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)     

Dexamethasone increases adult rat lung surfactant lipids

Prenatal administration of glucocorticoids stimulates epithelial cell maturation and induces a precocious development of pulmonary surfactant. The response of the adult lung to steroid administration is less well understood. We administered dexamethasone (2 mg X kg-1 X day-1) to adult male rats for 1 wk by daily subcutaneous injection. After pentobarbital anesthesia we lavaged the lungs and also isolated lamellar bodies from the tissue. Lipid analyses of the extracellular and intracellular surfactant compartments showed two- to fourfold greater amounts of total phospholipids and disaturated phosphatidylcholine compared with control. These changes were not found in kidney nor liver and were not present in plasma membrane, mitochondrial, or microsomal fractions from lungs. Morphometric analyses of the type II cells showed that anatomic measures of the lamellar body pool did not increase. We conclude that glucocorticoids have a significant effect to increase lung surfactant lipid pools of adult rat lungs by changing the phospholipid content of lamellar bodies, without changing lamellar body volume.     

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.     

Lamellar bodies are the intracellular site of membrane turnover in insect fat body

Analysis of the time course of highly cationic ferritin uptake by fat body cells has shown that the tracer bound to the plasma membrane and was pinocytosed by coated vesicles. The first sites of intracellular accumulation were multivesicular bodies which became filled with ferritin between 30-60 min after cells were exposed to the tracer. At no time during the experiments were any parts of the Golgi complex labeled by the tracer. By 60 min, the ferritin was increasingly found in lamellar bodies. The different types of 'light' and 'dark' multivesicular bodies suggest that lamellar bodies form from multivesicular bodies as they fill with tracer. The occurrence of lamellar bodies in many different cell types suggests an important role in membrane dynamics.     

Actin in peripheral rat lung: S1 labeling and structural changes induced by cytochalasin

Actin was identified with S1-labeling in type I and II cells, pericytes, and capillary endothelial cells in the peripheral lung of the adult rat. In type II cells abundant actin was present in the apex of cells, in microvilli, and in close association with lamellar bodies near the cell surface. Lamellar bodies secreting their content into the lumen of alveoli were always surrounded by a thick layer of actin-like material. In specimens treated with cytochalasin D the surface of type I, type II and contractile interstitial cells became irregular. In type II cells, lamellar bodies were no longer surrounded by actin-like material and no exocytic profiles of lamellar bodies were encountered. In type II cells actin filaments may be involved in moving lamellar bodies through the cytoplasm and/or in their secretion into alveoli. These observations also suggest that intact actin filaments may be required for maintenance of cell shape in various lung cells and that cells containing actin may be capable of limited contraction.     

Twenty-four-hour variations in subcellular structures of rat type II alveolar epithelial cells

Summary Subcellular structures of type II alveolar epithelial cells in the rat lung were analyzed at six evenly spaced times over 24 h (light period: 06.00 h–18.00 h), using a morphometric technique. The cell volumes were maximal at 16.00 h and minimal at 08.00 h. The volume and surface densities of rough endoplasmic reticulum and mitochondria were low during the light period, and high during the dark period. Morphometric parameters of multivesicular bodies did not significantly fluctuate over 24 h, but they increased from 04.00 h to 08.00 h. The volume densities of lamellar bodies increased from 16.00 h to 20.00 h, and decreased from 00.00 h to 08.00 h. The change in numerical densities of lamellar bodies was inversely correlated to that in the volume densities. As shown by electron microscopy, small lamellar bodies predominated at 08.00 h, larger lamellar bodies increasing at 16.00h. Composite bodies often appeared at 08.00 h and 12.00 h. Type II cells thus appear to fluctuate, showing three phases over 24 h: formation, accumulation and secretion of lamellar bodies. In particular, it is noteworthy that the accumulation stage occurs during the resting phase of the rat, whereas the secretion stage occurs during its body-active phase.     

Electron microscopic observations of young rat liver

Summary Electron microscopic observations on normal liver tissue of four-day-old rats reveal the presence of numerous lamellar structures (lamellar bodies). These can be contained within parenchymal cells or in bile canaliculi, Disse's space, and in the lumen of blood sinusoids. Such bodies can also be found in Kupffer and endothelial cells.The lamellar bodies within hepatic cells are generally seen in very intimate relation to glycogen particles and lipide droplets, but in some to agranular endoplasmic reticulum and Golgi membranes as well.On the basis of this intimate relation to intracellular glycogen granules and lipide droplets, it is presumed that lamellar bodies represent a special intermediate stage in carbohydrate and lipide metabolism.Discontinuities in the endothelial layer of intrahepatic sinusoids are described.This work was supported in part by a N.A.T.O. research fellowship of the Consiglio Nazionale delle Ricerche, Roma.Assistant Professor in the Department of Veterinary Anatomy, Histology and Embryology (Dir.: Prof. A. de Girolamo), University of Naples, Naples, Italy.     

Lysozyme is an ozone-sensitive component of alveolar type II cell lamellar bodies

Exposure of rats to 3 ppm ozone for up to 8 h results in significant changes in lamellar bodies, the surfactant storing organelles of type II cells. We have previously shown that a 14 kDa lamellar body protein is decreased as early as 4 h after the onset of ozone exposure. We have isolated this ozone-sensitive protein from rat lung lamellar bodies and identified it as lysozyme by immunochemical methods, as well as by its amino acid composition, N-terminal amino acid sequence and bacteriolytic activity. Reduced lysozyme activity in isolated lamellar bodies is detected as early as 4 h after the start of ozone exposure. Following an 8 h ozone exposure, the activity does not return to control levels for at least 48 h. Lamellar body lysozyme is expected to be secreted with surfactant phospholipids, thereby contributing to the antimicrobial defense of the alveolar lining layer. The acute lysozyme deficiency seen in ozone-induced oxidant injury may reduce the resistance of the lung to infection.     

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.     

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.     

Ultrastructural analysis of the lining layer of the rat pulmonary alveolus.

Using electron microscopy we have examined the lining layer of the rat pulmonary alveolus. This layer appears as a morphological entity 1-3 days after birth: it is composed at first of a filamentous Ruthenium Red-negative material derived from lamellar bodies, and subsequently (4 days after birth) of a homogeneous Ruthenium Red-positive material. This latter material, which corresponds to the epithelia lining of the alveolus typical of adult rats, is presumably derived from a mixture of the filamentous material produced by the lamellar bodies, and a material produced by the alveolar cells 4 days after birth which contains acidic groups which bind Ruthenium Red.     

Localization of acid phosphatase in lamellar bodies of tannic acid treated alveolar type II cells

Summary Acid phosphatase was demonstrated in well preserved lamellar bodies of rats' alveolar type II cells. The highly ordered lamellar organization was preserved by using tannic acid in the tissue procession protocol. Acid phosphatase reaction products were observed in the amorphous regions of the lamellar bodies adjacent to the limiting membranes and in the central core regions. No reaction product was observed in the lamellar areas. 85%±5% of the lamellar bodies were positively reactive, unrelated to their size. Multivesicular bodies were only partially reactive (approx. 50%), except for those attached to lamellar bodies which all had reaction product.     

Localization of acid phosphatase in lamellar bodies of tannic acid treated alveolar type II cells

Acid phosphatase was demonstrated in well preserved lamellar bodies of rats' alveolar type II cells. The highly ordered lamellar organization was preserved by using tannic acid in the tissue procession protocol. Acid phosphatase reaction products were observed in the amorphous regions of the lamellar bodies adjacent to the limiting membranes and in the central core regions. No reaction product was observed in the lamellar areas. 85% +/- 5% of the lamellar bodies were positively reactive, unrelated to their size. Multivesicular bodies were only partially reactive (approx. 50%), except for those attached to lamellar bodies which all had reaction product.     

Cytochemical study of the lamellar bodies in the swimbladder of the toadfish Opsanus tau L.

Summary The columnar epithelial cells of the gas gland in the swimbladder of the toadfish, Opsanus tau L., contain lamellar bodies that resemble the lamellar bodies found in epithelial cells of vertebrate lungs. Cytochemical assays indicate that swimbladder lamellar bodies are soluble in chloroform-methanol solution, react with tricomplex flocculation solution (indicating a phospholipid component), exhibit a positive reaction for cholesterol when exposed to digitonin, and contain acid phosphatase.The anterior chamber of the toadfish swimbladder is lined by an extracellular layer. Digitonin-cholesterol crystals are found in this layer when the swimbladder is treated with digitonin. A ruthenium red positive layer is also present in the anterior chamber of the toadfish swimbladder.The structure and cytochemistry of swimbladder lamellar bodies are compared with those of vertebrate lung lamellar bodies. Similarities between the extracellular layer in the swimbladder and the extracellular layer in lungs are also noted.Supported in part by a grant No 1 R23 HL 19593-01 from the National Institutes of Health     

Isolation of lamellar bodies from rat granular pneumocytes in primary culture

A lamellar body fraction was isolated from rat alveolar granular pneumocytes in primary culture by upward flotation on a discontinuous sucrose gradient and compared with a similar fraction isolated from lung homogenates. Lamellar bodies from granular pneumocytes were free of detectable contamination with either succinate dehydrogenase or NADPH-cytochrome c reductase. There was an enrichment of acid phosphatase activity, which, based on distribution of enzyme activity on the gradient, did not appear to be a contamination from other fractions. The lamellar body fraction of granular pneumocytes yielded approx. 1 microgram protein/10(6) cells with a phospholipid-to-protein ratio (mg/mg) of 9.6 +/- 0.4 (n = 7). Composition with respect to total phospholipids was 71.0% phosphatidylcholine (disaturated phosphatidylcholine, 45.2%), 8.4% phosphatidylglycerol and 12.8% phosphatidylethanolamine. Palmitic acid comprised 66% of the fatty acids in phosphatidylcholine and 34% of those in phosphatidylglycerol. The lamellar body fraction from granular pneumocytes was similar to that from whole lung with respect to phospholipid-to-protein ratio and phospholipid composition and showed only minor differences in fatty acid composition. Ultrastructurally, lamellar bodies showed generally intact limiting membranes and lamellated structure. Lamellar bodies from granular pneumocytes showed occasional multinucleated whorls which were not seen in those isolated from lung homogenates. This study describes a method for preparing a homogeneous fraction of intact lamellar bodies from small amounts of material (6 X 10(7) granular pneumocytes). The yield on a per cell basis was higher when compared with a similar preparation from whole lung, although overall yield is small, due to loss of cells during the cell isolation procedure. This preparation may be useful to evaluate the role of lamellar bodies in the synthesis and secretion of lung surfactant by isolated granular pneumocytes.     

Structure and function of lamellar bodies, lipid-protein complexes involved in storage and secretion of cellular lipids.

This review article attempts to present an overview of the occurrence and function of lipid storage and secretory organelles: the lamellar bodies. Morphologically these organelles vary considerably in size (100 nm to 2400 nm); they are surrounded by a membrane and contain multilamellar lipid membranes. Lamellar bodies may also contain apolipoproteins and lytic enzymes and have an acidic pH, which confers on them a lysosomal character. Under normal physiological conditions, the main function of lamellar bodies is the supply of extracellular domains with specialized lipid components related to a specialized function. The lamellar bodies of the lung epithelium are best investigated in their functional and structural features and are the storage form of the lung surfactant. They provide a monomolecular lipid film of dipalmitoyl phosphatidylcholine (DPPC) on the surface of lung alveoli to lower surface tension necessary for optimal gas exchange and a hydrophobic protective lining against environmental influences. Additional cells of the respiratory system such as the mucosa of the human nose and the bronchi contain lamellar bodies. Lamellar bodies are also found in the gastrointestinal tract, in tongue papillae, oral epithelium, and mucosa cells of the stomach. The major phospholipid of lamellar bodies in mucosa cells of the stomach is DPPC, providing a hydrophobic protective lipid film against the tissue-damaging activities of gastric juice. The hydrophobic water-protective barrier of the skin, which consists mainly of neutral lipids, however, also originates from lamellar bodies secreted by epithelial cells. Lamellar bodies, mainly consisting of DPPC, also occur in mesodermal cell layers of sliding surfaces to provide the lubrication of joints, of the peritoneum, pericardium, and pleural mesothelium. In certain pathological conditions, such as atherosclerosis, Niemann-Pick disease, lecithin:cholesterol acyltransferase (LCAT) deficiency, cholestasis, degeneration of nerves and brain, and regeneration of nerves and wound healing, lipid-containing lamellar bodies have been observed in various cells, the function of which still remains to be elucidated. In early and late lesions of atherosclerotic plaques, lamellar bodies, consisting of unesterified cholesterol and phospholipids, are associated with the extracellular matrix of the intima. During regression of fatty streaks, lamellar bodies are seen intracellularly in macrophages and smooth muscle cells. Inherited metabolic disorders, such as Niemann-Pick disease type I and type II, result in the excessive accumulation of lamellar body-containing cells, for example in bone marrow, spleen, and lymphoid tissue. Type I is a deficiency in sphingomyelinase and type II is a defect in intracellular trafficking of lipoprotein-derived cholesterol.(ABSTRACT TRUNCATED AT 400 WORDS)     

Respiratory distress after intratracheal bleomycin: selective deficiency of surfactant proteins B and C

Intratracheal bleomycin in rats is associated with respiratory distress of uncertain etiology. We investigated the expression of surfactant components in this model of lung injury. Maximum respiratory distress, determined by respiratory rate, occurred at 7 days, and surfactant dysfunction was confirmed by increased surface tension of the large-aggregate fraction of bronchoalveolar lavage (BAL). In injured animals, phospholipid content and composition were similar to those of controls, mature surfactant protein (SP) B was decreased 90%, and SP-A and SP-D contents were increased. In lung tissue, SP-B and SP-C mRNAs were decreased by 2 days and maximally at 4--7 days and recovered between 14 and 21 days after injury. Immunostaining of SP-B and proSP-C was decreased in type II epithelial cells but strong in macrophages. By electron microscopy, injured lungs had type II cells lacking lamellar bodies and macrophages with phagocytosed lamellar bodies. Surface activity of BAL phospholipids of injured animals was restored by addition of exogenous SP-B. We conclude that respiratory distress after bleomycin in rats results from surfactant dysfunction in part secondary to selective downregulation of SP-B and SP-C.     

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.     

Ultrastructural changes in rat epididymis after vasectomy

Summary Epididymal biopsies from rats that had undergone unilateral or bilateral vasectomies from one to eight months previously were compared with biopsies from their contralateral side or from normal controls to ascertain what ultrastructural changes had occurred. After vasectomy, spermatozoa appeared to dissolve in the lumen of the caput epididymidis and to be absorbed by the principal cells. About 5 weeks after vasectomy, numerous lamellar accumulations became apparent in the supernuclear region. Their resemblance to lysosomes or residual bodies was confirmed by an acid phosphatase reaction. After 10 weeks, similar lamellar and polymorphic accumulations on the contralateral side of animals with unilateral vasectomies indicated that resorption had also increased on the unligated side.Publication No. 627 of the Oregon Regional Primate Research Center. This study was supported by NIH Grants No. RR-00163 and HD-05969.The author wishes to thank Ms. J. Hren for her excellent technical assistance.     

Alveolar type II cells: studies on the mode of release of lamellar bodies.

There is increasing evidence that type II alveolar cells are capable of synthesizing surface active material like that obtained from the airways. However a number of problems remain to be solved before it can be stated conclusively that type II cells synthesize the surface active material of the terminal airspace. Among these problems is that of secretion. A number of previous studies have given evidence of the release of lamellar bodies by merocrine secretion. In this study morphologic evidence is presented which supports the view that secretion of lamellar bodies is accomplished by exocytosis. At the apical surface of type II cells, sites can be found where the limiting membrane of the lamellar body is clearly fused with the type II cell plasma membrane and an open channel exists between the contents of the lamellar body and the alveolar space. At these sites the lamellar contents extrude into the airspace with consequent loss of the highly compact organization of intracellular lamellar bodies. The intactness and continuity of the membranes can be traced for the full extent of the exocytosis site. Freeze-etch replicas of the membranes of type II cells show depressions which may represent the sites of discharged lamellae. In addition, tongue-like folds are seen which could be explained as the extensions of cytoplasm which surround the releasing lamellar body and which may flap over the exocytosis pit after discharge. Micrographs of the alveolar space show disorganized lamellar whorls which appear to be unravelling to produce tubular myelin. In view of the unusually large size and lipid composition of lamellar bodies, a mechanism involving hydration of mucopolysaccharide contents as an aid to expulsion of lamellar contents is suggested.