The formation of histotypic structures from monodisperse fetal rat lung cells cultured on a three-dimensional substrate.

Enzymatically dissociated lungs from rat fetuses at 19-days gestation yield single cells which reaggregate to form alveolar-like structures when cultured on gelatin sponge discs. These structures form within 2 days and have been maintained in vitro for as long as 6 weeks. They are composed primarily of type II pneumonocytes as characterized by large, lightly stained nuclei and cytoplasmic inclusion bodies. The lamellar structure of these inclusion bodies has been confirmed by electron microscopy. The dynamic formation of inclusion bodies is suggested by the presence of lamellar bodies in the extra-cellular space and the appearance of new inclusions in the cytoplasm of the type II pneumonocytes. The formation and long-term maintenance of histotypic lung structures in vitro provides a model system for the study of lung development and synthesis of surfactant by type II alveolar pneumonocytes.     

Phospholipid composition of lamellar bodies formed by fetal rabbit lung type II cells in organ culture

Lung tissue obtained from fetal rabbits of 23 days gestational age was maintained in organ culture to study the in vitro formation of lamellar body phospholipids. During the culture period, the epithelium of the prealveolar ducts of the explants differentiated to form type II pneumonocytes. After 8 days in culture, the explants were harvested, homogenized, and two lamellar body fractions were isolated by sucrose density gradient centrifugation. The lamellar body fraction which best retained the distinct multilamellar structure was recovered at the interface between a solution of buffer without sucrose and buffer containing 0.41 m sucrose. The phospholipid compositions of both lamellar body fractions were similar to those reported for lamellar bodies and surfactant isolated from fetal rabbit lung, with the exception of a slightly higher phosphatidylethanolamine content. The disaturated phosphatidylcholine content of the lamellar body fractions, expressed as a percentage of total lipid phosphorus, was not influenced by the presence of palmitate in the medium.     

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.     

Fine structural localization of alkaline phosphatase in the granular pneumonocytes of hamster lung.

The fine structural localization of nonspecific alkaline phosphatase was studied in the granular pneumonocytes (type II alveolar epithelial cells) of hamster lung by incubating sections of glutaraldehyde-fixed tissues in a medium containing lead ions and sodium beta-glycerophosphate or alpha-naphthyl acid phosphate. The specificity of the reaction was tested by exposing the sections to inhibitors of alkaline phosphatase. The results showed that alkaline phosphatase activity was present in the inclusion bodies of granular pneumonocytes. The enzyme reaction was strong in the membrane lining the inclusion bodies and a weaker reaction was generally detectable in the inclusion contents. Although only a proportion of the inclusion bodies showed enzyme activity, there was no obvious correlation between the reactivity of the inclusions and their intracellular position or size. The other organelles were unreactive. The finding of alkaline phosphatase activity within the inclusion bodies of granular pneumonocytes is an enigma as these organelles are generally considered to be lyosomes.     

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.     

Ultrastructure of the lung of the rattlesnake,Crotalus viridis oreganus

Scanning and transmission electron microscopic observations were made on the rattlesnake lung, which has the form of a cigar-shaped bag enclosing a large axial air chamber. The lungs were fixed by tracheal instillation of fixative to preserve the structural features of inflated lungs. An open tracheal groove along the ventral aspect of the lung is the only structural “airway” present. The wall of the lung has two histologically distinct regions: anteriorly, a respiratory portion, where up to three generations of septa subdivide the wall into cup-shaped gas-exchange chambers, termed faveoli; and posteriorly, a simple, thin-walled saccular portion. The epithelium lining the internal surface of the lung is composed of several cell types: (1) ciliated cells; (2) type I pneumonocytes; (3) type II pneumonocytes, secretory cells characterized by the presence of lamellar bodies; and (4) serous epithelial cells, secretory cells characterized by the presence of homogeneous, densely staining secretory granules. However, the distinctiveness of the secretory cell types in the snake lung is blurred because intermediate-appearing cells have both the lamellar body and homogenous type of secretory granule. The nonepithelial components of the pulmonary wall and septa consist of blood vessels and lymphatics, smooth muscle cells and fibroblasts, embedded in a matrix of extracellular connective tissue fibers. Tubular myelin figures were observed in the faveolar lining layer.     

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

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

Basement membrane formation and lung cell differentiation in vitro

In high density cultures of mouse fetal lung cells, so-called "mass cultures", development of organoid structures, formation of a basement membrane (BM), and differentiation of pneumocytes type II occur accompanied by synthesis and secretion of lamellar bodies. The relationship between the formation of a BM, on the one hand, and morphogenesis as well as differentiation of pneumocytes type II, on the other hand, has been investigated by use of antibodies against BM components in the lung mass culture. It is shown here that anti-laminin antibodies prevented BM formation, but morphogenesis and pneumocyte differentiation occurred as in untreated cultures. Short-term treatment with the antibody revealed that the BM is formed only during the first 2 to 3 days in vitro. Already formed BM could not be removed by anti-laminin. Anti-collagen type IV antibodies showed no effect in the lung mass culture except for a stronger staining of the BM. Anti-BM-1 antibodies caused no changes in morphogenesis, cell differentiation and BM formation either, but the mesenchymal intercellular space exhibited a dark staining, which is probably due to antigen-antibody complexes. The results obtained with anti-laminin antibodies indicate that a BM is not necessary for lung cell differentiation in vitro.     

In vitro fusion of lung lamellar bodies and plasma membrane is augmented by lung synexin.

Lamellar bodies of lung epithelial type II cells undergo fusion with plasma membrane prior to exocytosis of surfactant into the alveolar lumen. Since synexin from adrenal glands promotes aggregation and fusion of chromaffin granules, we purified synexin-like proteins from bovine lung cytosolic fraction, and evaluated their effect on the fusion of isolated lamellar bodies and plasma membrane fractions. Synexin activity, which co-purified with an approx. 47 kDa protein (pI 6.8), was assessed by following calcium-dependent aggregation of liposomes prepared from a mixture of phosphatidylcholine:phosphatidylserine (PC:PS, 3:1, mol/mol). Lung synexin caused aggregation of liposomes approximating lung surfactant lipid-like composition, isolated lamellar bodies, or isolated plasma membrane fraction. Lung synexin promoted fusion only in the presence of calcium. It augmented fusion between lamellar bodies and plasma membranes, lamellar bodies and liposomes, or between two populations of liposomes. However, selectivity with regard to synexin-mediated fusion was observed as synexin did not promote fusion between plasma membrane and liposomes, or between liposomes of surfactant lipid-like composition and other liposomes. These observations support a role for lung synexin in membrane fusion between the plasma membrane and lamellar bodies during exocytosis of lung surfactant, and suggest that such fusion is dependent on composition of interacting membranes.     

Ultrastructure of the respiratory epithelium in the lungs of the tortoise,Testudo graeca

The respiratory epithelium in the lungs of the tortoise (Testudo graeca) has been studied by electron microscopy. The epithelium consists of a mosaic of two different cell types (here called "pneumonocytes"). Type I pneumonocytes are roughly squamous and possess attenuated flanges of cytoplasm which extend over the septal capillaries. Localized cytoplasmic expansions are often present near the periphery of these flanges. Most of the organelles are concentrated in the perinuclear region; the most prominent of these are the mitochondria and osmiophilic inclusions. In contrast, type II pneumonocytes are cuboidal and are richly endowed with organelles including large Golgi complexes, extensive endoplasmic reticulum and numerous inclusion bodies. The morphological evidence suggests that type I pneumonocytes are involved in the secretion of osmiophilic material (presumed to be pulmonary surfactant) and in maintaining the integrity of the air-blood barrier. Type II pneumonocytes appear to be concerned solely with the production of surfactant.     

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.     

The alveolar epithelium of the newborn rat,and the significance of the osmiophilic lamellated bodies in cellular autophagy

Abstract

An attempt was made to determine the nature, origin, and fate of the membrane material of osmiophilic lamellated bodies, using lung tissue from neonate rats. The cytoplasm of the type II alveolar pneumonocyte contains centrioles, multivesicular bodies, and minute free vesicles similar to those in the multivesicular bodies. Autolysosomes, comprising membrane-bounded cytoplasmic regions and osmiophilic lamellated material, also occur in the type II pneumonocytes. The mitochondria often contain concentric membrane accumulations and membranous whorls. The type II alveolar cells are characterised by an intensive autophagy; this is apparently correlated with glycogenolysis, and with a radical cytodifferentiation by which the cells transform to the type I pneumonocyte. The osmiophilic lamellae of the autolysosomes are probably emptied isolation membranes. The mitochondria possibly serve as repositories for the massive membrane accumulations remaining after cytoplasmic lysis, which may invaginate into the organelles. The osmiophilic lamellated bodies typical of type II alveolar pneumonocytes may be mitochondrial membranes packed with the residual membranous material. Myeloid matter in the alveolar spaces (derived from the osmiophilic lamellated bodies) is best interpreted, not as an organised secretory product, but rather as a residue of cellular autophagy.     

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)     

Clonal isolation of differentiated rat lung cells

Summary A number of diploid clones have been isolated from an enzymatic dispersion of normal rat lung. Four of these clones are epithelial in morphology, the remainder fibroblastic. On the basis of electron microscopic observations, two of the epithelial clones appear to have originated from type II alveolar pneumonocytes. Supported by funds from the W. Alton Jones Foundation and the American Lung Association.     

Surface-expressed lamellar body membrane is recycled to lamellar bodies

Monoclonal antibody (MAb) 3C9, an antibody generated to the lamellar body of rat lung type II pneumocytes, specifically labels the luminal face of the lamellar body membrane. To follow the retrieval of lamellar body membrane from the cell surface in these cells, MAb 3C9 was instilled into rat lungs. In vivo, it was endocytosed by type II cells but not by other lung cells. In type II cells that were isolated from rat lungs by elastase digestion and cultured on plastic for 24 h, MAb 3C9 first bound to the cell surface, then was found in endosomes, vesicular structures, and multivesicular bodies and, finally, clustered on the luminal face of lamellar body membranes. The amount internalized reached a plateau after 1.5 h of incubation and was stimulated with the secretagogue ATP. In double-labeling experiments, internalized MAb 3C9 did not completely colocalize with NBD-PC liposomes or the nonspecific endocytic marker TMA-DPH, suggesting that lamellar body membrane is retrieved back to existing lamellar bodies by a pathway different from that of bulk membrane and may be one pathway for surfactant endocytosis. The lamellar body membrane components are retrieved as subunits that are redistributed among the preexisting lamellar bodies in the cell.     

Giant lamellar bodies in pulmonary MALT lymphoma. A case report

BACKGROUND: Giant lamellar bodies are laminated, scroll-like whorls seen within alveolar spaces and have been occasionally observed in sclerosing hemangioma of the lung. However, to the best of our knowledge, the cytologic findings of giant lamellar bodies have not been reported. We describe cytologic findings of giant lamellar bodies associated with pulmonary mucosa-associated lymphoid tissue (MALT) lymphoma. CASE: A 72-year-old male had a pulmonary mass measuring 2.0 x 1.4 x 1.5 cm. Cytologic smears imprinted from a cut surface of the resected mass revealed a large number of concentrically laminated structures, giant lamellar bodies, measuring 15-40 microns in diameter. Necrotic cellular remnants were occasionally observed in the center of the structures. In the background, small to medium-sized lymphoid cells and plasmacytoid cells were observed. Histologic diagnosis of the tumor was IgG, kappa type, MALT lymphoma. An aggregate of giant lamellar bodies was observed within entrapped, dilated alveolar spaces lined with hypertrophied, type II pneumocytes. Immunohistochemically, the giant lamellar bodies were positive for KL-6. CONCLUSION: Giant lamellar bodies may be derived from surfactant and necrotic type II pneumocytes and may be observed cytologically in cases of pulmonary MALT lymphoma.     

A role for diacylglycerol in annexin A7-mediated fusion of lung lamellar bodies

Lung surfactant secretion in alveolar type II cells occurs following lamellar body fusion with plasma membrane. Annexin A7 is a Ca2+-dependent membrane-binding protein that is postulated to promote membrane fusion during exocytosis in some cell types including type II cells. Since annexin A7 preferably binds to lamellar body membranes, we postulated that specific lipids could modify the mode of annexin A7 interaction with membranes and its membrane fusion activity. Initial studies with phospholipid vesicles containing phosphatidylserine and other lipids showed that certain lipids affected protein interaction with vesicle membranes as determined by change in protein tryptophan fluorescence, protein interaction with trans membranes, and by protein sensitivity to limited proteolysis. The presence of signaling lipids, diacylglycerol or phosphatidylinositol-4,5-bisphosphate, as minor components also modified the lipid vesicle effect on these characteristics and membrane fusion activity of annexin A7. In vitro incubation of lamellar bodies with diacylglycerol or phosphatidylinositol-4,5-bisphosphate caused their enrichment with either lipid, and increased the annexin A7 and Ca2+-mediated fusion of lamellar bodies. Treatment of isolated lung lamellar bodies with phosphatidylinositol- or phosphatidylcholine phospholipase C to increase diacylglycerol, without or with preincubation with phosphatidylinositol-4,5-bisphosphate, augmented the fusion activity of annexin A7. Thus, increased diacylglycerol in lamellar bodies following cell stimulation with secretagogues may enhance membrane fusion activity of annexin A7.     

Regulation of surfactant secretion in alveolar type II cells

Molecular mechanisms of surfactant delivery to the air/liquid interface in the lung, which is crucial to lower the surface tension, have been studied for more than two decades. Lung surfactant is synthesized in the alveolar type II cells. Its delivery to the cell surface is preceded by surfactant component synthesis, packaging into specialized organelles termed lamellar bodies, delivery to the apical plasma membrane and fusion. Secreted surfactant undergoes reuptake, intracellular processing, and finally resecretion of recycled material. This review focuses on the mechanisms of delivery of surfactant components to and their secretion from lamellar bodies. Lamellar bodies-independent secretion is also considered. Signal transduction pathways involved in regulation of these processes are discussed as well as disorders associated with their malfunction.     

Concentrically arranged endoplasmic reticulum containing some lamellae (bar-like structure) in alveolar type II cells of rat lung

We examined in vivo the effect of pilocarpine (a cholinergic agent) and cycloheximide (an inhibitor of protein synthesis) on the "bar-like structures" in alveolar type II cells of rat lung to clarify their origin and significance in pulmonary surfactant production and secretion. Lungs were examined with an electron microscope using ultrathin sectioning, freeze-fracture technique, and morphometry. The bar-like structures in type II cells consisted of a concentrically arranged endoplasmic reticulum containing some amount of osmiophilic periodic material similar to the lamellae of lamellar bodies. Pilocarpine induced the accumulation of lamellar bodies of normal size which paralleled the increase in the number of bar-like structures in the cytoplasm of the type II cells. Cycloheximide induced a decrease in size of the lamellar bodies and an enlargement of the bar-like structures. Our morphological findings suggest that: The phospholipid that would normally be incorporated into the lamellar bodies might be sequestered instead in the concentrically arranged endoplasmic reticulum, forming the bar-like structures, and The enlargement and the increased number of bar-like structures may be responsible in part for the changed metabolic process of surfactant production by alveolar type II cells.