Fetal lung disaturated phosphatidylcholine. Ostensible increase following exposure to dexamethasone

Fetal rat lung removed at 15 days gestation and placed in organ culture incorporates choline into phosphatidylcholine. Addition of 10(-9) M dexamethasone resulted in increased rates of choline incorporation per micrograms protein after both 6 and 12 days culture. This concentration of dexamethasone did not increase tissue phosphatidylcholine or disaturated phosphatidylcholine. Thus, at a culture time when dexamethasone had a significant effect on choline incorporation, there was no change in either the total phospholipid or disaturated phosphatidylcholine content of the lung tissue. The transplacental administration of dexamethasone decreased fetal lung DNA and phospholipid content. At the mid-range dosage tested (400 micrograms), dexamethasone depressed DNA (51%) appreciably more than total phosphatidylcholine (28%) and disaturated phosphatidylcholine (33%). These results show that the hormone does not increase the total amount of surfactant per lung. The increased disaturated phosphatidylcholine per mg DNA results in an ostensible beneficial effect of dexamethasone on surfactant and may reflect an increased proportion of Type II cells in fetal lung both in vitro and in vivo following hormone exposure. Disaturated phosphatidylcholine per Type II alveolar cell is no doubt increased but the trade-off is fewer total cells in the lung.     

Relationships among surfactant fraction lipids, proteins and biophysical properties in the developing rat lung

Lung development is associated with increases in specific phospholipids and proteins that function as critical pulmonary surfactant components. Attempts to characterize the pattern of surfactant development in fetal rat lungs have been hampered by the lack of a micromethod which will permit quantitative isolation of surface active components from small tissue specimens. As part of studies designed to elucidate the metabolic regulation of lung development in the rat, we developed sucrose density gradient centrifugation procedures to separate pulmonary phospholipids and proteins into a presumed surfactant (S) fraction and a residual (R) fraction. Electron microscopy of S pellets from mature fetuses identified predominant lamellar bodies and minimal contamination; incubation with 5 mM CaCl2 induced the appearance of tubular myelin figures, implying functional potential. This was confirmed by demonstrating low surface tension (less than 1 dyn/cm) in S, but not R, fractions at term gestation (21.5 days) and in 1-day-old neonatal lung isolates, based on dynamic measurements using the oscillating bubble technique. Surface activity was also high in the S pellets from fetuses at 20.5 days of gestation; however, at 19.5 days, minimum surface tension values of at least 19 dyne/cm were seen. These results correlated directly with biochemical analyses which indicated striking increases in three surfactant-associated proteins (SP-A, SP-B, and SP-C) after 19.5 days of gestation; a finding in agreement with previously reported data on the developmental increase of disaturated phosphatidylcholine in fetal rat lung. We conclude that isolation of S fraction components is valuable for demonstrating maturation of the fetal rat lung and may provide a useful tool for the study of regulatory mechanisms influencing surfactant production and function.     

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.     

Quantification of surfactant pool sizes in rabbit lung during perinatal development

Methods are presented for the quantitative isolation of surfactants from fetal and newborn rabbit alveolar lavage returns and post-lavaged lung tissue homogenates. The phospholipid content of both fractions progressively increased between 27 days gestation and term (31 days). The tissue-stored fraction increased approximately 16-fold (from 0.48 +/- 0.13 to 7.83 +/- 0.86 mg/g dry lung) and the alveolar fraction more than 30-fold (from 0.08 +/- 0.02 to 2.69 +/- 0.52 mg/g dry lung). Developmental changes in phospholipid composition were also observed. Tissue-stored surfactant was prepared using differential and density gradient centrifugation. Alveolar surfactant was isolated during fetal development as a high-speed pellet following a one-step differential centrifugation. There was little change in the phospholipid content of fetal alveolar lavage supernatant (range 0.12 +/- 0.04 to 0.28 +/- 0.09 mg/g dry lung). By the first postnatal day the phospholipid content of both lavage fractions significantly increased (pellet, 7.51 +/- 1.79; supernatant, 4.01 +/- 1.36 mg/g dry lung) and both were identified as surfactant. This increase in alveolar surfactant was accompanied by an approximately twofold decrease (to 3.81 +/- 1.1 mg/g dry lung) in the tissue-stored fraction. These data provide a quantitative profile of surfactant accumulation and secretion in developing rabbit lung.     

Optimization of fetal lung organ culture for surfractant biosynthesis

Summary Lung organ culture has been a widely used system for studying differentiation and maturation of alveolar epithelium through various culture conditions. The purpose of this work was to carefully characterize in vitro lung biochemical diffeentiation through isolation of surfactant fraction from tissue and to search for optimal culture conditions. Fetal rat lung was explanted on the 18th gestational day for studying glycogen storage, and on the 20th gestational day for studying surfactant accretion, and cultivated for 48 h. Morphologic differentiation was studies byelectron microscopy tissue explanted on the 17th or 18th gestational days and cultivated for various times. Glycogen storage was greater on fluid medium, although less than occurring in vivo. Cellular integrity and surfactant accumulation were maximal on a semisolid medium containing 0.5% agar. Use of O₂-CO₂ instead of air-CO₂ for gassing the explants slighlty decreased phospholipid accumulation. Among media used in previous lung culture studies, Waymouth MB 752/1 was the only one to allow net glycogen accumulation in vitro. The most favorable media for surfactant phospholipid accretion were Waymouth MB 752/1, Eagle’s minimum essential and its Dulbeccco’s modification, CMRL 1066, and NCTC 109. They allowed a 12- to 14-fold increase of surfactant fraction phospholipids in vitro, which is similar to the increase occurring in vivo during the same peiod. Ham’s F10 and F12 media allowed a six fold increase. RPMI 1640 and medium 199 (M199) allowed only a three fold increase. Phospholipid concentration in nonsurfactant fraction only doubled during culture, and differences between various media were much less marked. DNA concentration changed little during culture. Morphologic differentiation of epithelial cells was advanced as compared with in vivo timing in a medium allowing maximal surfactant accretion (Waymouth MB 752/1) but not in a medium allowing low surfactant increase (RPMI 1640). The possible role of compositional differences between media is discussed.     

Leptin does not influence surfactant synthesis in fetal sheep and mice lungs

In the fetus, leptin in the circulation increases at late gestation and likely influences fetal organ development. Increased surfactant by leptin was previously demonstrated in vitro using fetal lung explant. We hypothesized that leptin treatment given to fetal sheep and pregnant mice might increase surfactant synthesis in the fetal lung in vivo. At 122-124 days gestational age (term: 150 days), fetal sheep were injected with 5 mg of leptin or vehicle using ultrasound guidance. Three and a half days after injection, preterm lambs were delivered, and lung function was studied during 30-min ventilation, followed by pulmonary surfactant components analyses. Pregnant A/J mice were given 30 or 300 mg of leptin or vehicle by intraperitoneal injection according to five study protocols with different doses, number of treatments, and gestational ages to treat. Surfactant components were analyzed in fetal lung 24 h after the last maternal treatment. Leptin injection given to fetal sheep increased fetal body weight. Control and leptin-treated groups were similar in lung function (preterm newborn lamb), surfactant components pool sizes (lamb and fetal mice), and expression of genes related to surfactant synthesis in the lung (fetal mice). Likewise, saturated phosphatidylcholine and phospholipid were normal in mice lungs with absence of circulating leptin (ob/ob mice) at all ages. These studies coincided in findings that neither exogenously given leptin nor deficiency of leptin influenced fetal lung maturation or surfactant pool sizes in vivo. Furthermore, the key genes critically required for surfactant synthesis were not affected by leptin treatment.     

Development of the pulmonary surfactant system in non-mammalian amniotes

Pulmonary surfactant (PS) is a complex mixture of phospholipids, neutral lipids and proteins that lines the inner surface of the lung. Here, it modulates surface tension thereby increasing lung compliance and preventing the transudation of fluid. In mammals, the PS system develops towards the end of gestation, characterized by an increase in the saturation of phospholipids in lung washings and the appearance of surfactant proteins in amniotic fluid. Birth, the transition from in utero to the external environment, is a rapid process. At this time, the PS system is important in opening and clearing the lung of fluid in order to initiate pulmonary ventilation. In oviparous vertebrates, escape from an egg can be a long and exhausting process. The young commence pulmonary ventilation and hatching by 'pipping' through the eggshell, where they remain for some time, presumably clearing their lungs. This paper relates changes in the development of the pulmonary surfactant system within the non-mammalian amniotes in response to birth strategy, lung morphology and phylogeny in order to determine the conservatism of this developmental process. Total phospholipid (PL), disaturated phospholipid (DSP) and cholesterol (Chol) were quantified from lung washings of embryonic and hatchling chickens, bearded dragons (oviparous), sleepy lizards (viviparous), snapping turtles and green sea turtles throughout the final stages of incubation and gestation. In all cases, the pattern of development of the pulmonary surfactant lipids was consistent with that of mammals. PL and DSP increased throughout the latter stages of development and Chol was differentially regulated from the PLs. Maximal secretion of both PL and DSP occurred at 'pipping' in oviparous reptiles, coincident with the onset of airbreathing. Similarly, the amount of DSP relative to total PL was maximal immediately after the initiation of airbreathing in chickens. The relative timing of the appearance of the lipids differed between groups. In the oviparous lizard, surfactant lipids were released over a relatively shorter time than that of the sleepy lizard, turtles, birds and mammals. Thus, despite temporal differences and vastly different lung morphologies, birth strategies and phylogenies, the overall development and maturation of the PS system is highly conserved amongst the amniotes.     

Lack of change in the composition of fetal lamb lung surfactant during gestation

Fetal surfactant from lamb lung fluids collected daily from day 114 to day 146 of gestation, was isolated by centrifugation (pellet material) and further purified by sucrose density gradient centrifugation. The concentration of the pellet material from lung fluid (crude surfactant) increased from day 125 till day 135 and fluctuated strongly from that period onwards, whereas lung fluid secretion increased linearly until a few days before parturition. The pellet phospholipid composition changed with gestational age, suggesting biochemical maturation of the surfactant-producing system. The purified surfactant fraction, of which approximately 85% was phosphatidylcholine, did not change however from day 122 onwards except for a small increase in the percentage of phosphatidylglycerol. Alveolar wash surfactant or the lamellar body material, isolated from fetal lungs at different gestational ages had the same composition as surfactant from lung fluids. Only the composition of lamellar bodies of '125 day' lungs differed slightly from that of the lung fluid surfactant. The similar characteristics of all purified surfactant fractions throughout gestation indicate that, in the fetal lamb, lung maturation is associated with an increase in surfactant production no significant changes in phospholipid composition.     

An organ culture system for study of fetal lung development

Fetal rat lungs placed in $\text{in}$$\text{vitro}$ organ culture at 15.5 days gestation grow significantly based on accumulation of DNA and protein. In the experimental system described, DNA accumulated rapidly during the first three days in culture and increased from 4.8 to 15.6 micrograms per lung culture. Protein content increased more slowly and reached a value more than double the initial value after six days in the culture system. Glycogen accumulated in the tissue during the first six days in culture and was depleted during the subsequent culture period, a pattern strikingly similar to that observed during lung development $\text{in}$$\text{vivo}$. Phospholipid accumulation was biphasic with respect to time with an inflection point at about the sixth day of culture. The phosphatidylcholine species synthesized in the culture system $\text{in}$$\text{vitro}$ were similar to those produced $\text{in}$$\text{vivo}$ in fetal lung at 21 days gestation.     

Studies on pulmonary surfactant. Effects of cortisol administration to fetal rabbits on lung phospholipid content, composition and biosynthesis.

Corticosteroids are known to accelerate maturation of the fetal lung and production of surfactant. We examined the effect of cortisol administration to fetal rabbits on the phospholipid content and composition of lung lavage and lung tissue, as well as on the activities of enzymes involved in the synthesis of phosphatidylcholine and phosphatidylglycerol, the major surface-active components of surfactant. Cortisol was administered by intrauterine injection at 25 days' gestation and the fetuses were delivered at 27 days (full term, 31 days). Saline-injected fetuses, littermates of the cortisol-treated as well as non-littermates, were used as controls. The amount of phospholipid in lung lavage from the hormone-treated fetuses was almost double that of the saline-injected controls and was similar to that of an untreated fetus of more than 30 days' gestation. Similarly, the phospholipid composition of lung lavage from the hormone-treated fetuses was similar to that of an untreated fetus at a greater gestational age. These data, therefore, suggest that cortisol acts by accelerating physiological development. Cortisol administratration stimulated the activity of cholinephosphate cytidylyltransferase and lysolecithin acyltransferase to a small, but statistically significant extent. This is also consistent with an acceleration of normal development. The stimulation of lysolecithin acyltransferase is of interest, since this enzyme is believed to be involved in the synthesis of dipalmitoylglycerophosphocholine, the major surface-active species of phosphatidylcholine. Cortisol administration had no effect on the activities of pulmonary choline kinase, cholinephosphotransferase, lysophosphatidic acid acyltransferase and glycerolphosphate phosphatidyltranferase, although we have previously shown the latter enzyme to be stimulated following a longer period of exposure to the hormone. Saline injection produced some maturational effects presumably as a result of stress, which may be mediated by corticosteroids or other hormones.     

Alterations in rat alveolar surfactant phospholipids and proteins induced by administration of chlorphentermine

Chlorphentermine is a cationic amphiphilic drug which produces a phospholipid storage disorder in rat lungs. Experiments were carried out to characterize changes in the composition of acellular alveolar lavage materials and to study possible mechanisms by which pulmonary surfactant phospholipidosis is produced by administration of the drug. Following ten daily injections of chlorphentermine (25 mg/kg body weight), there are 12.2- and 13.6-fold increases of pulmonary lavage total phospholipids and disaturated phosphatidylcholines (disaturated PC), respectively. In addition, there is a 2.8-fold increase in total protein and a 12.7-fold increase in the surfactant apoprotein group with molecular weights from 28,000 to 32,000. We measured incorporation of labeled palmitate, choline and glycerol into disaturated PC in type II cells and alveolar macrophages isolated from control and chlorphentermine-treated animals. The drug does not affect the incorporation of labeled substrates into disaturated PC in either cell type. However, in alveolar macrophages there is a decrease in the rate of intracellular degradation of recently synthesized disaturated PC in chlorphentermine-treated animals. The drug also inhibits the phospholipase-induced catabolism of rat surfactant disaturated PC which occurs during incubation of alveolar lavage fluid in vitro at 37 degrees C. When the lavage fluid is divided into subfractions by differential centrifugation, a larger percentage of the phospholipid is distributed in the less sedimentable subfractions in chlorphentermine-treated animals relative to controls, suggesting the accumulation of older surfactant materials. These results suggest that chlorphentermine-induced phospholipidosis of pulmonary surfactant materials is due to decreased rates of phospholipid degradation.     

Stimualtion of glycerolphosphate phosphatidyltransferase activity in fetal rabbit lung by cortisol administration.

Phosphatidylglycerol is an important component of pulmonary surfactant. Previous studies have shown that direct administration of corticosteroids of thyroxine to the fetus during the latter part of gestation results in accelerated lung maturation with increased surfactant production. We have shown that administration of cortisol to fetal rabbits at 24 days' gestation results 3 days later in a significant increase in the activity of pulmonary glycerolphosphate phosphatidyltransferase, an enzyme involved in the synthesis of phosphatidylglycerol. The activity of the liver enzyme was not affected. Choline phosphotransferase, CDPdiglyceride-inositol phosphatidyltransferase, lysophosphatidic acid acyltransferase and lysolecithin acyltransferase activities were not altered significantly by cortisol treatment. Thyroxine treatment had no effect on any of the enzymes of phospholipid or fatty acid biosynthesis studied.     

Phospholipid content, composition and biosynthesis during fetal lung development in the rabbit.

The phospholipid content and composition of lung wash and lung tissue as well as the activities of the enzymes involved in the synthesis of phosphatidylcholine and phosphatidylglycerol (the major surface active components of pulmonary surfactant) were studied in the rabbit during fetal lung development. In lung wash the amount of phospholipid increased four-fold during the period 27-31 day's gestation. There was a further ten-fold increase following the onset breathing. During the same period the amount of phosphatidylcholine in lung wash increased from 29% of the total phospholipid to 80% while the amount of sphingomyelin decreased from 38% to 2%. The amount of phosphatidylcholine in lung tissue also increased during development but to a much lesser extent. During fetal lung development the activities of choline kinase and cholinephosphate cytidyltransferase changed little, cholinephosphotranserase decreased while lysophosphatidic acid acyltransferase and lysolecithin acyltransferase increased. There was a postnatal increase in the activities of cholinephosphate cytidyltransferase, cholinephosphotransferase and both acyltransferases. The amount of phosphatidylglycerol, as a percentage of the total phospholipid, in lung wash and lung tissue as well as the activity of pulmonary glycerolphosphate phosphatidyltransferase did not change appreciably during development.     

Regulation of the synthesis of the major surfactant apoprotein in fetal rabbit lung tissue

Antibodies directed against the major apoprotein of rabbit lung surfactant, a 29-36-kDa glycoprotein, were used to study changes in the levels of translatable surfactant apoprotein mRNA in rabbit lung tissue during development, as well as the effects of cortisol and cyclic AMP analogues on the levels of surfactant apoprotein and its mRNA in fetal rabbit lung tissue in organ culture. The major surfactant apoprotein and its mRNA were undetectable in lung tissues of 21-day gestational age fetal rabbits. Translatable mRNA specific for the major surfactant apoprotein was first detectable in lung tissues of 26-day fetuses, increased 25-fold on day 28, reached peak levels at day 31, and declined after birth. Incubation of 21-day fetal rabbit lung explants with cortisol in serum-free medium resulted in an increase in the specific content of the 29-36-kDa apoprotein. Cyclic AMP analogues and forskolin, an activator of adenylate cyclase, also caused a marked increase in the accumulation of surfactant apoprotein. When fetal lung explants were incubated with cortisol and dibutyryl cyclic AMP in combination, the specific content of the surfactant apoprotein was increased to levels greater than that of explants treated with either cortisol or dibutyryl cyclic AMP alone. These effects of dibutyryl cyclic AMP and cortisol on surfactant apoprotein accumulation were associated with comparable changes in the levels of translatable surfactant apoprotein mRNA. Thus, we have shown for the first time that the induction of pulmonary surfactant apoprotein synthesis during differentiation in vitro and in vivo is associated with an increase in the level of translatable mRNA and that cortisol and cyclic AMP increase both the accumulation of the major surfactant apoprotein and the corresponding mRNA in fetal rabbit lung tissue in vitro.     

Fetal lung surfactant lipid synthesis from glycogen during organ culture

The role of fetal lung glycogen as a precursor for lipids during late gestational development was explored by a combination of in vivo labeling with [U-14C]glucose, administered directly to rat fetuses at 18.5 days, and in vitro assessment using an organ explant culture system. Our major objectives were to demonstrate that radioactivity was transferred specifically and preferentially to surfactant lipids, as glycogenolysis occurred, and to determine the molecular distribution of 14C labeling in newly synthesized phosphatidylcholine (PC). Surfactant and residual (non-surfactant) lipids were separated by sucrose density gradient centrifugation, and other subcellular fractions such as microsomes were isolated by subsequent centrifugations. After 72 h of culture, there was a 5.7-fold increase in the concentration of PC in the surfactant fraction, which contributed 8.8% of total PC at the beginning and 29.6% (P less than 0.001) at the end of the 72 h period. The labeling of PC in the surfactant fraction increased markedly during culture, but there was no significant change in the residual fraction or microsomal PC. Hydrolysis of surfactant PC indicated that the radioactivity was predominantly located in the fatty acyl portion of the molecule, both before and after culture; however, PC glycerol labeling also increased significantly during culture. The distribution of PC radioactivity was similar in the residual fraction and microsomes, with the majority of 14C in the fatty acids. Neutral lipid radioactivity also increased significantly in both the surfactant (240%) and residual (136%) fractions. Quantitation of the changes in radioactivity among subcellular components during lung explant culture indicated that the greatest decrease occurred in glycogen, whereas only lipids, particularly those of the surfactant fraction, were found to show significant increases. These results support the hypothesis that glycogen, which accumulates in fetal lung prior to augmented surfactant production, can supply precursors for synthesis of functionally essential pulmonary phospholipids.     

Differential effects of epidermal growth factor and transforming growth factor-beta on synthesis of Mr = 35,000 surfactant-associated protein in fetal lung

Differentiation of pulmonary Type II epithelial cells in late gestation is associated with the synthesis of pulmonary surfactant required for adaptation to air breathing at birth. In the present work, induction of synthesis of a Type II epithelial cell protein, surfactant-associated glycoprotein of Mr = 35,000 (SAP-35) was studied in human fetal lung tissue obtained at 15-24 weeks of gestation. SAP-35 content increased during organ culture in the absence of exogenous hormones. Epidermal growth factor or triiodothyronine stimulated the induction of SAP-35 synthesis during culture. Stimulation by epidermal growth factor (EGF) was detected as early as 2 days and persisted for up to 5 days in culture. Response to EGF was dose-dependent (0.01-10 ng/ml) and was associated with enhanced incorporation of [35S]methionine into immunoprecipitable SAP-35. Increased SAP-35 synthesis was associated with increased SAP-35 RNA as assessed by Northern blot and hybridization assays with human SAP-35 cDNA. Effects of EGF were comparable to the induction of SAP-35 synthesis by 8-bromo-cAMP. In contrast to the stimulatory effect of EGF and triiodothyronine, SAP-35 content was inhibited by transforming growth factor-beta. Both the stimulatory and inhibitory effects of these agents on SAP-35 content were associated with concomitant changes in SAP-35 synthesis. These findings demonstrate multihormonal control of SAP-35 expression and strongly implicate both EGF and transforming growth factor-beta in the regulation of surfactant apoprotein synthesis.     

Adenosine and leukotrienes have a regulatory role in lung surfactant secretion in the newborn rabbit

Previous studies have shown that secretion of phosphatidylcholine in cultured adult rat type II pneumocytes is stimulated by purinoceptor agonists and leukotrienes. The objective of the present study was to determine if such agents have a physiological role in the regulation of surfactant secretion. We chose the newborn rabbit as the experimental model, since in this system there is a marked increase in surfactant secretion immediately after birth. We examined the effects of an inhibitor of leukotriene biosynthesis, nordihydroguaiaretic acid, two leukotriene antagonists, FPL-55712 and FPL-57231, and a P1 purinoceptor antagonist, 8-phenyltheophylline, on this increase. Newborn rabbits were delivered by Cesarean section at 30 days gestation. Some animals in each litter were killed immediately, while others were injected with test agents or solvent vehicle while still in the amniotic sacs. After breathing for 3 h in an incubator, these animals were also killed. The lungs were lavaged with saline and the phospholipid content and composition of the lung lavage liquid was measured. In control animals, there was a greater than 2-fold increase in the amounts of total phospholipid and phosphatidylcholine and in the phosphatidylcholine/sphingomyelin ratio during the 3 h period of breathing. The increases in total phospholipid and phosphatidylcholine were decreased 38-62% by the antagonists, while the increase in the phosphatidylcholine/sphingomyelin ratio was decreased 61-77%. These data show that the ventilation-induced increase in secretion of lung surfactant in the newborn rabbit is inhibited by leukotriene and P1 receptor antagonists and by an inhibitor of leukotriene biosynthesis and, when taken together with the data from the tissue culture system, support a role for leukotrienes and adenosine in the physiological regulation of surfactant secretion.     

Induction of intra- and extra-cellular phospholipids in the lungs of rats exposed to silica.

Intracellular and extracellular compartments of phospholipids in the lungs of rats were examined 28 days after intratracheal injection of silica (200 mg/kg). All compartments containing phospholipids were elevated, but the largest increases were seen in the intracellular and extracellular pulmonary surfactant. Intracellular pulmonary surfactant increased 123-fold from 1.18 +/- 0.65 to 144.9 +/- 53.8 and the extracellular surfactant increased 22-fold from 1.17 +/- 0.04 to 25.1 +/- 7.1 mg per pair of rat lungs respectively. The phospholipid composition of intracellular and extracellular surfactant did not change in response to silica, except for an almost 2-fold increase in the percentage of total phosphatidylinositol in both compartments. The phospholipid content of the lungs increased from 24.9 +/- 4.6 to 268.6 +/- 20.8 mg, with the intracellular and extracellular surfactant accounting for 59.1 and 24.6% of this total increase respectively. These data demonstrate that the major increases in the phospholipid content of the lungs induced by silica is associated with the pulmonary-surfactant system.     

Ontogeny of the pulmonary surfactant and antioxidant enzyme systems in the viviparous lizard,Tiliqua rugosa

The antioxidant enzyme (AOE) system protects the lung from oxidative damage. The pulmonary surfactant (PS) system lowers the interfacial pressure within the lung, improving lung compliance and aiding lung clearance. In mammals, the AOE and PS systems develop in tandem during the final 10%-20% of gestation. Here, we investigated the development of these systems in the viviparous skink, Tiliqua rugosa. The content of total phospholipid (PL), disaturated phospholipid (DSP), and cholesterol (Chol) increased in lung washings from foetal lizards with advancing gestational age. Similarly, the relative saturation of the PLs increased throughout gestation, with mid-stage 40 foetuses having a DSP/PL equivalent to newborns and adults. Maternal lizards had significantly less total PL, DSP, and Chol than nongravid and newborn lizards; however, the relative composition did not differ from nongravid animals. This presumably results from compression of the lungs under the bulk of the developing foetus. The Chol/PL and Chol/DSP ratios declined early in development such that mid-stage 40 embryos had comparable ratios to both newborns and adults. Thus, it appears that the PS system matures in a similar manner in skinks and in mammals. However, the composition of surfactant is complete some weeks before parturition, probably to enable improved survivorship of the precocial young in the event of premature birth. Unlike the surfactant lipids, the AOEs, catalase, superoxide dismutase, and glutathione peroxidase did not differ appreciably throughout gestation. It appears therefore that like the surfactant lipids the AOE system is in readiness for air breathing throughout the latter stages of gestation, possibly in preparation for premature birth. Unlike mammals, the PS and AOE systems develop independently from one another.     

Role of phospholipase C in chlorphentermine-induced pulmonary phospholipidosis in rat

Daily, oral administration of chlorphentermine (60 mg/kg) for 5 days to rats produced a significant increase in the concentration of whole lung total phospholipid as well as sphingomyelin, phosphatidylserine, phosphatidylethanolamine, phosphatidylglycerol, phosphatidylinositol, and phosphatidylcholine. Similarly, a significant elevation in total and all individual phospholipid components was found in the lysosomal fraction of chlorphentermine-treated rat lung. In contrast, the activities of pulmonary Na+,K+-ATPase and alkaline phosphatase, enzymatic markers of membrane function, were not markedly affected by chlorphentermine treatment. The observed lung phospholipidosis was accompanied by inhibition of phospholipase C activity. Regardless of the phospholipid substrate, chlorphentermine significantly decreased pulmonary phospholipase C to approximately the same extent. Our data show that accumulation of phospholipid in whole lung and lysosomes is associated with an inhibition of phospholipase C activity.