Role of lamellar inclusions in surfactant production: studies on phospholipid composition and biosynthesis in rat and rabbit lung subcellular fractions.

Lamellar inclusion bodies in the type II alveolar epithelial cell are believed to be involved in pulmonary surfactant production. However, it is not clear whether their role is that of synthesis, storage, or secretion. We have examined the phospholipid composition and fatty acid content of rabbit lung wash, lamellar bodies, mitochondria, and microsomes. Phosphatidylcholine and phosphatidylglycerol, the surface-active components of pulmonary surfactant, accounted for over 80% of the total phospholipid in lung wash and lamellar bodies but for only about 50% in mitochondria and microsomes. Phosphatidylethanolamine, phosphatidylinositol, phosphatidylserine, and sphingomyelin accounted for over 40% of the total in mitochondria and microsomes but for only 6% in lung wash and 15% in lamellar bodies. The fatty acid composition of lamellar body phosphatidylcholine was similar to that of lung wash, but different from that of mitochondria and microsomes, in containing palmitic acid as a major component with little stearic acid and few fatty acids of chain length greater than 18 carbon atoms. The biosynthesis of phosphatidylcholine and phosphatidylglycerol was examined in the mitochondrial, microsomal, and lamellar body fractions from rat lung. Cholinephosphotransferase was largely microsomal. The activity in the lamellar body fraction could be attributed to microsomal contamination. The activity of glycerolphosphate phosphatidyltransferase, however, was high in the lamellar body fraction, although it was highest in the mitochondria and was also active in the microsomes. These data suggest that the lamellar bodies are involved both in the storage of the lipid components of surfactant and in the synthesis of at least one of those components, phosphatidylglycerol.     

Role of myo-inositol in the synthesis of phosphatidylglycerol and phosphatidylinositol in the lung

The addition of $\text{myo}$-inositol to lung microsomes inhibited phosphatidylglycerol synthesis up to 94% while it stimulated that of phosphatidylinositol. The inhibition was evident only when CDP-diacylglyceride availability was limiting the rate of acidic phospholipid synthesis. Excess $\text{myo}$-inositol given to rabbits for two days decreased surfactant phosphatidylglycerol from 5.3–5.7% to 0.4–0.5%, and increased that of phosphatidylinositol from 5.4–5.8% to 9.3–8.6% of total phospholipid. The composition of other surfactant phospholipids as well as those in mitochondria and microsomes were little affected. The quality of microsomally synthesized acidic phospholipids may be controlled by $\text{myo}$-inositol at the biosynthetic surface.     

Origins of the phospholipids in animal mitochondria

As is the case for the assembly of protein components of the membranes in animal mitochondria, the bilayer phospholipids arise from a complicated interplay of intra- and extra-mitochondrial reactions. Our early studies indicated that the bulk of mitochondrial phospholipids (typified by phosphatidylcholine) had their origin in the endoplasmic reticulum and were transported to the mitochondria as complexes with phospholipid-exchange proteins. The polyglycerophosphatides (typified by diphosphatidylglycerol) were apparently synthesized in situ by intramitochondrial membrane-bound enzymes using CDP-diglycerides as intermediates. The case for the precursors in the latter pathway is less clear, although evidence has been presented for dual localization of enzymes for glycerophosphate acylation and CTP:phosphatidate cytidylyl transfer in both mitochondria and microsomes. Phosphatidylethanolamine also shows evidence for two sites of origin: by translocation from its site of synthesis in the endoplasmic reticulum and by translocation of phosphatidylserine followed by decarboxylation within the mitochondria. In the latter case mitochondrial phosphatidylserine decarboxylase may play an important role in the regulation of phospholipid metabolism throughout the cell.     

Intracellular transfer of phospholipids in the yeast, Saccharomyces cerevisiae

In Saccharomyces cerevisiae, unlike in higher eukaryotic cells, most of the reactions involved in phospholipid biosynthesis occur both in mitochondria and in the endoplasmic reticulum. Some of the key enzymes involved, however, are restricted to one compartment. Thus, the formation of phosphatidylethanolamine by decarboxylation of phosphatidylserine occurs only in mitochondria, while phosphatidylcholine synthesis via methylation of phosphatidylethanolamine is restricted to microsomes. When yeast cells were pulse labelled with [3H]serine,[3H] phosphatidylethanolamine formed in mitochondria was found not only in the organelle but also, with even higher specific radioactivity, in the endoplasmic reticulum. Translocation of phosphatidylethanolamine between organelles was blocked immediately after poisoning cells with cyanide, azide and fluoride. Part of the [3H]phosphatidylcholine formed in the endoplasmic reticulum by methylation of [3H]phosphatidylethanolamine was transferred to mitochondria. This process continued in deenergized cells, although at a lower rate as compared to metabolizing cells. This result indicates rapid movement of both phosphatidylethanolamine and phosphatidylcholine requires metabolic energy, but that phosphatidylinositol-specific phospholipid transfer protein that has been found in saccharomyces cerevisiae (Daum, G. and Paltauf, F. (1984) Biochim. Biophys. Acta 784, 385-391). The mechanism of movement of phospholipids from internal membranes to the cell surface was studied with temperature-sensitive secretory mutants (Schekman, R. (1982) Trends Biochem. Sci. 7, 243-246) of Saccharomyces cerevisiae. A shift from the permissive to the restrictive temperature, which blocks the flow of vesicles involved in the secretion of proteins, had no effect on the transfer of phosphatidylinositol to the plasma membrane.     

Subcellular incorporation of 32P into phosphoinositides and other phospholipids in isolated hepatocytes

Isolated rat hepatocytes were incubated with 32Pi for various times and then fractionated into plasma membranes, mitochondria, nuclei, lysosomes, and microsomes by differential centrifugation and Percoll density gradient centrifugation. The phospholipids were isolated and deacylated by mild alkaline treatment. The glycerophosphate esters were separated by anion exchange high pressure liquid chromatography and assayed for radioactivity. It was found that plasma membranes, mitochondria, nuclei, lysosomes, and microsomes displayed similar rates of 32P incorporation into the major phospholipids, phosphatidylcholine, phosphatidylethanolamine, phosphatidylinositol, phosphatidylglycerol, and phosphatidic acid. This suggests that the phospholipids of these organelles are undergoing rapid turnover and replacement with newly synthesized phospholipids from the endoplasmic reticulum. However, the plasma membrane fraction incorporated 32P into phosphatidylinositol 4-phosphate (DPI) and phosphatidylinositol 4,5-bisphosphate (TPI) at rates 5-10 and 25-50 times, respectively, faster than any of the other subcellular fractions. Although the plasma membrane is the primary site of 32P incorporation into DPI and TPI, this study also demonstrates that significant incorporation of 32P into DPI occurs in other subcellular sites, especially lysosomes.     

An apolipoprotein preferentially enriched in cholesteryl ester-rich very low density lipoproteins

Phosphatidyl glycerol is present in lamellar bodies and in the material obtained by alveolar wash representing 12.3 and 11.5%, respectively, of the total phospholipid phosphorus. Lung microsomes catalyze the formation of phosphatidyl glycerol from the known precursors, L-glycerol 3-phosphate and CDP-diglyceride. The rate of [¹⁴C]L-glycerol 3-phosphate incorporation into phosphatidyl glycerol was 30% higher in microsomes as compared to mitochondria. The addition of mercuric chloride inhibited the synthesis of phosphatidyl glycerol, and stimulated the incorporation into another as yet incompletely identified lipid. After pulse labeling of microsomal phosphatidyl glycerol $\text{in vitro}$, further incubation of microsomes with lamellar bodies or alveolar wash resulted in nearly quantitative appearance of label in surfactant.     

Exchange of phospholipids between mitochondria and rough or smooth microsomes in vitro.

Phospholipids in mitochondria can be exchanged with those in two microsomal fractions from rough endoplasmic reticulum (rough microsomes) and smooth endoplasmic reticulum (smooth microsomes) in vitro in the presence of cell supernatant. The amounts of phospholipids transferred from each submicrosomal fraction to nitochondria were slightly different. The compositions of the phospholipids transferred to mitochondria from both microsomal fractions were the same, though these two fractions actually had different phospholipid compositions.     

The in vivo labeling with acetate and palmitate of lung phospholipids from developing and adult rabbits

The labeling with radiolabeled acetate and palmitate of lung, microsomes isolated from lung, and surfactant phospholipids from adult, 3-day-old, and newborn rabbits was studied. The half-life of phosphatidylcholine from lung and microsomal fractions was shorter when labeled with acetate than when labeled with palmitate. Half-time values similarly measured for phosphatidylglycerol, phosphatidylinositol or phosphatidylethanolamine were not different for the two labels. Acetate and palmitate-labeled phospholipids appeared in the surfactant fraction with similar accumulation curves. The relative specific activities of acetate-labeled phosphatidylcholine from adult, 3-day-old, and newborn rabbits, respectively, were 1.30, 1.86 and 1.77 times those measured for those measured for the palmitate label. Surfactant phosphatidylinositol and phosphatidylethanolamine from 3-day-old animals similarly were labeled preferentially with acetate. However, phosphatidylglycerol purified from the surfactant fraction contained equivalent relative amounts of the acetate and palmitate labels in 3-day-old and adult rabbits. These results suggest that the type II pneumocyte may use acetate preferentially for the synthesis of palmitic acid which then is incorporated into surfactant phospholipids.     

Phosphatidylinositol and not phosphatidylglycerol is the important minor phospholipid in rhesus-monkey surfactant

Pulmonary surfactant was isolated from lung tissue and alveolar washes of lungs of adult rhesus monkeys (Macaca mulatta). The phospholipid composition was determined and compared to the composition of human surfactant fractions. Contrary to human surfactant, phosphatidylinositol is the major acidic phospholipid, whereas phosphatidylglycerol is only a minor component in rhesus-monkey surfactant. These differences are not caused by a difference in plasma myo-inositol concentrations between the two species.     

Characterization of phospholipids accumulated in pulmonary-surfactant compartments of rats intratracheally exposed to silica.

Phospholipids in the lung fractions, i.e. alveolar free cells, extracellular pulmonary surfactant, intracellular pulmonary surfactant (lamellar bodies) and microsomal fractions, of rats were examined 28 days after intratracheal injection of silica (40 mg/kg). Significant accumulations of phospholipids were observed in the extracellular- and intracellular-surfactant fractions of rats exposed to silica. The prominent phospholipid accumulated was phosphatidylcholine (PC), consisting mainly of the dipalmitoyl species. However, a compositional change in acidic phospholipids of surfactant fractions was produced by the silica treatment. The percentage of phosphatidylglycerol (PG) was significantly decreased; in contrast, that of phosphatidylinositol (PI) was increased. Thus the ratio PG/PI in the surfactant fractions was markedly decreased in response to silica. This compositional change in both acidic phospholipids occurred even in the early stages, i.e. before appreciable accumulations of alveolar phospholipids were noticed. The molecular-species profiles of both acidic phospholipids in the surfactant fractions were distinctly different from each other. The dipalmitoyl species accounted for more than 30% of PG and less than 6% of PI, respectively. These species patterns of PG and PI were similar in control and silica-treated rats. These findings suggest two possibilities that (1) PG and PI destined for pulmonary surfactant are synthesized from each specific CDP-diacylglycerol (DG) pool having different molecular species in the lung, or (2) individual enzymes responsible for synthesis of surfactant PG and PI have substrate specificities for molecular species of CDP-DG, thereby producing PG and PI having different molecular species in surfactant compartments.     

Phosphatidylglycerol of rat lung. Intracellular sites of formation de novo and acyl species pattern in mitochondria, microsomes and surfactant.

The subcellular site of phosphatidylglycerol (PG) formation for lung surfactant has not been convincingly clarified. To approach this problem we analysed the acyl species pattern of lung PG in mitochondria, microsomes and surfactant by h.p.l.c. separation of its 1,2-diacyl-3-naphthylurethane derivatives. Both mitochondrial and microsomal PG proved identical with surfactant PG, containing the major species 1-palmitoyl-2-oleoyl-PG and 1,2-dipalmitoyl-PG. The fatty acid composition of mitochondrial PG differs markedly from that of diphosphatidylglycerol. This may be taken as an indication that mitochondrial PG is synthesized on purpose to form surfactant, rather than being only the precursor of diphosphatidylglycerol. In vitro, sn-[U-14C]glycerol 3-phosphate incorporation into PG of mitochondria or microsomes occurs in the presence of CTP, ATP and CoA but independently of the supply of exogenous lipoidic precursors. Although the rate in vitro of autonomous PG synthesis, and the endogenous PG content, are higher in mitochondria than in microsomes, it is assumed that both subcellular fractions are involved in PG formation for surfactant.     

A phospholipid requirement for dolichol pyrophosphate N-acetylglucosamine synthesis in phospholipase A2-treated rat lung microsomes

The role of phospholipids in the activity of UDP-Glc-NAc:dolichol phosphate GlcNAc-1-phosphate transferase of rat lung microsomes has been investigated. Treatment of microsomes with phospholipase A2 in the presence of delipidated bovine serum albumin resulted in a time-dependent loss of 65 to 75% of the enzyme activity and approximately 30% of the phospholipids. Addition of phosphatidylglycerol to the enzyme assay system containing phospholipase A2-treated microsomes restored activity to that obtained with native microsomes and phosphatidylglycerol. Addition of phosphatidylinositol, phosphatidylcholine, or cardiolipin resulted in only partial restoration of activity, whereas phosphatidylserine and phosphatidylethanolamine were without effect. Triton X-100 was not by itself capable of restoring activity, but was required for the phospholipid effect. Measurements of the phospholipase A2 hydrolysis products released from the microsomes during digestion, and other control experiments of adding fatty acids and lysophospholipids to the enzyme assay system, indicated that the loss of UDP-GlcNAc:dolichol phosphate GlcNAc-1-phosphate transferase activity was not due to product inhibition.     

Phospholipid exchange reactions within the liver cell

1. Isolated rat liver mitochondria do not synthesize labelled phosphatidylcholine from CDP-[(14)C]choline or any phospholipid other than phosphatidic acid from [(32)P]phosphate. The minimal labelling of phosphatidylcholine and other phosphoglycerides can be attributed to microsomal contamination. However, when mitochondria and microsomes are incubated together with [(32)P]phosphate, the phosphatidylcholine, phosphatidylinositol and phosphatidylethanolamine of the reisolated mitochondria become labelled, suggesting a transfer of phospholipids between the two fractions. 2. When liver microsomes or mitochondria containing labelled phosphatidylcholine are independently incubated with the opposite un-labelled fraction, there is a substantial and rapid exchange of the phospholipid between the two membranes. Exchange of phosphatidylinositol also occurs rapidly, whereas phosphatidylethanolamine and phosphatidic acid exchange only slowly. There is no corresponding transfer of marker enzymes. The transfer of phosphatidylcholine does not occur at 0 degrees , and there is no requirement for added substrate, ATP or Mg(2+), but the omission of a heat-labile supernatant fraction markedly decreases the exchange. 3. After intravenous injection of [(32)P]phosphate, short-period labelling experiments of the individual phospholipids of rat liver microsomes and mitochondria in vivo give no evidence for a similar exchange process. However, the incubation of isolated microsomes and mitochondria with [(32)P]phosphate also fails on reisolation of the fractions to demonstrate a precursor-product relationship between the individual phospholipids of the two membranes. 4. The intraperitoneal injection of [(32)P]phosphate results in a far greater proportion of the dose entering the liver than does intravenous administration. After intraperitoneal administration of [(32)P]phosphate the specific radioactivities of the individual phospholipids are in the order microsomes > outer mitochondrial membrane > inner mitochondrial membrane. 5. The incorporation of (32)P into cardiolipin is very slow both in vivo and in vitro. After labelling in vivo the radioactivity in the cardiolipin persists compared with that of the other phospholipids, whose specific radioactivities in the microsomes and mitochondrial fragments decay at a similar rate to that of the acid-soluble phosphate pool. 6. The possibility of phospholipid exchange processes occurring in the liver cell in vivo is discussed, and it is suggested that only a small but highly labelled part of the endoplasmic-reticulum lipoprotein pool is involved in the transfer.     

Biosynthesis of mitochondrial phospholipids using endogenously generated diglycerides.

When isolated mitochondria or microsomes from rat liver were treated with phospholipase C, the incorporation of radioactive phospholipid precursors was markedly enhanced, presumably as a result of production of diglycerides by hydrolysis of endogenous phospholipids. Incorporation of CDP[14C]choline into lecithin in rat liver or BHK-21 mitochondria could be attributed to residual contamination from elements of the endoplasmic reticulum, with added diglycerides or with endogenous diglycerides produced by the phospholipase C treatment. A similar stimulation of [gamma32P]ATP incorporation into phospholipids was observed with exogenous or endogenous diglycerides, but the mitochondrial diglyceride kinase in either case was also related to the degree of microsomal contaminants. It was concluded that previous studies showing negligible capacity of mitochondria for lecithin biosynthesis de novo were not explainable on the basis of limited accessibility of added diglycerides, and that formation of phosphatidic acid by diglyceride kinase was not of significance in rat liver mitochondria.     

Newly made phosphatidylserine and phosphatidylethanolamine are preferentially translocated between rat liver mitochondria and endoplasmic reticulum

The translocation of: (i) phosphatidylserine (PtdSer) from its site of synthesis on microsomal membranes to its site decarboxylation in mitochondrial membranes and (ii) phosphatidylethanolamine (PtdEtn) from the mitochondria to its site of methylation to phosphatidylcholine on microsomal membranes has been reconstituted in cell-free systems consisting of rat liver mitochondria and microsomes. Two types of systems have been reconstituted. In one, the translocation of newly made PtdSer or PtdEtn was examined by incubation of microsomes and mitochondria with [3-3H]serine. In the other, membranes were prelabeled with radioactive PtdSer or PtdEtn, and the transfer of these two lipids between mitochondria and microsomes was monitored. For the transfer of both PtdSer from microsomes to mitochondria and PtdEtn from mitochondria to microsomes, newly made phospholipids were translocated much more readily than pre-existing phospholipids. The data suggest that with respect to their translocation between these two organelles, the pools of newly synthesized PtdSer and PtdEtn were distinct from the pools of "older" phospholipids pre-existing in the membranes. Transfer of neither phospholipid in vitro depended on the presence of cytosolic proteins (i.e. soluble phospholipid transfer proteins) or on the hydrolysis of ATP, although there was some stimulation of PtdSer transfer by ATP and several other nucleoside mono-, di-, and triphosphates. The data are consistent with a collision-based mechanism in which the endoplasmic reticulum and mitochondria come into contact with one another, thereby effecting the transfer of phospholipids. The proposal that there is contact between the endoplasmic reticulum and mitochondria is supported by the recent isolation of a membrane fraction having many, but not all, of the properties of the endoplasmic reticulum, but which was isolated in association with mitochondria (Vance, J. E. (1990) J. Biol. Chem. 265, 7248-7256).     

Isolation, characterization and phospholipid composition of lamellar bodies and subcellular fractions from dog lung

1. Lamellar body fractions from dog lung can be separated by a procedure based on differential centrifugation before ultracentrifugation onto a discontinuous sucrose gradient. This fraction yields about 1% of total protein from the homogenate. 2. The different fractions obtained in the isolation were assayed for the measurement of four subcellular marker enzymes: beta-N-acetylglucosaminidase, acid phosphatase, 5'-nucleotidase and succinate dehydrogenase. 3. Lamellar bodies were not contaminated by mitochondria (0.7 succinate dehydrogenase relative specific activity), whereas high specific hydrolase activities were found (beta-N-acetylglucosaminidase and 5'-nucleotidase were enriched 1.8- and 2.8-fold, respectively). 4. The chemical criterion was established by measuring the specific components of lamellar bodies. The lamellar bodies have the highest phospholipid/protein ratio (0.35); cholesterol/protein ratio (0.15) and the highest phosphatidylglycerol percentages (7.9%). 5. The phospholipid composition of lamellar bodies is distributed among phosphatidylcholine (64.5%), phosphatidylethanolamine (11%), phosphatidylglycerol (7.9%), sphingomyelin (4%), phosphatidylserine and phosphatidylinositol (3%), respectively. The remainder were considered as trace amounts (less than 1%).     

Role of inositol-containing sphingolipids in Saccharomyces cerevisiae during inositol starvation.

The in vitro lipid requirements of UDP-N-acetylglucosamine-dolichol phosphate N-acetylglucosamine-1-phosphotransferase for the inositol-containing sphingolipids from Saccharomyces cerevisiae were characterized in terms of concentration and specificity. The effects of combinations of lipids, especially phosphatidylinositol and the inositol-containing sphingolipids, were also tested on the transferase. Phosphatidylinositol and phosphatidylglycerol stimulated the enzyme 3.3- and 2.8-fold, respectively. The inositol-containing sphingolipids, phosphatidylcholine, phosphatidylethanolamine, and phosphatidylserine did not stimulate the activity of the transferase. Phosphatidylcholine and phosphatidylethanolamine in combination with phosphatidylinositol had no effect on the transferase activity; however, the inositol-containing sphingolipids markedly inhibited the stimulation of the transferase by phosphatidylinositol. This inhibition by the sphingolipids was prevented if phosphatidylcholine, in addition to the other lipids, was present in the assay mixture. In addition, changes due to inositol starvation in the in vivo membrane lipid environment, i.e., phosphatidylinositol and the inositol-containing sphingolipids, were analyzed to determine whether they corresponded to the observed in vitro effects. Three hours after the beginning of inositol starvation, there were 9- and 14-fold reductions in the accumulation of phosphatidylinositol in membrane fractions IIA (vesicles) and IV (endoplasmic reticulum), respectively, although there was only a 6-fold reduction in membrane fraction I (plasma membrane). The accumulation of [14C]inositol into inositol-containing sphingolipids also reflected the differences in the cellular location of membranes.     

Distribution of phosphatidylinositol biosynthetic activities among cell fractions from rat liver.

The distribution of activities for synthesis of phosphatidylinositol among cell fractions from rat liver was determined. Activity was concentrated in endoplasmic reticulum; rough and smooth fractions were nearly equal. Golgi apparatus exhibited a biosynthetic rate 44% that of endoplasmic reticulum. Plasma membranes and mitochondrial fractions were only 6% as active as endoplasmic reticulum. Thus, endoplasmic reticulum and Golgi apparatus fractions from rat liver catalyze the net synthesis of phosphatidylinositol in vitro, whereas plasma membrane and mitochondrial fractions do not.     

Lipids of the adrenal medulla: Lysolecithin, a characteristic constituent of chromaffin granules

1. The lipid composition of microsomes, mitochondria and chromaffin granules, obtained from homogenates of bovine adrenal medulla, has been investigated. 2. The three types of particle showed characteristic differences of phospholipid and cholesterol content. The lipid composition of microsomes and mitochondria resembled that of corresponding particles from other tissues. The chromaffin granules contained 19% of the cholesterol and 14% of the phospholipids of the low-speed supernatant. 3. Thin-layer chromatography indicated the presence of these phospholipids in extracts from each particle: lecithin, lysolecithin, phosphatidylethanolamine (partly plasmalogen), phosphatidylserine, phosphatidylinositol and sphingomyelin. 4. On quantitative analysis of the phospholipids, chromaffin granules were found to contain a high concentration of lysolecithin (17% of the lipid phosphorus). Mitochondria and microsomes, on the other hand, contained very little lysolecithin (less than 2% of the lipid phosphorus).     

Biogenesis of mitochondria. The effects of catabolite repression on the in vitro phospholipid synthetic capacities of subcellular fractions of respiratory-competent and respiratory-deficient strains of Saccharomyces cerevisiae.

A respiratory-competent wild-type strain and a nuclear isogenic, mitochondrial DNA-less, petite mutant strain of Saccharomyces cerevisiae were grown under conditions of catabolite repression in batch cultures and under conditions of catabolite derepression in chemostat cultures. Subcellular fractions were isolated and the capacity of these fractions to incorporate sn-[2-³H]glycerol 3-phosphate into phospholipids was studied. Neither catabolite repression nor loss of mitochondrial DNA appreciably altered the total in vitro lipid synthesized by mitochondrial fractions during the incubation. Mitochondria isolated from catabolite-derepressed wild-type and petite cells had approximately the same specific activity in vitro for the synthesis of phosphatidylinositol. phosphatidic acid, phosphatidylethanolamine, phosphatidylserine, and neutral lipids. Mitochondria isolated from the petite cells retained the capacity to synthesize phosphatidylglycerol and diphosphatidylglycerol, although the synthesis of these phospholipids was far less extensive than that by the mitochondria isolated from the wild-type cells. In both cases, mitochondria prepared from catabolite-repressed cells synthesized a greater proportion of phosphatidylserine than did mitochondria from catabolite-derepressed cells. The proportions of phospholipid species synthesized in vitro by the microsomal fractions studied were not grossly affected by catabolite repression or loss of mitochondrial DNA.