Isolation and characterization of rabbit lung lamellar bodies

A method has been devised for the isolation of a highly purified preparation of lamellar bodies from rabbit lung. The purity of the preparation was confirmed by electron microscopy, marker enzymes, phospholipid composition, and isopycnic centrifugation on continuous density sucrose gradients. Contamination of the lamellar bodies by such subcellular components as mitochondria, nuclei, lysosomes and plasma membranes could be excluded; however, reduced nicotinamide adenine dinucleotide phosphate (NADPH) cytochrome c reductase, an enzyme specific for the endoplasmic reticulum components was a persistent contaminant in the preparation of the isolated lamellar bodies. When the lamellar bodies were subject to isopycnic centrifugation, all of the NADPH cytochrome c reductase activity was associated with the lamellar bodies in the low density peak; no reductase activity could be detected in the region of the density gradient demonstrated to localize microsomes. Use of 3H-radiolabeled microsomes confirmed that all of the NADPH cytochrome c reductase activity present in the lamellar body preparations could be accounted for by microsomal contamination. When lamellar bodies or liposomal membranes synthesized from the total phospholipid fraction of lamellar bodies were analyzed by the electron paramagnetic resonance probe, 5-dioxyl-methylstearate, they exhibited a high degree of fluidity at physiological temperature. This was in contrast to the low fluidity of liposomal membranes composed of pure dipalmitoylphosphatidylcholine, the major component (50%) of rabbit lamellar body phospholipids. Furthermore, the major temperature-dependent phase transition in lamellar body membranes occurred at a different temperature (30.5 degrees C) from that of dipalmitoyl-phosphatidylcholine (41.0 degrees C). It is clear, therefore, that the membrane fluidity of lamellar bodies must be highly influenced by the minor lipid component.     

Formation of lung surfactant films from intact lamellar bodies.

Lamellar bodies, an intracellular source of lung alveolar surfactant, were isolated from rat lung homogenates and studied in the Langmuir-Adams surface balance. By layering intact lamellar bodies on the surface of a more dense sucrose subphase, we studied the factors affecting film formation from surface tension-vs-time data and determined surface tension-surface area isotherms by compression and expansion of the resulting films. We found that films with properties representative of the alveolar surfactant are formed in the presence of Ca2+ or Mg2+ alone, or either plus Na+; that film formation is incomplete with Na+ alone or on ion-free subphases; and that Ca2+-induced film formation is blocked by chelation with EGTA but is unaffected by diisopropylfluorophosphate. The results suggest that divalent cations induce film formation by interactions at sites within the lamellar bodies and may be responsible for the binding of membrane lipids to membrane proteins in lung surfactant.     

Human fetal heart development after mid-term: morphometry and ultrastructural study.

A total of 44 normally developed human fetal hearts aged from 17 to 40 weeks gestation were provided for routine ultrastructural and morphometric studies. For morphometric analysis, the maximal thicknesses of the anterior, lateral and posterior wall of both ventricles and that of interventricular septum were measured and the left-to-right thickness ratios calculated. The cross-sectional areas of both ventricles in the plane of the greatest heart diameter were measured with computerized image analysis system. Data were analyzed using linear regression and one-way analysis of variance. Myofibril formation occurred by attachment of thin filaments into amorphous Z materials which were presented in sarcolemmal plaques, sarcoplasmic condensations, desmosomes and in Z lines. From these Z centers, myofibrils radiated many directions and branched and anastomosed with further development. This pattern of myofibrillar development continued throughout the whole fetal period. A transverse tubule system was clearly evident in later fetal development. It occurred by invagination of sarcolemma into myocardial cells and formation of subsarcolemmal caveolae. Mitochondria, well-developed Golgi complexes, glycogen granules and well-developed microvessels were found throughout the whole fetal period. Binucleated myocytes appeared by 32 weeks gestation and this suggests that myocyte hyperplasia may cease before birth in humans. The growth of both ventricular walls, the interventricular septum and that of both ventricular cross-sectional areas showed linear regression, and the left-to-right wall thickness ratios were nearly constant. Also, there were no differences in morphometric data between the left and right ventricles. In conclusion, development of the myocyte is an ongoing process which may be continued in the post-natal period in humans, and our statistical results do not support the theory of the right ventricular dominance during the fetal period.     

Concerning the coidentity of phosphatidic acid phosphohydrolase and phosphatidylglycerophosphate phosphohydrolase in rat lung lamellar bodies

The properties of the phosphatidylglycerophosphate phosphohydrolase activity in lamellar bodies from rat lung have been compared with the properties of the activities responsible for the degradation of aqueously-dispersed phosphatidic acid (PAaq) and membrane-bound phosphatidic acid (PAmb). Subcellular fractionation studies revealed that the phosphatidylglycerophosphate phosphohydrolase activity and the PAaq-dependent phosphatidic acid phosphohydrolase activity were predominantly associated with the mitochondrial and microsomal fractions, while the PAmb-dependent phosphohydrolase activity was associated with the cytosol. Although the lamellar body fraction contained less than 1% of the total activity, the phosphatidic acid phosphohydrolase activities associated with this fraction could not be explained by contamination with microsomes or cytosol. The three activities exhibited similar heat inactivation profiles at 55 degree C. However, differences in the responses of these activities to the presence of iodoacetate, p-chloromercuriphenyl sulphonate, mercaptoethanol, mercaptoethanol plus MgCl2, and Triton X-100 indicated that the enzymes responsible for these activities may be distinct. Furthermore, addition of up to a ten-fold greater amount of PAaq did not seriously affect the hydrolysis of phosphatidylglycerophosphate. These results indicate that the phosphatidic acid phosphohydrolase and phosphatidylglycerophosphate phosphohydrolase activities in rat lung lamellar bodies are not necessarily catalyzed by the same protein.     

Hormonal regulation of the synthesis of lamellar body phosphatidylglycerol and phosphatidylinositol in fetal lung tissue

The influence of hormones on the synthesis of phospholipids of lung lamellar bodies was studied using lung tissue explants from 16- to 22-week gestational age human abortuses. Lung explants were incubated in a defined medium containing either no hormonal additions or insulin (2.5 micrograms/ml), cortisol (0.2 microgram/ml), or PRL (2.5 micrograms/ml), added alone or in various combinations. After 7 days of incubation, a purified lamellar body fraction was isolated from the explants. The effects of various hormone combinations on the relative rates of synthesis of lamellar body anionic glycerophospholipids during the last 24 h of culture were analyzed and compared to that of control explants. In control explants, 7.1% of the glycerophospholipid was synthesized as phosphatidylinositol, and 2.2% was synthesized as phosphatidylglycerol. Phosphatidylinositol synthesis was decreased significantly in explants incubated with cortisol alone, insulin plus cortisol, or insulin plus cortisol plus PRL (to 4.4%, 4.3%, and 3.7%, respectively), while phosphatidylglycerol synthesis was increased significantly in lamellar bodies from explants incubated with insulin plus cortisol or insulin plus cortisol plus PRL (to 5.5% and 5.7%, respectively). Although the relative rates of synthesis of lamellar body phosphatidylinositol and phosphatidylglycerol were significantly altered by hormones, the percentages of the total anionic glycerophospholipid were similar in all treatment groups (9.5%). The results of this study, therefore, are suggestive that lamellar body formation and glycerophospholipid composition are under hormonal control.     

Effect of platelet-activating factor on glycogen metabolism in fetal rat lung

Platelet-activating factor (1-alkyl-2-acetyl-sn-glycero-3-phosphocholine, or PAF) has previously been shown to induce glycogenolysis in the perfused adult rat liver and in the lung and liver of 24 day (gestational age) fetal rabbits in utero. In the present report, the effect of PAF was examined in fetal rats that were intravenously injected (through the vitellin vein) at a stage in their gestational development characterized by rapid glycogen depletion and surfactant accumulation. At 24 h after PAF administration of 2.5 micrograms and 5.0 micrograms to 19.5- and 20.5-day-old fetal rats, respectively, the lung glycogen content decreased significantly. In contrast, the inactive enantiomer of PAF did not modify the glycogenolytic response in vivo. When [14C]glucose (5 muCi) and PAF (5 micrograms) were simultaneously injected through the vitellin vein of the fetus, the radioactivity incorporated into lung glycogen was reduced as compared with control fetuses receiving the vehicle alone. An additional effect of PAF was noted in experiments designed to correlate glycogen breakdown to surfactant phospholipid biosynthesis. An inhibition of [3H]choline uptake and incorporation into phospholipids of fetal human lung explants and fetal lung type II pneumonocytes was induced by PAF. It is concluded that PAF appears to be a potential inducer of glycogen breakdown in the fetal lung and the relationship of these findings to fetal lung maturation is discussed.     

Endogenous corticoids and lung development in the fetal rabbit

Corticosteroid treatment of the fetus, which accelerates lung maturation, may mimic a modulating role of endogenous corticoids in normal development. To investigate this question, we determined the developmental pattern of plasma corticoids and their binding proteins in the rabbit, a commonly used species for studies of lung differentiation. The concentration of cortisol, the most potent glucocorticoid in the rabbit, was maximal at 23 days gestation (1.89 micrograms/dl), declining to 0.54 micrograms/dl at term (31 days). Levels of plasma corticosterone were always lower than those of cortisol. The adrenal content of corticoids, expressed per adrenal DNA or g BW, decreased during late gestation. Corticosteroid-binding globulin in fetal plasma decreased strikingly between day 23 (36 micrograms cortisol bound/dl) and day 31 (4.4 micrograms/dl; P less than 0.001), whereas maternal levels increased about 10-fold during this time. Free cortisol in the fetus increased between 21 and 23 days (0.041 micrograms/dl) and then decreased somewhat until after day 29 when there was an increase. To examine more directly the influence of endogenous glucocorticoids in the fetal lung, we assayed cortisol in extracts of purified lung nuclei as a reflection of receptor-cortisol complexes. The nuclear content of cortisol was constant between 23 and 30 days at levels (0.056-0.074 ng/mg DNA) comparable to those predicted from data for plasma free cortisol. Thus, in the rabbit, increases in plasma cortisol and nuclear receptor-cortisol complex are not temporally associated with the major events of lung development as in other species. We speculate that endogenous glucocorticoids may have a permissive or delayed influence on the lung during normal development in the rabbit.     

Bicarbonate concentration in rhesus monkey and guinea pig fetal lung liquid.

Fetal lung liquid secretion is essential for the normal growth of the lung in utero. Previous studies of fetal lung liquid secretion, mostly performed in lambs, have demonstrated that it has high Cl and very low HCO3- concentrations relative to plasma values. Because it is unknown whether primates have a similar electrolyte profile in their lung liquid, we sampled the lung liquid from rhesus monkeys (Macaca mulatta) at 127 to 128 days gestation (0.8 gestation). Although we found that lung liquid Cl concentration was higher than plasma values (p < 0.05), the HCO3- concentration was the same as in the plasma. This indicates that nonhuman primates, relative to lambs, have different cellular mechanisms for regulating fetal lung liquid HCO3- concentrations.     

Morphological and cytochemical characterization of neuroepithelial bodies in fetal rabbit lung. I. Studies of isolated neuroepithelial bodies

Neuroepithelial bodies (NEB) in 29-day fetal rabbit lung were examined by light microscopy and cytochemistry to demonstrate their structural and biochemical properties in situ. Longitudinal sections of NEB at airway bifurcations demonstrated their chemoreceptor-like appearance. Furthermore, the cytochemical presence of serotonin, acetylcholinesterase, formaldehyde-induced fluorescence, and silver-staining properties demonstrated the neural-like biochemical properties of NEB cells. Forty-one NEB and eight single neuroendocrine cells from whole fetal lungs were examined ultrastructurally. Juxtaluminal junctional complexes composed of tight and intermediate junctions, desmosomes, and cytoplasmic filaments were demonstrated in the corpuscular-shaped NEB. Basal bodies were apparent in NEB cell cytoplasm; cilia extended from NEB cells. Dense-core vesicles (DCV) were of at least three types: type 1, type 2, and enterochromaffin type. The majority of epithelial cells adjacent to NEB in near-term airway epithelium were undifferentiated, with large amounts of glycogen. However, ciliated cells were adjacent to some small NEB and single neuroendocrine cells; mucus or Clara-type cells were not observed. NEB isolated by collagenase treatment revealed an intact organoid structure, DCV, and desmosomes and retained their argyrophilia and formaldehyde-induced fluorescence. NEB were recovered in cell fractions separated by unit gravity that had cells in clumps of four or more. One to five NEB stained with silver in cytocentrifuge preparations of control, mixed cells, whereas up to 20 intact NEB were demonstrated in the clump-containing, separated fractions. We propose that isolated NEB retain certain biochemical and metabolic properties similar to those of their counterparts in situ. Serotonin and 5-hydroxyindole acetic acid were found by high-performance liquid chromatography analysis in the fractions containing NEB, and amine precursor uptake and decarboxylation (APUD) activity were demonstrated. Moreover, muscarinic cholinergic receptors were detected, consistent with the occurrence of acetylcholinesterase in NEB. The elution profile of bombesin radioimmunoactivity substantiated that isolated fetal rabbit NEB contained this neuropeptide and that NEB were enriched by unit gravity sedimentation. These studies suggest that NEB are structurally and functionally developed before other cell types in immature airway epithelium and can be isolated as intact organoids, which retain some of their structural and metabolic integrity.     

Postnatal development of rat lung following retarded fetal lung growth

Postnatal lung development was examined in rats born with smaller than normal lungs after either prenatal exposure to glucocorticoid or to an inhibitor of collagen synthesis. At birth, treated animals had lower than normal lung weights, lung to body weight ratios, hydroxyproline (HYP) levels, total DNA; and rates of DNA synthesis. Rats exposed to steroid showed a rapid recovery in growth during the normal postnatal cell proliferative phase from 4 to 11 days, though collagen levels did not return to normal until 3 weeks of age. Rats exposed to a prenatal proline analog showed a much slower rise in lung weight and total DNA, and these levels were still much below normal at 2-3 weeks when the cell proliferation phase was completed. Levels of disaturated phosphatidylcholine were significantly below normal up to 11 days, whereas total HYP was significantly reduced and less fibrillar collagen was seen in the lung throughout the study. The results indicate that the smaller but mature lungs at birth after antenatal steroid show a growth rebound and quickly become structurally normal. In contrast, inhibition of fibroblast growth and collagen deposition produces small lungs at birth, which continue to show inhibited growth and development at least up to 3 weeks of age, when the cell division phase is over.     

Lung surfactant in the hyperinsulinemic fetal monkey

We examined the effect of hyperinsulinemia in the absence of hyperglycemia on parameters of lung surfactant production in the fetal rhesus monkey at 134–148 days gestation. Hyperinsulinemia was achieved by infusion of insulin for 21 d from an Alzet minipump implanted in the fetal hind leg. Blood insulin levels were elevated 80-fold in the treated group. These fetuses were also slightly hypoglycemic and their body weights were 25% greater than expected. There were no differences, however, between the insulin-treated and control groups in the phospholipid content and composition of lung lavage or lavaged lung tissue or in the rate of choline incorporation into disaturated phosphatidylcholine in lung slices. These data suggest that hyperinsulinemiaper se does not inhibit surfactant production in the fetal primate at least up to 148 d gestation. Although an inhibitory effect of insulin later in gestation is not ruled out, it is also possible that hyperglycemia rather than hyperinsulinemia is responsible for the deficiency in surfactant often observed in human infants of diabetic mothers.     

Effect of zidovudine on human fetal lung development

Zidovudine (AZT) is currently used to treat human immunodeficiency virus (HIV)-positive women during pregnancy to prevent the prenatal transmission of HIV type 1 (HIV-1). However, AZT not only inhibits HIV replication but also affects the DNA polymerases of human cells; hence AZT is not recommended during the first trimester of pregnancy. The lung is a unique organ because it continues to grow and develop throughout fetal life. Using a human fetal lung organ culture system, we sought to determine the effect of AZT on morphogenesis and epithelial cytodifferentiation of developing alveoli. Lung tissues from three fetuses, 14-15 weeks gestational age, were grown in culture for 24 hours (day 0). AZT at a concentration of either 0.4, 4.0, 8.0, or 40.0 mumol/L was added on days 1, 5, and 10 of growth. The cultures were interrupted on days 6 and 15 and examined by light and electron microscopy for alveolar saccular development, interstitial thinning, and epithelial cell differentiation. On day 6 of growth the treated cultures demonstrated fewer alveolar saccules and a thicker, more cellular interstitium compared to the controls. After 15 days of growth the cultures treated with 0.4 mumol/L of AZT appeared structurally similar to the controls. The cultures treated with AZT concentrations of 4.0 to 40.0 mumol/L appeared unchanged from day 6, implying arrested maturation of the culture. However, epithelial cell differentiation was unaffected. We conclude that AZT at concentrations of 4.0 mumol/L and greater affects the structural development of the human fetal lung in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)     

Programmed cell death in normal fetal rat lung development

Lung development is a coordinated process regulated by the interactions of extracellular and intracellular factors, yet little is known about the process of programmed cell death during lung development. To study this question, we examined fetal rat lung from the pseudoglandular period (gestational day 15) to the day of birth (gestational day 21) using BrdU incorporation into DNA as a proliferative marker, while in parallel examining several markers of programmed cell death including terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling (TUNEL), DNA "laddering, " and expression of programmed cell death pathway proteins. Cell proliferation was ongoing throughout fetal days 15 to 21 with a decrease in proliferation over days 20 and 21. Programmed cell death in fetal lung also appeared to be present at all ages examined, but demonstrated 2 peaks of activity at fetal days 15 and 18 to 20. Bcl-XL expression was detected on fetal days 15 to 21, with diminished expression on days E15 to E18. Cleaved poly(ADP-ribose)polymerase (PARP), activated caspase-3, Bax, and Bad were increased on days 18 to 20. We conclude that proliferation is the primary process driving fetal lung development with programmed cell death occurring throughout the lung developmental process to refine structural remodeling.     

5 alpha-reductase, aromatase, and androgen receptor levels in the monkey brain during fetal development

To elucidate the metabolic fate and possible role of androgens and their derivatives during primate fetal development, aromatase (AROM), 5 alpha-reductase (5 alpha R), and androgen receptor (AR; cytosolic) levels were assessed in the brain, heart (HRT), lung (LNG), and skeletal muscle (MUS) of fetal rhesus monkeys. Analyses were performed on tissues taken on days 100 and 160 postconception. Five male and four or five female fetuses were examined at each stage. Brain tissues analyzed included medial basal hypothalamus (MBH), amygdala (AMG), cerebellum (CB), corpus callosum (CAL; splenial region), cerebral cortex (CTX), and cingulate cortex (CNG). In the following, enzyme activities are reported as picomoles per mg protein/h, while receptor levels are femtomoles per mg protein. 5 alpha R activity was measurable in all tissues. Analysis of variance revealed significant tissue differences [P less than 0.001, combined stages and sexes; CAL (2.05) greater than MBH (1.08) greater than AMG (0.63) greater than CB (0.4)-CNG-CTX-LNG-HRT-MUS (0.02); -indicates not significantly different]. A significant age x tissue interaction (P less than 0.001) was noted which could be explained by higher MBH and CAL levels in older vs. younger fetuses and higher AMG levels in younger vs. older fetuses. There was also a significant sex x tissue interaction which was attributed to higher female values in the MBH and CAL. AROM activity was detected in all tissues. Levels varied significantly among tissues [P less than 0.001, combined stages and sexes; MBH (0.80)-AMG (0.76) greater than CAL (0.4)-CNG-CB-CTX-LNG-HRT-MUS (0.07)]. Significant age (P less than 0.001) and age x tissue (P less than 0.001) effects were noted, which were due to higher MBH and AMG levels in younger vs. older fetuses. No sex difference in AROM levels was evident in any tissue. AR was measurable in all cases. Although stage and sex differences were not significant, tissue levels varied significantly [P less than 0.001; LNG (2.8)-MUS (2.6)-MBH (2.2) greater than HRT-AMG-CB-CTX-CAL-CNG (0.9)]. These findings indicate that neural and nonneural fetal primate tissues have the potential for transforming androgens to products that could have greater or lesser biological activity. AR were also noted through which dihydrotestosterone or testosterone could effect a genomic response. Since stage, tissue, and sex differences were evident in neural tissues, metabolic and receptor activities may be important for the normal differentiation of sexually dimorphic behavioral systems in monkeys as well as for potential teratogenic changes under abnormal metabolic or physiological conditions.