Growth characteristics,morphology, and phospholipid composition of human type II pulmonary alveolar cells grown in a collagen-free microenvironment

Summary Human lung epithelial cells have been isolated and maintained in pure culture and characterized during their time in culture. Any residual fibroblasts were removed by selective trypsinization within the first 48 h in culture and the residual epithelial cells from the primary culture grew to confluent density. The epithelial cells at Passage 2 or greater were serially subpassaged when cultures reached ca. 80% confluency. This procedure permitted us to conduct biochemical and structural studies of starting materials and subsequent population doublings. Electron microscope evaluation of both initial monolayers and cell suspensions showed cultures to be composed of a single cell type. These cells had microvilli on their free or apical surface. Subsequent population doubling level 1 up to 5 exhibited the same structures. They contained lamellar inclusions, which are typical of Type II alveolar epithelial cells. Fetal lung (age 18 to 20 wk) cell suspensions processed for electron microscopy before culturing showed cells to be undifferentiated, epithelial-like with small microvilli along cell borders, and with desmosomes at cell junctions. Lamellar inclusions were not observed in these cells. Ultrastructural studies of the cultured epithelial cells demonstrated that the lamellar inclusions had a slightly positive reaction when tested for acid phosphatase. Phospholipid analysis of these lung epithelial cells showed a phospholipid composition consistent with that found in surfactant-containing Type II cells. Cultured epithelial cells stained with phosphine 3-R demonstrated a green fluorescent cytoplasm and nucleus with brightly fluorescent yellow-orange perinuclear particles. The preceding characterization of these cells leads us to conclude that they exhibit structural and biochemical features commensurate with Type II epithelial cells from human lung. Moreover, these selection techniques applied to the isolation of human lung Type II cells from the tissue permit us to study the differentiative function of these cells routinely under conditions of growth in vitro. This work was supported in part by grants from EPA, R 806638-01 and 131-640-1599A1     

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.     

Repopulation of a human alveolar matrix by adult rat type II pneumocytes in vitro : A novel system for type II pneumocyte culture

This paper describes the preparation of lung acellular alveolar matrix fragments and culture of rat type II pneumocytes directly on the alveolar epithelial basement membrane, thereby permitting study of the effect of lung basement membrane on the morphology and function of type II cells. Collagen types I, III, IV and V, laminin and fibronectin were located by immunofluorescence in the lung matrix with the same patterns as those described for the normal human lung. Transmission electron microscopy (TEM) of the fragments revealed intact epithelial and endothelial basement membranes. The matrix maintained the normal three-dimensional alveolar architecture. Glycosaminoglycans were still present by Alcian Blue staining. Isolated adult rat type II pneumocytes cultured on 150 micron thick fragments of acellular human alveolar extracellular matrix undergo gradual cytoplasmic flattening, with loss of lamellar bodies, mitochondria, and surface microvilli. These changes are similar to the in vivo differentiation of type II pneumocytes into type I pneumocytes. The type II pneumocyte behaviour on the lung epithelial basement membrane contrasted sharply with that of the same cell type cultured on a human amnionic basement membrane. On the latter surface the cells retained their cuboidal shape, lamellar bodies and surface microvilli for up to 8 days. These observations suggest that the basement membranes from different organ systems exert differing influences on the morphology and function of type II pneumocytes and that the alveolar and amnionic basement membranes may have differing three-dimensional organizations. The technique of direct culture of type II cells on the lung basement membrane provides a useful tool for studying the modulating effect of the basement membrane on alveolar epithelial cells.     

Identification and isolation of mouse type II cells on the basis of intrinsic expression of enhanced green fluorescent protein

The unique morphology and cell-specific expression of surfactant genes have been used to identify and isolate alveolar type II epithelial cells. Because these attributes can change during lung injury, a novel method was developed for detecting and isolating mouse type II cells on the basis of transgenic expression of enhanced green fluorescence protein (EGFP). A line of transgenic mice was created in which EGFP was targeted to type II cells under control of the human surfactant protein (SP)-C promoter. Green fluorescent cells that colocalized by immunostaining with endogenous pro-SP-C were scattered throughout the parenchyma. EGFP was not detected in Clara cell secretory protein-expressing airway epithelial cells or other nonlung tissues. Pro-SP-C immunostaining diminished in lungs exposed to hyperoxia, consistent with decreased expression and secretion of intracellular precursor protein. In contrast, type II cells could still be identified by their intrinsic green fluorescence, because EGFP is not secreted. Type II cells could also be purified from single-cell suspensions of lung homogenates using fluorescence-activated cell sorting. Less than 1% of presorted cells exhibited green fluorescence compared with >95% of the sorted population. As expected for type II cells, ultrastructural analysis revealed that the sorted cells contained numerous lamellar bodies. SP-A, SP-B, and SP-C mRNAs were detected in the sorted population, but T1alpha and CD31 (platelet endothelial cell adhesion molecule) were not, indicating enrichment of type II epithelial cells. This method will be invaluable for detecting and isolating mouse type II cells under a variety of experimental conditions.     

Characterization of the A549 Cell Line as a Type II Pulmonary Epithelial Cell Model for Drug Metabolism

Multiple cell types contribute to the pulmonary barrier including Type I and Type II alveolar epithelium. The objective of this research was to establish and characterize anin vitromodel of Type II alveolar epithelium using the A549 human lung adenocarcinoma cell line. A549 cells form confluent monolayers with Type II characteristic morphology and tannic acid staining for typical lamellar bodies. A549 cells possess P450 IA1 and P450 IIB6 as determined by Western blots. Both CYPIA1 and CYPIIB6 P450 isozymes were determined to be functional with the fluorescent resorufin assay. Only the IA1 isozyme was observed to be inducible with selected polycyclic hydrocarbons. Uptake and transport experiments were carried out in cluster plates and in Snapwells. Cationized ferritin, a nonspecific absorbtive marker, was found to be taken up by the cells in a concentration-, time-, and temperature-dependent fashion. Lucifer yellow, a fluid-phase marker, was not internalized by the A549 cells. Transferrin, a representative receptor-mediated endocytic marker, was found to be taken up by the cells in a concentration-dependent and competitive fashion. Transport experiments involving fluorescein–transferrin also showed that A549 monolayers were polarized, with a greater amount of intracellular transferrin being transported out of the basolateral side of the cells. The experimental data agree favorably with literature for primary cultures of Type II pulmonary epithelial cells. These results indicated that the A549 cell line may be useful for the studying the metabolic and macromolecule processing contributions of alveolar Type II cells to mechanisms of drug delivery at the pulmonary epithelium.     

Density and substrata are important in lung type II cell transdifferentiation in vitro.

Morphological techniques and metabolic cell marker assays were used to study the transdifferentiation of pulmonary type II epithelial cells to type I-like cells in vitro. In the lung this process is important during remodelling and alveolar repair. Type II cell phenotype was best maintained over eight days when densely packed cells were plated out on a commercially available extracellular matrix. Such cells retained type II cell characteristics (lamellar bodies, high activities of gamma glutamyl transpeptidase and alkaline phosphatase) but expressed low levels of rT1(40) a surface protein marker of type I cells. In contrast, low density cultures, irrespective of substratum, exhibited rapid cell spreading, loss of lamellar bodies, loss of type II cell enzyme markers and expressed high levels or rT1(40). Conditions have been described whereby the same isolate of type II cells can be used to produce differential epithelial phenotypes and use can be made of this for further characterisation or to investigate the effect of toxins on different lung cell types in vitro.     

Epithelial cell differentiation in organotypic cultures of fetal rat lung

The purpose of this investigation was to examine the suitability of an organotypic lung-cell culture model for the study of factors influencing fetal lung-cell differentiation. It has been reported that the use of carbon-stripped (hormone-depleted) bovine fetal calf serum in monolayer cell cultures of fetal rat lung prevents continued epithelial cell differentiation in vitro. In this study, organotypic cultures of fetal rat lung cells taken at day 20 of gestation (late canalicular stage) were prepared with a carbon-stripped medium. These organotypic cultures were examined by light, scanning, and transmission electron microscopy for comparison with controls prepared with unstripped bovine fetal calf serum. Highly organized three-dimensional tubular epithelial structures resembling saccules of immature lung were observed within the gelatin sponge matrix. Morphometric analysis of day 20 carbon-stripped samples revealed that 74.6% of the epithelial cells in the tubular structures contained osmiophilic lamellar bodies characteristic of type II pneumonocytes. Control specimens had 71.2% cells with lamellar bodies and did not differ significantly from the experimental group. These data are similar to those obtained with organ cultures of fetal rat lung but are in contrast to findings with monolayer culture systems. The observations of this study suggest that 1) the hormones extracted from bovine fetal calf serum by carbon-stripping are not solely responsible for the continued fetal lung cell differentiation observed in vitro, and 2) that spatial relationships between lung cells in vitro may be a significant factor in the control of differentiation.     

Maternal nicotine exposure: reponse of type II pneumocytes of neonatal rat pups.

The influence of maternal nicotine exposure during pregnancy and lactation on the Type II cells of lung tissue of one day old neonatal rat pups was investigated. The results clearly show that maternal nicotine exposure resulted in an increase in the type II cell count in the lungs of the offspring. In addition the lamellar body content of the type II cells of the nicotine exposed rat pups were significantly (P< 0.01) higher than that of the control animals. The type II cell mitochondria of lung tissue of nicotine exposed rat pups were swollen and no microvilli occurred on the alveolar surface. This clearly illustrates that nicotine interfered with type II cell integrity of tlte neonatal lung and may subsequently interfere with the normal development of the alveolar region of the lung.     

Differentiation of the pulmonary surfactant system. Disaturated phosphatidylcholine accumulation in fetal rat lung in vivo and in vitro

Fetal rat lung was placed in organ culture at 15 days gestation (22 days total gestation period), before biochemical and morphological development of the pulmonary surfactant system. At the fifth day of culture numerous Type II cells containing lamellar bodies were present as determined by electron micrography. Phospholipid accumulation in the cultures increased abruptly beginning at 6 days in culture. The phospholipid which accumulated between the sixth and twelfth culture days was composed of 21--27% disaturated phosphatidylcholines. Both the percent of disaturated phosphatidylcholines in the phospholipid fraction and the qualitative pattern of accumulation as a function of time were similar to observations for fetal rat lung developing in vivo. The data presented provide evidence for development of the pulmonary surfactant system in organ culture in vitro.     

Phospholipid biosynthesis and secretion by a cell line (A549) which resembles type II aleveolar epithelial cells.

The A549 cell line is a continuous cell line derived from a human adenocarcinoma of the lung. At low cell population density the cells contain relatively few lamellar bodies, but in mature cells in very confluent cultures lamellar bodies are abundant. The lamellar bodies from these cells are enriched for phosphatidylcholine and disaturated phosphatidylcholine. In mature cells, 45% of newly synthesized phosphatidylcholine is disaturated. Stimulation with the calcium ionophore A23187 produces exocytosis of phosphatidylcholine (46% disaturated). The A549 cell synthesizes, stores in lamellar bodies, and secretes phosphatidylcholine, and thus has many important biological properties of the alveolar epithelial type II cell.     

Culture characteristics of cells derived from type II pneumocyte enriched fractions from rabbit and rat.

Type II cell enriched fractions were isolated from rabbit and rat lungs using density gradient centrifugation. Cultures established from these fractions contained predominantly cells similar in most morphological respects to type II pneumocytes. These were in continuous replicating culture for 1 year and still exhibited contact inhibition. Membrane-bound structures reminiscent of, but no longer strictly identical to, type II cell lamellar cytosomes were seen in cells from these long-term cultures although their numbers were reduced in comparison to lamellar bodies in freshly isolated cells. Mitochondrial numbers and sizes, determined morphometrically, were reduced after culture in comparison to freshly isolated type II cells and those in situ. Phosphatidylcholine was synthesized by these cells and released into the extracellular medium. Application of laser activated electronic sizing data, confirmed by direct micrometry, demonstrated a significant increase in cell size as a function of culture. This sizing data, after prior confirmation by electron microscopy, was used as an aid in identifying type II cells and macrophages in dispersion, especially with those cells derived from rabbit lungs.     

Isolation of viable type II alveolar epithelial cells by flow cytometry

We developed a new method for isolating viable type II cells from fractionated and unfractionated lung cell suspensions by flow cytometry using acridine orange (AO). Fischer-344 rat lungs were dispersed into single-cell suspensions by a technique that yields a high number of cells (4-5 X 10(8) cells/lung, congruent to 85% viable), congruent to 11% of which are type II cells. Elutriated fractions from the lung cell preparation and parent, unfractionated cell suspensions were incubated with 1.0-0.02 micrograms/ml AO and analyzed by flow cytometry. Parameters analyzed included axial light loss (ALL) and red fluorescence (RF). Based on their unique RF, attributable to AO staining of type II cell lamellar bodies, and their ALL characteristics, type II pneumocytes were sorted from elutriated fractions to greater than 95% purity. Using the same approach, type II pneumocytes were sorted from unfractionated lung cell suspensions at greater than or equal to 85% purity. The viabilities of the type II alveolar epithelial cells isolated by this method range from 85% to 95%, and the ultrastructural features of the sorted cells were unaltered by AO labeling or sorting.     

Colocalization of cytokeratin 18 and villin in type III alveolar cells (brush cells) of the rat lung

Alveoli of the rat lung are lined by three different cell types, the flat type I cells and the cuboidal type II and type III cells. Type III cells differ from type II cells by the presence of an apical tuft of microvilli and the absence of lamellar type secretory granules. In the present study we show by double immunolabelling that type III cells of the rat lung can be identified at the light-and electron microscope level by antibodies against both cytokeratin 18 and the actin-crosslinking protein villin. At the ultrastructural level, microvilli and their rootlets in the apical cytoplasm were labelled by the anti-villin antibodies, whereas a monoclonal antibody against cytokeratin 18 (Ks18.04) labelled bundles of intermediate filaments. In conclusion, antibodies against villin and certain monoclonal antibodies specific for cytokeratin 18 can be used as tools for selective visualization of type III cells in the rat lung.     

Organotypic cultures of diploid type II alveolar pneumonocytes: surfactant associated esterase activity

Organotypic cultures, established from enzymatically dispersed day 19 fetal rat lung, are comprised primarily of cells which are morphologically similar to type II alveolar pneumonocytes, the cells involved in surfactant synthesis. To further characterize these cultures, the nonspecific esterase pool was examined to determine if these cultures contained certain nonspecific esterases previously shown to be enzyme markers for the surfactant system. The results of biochemical, electrophoretic and cytochemical studies indicate that these organotypic cultures contain the same nonspecific esterases already demonstrated in surface active fractions derived from rat and mouse lung homogenates and pulmonary lavage fluid. As in whole lung, the major site of esterase activity in the organotypic cultures is the type II cell lamellar body, the putative site of surfactant synthesis and storage. These findings support the concept that the organotypic cultures derived from fetal rat lung are comprised predominantly of type II cells which retain surfactant associated functions in vitro.     

Culture characteristics of cells derived from type II pneumocyte enriched fractions from rabbit and rat

Summary Type II cell enriched fractions were isolated from rabbit and rat lungs using density gradient centrifugation. Cultures established from these fractions contained predominantly cells similar in most morphological respects to type II pneumocytes. These were in continuous replicating culture for 1 year and still exhibited contact inhibition. Membrane-bound structures reminiscent of, but no longer strictly identical to, type II cell lamellar cytosomes were seen in cells from these long-term cultures although their numbers were reduced in comparison to lamellar bodies in freshly isolated cells. Mitochondrial numbers and sizes, determined morphometrically, were reduced after culture in comparison to freshly isolated type II cells and those in situ. Phosphatidylcholine was synthesized by these cells and released into the extracellular medium. Application of laser activated electronic sizing data, confirmed by direct micrometry, demonstrated a significant increase in cell size as a function of culture. This sizing data, after prior confirmation by electron microscopy, was used as an aid in identifying type II cells and macrophages in dispersion, especially with those cells derived from rabbit lungs.     

Culture of differentiated and undifferentiated type II cells from fetal rat lung

We have developed a relatively simple and reproducible method for the isolation and culture of both differentiated and undifferentiated type II cells from fetal rat lung. The technique involves an initial period of explant culture in serum and hormone free medium, followed by enzymatic dissociation of the explants, differential adhesion to remove fibroblasts, incubation of the cell pellet to promote aggregation of the type II cells and monolayer culture of the type II cells. The type II cells form clusters which are surrounded by scattered fibroblasts. When the technique was performed with three differential adhesion steps, cultures contained 86.0 +/- 1.4% type II cells. To obtain a higher degree of purity and greater yield, two differential adhesions followed by gentle trypsinization of the cultures which selectively removes the isolated fibroblasts was performed. This resulted in cultures with 89.4 +/- 1.7% type II cells. The differentiated fetal type II cell cultures were prepared from 19-day fetal rat lungs which were initially maintained in explant culture for 48 h. These differentiated cells demonstrated the characteristic morphologic features of type II cells including lamellar bodies and microvilli. Undifferentiated fetal cells were prepared in a similar manner from 18-day fetal rat lung maintained in explant culture for 24 h. These cells did not contain intracellular osmiophilic granules; the appearance of these granules could, however, be induced by hormones. For this reason they are considered to be pre-type II cells. The viability of the cultured cells was 97%. Both the differentiated and undifferentiated fetal type II cells specifically bound the Maclura pomifera lectin, a type II cell surface marker. The phospholipid profile of the fetal cells was similar to that of adult rat type II cells; the differentiated fetal cells, however, synthesized less phosphatidylcholine than the adult cells did, but more than the undifferentiated fetal cells. The differentiated fetal cells secreted phosphatidylcholine at a basal rate of 0.6% +/- 0.1% during a 90-min incubation. There was dose-dependent stimulation of phosphatidylcholine secretion after exposure to terbutaline. Maximum stimulation (76%) was observed at a concentration of 10 microM. This culture system provides a valuable model for studies of the maturation of the undifferentiated fetal type II cell and surfactant metabolism and secretion in the differentiated fetal type II cell.     

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.     

Fine structural identification of organoid mouse lung cells cultured on a pigskin substrate

Summary Mouse full-term embryonic lung tissue was cultured as organ bits using dead, sterile pigskin dermal collagen as a substrate. Explanted organ bits grew on the surface of, and into, the pigskin dermal collagen for at least 9 weeks after the initiation of culture. The out-growth consisted of a thick cellular sheet containing various sizes of ductular structures within a cellular matrix that did not show any particular structure. Electron microscopic observation revealed that the larger ductular structures consisted largely of ciliated cells. The smaller ductular structure consisted largely of Type II pneumocytes containing lamellar hodies. The cellular matrix consisted of Type II pneumonocytes and other cell types including fibroblasts and macrophages in the early stage of cultivation. Macrophages invaded the pigskin dermal collagen. An intermediate cell type, which has never been observed in vivo, possessing both cilia and lamellar bodies was identified in the larger ductular structures. Upon comparison of the ultrastructure of the organoid in vitro cultures in pigskin with the components and structure of the cultured cells more closely resembled adult lung than the fetal lung used to initiate the cultures. This work was supported by the Council for Tobacco Research Grant 1203M, American Cancer Society Grant RD-65 (for the equipment), and the National Cancer Institute Grant CA 25392.     

A comparison of the specificity of phosphatidylcholine synthesis by human fetal lung maintained in either organ or organotypic culture.

Human fetal lung (14-18 weeks gestation) was maintained in either organ or organotypic culture. By 4 days in organ culture or 14 days in organotypic culture, epithelial cells within both culture systems exhibited well-developed apical microvilli and possessed numerous intracellular lamellar bodies characteristic of surfactant phospholipid stores. However, analysis of the pattern of synthesis of individual molecular species of phosphatidylcholine by [14C]choline incorporation and reversed-phase h.p.l.c. showed that this apparent maturation was not paralleled by an increased synthesis of the dipalmitoyl species in either culture system. By contrast, the fractional synthesis of dipalmitoyl phosphatidylcholine, expressed as a percentage of total [14C]choline incorporation, decreased with time in both organ and organotypic culture. Moreover, these fractions were not significantly different from those measured in parallel monolayer cultures of mixed human fetal lung cells that displayed mainly fibroblast morphology. These results suggest that the synthesis pattern of phosphatidylcholine species by lung cells in culture is determined principally by their incubation conditions and not by their state of apparent maturation.     

Modification of surfactant metabolizing cells in rat lung by clofibrate, a hypolipidemic peroxisome proliferating agent. Evidence to suggest that clofibrate influences pulmonary surfactant metabolism

The influence of clofibrate (ethyl-alpha-p-chlorophenoxy-isobutyrate), a hypolipidemic peroxisome proliferating agent, has been tested on the lungs of adult male rats. Drug administration for 7 days caused structural changes in two types of lung cells, both of which are involved in the metabolism of the pulmonary surfactant. By light microscopy the prominent features were the presence of enlarged type II alveolar epithelial cells and foamy intraalveolar macrophages. Compared with controls, type II cells in treated rats apparently contained more numerous surfactant-containing lamellar bodies, as visualized in semi-thin sections of Epon-embedded tissue. This difference was quantified morphometrically by light microscopy: the number of lamellar bodies was estimated as the profile number per individual type II alveolar cell, transsected at its nucleus. Clofibrate administration for 7 days resulted in a significant increase in the number of the lamellar inclusions. In contrast the number of type II alveolar cells per area of lung remained unchanged. There was no evidence of atelectasis or inflammatory infiltration in the drug-treated lungs, a finding confirmed in sections of perfusion-fixed, paraffin-embedded whole lung-lobes. By electron microscopy the lamellar inclusion bodies in the type II alveolar cells in treated rats, apart from being more numerous and sometimes smaller, were morphologically identical to those in controls. The vacuolated alveolar macrophages seen in treated rats also contained various lamellar phospholipid inclusions.(ABSTRACT TRUNCATED AT 250 WORDS)