suppression subtractive hybridization to identify gene expressions in variant and classic small cell lung cancer cell lines.

Small Cell Lung Cancer (SCLC), a clinically aggressive cancer, accounts for approximately 25% of primary lung cancers. We carried out suppression subtractive hybridization (SSH), a PCR-based method for cDNA subtraction, between the human classic, NCI-H69 and variant, more aggressive NCI-N417 SCLC cell lines to isolate and characterize variable expression of genes, which may be responsible for differential degree of tumorigenicity of SCLC. Using NCI-N417 as a tester, we obtained 28 differentially expressed cDNA clones from a total of 60 arbitrarily picked clones. Among the 28 cDNA clones, 4 were unknown genes, 2 were fatty acid binding protein (FABP) with specific identification of mRNA for mammary-derived growth inhibitor (MDGI), 1 was human alpha-enolase, 4 were ribosomal proteins, 2 were structural genes, vimentin and moesin (membrane-organizing extension spike protein), and 9 were homologous with murine leukemia viruses, whereas 2 others had enhanced expression in NCI-H69 and A549 cell lines, and 4 were cell surface proteins and murine type C retrovirus. Expression of FABP/MDGI was significantly high in NCI-H417, which may influence mitosis and cell growth as implicated in other tissues, contrary to the conclusion drawn for the role of MDGI in human breast cancer. Higher expression of ribosomal proteins in NCI-N417 compared to NCI-H69 may have a role in differential tumorigenicity and metastatic ability. Further, we obtained 14 differentially expressed cDNA clones by reversing the tester and driver, using NCI-H69 as a tester. Of these 14 differential cDNAs, 5 were unknown genes, 2 were specific for keratins, others had similarities with protease inhibitor, human BAC clone, Alu RNA binding protein, and tumor expression-enhanced gene. Characterization of these differentially expressed cDNA clones will provide useful information in understanding of the genes responsible for differential tumorigenicity of SCLC.

Fetal lung development: airway pressure enhances the expression of developmental genes.

BACKGROUND/PURPOSE: The mechanisms by which static airway pressures in the developing lung affect development are unknown. The in vitro murine fetal lung model with airway ligation reproduces the phenomenon of intraluminal airway pressure in developing lungs. We have applied the technique of differential display of mRNAs to fetal murine lungs that were maintained in organ culture with and without tracheal ligation. The goal of this investigation was to identify genes that are induced or enhanced by airway pressure during lung development. METHODS: Fetuses were harvested from CD-1 mice on gestational day (Gd) 14. The lungs were removed and trachea either transected or ligated and organ cultured for 7 days. Total RNA was extracted from cultured unligated controls and ligated lungs. Reverse transcription (RT) of the purified total RNA from each pooled sample was performed with anchor primer H-T11G or C and one of 24 arbitrary primers followed by polymerase chain reaction (PCR) of the RT mixtures. PCR products were electrophoresed on a DNA sequencing gel. Differentially expressed cDNA bands of interest were cut from the dried gel. Each cDNA was then reamplified. Reamplified cDNAs were extracted, PCR amplified, cloned, and sequenced for homology to existing sequences in the GenBank database. RESULTS: Sequencing identified 4 differentially expressed genes enhanced by tracheal ligation: hepatoma-derived growth factor (HDGF), ribosomal protein S24, stathmin, and parathyroid hormone (PTH). CONCLUSIONS: Genes enhanced by airway pressure or tracheal ligation are mitogenic for fibroblasts, correlate with cell proliferation, regulate cell proliferation and differentiation, and may play a role in growth in distal lung and type II cell differentiation. Further work is necessary to identify the mechanisms by which these genes influence lung maturational processes.

Effects of dexamethasone, growth factors, and tracheal ligation on the development of nitrofen-exposed hypoplastic murine fetal lungs in organ culture.

BACKGROUND/PURPOSE: The addition of growth factors EGF (epidermal growth factor) plus TGFbeta1 (transforming growth factor beta1; E + T) or dexamethasone (DEX) to normal murine fetal lungs in culture enhances lung development. In addition, ligation of the airway in lungs in organ culture, enhances lung development. Nitrofen (2,4-dichlorophenyl-p-nitrophenylether) administration to pregnant mice results in pulmonary hypoplasia in the offspring with many similarities to human hypoplastic lung conditions. This study investigates the effects of growth factors, dexamethasone, and airway ligation on the development of hypoplastic fetal murine lungs in whole-organ culture. We hypothesized that E+T, DEX, or airway ligation will enhance the development and maturation of hypoplastic murine fetal lungs in vitro. METHODS: Time-dated pregnant CD-1 mice were given nitrofen, 25 mg, intragastrically at gestational day (Gd) 8. The dams were killed on Gd 14, and the fetuses were removed. The hypoplastic fetal lungs were excised, and the tracheae were transected. The lungs were cultured in serum-free BGJb media in the presence or absence of E+T (10 ng/mL + 2 ng/mL, respectively) or DEX (10 nmol/L). Some lungs were cultured for 7 days with the tracheae ligated. RESULTS: Gross morphology under a dissecting stereomicroscope showed that the lungs were larger after E+T, DEX, or tracheal ligation. Histologically, the untreated lungs had progressed from the pseudoglandular stage to a canalicular-like stage with poorly differentiated airways. The E+T-treated lungs had better developed airway branching and small acini; however, thick mesenchyme persisted. The ligated lungs had well-developed airway branching and acinar structures. After DEX treatment the lungs were most developed with very well defined airway branching and expanded acinar structures; however, there was no secondary septation. Ultrastructurally, the hypoplastic lungs at Gd 14 and after 7 days in culture had no glycogen in their epithelial cells, no defined acinar formation, and had damaged mitochondria. The E+T-treated or tracheally ligated lungs had abundant type II cells, secreted lamellar bodies (LBs), and showed infrequent tubular myelin. Mitochondrial damage was noted in these lungs as in the untreated lungs. DEX-treated hypoplastic lungs showed large acini. The acinar walls were thick; however, they had type II cells with abundant LBs and intact mitochondria. The airways were noted to have differentiated cell types. Surfactant secretions in acinar spaces showed tubular myelin structures. CONCLUSIONS: E+T, tracheal ligation, or DEX accelerates lung development and maturation of hypoplastic fetal murine lungs compared with untreated controls. DEX had a greater effect with special reference to repair of mitochondrial damage. DEX not only accelerated lung development, but it may have reversed some of the effects nitrofen.

Differential gene expression at gestational days 14 and 16 in normal and nitrogen-induced hypoplastic murine fetal lungs with coexistent diaphragmatic hernia.

The purpose of this study was to identify differentially expressed genes in normal and nitrofen-induced hypoplastic lungs in fetal mice. Such genes may play a role in the regulation of lung development. CD-1 pregnant dams were gavaged with 25 mg of nitrofen on gestational day (Gd) 8 to induce pulmonary hypoplasia and diaphragmatic hernia (DH). Normal and nitrofen-treated fetuses were removed on Gd 14 and Gd 16. Lungs were examined in all nitrofen-exposed fetuses and only those that had developed severely hypoplastic lungs with coexistent diaphragmatic hernia were taken for molecular analyses. RNA was extracted from normal and nitrofen-treated lungs, reverse transcribed, and PCR-amplified using 48 combinations of anchor and arbitrary primers for each condition. The resulting cDNAs from normal and hypoplastic lungs were run on 6% polyacrylamide differential display gels. In Gd 14 lungs, we observed 10 differentially expressed cDNA bands, of which 6 were identified to be inhibited and 4 were reduced in the hypoplastic lungs compared to normal fetal lungs. From the Gd 16 lungs, a total of 29 differentially expressed cDNA bands were found, of which 11 were reduced, 4 were inhibited, 11 were enhanced, and 3 were induced in the hypoplastic compared to the normal lungs. All 39 differentially expressed cDNAs were cloned, sequenced, and identified through BLAST searches. Among the sequences that were identified, results were as follows: 1) Hypoplastic Gd 14 lungs had two unknown cDNA sequences with reduced/inhibited expressions, whereas one was a known sequence having 77% similarity with a promoter region regulating various cytokines such as IL-1, IL-2, and IL-11. The expression of this sequence was inhibited in the hypoplastic lungs. This sequence also had similarity to lipid-binding proteins. 2) On Gd 16, hypoplastic lungs had one cDNA sequence with reduced expression which had 82% similarity with thyroid hormone receptor gene exon 1 and two other cDNA sequences with enhanced expressions. One of these enhanced cDNA sequences in hypoplastic lungs had 98% similarity with the fibroblast growth factor receptor-3 gene, and the other was an unknown sequence. Northern blot hybridizations were performed to confirm the differential expression of the two sequences of interest, which were identified as thyroid hormone receptor and fibroblast growth factor (FGF) receptor-3. Overall, out of a total of 39 RT-PCR products (i.e., cDNAs), the abundance of which was altered by nitrofen, 6 were found to be homologous to sequences in Gen Bank through BLAST searches. These 6 sequences became the products of interest, and 3 of these 6 products were similar to previously identified genes. Our results may shed some light on regulatory aspects of lung development and open avenues for treatment of hypoplastic lungs and other respiratory problems in human neonates.

Differential display of genes in normal and hypoplastic fetal murine lungs.

To evaluate lung development at the level of gene expression, a comparison was made between normal and hypoplastic murine fetal lungs by using the mRNA differential display technique. We focused on altered gene expressions at gestational day (Gd) 19 in normal and hypoplastic murine lungs. Hypoplastic fetal lungs were created by gavaging pregnant mice at Gd8 with 25 mg of nitrofen (2,4-dichlorophenyl-p-nitrophenyl ether) [1]. Normal as well as gavaged mice were euthanized by an overdose of halothane at Gd19, and fetuses were removed by laparotomy. Lungs were excised and total RNA was extracted from normal and hypoplastic fetal lungs. Differential display technique was carried out using the RNAimage kit (GenHunter Corp., TN). Each reverse transcription and polymerase chain reaction (RT-PCR) was performed using one specific anchor primer H-T11M (5'HindIII-T11A/C/G3') and one arbitrary primer. We have used a total of 3 different anchor primers and 24 arbitrary primers for each sample. There were 20 differentially expressed cDNA clones, either induced, inhibited, enhanced, or reduced in hypoplastic fetal lungs as compared to normal. Of these, one clone (NL2) with reduced expression in Gd19 hypoplastic lungs had 100% homology with mouse nucleosome assembly protein I gene. Another clone (NT5) with induced expression in hypoplastic lungs is an unknown gene. Further, analyses of Northern blots of lungs from various gestational ages showed that the expression of NT5 was induced in hypoplastic lungs at Gd18, whereas in normal lungs it was first expressed at the neonatal stage and was increasingly expressed into adulthood. There is a single hybridized band, approximately 400 bp long for NT5 message. Dexamethasone induced expression of NT5 in normal Gd14 pseudoglandular lungs cultured for 7 days; however, different growth factors did not. Northern blot hybridization of multiple adult mice tissues showed NT5 expression in the lung, intestine, and spleen. The thyromimetic action of nitrofen and the interactive functional pathways of dexamethasone with T3 are known. Therefore, we suggest that the isolation and characterization of NT5 may provide valuable information on the regulation of lung development.

Guanine nucleotide-binding inhibitory protein-mediated inhibition of adenylyl cyclase is enhanced in spontaneously hypertensive rat preglomerular arteriolar smooth muscle cells.

The purpose of our study was to determine whether Gi-mediated control over adenylyl cyclase in preglomerular arteriolar smooth muscle cells (PGASMC) is enhanced in the spontaneously hypertensive rat (SHR). PGASMC were cultured from preglomerular microvessels isolated from adult SHR (14-15 wk of age) and age-matched WKY rats. Confluent monolayers of cells in third passage were used for the experiments. cAMP released into the media (30 min) as well as cellular levels of cAMP were measured in the presence of a phosphodiesterase inhibitor, 1-isobutyl-3-methyl-xanthine (IBMX; 100 microM) and expressed as pmol/mg protein. Total (released + cellular) cAMP was significantly lower in SHR (14.19 +/- 2.30 pmol/mg protein) as compared with WKY (28.3 +/- 3.04 pmol/mg protein). Correspondingly, the released (4.6 +/- 0.4 pmol/mg protein) as well as cellular (9.78 +/- 2.18 pmol/mg protein) cAMP levels were also significantly lower in SHR when compared with WKY (8.85 +/- 1.26 and 18.86 +/- 2.0 pmol/mg protein, respectively). The steady-state levels of none of the Gi alpha subunits, namely Gi alpha 1, Gi alpha 2 and Gi alpha 3, were higher in the SHR PGASMC. Pertussis toxin treatment (PTX; 100 ng/ml; 24 hr) caused complete ADP-ribosylation of Gi alpha subunits in both WKY and SHR PGASMC. The same treatment of PTX also produced a significant increase in total cAMP in SHR, but not in WKY, such that the total cAMP levels after PTX treatment were not significantly different between the two strains. Interestingly, PTX significantly increased the released (20.26 +/- 0.90 pmol/mg protein) but not the cellular (13.63 +/- 1.63 pmol/mg protein) cAMP in SHR. Forskolin (1 microM) induced similar increases in total cAMP and isoproterenol (1 microM) caused greater increases in total cAMP in SHR cells compared with WKY cells. These data strongly suggest that in SHR PGASMC total adenylyl cyclase activity is not altered. Furthermore, steady-state expressions of Gi alpha-1, Gi alpha-2 and Gi alpha-3 are not increased whereas Gi-mediated inhibition of adenylyl cyclase is augmented in SHR PGASMC.

Influence of epidermal growth factor and transforming growth factor beta-1 on patterns of fetal mouse lung branching morphogenesis in organ culture.

Transforming growth factor-beta (TGF-beta), a potent inhibitor of epithelial cell proliferation, and epidermal growth factor (EGF), a mitogenic polypeptide that binds to cell surface receptors, are important regulators of cell differentiation; however, their distinct role(s) in lung development and their mechanisms of action are not well understood. We evaluated the effects of these factors on lung morphogenesis in murine fetal lungs at gestational day 14 (time:zero) and again after 7 days in culture. Baseline controls were cultured after tracheal transection in supplemented BGJb medium, and other tracheally transected lungs were cultured following addition of EGF (10 ng/ml BGJb), TGF-beta1 (2 ng/ml BFJb), or with both in combination added to the medium. The control lungs in culture had poorly developed airways and an absence of defined acinar structures. The addition of EGF resulted in hyperplasia of primary airways with stunted outgrowths, monopodial branching, and absence of distinct acinar structures. Addition of TGF-beta1 alone, led to significant elongation of primary airways, without normal airway branching; however, terminal dipodial branching was seen and the prospective pulmonary acini were well defined. Combination of these growth factors (GF) resulted in a more normal branching pattern and differentiation, suggesting their epigenetic role in lung morphogenesis and mutual interactive mechanisms that regulate lung development. These lungs had more abundant and larger lamellar bodies than those after other treatments. Control lungs remained immature with prominent glycogen aggregates with occasional dense lamellar bodies. The total protein and DNA contents were highest with EGF treatment, followed by combination treatment; these observations were supported by immunohistochemical localization of proliferating cell nuclear antigen, an indication of the proliferative state of tissues. All the surfactant proteins were relatively unaltered and their messages were up-regulated for SP-A, but down-regulated for SP-B and SP-C in the lungs treated with growth factors. In conclusion, we have demonstrated enhanced biochemical and structural development of lungs treated in vitro with GF, and propose that further research in this area may lead to therapeutic uses of GF alone or in combination with other agents for the treatment of newborn respiratory distress due to lung immaturity or hypoplastic lung development.

Growth factors and dexamethasone regulate Hoxb5 protein in cultured murine fetal lungs.

Studies on lung morphogenesis have indicated a role of homeobox (Hox) genes in the regulation of lung development. In the present study, we attempted to modulate the synthesis of Hoxb5 protein in cultured murine fetal lungs after mechanical or chemical stimuli. Murine fetuses at gestational day 14 (GD14) were removed from pregnant CD-1 mice, and lungs were excised and cultured for 7 days in BGJb media. The experimental groups were 1) untreated, unligated; 2) tracheal ligation; 3) supplemented media with either epidermal growth factor (EGF; 10 ng/ml), transforming growth factor (TGF)-beta 1 (2 ng/ml), dexamethasone (10 nM), EGF + TGF-beta 1, or EGF + TGF-beta 1 + dexamethasone. After 3 or 7 days, the cultured lungs were compared with in vivo lungs. Immunoblotting signals at 3 days in culture were stronger than those at 7 days. Western blot analyses showed that ligation, EGF, TGF-beta 1, and EGF + TGF-beta 1 downregulated Hoxb5 protein to approximately 20-70% of Hoxb5 protein levels in unligated, untreated cultured lungs. Furthermore, dexamethasone alone or in combination with EGF and TGF-beta 1 downregulated Hoxb5 protein by > 90% (P < 0.05) signal strength, similar to that seen in GD19 or in neonatal lungs. Immunostaining showed that Hoxb5 protein was expressed strongly in the lung mesenchyme at early stages in gestation. However, by GD19 and in neonates, it was present only in specific epithelial cells. A persistent level of Hoxb5 protein in the mesenchyme after EGF or TGF-beta 1 treatments or tracheal ligation was noted. Hoxb5 protein was significantly downregulated by EGF + TGF-beta 1, and it was least in lungs after dexamethasone or EGF + TGF-beta 1 + dexamethasone treatment. The decrease in Hoxb5 protein was significant only in the groups with dexamethasone added to the media. Thus immunostaining results parallel those of immunoblotting. The degree of Hoxb5 downregulation by dexamethasone or EGF + TGF-beta 1 + dexamethasone was similar to that seen in vivo in very late gestation, which correlated to the advancing structural development of the lung.

Esophageal/pyloric ligation enhances development of the murine fetal stomach in organ culture.

PURPOSE: The authors hypothesized that increased intraluminal pressure in the fetal stomach would enhance development in a murine organ culture model. METHODS: Gestation day 14 (Gd14) fetal stomachs from time-dated pregnant CD-1 mice (term, 20 days) were maintained in organ culture for 7 days. Some stomachs were ligated at the gastroesophageal (GE) and pyloroduodenal (PD) junctions. Others were left unligated. Gd14, Gd16, and Gd18 stomachs were taken as well to compare organogenesis in vivo. Tissues were processed for histological, morphometric, and immunohistochemical analysis, as well as total protein and DNA determination. RESULTS: The ligated stomachs were visibly distended compared with unligated stomachs in organ culture after 7 days. The length and width of the 7-day in vitro ligated stomachs were significantly increased compared with unligated (2.97+/-0.04 mm v 2.48+/-0.05 mm and 2.14+/-0.04 mm v 1.57+/-0.08 mm, respectively, P < .05). Mucosal epithelial cells showed nuclear polarization, and there was a distinct outer muscle layer in the ligated stomachs, but not in the unligated stomachs, which demonstrated pseudostratified epithelial cells in the mucosa. The ligated stomachs had increased in mucosal thickness compared with unligated (31.4+/-1.3 microm vs 24.9+/-0.9 microm, p < 0.05). The ligated stomachs also had significantly increased protein and DNA content when compared with unligated stomachs (65.8+/-3.1 microg and 23.3+/-1.2 microg v 55.0+/-2.7 microg and 19.0+/-1.2 microg, respectively, P < .05). However, there were no significant differences noted between the protein to DNA ratios. Immunohistochemical staining for proliferating cell nuclear antigen (PCNA), a marker for cell proliferation, demonstrated increased proliferative activity of the mucosal epithelial cells in the ligated stomachs. CONCLUSIONS: Esophageal and pyloric ligation enhanced the development of the fetal stomach in vitro in comparison with unligated stomachs cultured under similar conditions. Developmental characteristics of the ligated stomachs paralleled that of Gd16 stomachs in vivo.

Intraalveolar bubbles and bubble films: III. Vulnerability and preservation in the laboratory.

BACKGROUND: Having confirmed (Scarpelli et al. 1996. Anat. Rec. 244:344-357 and 246:245-270) the discovery of intraalveolar bubbles and films as the normal anatomical infrastructure of aerated alveoli at all ages, we now address three questions. Why have these structures been so elusive? Visible in fresh lungs from the in vivo state, can they be preserved by known laboratory methods? Can they be preserved intact for study in tissue sections? METHODS: Lungs of adult rabbits and pups were examined in thorax directly from the in vivo state to confirm normal bubbles both at functional residual capacity and at maximal volume; other lungs were permitted to deflate naturally to minimal volume. The fate of bubbles in situ (either intact, transected, or diced lung tissue) and of isolated bubbles was assessed (1) during conventional histopreparative processing, (2) during inflation-deflation after degassing, (3) after drying in air, (4) during and after quick freezing in liquid N2, and (5) after preservation in fixed and stained tissue sections prepared by a new double-impregnation procedure in which glutaraldehyde-fixed tissue was preembedded in agar, dehydrated and clarified chemically, embedded in paraffin, sectioned, and stained. Control studies included both blocking of bubble formation by rinsing the air spaces with Tween 20 prior to double impregnation and preparation of normal tissue without preembedding in agar. RESULTS: (1) Each of the following procedures in conventional processing dislocated and disrupted bubbles and films: osmium tetroxide and glutaraldehyde:formaldehyde:tannic acid mixture fixation; chemical dehydration (70-100% ethanol) and clarification (xylene and acetone); and embedding in paraffin or epoxy resin. Transection and dicing of the tissue aggravated the untoward effects. In contrast, bubbles and films remained stable in either glutaraldehyde or formaldehyde, which, however, did not protect against the other agents. (2) Degassing destroyed all bubbles as expected; however, bubbles and films re-formed immediately with reinflation. (3) Topography of fixed bubbles and films was retained after air drying. The dry polygonal configuration reverted to spherical-oval either in saline solution or in 50% ethanol, whereas vulnerability to upgraded ethanol concentrations was unchanged. (4) Normal topography and shape appeared to be retained during quick freezing and after thawing. (5) Intraalveolar and intraductal bubbles and films were preserved and photographed in sections from tissue prepared by the double-impregnation procedure; they were not seen either when bubble formation had been blocked (double-impregnation procedure) or when preembedding in agar had been omitted. CONCLUSIONS: (1) Whether or not fixed in glutaraldehyde or formaldehyde, preservation of intraalveolar and intraductal bubbles and films is not to be expected in tissue prepared by conventional histopreparative procedures, whereas product artifacts may be expected from bubble rupture in situ. (2) Degassing cannot be recommended for studies of alveolar structure-function interrelations because all natural bubbles are disrupted in the process, and bubble re-formation may not parallel their "natural history" in vivo. (3) Compared with glutaraldehyde or formaldehyde fixation, air drying offers no added protection against the untoward effects of conventional processing. (4) Quick-frozen tissue is equally at risk. (5) A new double-impregnation procedure does preserve bubbles and films during processing, sectioning, and staining.

Maintenance of fetal murine pulmonary microvasculature in heart-lung en bloc whole organ culture.

The authors have previously shown that murine fetal lungs can be maintained in serum-free whole organ culture and that airway ligation accelerates lung development. In spite of extensive use of lung organ culture systems, the vasculature of the unperfused lung in organ culture has not been studied. The aim of the present study was to compare organ cultures of heart-lung blocks with continuous perfusion of the pulmonary vasculature to those without perfusion, ie, whole lungs cultured without the attached heart. Time-dated pregnant CD-1 mice were killed on gestational day (Gd) 14. The fetuses were removed via laparotomy. Heart-lung blocks and whole lungs without the heart were excised under sterile conditions and cultured in BGJb media. Some of the heart-lungs and whole lungs underwent tracheal ligation whereas others were left with the trachea unligated allowing free egress of airway fluid. After 7 days, the cultured organs were processed for histology, ultrastructural analysis, and immunohistochemistry. (1) Lungs were fixed in 10% formalin, paraffin embedded, and processed for routine H&E staining. (2) Lungs were fixed in 2.5% glutaraldehyde in cacodylate buffer and processed for transmission electron microscopy. (3) Lungs were embedded in CRYOform and flash frozen for immunohistochemical localization of PECAM-1 (CD31) (PECAM-1, Platelet endothelial cell adhesion molecule-1, a selective endothelial cell marker). Our daily observations of the cultured organs showed that the heart maintained synchronized beating for all 7 days in culture. Perfusion of the pulmonary microvasculature was demonstrated. Light microscopically, H&E sections showed that fresh fetal Gd14 pseudoglandular lungs (time-zero) had a defined capillary network, which was more centrally localized and peripherally less developed. The presence of more numerous lung capillaries in the cultured heart-lung blocks was noted when compared with cultured lungs alone. Ultrastructurally, endothelial cells with intact structural integrity were identified only in cultured whole lungs with hearts. Immunohistochemical staining of the whole lungs with rat antimurine PECAM-1 monoclonal antibody performed on cryosections showed the presence of vasculature by specific PECAM-1 localization on endothelial cells. PECAM-1 labeling of capillaries was noted in Gd14 (time-zero) lungs. In addition, the lungs cultured with hearts, ie, perfused lungs, showed more well defined, distinct capillary networks stained with PECAM-1 antibody than unperfused lungs without hearts. Our results showed that microvasculature is present in murine fetal lungs at Gd14. After 7 days in organ culture, the maintenance of lung microvasculature was confirmed histologically, ultrastructurally, and immunohistochemically. The microvasculature in whole lungs cultured as perfused/beating heart-lung blocks was better maintained than the microvasculature of unperfused whole lungs cultured without hearts. A perfused whole lung organ culture model is attractive because the lung architecture is better maintained and may be useful in lung developmental studies as it mimics the in situ heart-lung functional physiological relationship.

Nitrofen dose-dependent gestational day-specific murine lung hypoplasia and left-sided diaphragmatic hernia.

2,4-Dichlorophenyl-p-nitrophenyl ether (nitrofen) is known to induce pulmonary hypoplasia (PH) with or without diaphragmatic hernias (DH) in rats and mice. We determined the timing of administration and dose of nitrofen needed to create left-sided DH and PH in fetal mice. Time-dated pregnant CD-1 mice were gavaged with various doses of nitrofen in the later one-half of gestational days (GD) 8-11. Fetuses were removed by laparotomy at GD 14, fixed, and evaluated histologically. Fetal lung size was inversely related to nitrofen dose. Morphometric analysis of normal and nitrofen-exposed hypoplastic lungs at the pseudoglandular stage revealed significant differences in lung length, surface area, and in the number of airways. Left-sided DH were observed in a "dorsolateral" position accompanied by PH in approximately 30% of GD 14 fetuses exposed to 25 mg nitrofen on GD 8. A minimal portion of liver was present in the hernia. The lungs of fetuses exposed on GD 9, 10, and 11 progressed to near normal size. Murine fetuses exposed to 25 mg nitrofen on GD 8 resulted in PH and DH, whereas other doses created dose-dependent PH alone or none at all on GD 11. Our study established that, to create left-sided DH and PH in murine fetuses, nitrofen dose specificity and time of administration during gestation were crucial.

Bronchial ligation enhances murine fetal lung development in whole-organ culture.

Evidence exists from both congenital anomalies and animal models that normal fetal lung development is dependent on maintenance of fluid pressure within the developing "airways." Fetal tracheostomy, allowing free egress of airway fluids, results in lung hypoplasia, indicating that some airway distending pressure is required for normal lung development to occur. In contrast, fetal tracheal ligation, which increases fetal airway pressure, reverses lung hypoplasia in animal models. The authors' experiments test the hypothesis that large airway obstruction accelerates the development of murine lungs in vitro in whole-organ culture. Fetuses from time-dated pregnant CD-1 mice at day 14 of gestation were removed (term, 20 days), and the lungs were excised. The left bronchus of each lung was ligated (n = 26), after which the left lung was isolated and cultured at 37 degrees C (95% air, 5% CO2) in BGJb media supplemented with vitamin C and antibiotics. Some fetal lungs were cultured under similar conditions without bronchial ligation (n = 11). After 7 days in culture, the lungs were taken for various analyses. The lungs were fixed in either formaldehyde and processed for paraffin embedding for light microscopic evaluation and morphometric data collection, or were freshly minced and aliquots taken for total protein and DNA content. Several more ligated and unligated lungs were processed for ultrastructural analysis. Morphometric analysis on transverse sections of lungs showed significant differences in the lung tissue size, thickness, epithelial cell height, luminal areas, perimeters, and total number of airspaces (airway + primordial alveolar airspaces). It was evident that bronchial ligation promoted lung development. The ligated lungs displayed thinning of the primordial alveolar walls with cuboidal epithelial cells. The total number of airspaces per field was lower for better developed ligated lungs because of the increased area of airspaces compared with that of the unligated lungs. The dorsoventral tissue thickness (in micrometers) of the ligated lungs was significantly greater than that of the unligated lungs (124.1 +/- 7.0 v 89.6 +/- 8.0); the average outer perimeter of the primordial alveolar airspaces was greater for ligated lungs (404.56 +/- 19.0 microns v 256.85 +/- 17.0 microns). Similarly, the luminal diameter of the spaces of ligated lungs was almost double that of the unligated lungs (38.0 +/- 2.0 microns v 20.3 +/- 2.0 microns), as was the luminal surface area. The morphometric data, which suggest enhanced maturation of the ligated lungs, are supported by results of ultrastructural studies. Ligated lungs had significantly more lamellar bodies. Although total protein and DNA content were greater among the ligated lungs, the protein/DNA ratios did not differ among the groups. The intraluminal pressure (airway pressure) of ligated lungs was 2.9 mm Hg and 3.1 mm Hg at 2 and 4 days in organ culture; the respective pressures for unligated lungs were 1.0 mm Hg and 0.8 mm Hg. These data support the hypothesis that mechanical distending pressure resulting from airway obstruction not only improves pulmonary architecture but also accelerates lung development in vitro. Although these effects have been seen in in vivo models, this is the first proposed in vitro organ culture model. This model may prove to be a powerful tool for the study of molecular mechanisms of mammalian lung development with respect to mechanical and chemical (cytokines, hormones) stimuli.

Intraalveolar bubbles and bubble films. I. formation and development during the first 48 hours of extrauterine life in rabbits.

BACKGROUND: Aeration of mature lungs at birth depends on formation of intraalveolar bubbles and bubble films (Scarpelli 1978. Pediatr. Res., 12:1070-1076). Bubbles establish immediately structural stability and pulmonary gas exchange. Given that air spaces are cleared in minutes of fetal liquid (the initial substrate for bubble formation), in formation possible beyond this period? If so, is this related to early development of pulmonary function and structure? METHODS: Mature, spontaneously breathing rabbit pups at 1-10 min and 1, 3, 8, 24, and 48 h after vaginal birth were anesthetized, trachea was occluded at "resting volume" (approximately functional residual capacity), and lungs were rapidly exposed to preserve in vivo intrapulmonary status. The entire lung was examined by stereomicroscopy. Other determinations included resting volume, lung wet weight, volume-pressure curves, histological sections, lung dry weight, tissue hydroxyproline (OH-Pro), and lavage phospholipids (PL). Bubble mobility in situ was tested. Bubbles were released into bathing liquid by incision of peripheral units and monitored over time. RESULTS: Pup activity and gross appearance of the lungs, together with septal thinning, secondary septal development, clearance of intraluminal liquid, increasing tissue OH-Pro, and PL distribution indicated normal postnatal development. Each aerated unit examined at resting volume (all lobes, all ages) contained intraalveolar bubbles. Transition to free gas exclusively in conducting airways and bubbles/bubble films in peripheral gas exchange units occurred within 1 h. Bubbles appeared to be exclusively within alveoli at 4 h and thereafter. Bubbles persisted and new bubbles were formed during subsequent inflation to maximal volume and deflation to atmospheric pressure (P0). Volume of intact lungs at P0 was maintained by the counterforce of rigid bubble films against tissue retraction. When bubbles were released either at resting volume or at P0, the bubble-free loci became airless. Constant size and stability of released bubbles support preferential incorporation of surfactants into bubble films and constant "near-zero surface tension" (Scarpelli 1978. Pediatr. Res., 12:1070-1076). CONCLUSIONS: We show the ubiquitous presence of intraalveolar bubbles and bubble films in vivo throughout the first 48 h of postnatal life. Bubble film rigidity sustains aeration and prevents collapse, while low surface tension of the films facilitate liquid removal from the air spaces. Bubbles in situ are stable and, within apparent limits, mobile; after birth they are quickly restricted to the alveolar spaces, leaving airways bubble free.

Elemental composition of lamellar bodies from fetal and adult human lung.

Previous studies in the rat using electron probe microanalysis have suggested that most of the Ca2+ in alveolar space is probably derived from secreted lamellar bodies (LB). However, the LB Ca2+ content in cultured rat type II cells is low and unaltered by dexamethasone supplementation. In this study, we examined LB Ca2+ content in adult human lung and cultured explants of fetal lung treated with hormones to promote type II cell differentiation. Lung tissue of 20 to 24 wk of gestation was cultured for 4 to 6 days without hormone and with dexamethasone (10 nM), triiodothyronine (2 nM), 8-bromo-cyclic adenosine monophosphate (0.1 mM), or their combinations. The cultured tissue samples were processed for light and electron microscopy or rapidly frozen and stored in freon-22 under liquid nitrogen. Thin cryosections from the frozen samples were prepared and examined using the electron probe microanalysis. Human lung tissue up to 24 wk of gestational age had no detectable LB before explant culture. Explants cultured for 4 days without hormone supplementation (control) had no detectable LB, single-hormone treatments resulted in small LB, and combination treatments resulted in the formation of many large LB in explant type II cells. Despite such morphologic changes, LB Ca2+ in both control and hormone-treated explants was low (overall mean, 4.1 +/- 0.6; P < 0.05) compared with LB of in situ rat and adult human lung (30 +/- 2 and 27 +/- 1.5 mmol/kg dry wt, respectively) and was similar to that found in cultured rat type II cells. LB phosphorus and sulfur under all explant culture conditions were comparable. These observations indicate that human and rat LB elemental compositions are similar and that optimal in vitro conditions with respect to LB Ca2+ metabolism have not been established.

Characterization of stem cells in human airway capable of reconstituting a fully differentiated bronchial epithelium.

The epithelia of the lung are complex structures that play an important role in normal lung physiology and are often involved in the pathophysiology of pulmonary diseases. The dynamics of cell turnover, lineage, and differentiation within these epithelia are complex and poorly understood. We have coupled the technique of retrovirus-mediated gene transfer with a xenograft model of proximal human airway to evaluate pathways of cellular proliferation and differentiation in human bronchial epithelia. Primary isolates of human bronchial epithelial cells (HBECs) were infected with mixtures of recombinant retroviruses expressing different reporter genes and seeded into denuded rat trachea, which were implanted subcutaneously into athymic mice. The HBECs were allowed to regenerate for four weeks in xenografts, which were then explanted. Clonal expansion of individual retrovirus-marked cells in the regenerated human bronchial epithelium was detected as clusters of transgene-expressing cells. Clone size varied with seeding density, resulting in the largest clones comprising 10(3)-10(4) cells. A substantial number of clones showed transgene expression in basal as well as differentiated columnar cells, a finding that appeared independent of clone size. These studies demonstrate the existence of a cell type within the human bronchial epithelium that is capable of extensive self-renewal and pluripotent development. Further characterization of these potential stem cells will be important in defining pathogenesis of pulmonary diseases and in developing novel approaches to treatment such as gene therapy.

Maturation of undifferentiated lung epithelial cells into type II cells in vitro: a temporal process that parallels cell differentiation in vivo.

BACKGROUND: Formation of alveolar-like structures (ALS) by mature fetal rabbit type II pneumocytes (day 29 gestation) and long-term differentiation on Engelbreth-Holms-Swarm mouse tumor extract or EHS gel (Matrigel) were reported by our group (Blau et al., 1988. J. Cell Physiol., 136:203-214). We now describe structural organization and differentiation of immature lung epithelial cells, isolated at day 22 gestation, into mature type II cells in vitro. METHODS: Peripheral pulmonary tissue was pooled and undifferentiated epithelial cells isolated for primary culture on Matrigel. Cells were examined 12-16 h after plating and on days 1, 3, 5, and 7 of culture and assessed by phase contrast and by transmission electron microscopy after fixation in situ. RESULTS: Cells formed ALS 12-16 h after plating. Spherule diameter increased about four to eight times from day 1-7 in culture. There was rapid transformation of tall columnar cells to cuboidal, normal polarization of cells with respect to cell-free lumen of ALS, progressive reduction of glycogen zones, apparent gradual increase of cell organelles such as Golgi apparatus, rough endoplasmic reticulum and mitochondria, and apparent extrusion of lipidic figures into the lumen. These morphologic transformations in vitro temporally paralleled cell differentiation in vivo. The relative increase of 14C-acetate precursor into phosphatidylcholine in contrast to cardiolipin was consistent with these transformations. CONCLUSIONS: Under the conditions of our culture system, maturation of undifferentiated pulmonary epithelial cells is reproduced in vitro along the same time course and according to the same developmental sequence of fetal lungs in vivo.