Innervation of pulmonary neuroendocrine cells and neuroepithelial bodies in developing rabbit lung.

We investigated the development of innervation of the pulmonary neuroendocrine cell (PNEC) system composed of single cells and organoid cell clusters, neuroepithelial bodies (NEB) in rabbit fetal and neonatal lungs. To visualize the nerve fibers and their contacts with PNECs/NEBs, we used confocal microscopy and multilabel immunohistochemistry (IHC) with pan-neural marker, synaptic vesicle protein 2 (SV2), and serotonin (5-HT) as markers for PNECs/NEBs, and smooth muscle actin or cytokeratin to identify airway landmarks. The numbers and distribution of PNEC/NEB at different stages of lung development (E16, 18, 21, 26, and P2) and the density of innervation were quantified. First PNECs immunoreactive for 5-HT were identified in primitive airway epithelium at E18 as single cells or as small cell clusters with or without early nerve contacts. At E21 a significant increase in the number of PNECs with formation of early innervated NEB corpuscules was observed. The overall numbers of PNECs/NEBs and the density of mucosal, submucosal, and intercorpuscular innervation increased with progressing gestation and peaked postnatally (P2). At term, the majority of NEBs and single PNECs within airway mucosa possessed neural contacts. Such an extensive and complex innervation of the PNEC system indicates a multifunctional role in developing lung and during neonatal adaptation.     

Immunohistochemical Characterization of the Chemosensory Pulmonary Neuroepithelial Bodies in the Naked Mole-Rat Reveals a Unique Adaptive Phenotype

The pulmonary neuroepithelial bodies (NEBs) constitute polymodal airway chemosensors for monitoring and signaling ambient gas concentrations (pO₂, pCO₂/H⁺) via complex innervation to the brain stem controlling breathing. NEBs produce the bioactive amine, serotonin (5-HT), and a variety of peptides with multiple effects on lung physiology and other organ systems. NEBs in mammals appear prominent and numerous during fetal and neonatal periods, and decline in the post-natal period suggesting an important role during perinatal adaptation. The naked mole-rat (NMR), Heterocephalus glaber, has adapted to the extreme environmental conditions of living in subterranean burrows in large colonies (up to 300 colony mates). The crowded, unventilated burrows are environments of severe hypoxia and hypercapnia. However, NMRs adjust readily to above ground conditions. The chemosensory NEBs of this species were characterized and compared to those of the conventional Wistar rat (WR) to identify similarities and differences that could explain the NMR’s adaptability to environments. A multilabel immunohistochemical analysis combined with confocal microscopy revealed that the expression patterns of amine, peptide, neuroendocrine, innervation markers and chemosensor component proteins in NEBs of NMR were similar to that of WR. However, we found the following differences: 1) NEBs in both neonatal and adult NMR lungs were significantly larger and more numerous as compared to WR; 2) NEBs in NMR had a more variable compact cell organization and exhibited significant differences in the expression of adhesion proteins; 3) NMR NEBs showed a significantly greater ratio of 5-HT positive cells with an abundance of 5-HT; 4) NEBs in NMR expressed the proliferating cell nuclear antigen (PCNA) and the neurogenic gene (MASH1) indicating active proliferation and a state of persistent differentiation. Taken together our findings suggest that NEBs in lungs of NMR are in a hyperactive, functional and developmental state, reminiscent of a persistent fetal state that extends postnatally.     

Hamster pulmonary endocrine cells with positive immunostaining for calbindin-D28K

 We have examined the distribution of calcium-binding proteins (CaBPs) in adult and fetal lungs of Syrian golden hamsters (Mesocricetus auratus) using immunostaining with confocal laser microscopy and electron microscopy. Single and grouped (neuroepithelial body; NEB) endocrine cells were distributed from bronchi to alveolar ducts in the adult lung. Serial frozen sections immunostained for CaBPs in combination with immunostaining for endocrine markers such as calcitonin gene-related peptide, serotonin, PGP9.5, and synaptophysin revealed that positive immunostaining for calbindin-D_28K (CB-D28K) was seen in single endocrine cells and NEBs. However, other so-called EF-hand family CaBPs, parvalbumin and calretinin, were not detected. Electron microscopically, positive immunoreaction for CB-D28K was mainly in the organelle-free cytoplasmic matrix of endocrine cells, and partly in nuclei and associated with secretory granules and endoplasmic reticulum. In fetal developing lungs, endocrine cells appeared first on gestational day 13, and they were positive for all the endocrine markers used. However, pulmonary endocrine cells were positively immunostained for CB-D28K from gestational days 15 and 16 onward. In summary, our observations suggest that CB-D28K is a useful marker for endocrine cells of the lung, and CB-D28K could function as a mediator of endocrine stimulation or calcium homeostasis in pulmonary endocrine cells. Accepted: 17 June 1997     

Expression of CFTR and Cl(-) conductances in cells of pulmonary neuroepithelial bodies

The pulmonary neuroendocrine cell system comprises solitary neuroendocrine cells and clusters of innervated cells or neuroepithelial bodies (NEBs). NEBs figure prominently during the perinatal period when they are postulated to be involved in physiological adaptation to air breathing. Previous studies have documented hyperplasia of NEBs in cystic fibrosis (CF) lungs and increased neuropeptide (bombesin) content produced by these cells, possibly secondary to chronic hypoxia related to CF lung disease. However, little is known about the role of NEBs in the pathogenesis of CF lung disease. In the present study, using a panel of cystic fibrosis transmembrane conductance regulator (CFTR)-specific antibodies and confocal microscopy in combination with RT-PCR, we demonstrate expression of CFTR message and protein in NEB cells of rabbit neonatal lungs. NEB cells expressed CFTR along with neuroendocrine markers. Confocal microscopy established apical membrane localization of the CFTR protein in NEB cells. Cl(-) conductances corresponding to functional CFTR were demonstrated in NEB cells in a fresh lung slice preparation. Our findings suggest that NEBs, and related neuroendocrine mechanisms, likely play a role in the pathogenesis of CF lung disease, including the early stages before establishment of chronic infection and chronic lung disease.     

Neuronal developmental marker FORSE-1 identifies a putative progenitor of the pulmonary neuroendocrine cell lineage during lung development.

The FORSE-1 (forebrain-surface-embryonic) monoclonal antibody (MAb) recognizes a carbohydrate cell surface epitope related to the Lewis-X (LeX) and stage-specific embryonic antigens (SSEAs). In the developing CNS, the FORSE-1 epitope is believed to serve as a marker of progenitor cells. We studied the expression of the FORSE-1 epitope in pulmonary neuroendocrine cells (PNECs) and related neuroepithelial bodies (NEBs), cell types implicated in paracrine regulation of lung development. We used dual immunolabeling to identify PNECs/NEBs in tissue sections from developing rabbit fetal lungs and corresponding primary lung cell cultures. During the early stage (E16), the FORSE-1 MAb labeled primitive airway epithelium, whereas serotonin (5HT) immunoreactivity, a marker of PNEC/NEB differentiation, was negative. After E18, FORSE-1 labeling became restricted to PNECs and NEBs, identified by co-expression with 5HT, then decreased coincident with an increase in 5HT. Expression of the FORSE-1 epitope correlated inversely with 5HT expression in PNEC/NEB cells. FORSE-1 immunoreactivity correlated with cell proliferation assessed by BrdU labeling. Downregulation of the FORSE-1 epitope correlated with maturation of PNECs/NEBs. The presence of few FORSE-1/5HT-positive cells in postnatal lung suggests retention of progenitors. The FORSE-1 epitope was associated with a high molecular weight (286 kD) glycoprotein that decreased with increasing gestational age, as demonstrated by immunoblotting. Overall expression of SSEA-1, -3, and -4 antigens was similar to FORSE-1/5HT, although the former was preferentially localized to neurite-like processes. Because the role of the FORSE-1 epitope in the CNS probably involves cell adhesion and differentiation, we propose a similar function in developing lung. The demonstration of LeX/SSEA antigen expression in the PNEC/NEB cell lineage underscores the importance of these cells in developing lung. Furthermore, the FORSE-1 antigen may identify committed progenitors of the PNEC/NEB cell system.     

Pulmonary and systemic endotoxin tolerance in preterm fetal sheep exposed to chorioamnionitis

In a model of human chorioamnionitis, fetal sheep exposed to a single injection, but not repeated injections, of intra-amniotic endotoxin develop lung injury responses. We hypothesized that repeated exposure to intra-amniotic endotoxin induces endotoxin tolerance. Fetal sheep were given intra-amniotic injections of saline (control) or Escherichia coli LPS O55:B5 (10 mg) either 2 days (2-day group, single exposure), 7 days (7-day group, single exposure), or 2 plus 7 days (2- and 7-day repeat exposure) before preterm delivery at 124 days gestation (term=150 days). Endotoxin responses were assessed in vivo in the lung and liver, and in vitro in monocytes from the blood and the lung. Compared with the single 2-day LPS exposure group, the (2 plus 7 days) repeat LPS-exposed lambs had: 1) decreased lung neutrophil and monocyte inducible NO synthase (NOSII) expression, and 2) decreased lung cytokine and liver serum amyloid A3 mRNA expression. In the lung, serum amyloid A3 mRNA expression decreased in the airway epithelial cells but not in the lung inflammatory cells. Unlike the single 7-day LPS exposure group, peripheral blood and lung monocytes from the repeat-LPS group did not increase IL-6 secretion or hydrogen peroxide production in response to in vitro LPS. Compared with controls, TLR4 expression did not change but IL-1R-associated kinase M expression increased in the monocytes from repeat LPS-exposed lambs. These results are consistent with the novel finding of endotoxin tolerance in preterm fetal lungs exposed to intra-amniotic LPS. The findings have implications for preterm infants exposed to chorioamnionitis for both responses to lung injury and postnatal nosocomial infections.     

Morphology of the apudocytes and neuroepithelial bodies in the lungs of rats

Endocrine cells (apudocytes) and neuroepithelial bodies (NEBs) were revealed in the lungs of rats of different ages by Grimelius' argyrophilic method. Solitary apudocytes were found among the bronchial epitheliocytes, they had the oval, columnar or triangular shape. NEBs comprise groups of argyrophilic cells, in some cases the penetration of neural fibers into the bodies and their branching in the terminals are observed. Apudocytes and NEBs in 1-, 7-, and 15-day-old rats are more numerous in the epithelium of small than big bronchi. In 21- and 30-day-old and in adult animals apudocytes and NEBs are very scarce. The elements under study are likely to take part in the early postnatal development of the rat lungs.     

Selective visualisation of neuroepithelial bodies in vibratome slices of living lung by 4-Di-2-ASP in various animal species

Pulmonary neuroepithelial bodies (NEBs) are extensively innervated organoid groups of neuroendocrine cells that lie in the epithelium of intrapulmonary airways. Our present understanding of the morphology of NEBs is comprehensive, but direct physiological studies have so far been challenging because the extremely diffuse distribution of NEBs makes them inaccessible in vivo and because a reliable in vitro model is lacking. Our aim has been to optimise an in vitro method based on vibratome slices of living lungs, a model that includes NEBs, the surrounding tissues and at least part of their complex innervation. This in vitro model offers satisfactory access to pulmonary NEBs, provided that they can be differentiated from other tissue elements. The model was first optimised for living rat lung slices. Neutral red staining, reported to stain rabbit NEBs, proved unsuccessful in rat slices. On the other hand, the styryl pyridinium dye, 4-(4-diethylaminostyryl)-N-methylpyridinium iodide (4-Di-2-ASP), showed brightly fluorescent cell groups, reminiscent of NEBs, in the airway epithelium of living lung slices from rat. In addition, nerve fibres innervating the NEBs were labelled. The reliable and specific labelling of pulmonary NEBs by 4-Di-2-ASP was corroborated by immunostaining for protein gene-product 9.5. Live cell imaging and propidium iodide staining further established the acceptable viability of 4-Di-2-ASP-labelled NEB cells in lung slices, even over long periods. Importantly, the in vitro model and 4-Di-2-ASP staining procedure for pulmonary NEBs appeared to be equally reproducible in mouse, hamster and rabbit lungs. Diverse immunocytochemical procedures could be applied to the lung slices providing an opportunity to combine physiological and functional morphological studies. Such an integrated approach offers additional possibilities for elucidating the function(s) of pulmonary NEBs in health and disease. This work was supported by the following research grants: Fund for Scientific Research Flanders (G.0155.01 to D.A.), NOI-BOF (to D.A.) and BOF-RUCA Small Projects (KPO2 to D.A., I.B. and F.V.M.) from the University of Antwerp.     

Pulmonary expression of voltage-gated calcium channels: special reference to sensory airway receptors

Studying depolarisation induced calcium entry in our recently developed in situ lung slice model for molecular live cell imaging of selectively visualised pulmonary neuroepithelial bodies (NEBs), exemplified the need for information on the localisation of voltage-gated calcium channels (Ca(v)) in lungs in general, and related to sensory airway receptors more specifically. The present study therefore aimed at identifying the expression pattern of all major classes and subtypes of Ca(v) channels, using multiple immunostaining of rat lung cryosections. Ca(v) channel antibodies were combined with antibodies that selectively label NEBs, nerve fibre populations, smooth muscle, endothelium and Clara cells. Ca(v)2.1 (P/Q-type) was the only Ca(v) channel expressed in NEB cell membranes, and appeared to be restricted to the apical membrane of the slender NEB cell processes that reach the airway lumen. Subpopulations of the vagal but not the spinal sensory nerve fibres that contact NEBs showed immunoreactivity (IR) for Ca(v)1.2 (L-type) and Ca(v)2.1. Ca(v)2.3 (R-type) was selectively expressed by the so-called Clara-like cells that cover NEBs only, and appears to be a unique marker to discriminate this epithelial cell type from the much more extensive group of Clara cells in rat airways. The laminar nerve endings of smooth muscle-associated airway receptors (SMARs) revealed IR for both Ca(v)2.1 and Ca(v)2.2 (N-type). More generally, Ca(v)1.2 was seen to be expressed in vascular smooth muscle, Ca(v)2.3 and Ca(v)3.1 (T-type) in bronchial smooth muscle, Ca(v)3.1 and Ca(v)3.2 (T-type) in endothelial cells, and Ca(v)1.3 (L-type) in a limited number of epithelial cells. In conclusion, the present immunocytochemical study has demonstrated that the various subtypes of Ca(v) channels have distinct expression patterns in rat lungs. Special focus on morphologically/neurochemically characterised sensory airway receptors learned us that both NEBs and SMARs present Ca(v) channels. Knowledge of the identification and localisation of Ca(v) channels in airway receptors and surrounding tissues provides a solid basis for interpretation of the calcium mediated activation studied in our ex vivo lung slice model.     

Induction and characterization of the major surfactant apoprotein during rabbit fetal lung development

Antibodies directed against the major apoprotein associated with rabbit lung surfactant were used to characterize the induction and cellular localization of this protein during rabbit fetal lung development. In lung tissues from rabbits of 26 days gestational age and older, discrete epithelial type II cells were stained positively using the peroxidase antiperoxidase technique. The content of the major protein in homogenates of fetal lung tissue was analyzed using an immunoblotting technique. A protein of about 29 kDa, pI less than or equal to 5.6, was first detectable in fetal lung tissue on day 24 of gestation. The 29-36 kDa, mature form of the surfactant apoprotein was first detectable in lung homogenates from 30-day gestational age fetal rabbits. Treatment of homogenates of day 26 and 31 fetal lung tissues with endoglycosidase F, yielded, in both cases, an immunoreactive triplet with more neutral isoelectric points than the proteins in the untreated homogenates. By immunoblot analysis, we found that only the 29-36 kDa, mature form of the surfactant apoprotein was present in lamellar bodies purified from lung tissues of fetuses of 28 and 31 days and from day 2 neonates. These findings are suggestive that only the mature, 29-36 kDa form of the surfactant apoprotein is associated with lamellar bodies during fetal lung type II cell differentiation in vivo.     

Isolation of alveolar type II cells from fetal rat lung by differential adherence in monolayer culture

Type II alveolar epithelial cells were isolated from fetal rat lung by differential adherence in monolayer culture. The preparation had a high degree of purity, as assessed by phase contrast microscopy and immunocytochemistry. Purity, based on reactivity with specific anti-adult lung serum (SAALS), which recognizes only type II cells, was 91% for cells isolated from 19-day fetal lungs and 79% for cells isolated from 21-day fetal lungs. The lower purity of type II cells in cultures derived from 1-day postnatal rat lungs (51% cells reactive with SAALS) is probably due to a lower tendency of the type II cells from neonatal rats to adhere to culture dishes than of type II cells from fetal rats. Type II cells isolated from 21-day fetal lungs contained a higher percentage phosphatidylglycerol and incorporated [Me-3H]choline faster into phosphatidylcholine (PC) than type II cells isolated from 19-day fetal lungs. Moreover, in cell preparations derived from lungs at fetal day 21, a higher percentage of epithelial cells contained lamellar bodies than in preparations derived from lungs at fetal day 19. The observation of these differences in the stage of maturation indicates that these differences, which are typical features of the original material, are not obliterated by differentiation during the culture. Type II cells isolated according to the present procedure were capable of synthesizing PC with a high percentage of the disaturated species. This method for the isolation of fetal type II cells may be a useful tool in studies concerning surfactant synthesis and its regulation in the fetal lung.     

GABAergic signaling in the pulmonary neuroepithelial body microenvironment: functional imaging in GAD67-GFP mice

Gamma-aminobutyric acid (GABA) is the main inhibitory neurotransmitter in the central nervous system (CNS) of vertebrates, but has also been reported in multiple cell types outside the CNS. A GABAergic system has been proposed in neuroepithelial bodies (NEBs) in monkey lungs. Pulmonary NEBs are known as complex intraepithelial sensory airway receptors and are part of the NEB microenvironment. Aim of the present study was to unravel a GABAergic signaling system in the NEB microenvironment in mouse lungs, enabling the use of genetically modified animals for future functional studies. Immunostaining of mouse lungs revealed that glutamic acid decarboxylase 65/67 (GAD65/67), a rate-limiting enzyme in the biosynthesis of GABA, and the vesicular GABA transporter (VGAT) were exclusively expressed in NEB cells. In GAD67-green fluorescent protein (GFP) knock-in mice, all pulmonary NEBs appeared to express GFP. For confocal live cell imaging, ex vivo vibratome lung slices of GAD67-GFP mice can be directly loaded with fluorescent functional probes, e.g. a red-fluorescent calcium dye, without the necessity of time-consuming prior live visualization of NEBs. RT-PCR of the NEB microenvironment obtained by laser microdissection revealed the presence of both GABA_A and GABA_B (R1 and R2) receptors, which was confirmed by immunostaining. In conclusion, the present study not only revealed the presence of a GABAergic signaling pathway, but also the very selective expression of GFP in pulmonary NEBs in a GAD67-GFP mouse model. Different proof of concept experiments have clearly shown that adoption of the GAD67-GFP mouse model will certainly boost future functional imaging and gene expression analysis of the mouse NEB microenvironment.     

Quantitative characteristics of the Feyrter cells and neuroepithelial bodies of the fetal rabbit lung in normoxia and short term chronic hypoxia

We report here quantitative data on the Feyrter (single) cells (APUD cells) and neuroepithelial bodies (grouped Feyrter cells), in the lungs of rabbit fetuses at 26, 27.5 and 29 days gestational age, during normoxia and short term chronic hypoxia. The apparent number of these cells declines during this period; we suggest that this might be due to increased hypoxemia. Moreover, the number of cells in the lungs of fetuses from short term chronically hypoxic mothers is lower than in the normoxic animals. These findings are in agreement with our previous studies in short term chronically hypoxic neonatal rabbits, and suggest that the increased hypoxemia in the fetus, caused by the induction of hypoxia in the mother, constitutes a stimulus for secretory activity of the Feyrter cells and neuroepithelial bodies (NEBs). This in turn could be part of the mechanism responsible for maintaining the pulmonary vasoconstriction due to hypoxemia. Our results from fetuses of normoxic does provide base line data on the chronological importance of the Feyrter cells and NEBs.     

Increased numbers of neuroepithelial bodies (NEB) in lungs of fetal Rhesus monkeys following maternal dexamethasone treatment

Summary Numbers of neuroepithelial bodies in the lungs of fetal Rhesus monkeys increase in a dose-dependent manner when mothers are treated antenatally with dexamethasone. Maternal doses of 15 mg/kg result in numbers of neuroepithelial bodies in lungs of fetuses of 135-day gestational age not different from those of the mature control group at 162 days. Controls at 135 days are significantly different from those at 162 days. Serotonin immunoreactive neuroepithelial bodies were localized by immunocytochemistry.     

Regulation of the glucocorticoid receptor in fetal rat lung during development

The effect of the synthetic glucocorticoid betamethasone on the regulation of the glucocorticoid receptor mRNA and on receptor protein was studied in fetal rat lung during development. Using a glucocorticoid receptor cRNA probe, glucocorticoid receptor mRNA was examined by Northern blot hybridization and by solution hybridization. A monoclonal antibody against the glucocorticoid receptor was used to study regulation of the receptor protein by the Western immunoblotting technique. In fetal rat lungs, of 16-21 days of gestation, as well as in adult lungs, betamethasone treatment resulted in a significant decrease of glucocorticoid receptor mRNA to 50-65% of the control level. In contrast, betamethasone treatment did not down-regulate the receptor protein in rat lungs of 16-19 days of gestation, whereas a decrease of glucocorticoid receptor protein to 40-60% of control was seen in lungs of 21 days of gestation, in postnatal and adult lung. These results provide data for a change in regulation in vivo of the glucocorticoid receptor by its homologous ligand in fetal rat lung during development.     

The organizational characteristics of the APUD system in mammalian lungs at different stages of ontogeny]

The organization peculiarities of APUD-system in the lungs of rabbits, rats and guinea pigs has been studied. The endocrine system in the lungs of rabbits in pre- and postnatal ontogenesis is presented by the adipocytes and neuroepithelial bodies (NEB) containing a considerable number of monoamines. The number of argyrophil adipocytes and NEBs in the lungs of 21 and more day-old adult rats seem to be less than in fetuses and newborns. Monoamines are not revealed in the endocrine rat lung structures by means of the glyoxylic acid. In the lungs of guinea pigs the single argyrophil adipocytes and NEBs are determined in the gestation period.     

Pulmonary intraepithelial vagal nodose afferent nerve terminals are confined to neuroepithelial bodies: an anterograde tracing and confocal microscopy study in adult rats

Our present understanding of the morphology of neuroepithelial bodies (NEBs) in mammalian lungs is comprehensive. Several hypotheses have been put forward regarding their function but none has been proven conclusively. Microscopic data on the innervation that appears to affect the reaction of NEBs to stimuli have given rise to conflicting interpretations. The aim of this study has been to check the validity of the hypothesis that pulmonary NEBs receive an extensive vagal sensory innervation. The fluorescent neuronal tracer DiI was injected into the vagal sensory nodose ganglion and NEBs were visualized in toto by using immunocytochemistry and confocal microscopy on 100-μm-thick frozen sections of the lungs of adult rats. The most striking finding was the extensive intraepithelial terminal arborizations of DiI-labelled vagal afferents in intrapulmonary airways, apparently always co-appearing with calcitonin gene-related peptide (CGRP)-immunoreactive NEBs. Not all NEBs received a traced nerve fibre. Intrapulmonary CGRP-containing nerve fibres, including those innervating NEBs, always appeared to belong to a nerve fibre population different from the DiI-traced fibres and hence did not arise from the nodose ganglion. Therefore, at least some of the pulmonary NEBs in adult rats are supplied with sensory nerve fibres that originate from the vagal nodose ganglion and form beaded ramifications between the NEB cells, thus providing support for the hypothesis of a receptor function for NEBs. Received: 13 November 1997 / Accepted: 17 February 1998     

Quantitation of pulmonary neuroepithelial bodies in pre- and postnatal rabbits

Summary The size, density and total number of neuroepithelial bodies (NEB) in the lungs of late fetal, neonatal, and mature rabbits were determined using fluorescence microscopy. In this study lungs from 27-, 29-, 30-, and 31-day fetuses; neonates of ages 2, 7, and 30 days; and 4- and 7(+)-month-old rabbits, were used. The total number of NEB in the entire lung of rabbits from each age group was estimated based on measurements of collapsed lung volume, average NEB diameter, and NEB density (number/mm²). Average NEB diameter increased between 27 and 29 days gestation, then remained constant at 42–44 m between 29 days gestation and two days post-partum. Thereafter the diameter was significantly reduced in the 7-day group (33.7 m) and further reduced in the 4-month group (20.3 m). NEB density was initially high in 27-day fetuses (3.87/mm²), decreased significantly by 30 days gestation, increased to a high level by 2 days post-partum, then fell steadily, reaching the lowest level in the adult (0.15/mm²). This steady decrease in density was paralleled by a large increase in lung volume. The estimated total number of NEB in the lung was constant in all age groups except for a significant drop at 30 and 31 days gestation. These data indicate that the total number of NEB is maintained into adulthood; however, the density and average diameter of NEB decreases rapidly after 2 days postpartum. A sharp decrease in both total number and density observed under fluorescence microscopy at 30 and 31 days gestation suggests a change in NEB cellular activity just prior to birth.     

Isolation and characterization of differentiated alveolar type II cells from fetal human lung

A method has been developed for isolating differentiated type II cells from human lung of 18-24-week gestation. The procedure involves an initial 4-day culture of lung explants in the presence of dexamethasone (10 nM) and triiodothyronine (2 nM). Type II cells (and fibroblasts) are isolated by trypsin digestion of the explants, two differential adherence steps and incubation overnight in primary culture. This method provides a high yield of type II cells ((50 +/- 15) X 10(6) cells/g wet weight of explant) with a purity of 85 +/- 5% in 16 experiments. The type II cells contain numerous perinuclear granules which stain darkly with toluidine blue and Papanicolaou stain; electron microscopy showed these inclusions to be lamellar bodies with tightly stacked, well defined lamellae. Type II cells, but not fibroblasts, were positive by immunofluorescence histology for surfactant apoprotein and binding of Maclura pomifera lectin which binds to the surface of type II but not type I cells in vivo. The rate of both [3H]acetate and [3H]choline incorporation into phosphatidylcholine (PC) was several-fold greater in type II cells than fibroblasts; the saturation of PC was 36.2 and 25.9%, respectively. Release of saturated PC was stimulated by terbutaline, the ionophore A23187, and tetradecanoyl phorbol acetate in type II cells but not fibroblasts. We conclude that differentiated type II cells can be isolated in relatively high yield and purity from hormone-treated explants of fetal human lung.     

Time-dependent effects of maternal continuous propranolol on fetal lung development in rats

Previous studies have demonstrated a role for the beta-adrenergic system in the maturation of the fetal alveolar epithelium. Chronic blockade of beta-adrenergic binding sites has been shown to adversely effect physiologic and biochemical indices of fetal lung maturation. In the present study timed-pregnant female Sprague-Dawley rats were treated with a continuous 0.5 mg/hr dose of propranolol HCl, or saline, via an osmotic pump. The treatment periods were days 18-21, or 20-23 of gestation. Fetal body weights were obtained, and the morphology of the fetal lungs studied by light and electron microscopy. Cytoplasmic volume densities of lamellar inclusion bodies and glycogen within developing type II alveolar epithelial cells were also determined. In addition, total phospholipids (as phosphorus) and glycogen content were determined biochemically. The fetuses from females treated from day 20-23 demonstrated no differences between saline-treated and propranolol-treated groups, in either fetal weight or the morphologic appearance of the developing lung. In contrast, the fetuses from mothers treated from day 18-21 with propranolol were significantly smaller, and their lungs appeared less mature than saline-treated counterparts. The glycogen content of developing type II alveolar epithelial cells was significantly more abundant (as judged by stereologic and biochemical analyses) in the propranolol-treated fetuses. In addition, total phospholipids were decreased in the propranolol-treated 21-day fetuses. The results of the present study suggest that the development of the alveolar epithelium is sensitive to continuous beta-adrenergic blockade by propranolol during a critical time late in gestation.