Phospholipid exchange between mitochondria and microsomes of rat hepatoma 27]

The phospholipid exchange in vitro between mitochondria and microsomes from rat liver and rat hepatoma 27 was investigated. On incubation with a postmicrosomal protein fraction the phospholipid exchange between subcellular fractions of the tumor was found to proceed much faster and less specific than between mitochondria and microsomes from normal liver. These results indicate that the earlier demonstrated lipid dedifferentiation of tumor cell membranes may be connected with an altered transmembrane phospholipid exchange in vivo.     

Inhibitory effect of glucose on the maturation of rat liver mitochondria at birth. Phospholipid and oxidative metabolism

(1) The rate of ATP synthesis coupled with succinate oxidation in rat liver mitochondria is low at birth and increases rapidly during the first postnatal hours (Nakazawa, T., Asami, K., Suzuki, H. and Yakawa, O. (1973) J. Biochem. 73, 397-406). A glucose injection given to newborn rats immediately after birth seemed to delay this maturation process. (2) Glucose administration specifically diminished the rate of 32Pi incorporation into phosphatidylcholine both in microsomes and in mitochondria while other phospholipids remained unaffected. (3) In newborn rat liver, 32Pi incorporation into phospholipids can be explained by de novo synthesis of phospholipids in microsomes followed by transfer to mitochondria with two exceptions phosphatidylserine and sphingomyelin. Indeed, after a 20-min incorporation of 32Pi into phospholipids, the specific radioactivity of phosphatidylserine and sphingomyelin was higher in mitochondria than in microsomes. (4) As far as phospholipid synthesis is concerned, no precursor-product relationship could be observed between light and heavy mitochondria.     

Abnormal membrane phospholipid content in subcellular fractions from the Morris 7777 hepatoma.

1. Mitochondrial and microsomal fractions were prepared from normal rat liver and the Morris 7777 hepatoma and characterized by the use of the marker enzymes, succinate dehydrogenase and rotenone-insensitive NADPH-cytochrome c reductase. 2. The phospholipid content per mg membrane protein of Morris 7777 hepatoma mitochondria was increased by 75% as compared with mitochondria from normal rat liver. Microsomes from this poorly-differentiated tumor were found to have a 45% decrease in the content of phospholipid. These abnormalities were independent of tumor size or age. 3. The percent phospholipid content of the subcellular fractions was determined, and revealed an increase in the percent sphingomyelin in both the microsomal and mitochondrial fractions of the tumor. Decreases in the percent phosphatidylcholine and phosphatidylethanolamine were noted in tumor microsomes as compared with normal liver. Diphosphatidylglycerol was not found in significant quantities in the microsomal fraction of this hepatoma line. 4. The content of the various phospholipid classes per mg protein in the respective mitochondrial and microsomal fractions was determined. Large increases in nearly all the major phospholipid classes were found in tumor mitochondria; tumor microsomes were characterized by an increased content of sphingomyelin but the content of nearly all other phospholipids was significantly decreased. These findings suggest the presence of disturbances in the regulation of phospholipid metabolism in subcellular organelle membranes of the Morris 7777 hepatoma.     

A universal lipid exchange protein from rat hepatoma.

The postmicrosomal protein fraction from rat hepatoma 27 adjusted to pH 5.1 stimulates phospholipid exchange between rat liver microsomes and mitochondria with higher rates and in a less specific way than the corresponding fraction from rat liver. A phospholipid exchange protein has been purified to homogeneity from the hepatoma pH-5.1 supernatant by gel filtration on Sephadex G-75 and ion-exchange chromatography on carboxymethylcellulose. The isolated protein had a molecular weight of 11200 as determined by electrophoresis on polyacrylamide in the presence of dodecyl sulfate and of 11168 as calculated from the amino acid composition. Isoelectric focusing showed a single band at pH 5.2. in the assay system rat liver microsomes leads to mitochondria the protein exhibits a complete lack of substrate specificity transferring all the major microsomal phospholipids to about the same extent. The possible role of the isolated phospholipid exchange protein in the chemical dedifferentiation of hepatoma cell membranes is discussed.     

Lipid composition of rat liver microsomes under various experimental conditions

Cholesterol and phospholipid content, and phospholipid composition (sphingomyelin, phosphatidylcholine, phosphatidylserine, phosphatidylinositol, phosphatidylethaolamine) were assayed in rat liver microsomes during regeneration, foetal development and pregnancy. Cholesterol was assayed using Liebermann-Buchard reagent; the phospholipid extract was separated by thin-layer chromatography. While in pregnancy no changes were observed, during foetal development and liver regeneration there was a significative decrease of cholesterol/phospholipid ratio, and of phosphatidylcholine content. Moreover, in developing liver microsomes, there is also a significative increase of sphingomyelin and phosphatidylserine + phosphatidylinositol.     

Lipid composition of the Golgi apparatus of rat kidney and liver in comparison with other subcellular organelles.

Golgi apparatus isolated from both rat liver and rat kidney have been characterized with respect to their neutral and phospholipid content and their phosphopipid composition and compared with mitochondria, rough endoplasmic reticulum and plasma membranes. In addition, the distribution of sulfatide in the subcellular fractions of rat kidney was determinich are rich in cholesterol esters and ubiquinone. Removal of about 75% of the cisternal contents of rat liver Golgi reduced its content of cholesterol esters but not of ubiquinone. The Golgi complex of liver most closely resembles endoplasmic reticulum in its phospholipid composition except for a higher content of sphingomyelin. Removal of most of the contents of the Golgi cisternae did not appreciably alter the phospholipid composition of the Golgi apparatus of liver. Goligi apparatus from kidney has a phospholipid composition which resembles liver Golgi much more closely than it does any other cell fraction from kidney. The sulfatide content of kidney Golgi, the cell fraction richest in this glycolipid, is about 14% of the total lipid present in this fraction. Sulfatide was present in plasma membranes, mitochondria and rough microsomes, but at about one-third the level found in Golgi. Sulfatide is the main glycosphingolipid present in all the cell fractions from kidney which were studied.     

Phospholipid-transfer proteins in human liver and primary liver carcinoma

Investigations have been carried out on phospholipid-transfer activity of the cytosol and the phospholipid composition of subcellular membranes from human liver and primary liver carcinoma. In both human liver and primary liver carcinoma cytosolic fractions, the transfer activity for phosphatidylcholine (PC), phosphatidylethanolamine (PE) and sphingomyelin has been observed for the first time. The transfer rate of PC and PE in normal human liver was almost equal, whereas sphingomyelin-transfer activity was much slower. In carcinoma cells, the transfer activity for PE and PC was significantly enhanced, while sphingomyelin transfer remained unchanged. Comparative investigations with HepG2 cultured cells have revealed a high PE-transfer activity in this cell line. Parallel with the phospholipid-transfer activity modifications in neoplasic cells, changes in the phospholipid composition of microsomes and mitochondria have been observed. The content of PC and PE in hepatocarcinoma cells was decreased in microsomes, while in the mitochondria it was increased. The possible role of the phospholipid-transfer proteins in the maintenance of membrane composition and structure is discussed.     

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.     

Phospholipid composition and fatty acid patterns of isolated phospholipids from rabbit reticulocyte mitochondria

The phospholipid composition and fatty acid patterns of individual phospholipid classes were determined in mitochondria from rabbit reticulocytes. Compared to mitochondria from rat liver reticulocyte, mitochondria exhibit about twice the amount of phospholipids. The phospholipid pattern of reticulocyte mitochondria (phosphatidylcholine, phosphatidylethanolamine, phosphatidylinositol and cardiolipin) is comparable with other mitochondrial species. Mitochondrial fractions from reticulocytes are characterized, however, by an additional content of sphingomyelin. This sphingomyelin differs in its fatty acid composition from the sphingomyelin of the plasma membrane. The fatty acid patterns of all other phospholipids essentially correspond to those of mitochondria from other sources and to those of plasma membranes as well.     

In vitro incorporation of ( 3 H) methyl choline into phosphatidyl choline of rat liver subcellular fractions

Incubation of a rat liver total homogenate with radioactive choline and subsequent isolation of subcellular fractions, at different times, showed similar patterns of labeling. Incubation of microsomes, mitochondria and purified nuclei isolated from rat liver, showed that all fractions were able to incorporate the precursor into phosphatidyl choline. The specific activity was higher in mitochondria and increased in all cases with added supernatant. The addition of microsomes to mitochondria diminished the incorporation of label. Contamination of mitochondria by microsomes, was negligible as shown by undetectable amounts of cytochrome P₄₅₀, while NADPH₂ cytochrome c reductase showed a 10% contamination. A certain amount of radioactivity was incorporated in the absence of ATP and oxidizable substrates due to the presence of substrates and cofactors in the fraction and/or the supernatant. Labeled fractions reincubated with unlabeled choline, showed no loss of radioactivity, proving that incorporation was not due to simple exchange processes. It is concluded that although rat liver mitochondria can acquire part of their own provision of phosphatidyl choline by transference from microsomes, all organelles and specially mitochondria, can independently synthesize this phospholipid.     

Phospholipid exchange activity in developing rat brain

Phospholipid exchange activity has been determined in the supernatant fraction of rat brain from birth through to maturity by measuring the protein-catalysed transfer of total and individual 32P-labelled phospholipids from microsomal membranes to mitochondria, and the transfer of [14C]phosphatidylcholine from liposomes to mitochondria. Transfer activity has also been compared in brain and liver supernatant. Overall phospholipid exchange activity in the brain increased only slightly with age. The activity at birth was 75% of the adult value. However, the transfer of individual phospholipids showed markedly different trends during postnatal brain development. The transfer of phosphatidylinositol (PI) and ethanolamine phospholipids increased postnatally to a maximum at 9 days of age, with lowest values in adult brain. Phosphatidylcholine (PC) transfer increased from 9 days to reach maximum values in the mature brain. The transfer of sphingomyelin was highest immediately after birth. PI transfer activity was higher in brain than liver, while PC and ethanolamine phospholipid transfer activity was higher in liver. The heterogeneity of phospholipid exchange proteins in central nervous system tissue is reflected in the developmental changes in exchange activity towards individual phospholipids. The various exchange proteins appear to have separate induction mechanisms. The presence of exchange-protein activity from birth in the rat indicates the functional importance of phospholipid transport during cell acquisition and membrane proliferation. Activity is not primarily associated with membrane formation such as the formation of the myelin sheath, and therefore is more likely to be involved in the process of phospholipid turnover.     

Topographical Distribution of Base Exchange Activities in Rat Brain Subcellular Fractions

Abstract: Enrichment in the base-exchange activities was found in the micro-somal fraction of rat brain, with less activity being associated with nuclei, mitochondria and synaptosomes. The distribution of the choline base exchange in microsomal subfractions differed from that for serine and ethanolamine and these three activities seemed asymmetrically distributed in the microsomes. Choline exchange activity was trypsin-sensitive and presumably was located on the cytoplasmic side of the microsomes, while serine and ethanolamine exchange activities were trypsin-insensitive and were assumed to be located on the luminal side of the microsomes. Treatment of rat brain microsomes with phospholipases A, C and D produced significant losses of membrane-bound base exchange activities. Some activity was restored in phospholipase C-treated microsomes by exogenous phospholipid, but significant restoration was not observed in phospholipase A-treated microsomes by such additions. Exogenous phospholipid stimulated choline and ethanolamine exchange activities, but not serine exchange activity of phospholipase D-treated microsomes. The exchange activities of rat brain microsomes differed in their responses to treatment with phospholipases, choline exchange activity in general being more sensitive than either serine or ethanolamine activities.     

Cholesterol exchange between microsomal, mitochondrial and erythrocyte membranes and its enhancement by cytosol.

1. Cholesterol exchanges between isolated rat liver microsomes and mitochondria and between erythrocytes and microsomes or mitochondria during incubation in vitro. The exchange process is temperature dependent and is no accompanied by a net movement of sterol. 2. cholesterol exchange between the membranes was enhanced by the addition of 105 000 x g supernatant fraction (S105) from rat liver. The degree to which sterol exchange was enhanced was dependent on the amount of this supernatant fraction present in the incubation. 3. enhancement of sterol exchange was not observed with heated S105 fraction, but activity was retained after dialysis or aging at 10 degrees C; these results suggest the presence of a cholesterol-exchange protein in the cytosol from rat liver.     

Fatty acid composition and unsaturated of intracellular membrane phospholipids from rat liver and hepatoma 27]

The fatty acid composition of phospholipids of mitochondria and microsomes from rat liver and hepatoma 27 was investigated. Basing on the fatty acid and phospholipid composition the unsaturation of the lipid bilayer of the intracellular membranes was calculated. The unsaturation of the phospholipids of the hepatoma mitochondria and microsomes was found to be much lower than that of the corresponding rat liver membranes. The lipid bilayer of the rat liver and hepatoma plasma membranes was shown to be more saturated than that of the intracellular membranes.     

Specificity of the phosphatidylcholine exchange protein from bovine liver

The phosphatidylcholine exchange protein from bovine liver stimulates the specific transfer of phosphatidylcholine (PC) from rat liver microsomes to mitochondria or phospholipid vesicles (Wirtz, K.W.A., Kamp, H.H., and van Deenen, L.L.M. (1972), Biochim. Biophys. Acta 274, 606). In the present study, it has been established which components of the PC molecule are essential to the specific interaction with the protein. Radiochemically labeled analogues of PC have been synthesized with modifications in the polar and apolar moiety, and their transfer was measured between donor and acceptor vesicles. Relative to 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphorylcholine (egg yolk PC), transfer is inhibited or abolished when (a) the distance between phosphorus and nitrogen is decreased or increased and (b) a methyl group on the quaternary nitrogen is removed or substituted by an ethyl or propyl group. Transfer is much less affected when (a) the ester bonds are replaced by ether or carbon-carbon bonds, (b) the PC molecule contains two saturated fatty acids, and (c) the D stereoisomer is used. It is concluded that the protein has a binding site which interacts specifically with the phosphorylcholine head group and which cannot accommodate substantial configurational changes. Interaction with the apolar moiety of PC is less specific. However, lyso-PC is not transferred, suggesting that two hydrocarbon chains are required to stabilize the exchange protein-phospholipid complex. Interaction of [14C]PC-labeled exchange protein with vesicles of different phospholipid compositon has been analyzed by measuring the release of [14C]PC into these vesicles. Vesicles of egg PC or dimethylphosphatidylethanolamine function as acceptors, in contrast to vesicles of sphingomyelin or phosphatidylethanolamine.     

Some properties of phosphatidylcholine exchange protein purified from beef liver

A phospholipid exchange protein has been purified 2680-fold from beef liver. The assay of the exchange activity of the protein was based on the transfer of [¹⁴C]phosphatidylcholine from microsomes labeled with [¹⁴C]phosphatidylcholine to liposomes. The homogeneity of the protein has been established by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoelectrophoresis and isoelectric focusing. The protein has a molecular weight of approximately 22000 and an isoelectric point of 5.8. The amino acid composition has been determined. The protein contains one disulfide bridge and has glutamic acid as the N-terminal amino acid. Phospholipid, tentatively identified as phosphatidylcholine, was found to be present in the protein preparation. The protein stimulated specifically the exchange of phosphatidylcholine between mitochondria and microsomes from rat liver.     

Extensive exchange of rat liver microsomal phospholipids

Liver microsomal fractions were prepared from rats injected with a single dose of choline [¹⁴C] methylchloride or with single or multiple doses of ³²P_i. Exchangeability of microsomal phospholipids was determined by incubation with an excess of mitochondria and phospholipid exchange proteins derived from beef heart, beef liver or rat liver. Labeled phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine and phosphatidylinositol were found to act as a single pool and were 85–95% exchangeable in 1–2 h. High latencies of mannose-6-phosphate phosphohydrolase activities and impermeability of microsomes to EDTA proved that phospholipid exchange proteins did not have access to the intracisternal space. If microsomal membranes are largely composed of phospholipid bilayers, the experiments suggest that one or more of the phospholipid classes in microsomal membranes undergo rapid translocation between the inner and outer portions of the bilayer.     

Exchange of phospholipids between brain membranes in vitro

1. When unlabelled mitochondria from guinea-pig brain were incubated with a (32)P-labelled microsomal fraction from brain there was a transfer of phospholipid to the mitochondria, which could not be accounted for by an aggregation of microsomes and mitochondria or an exchange with microsomes contaminating the mitochondria. Under similar circumstances there was a transfer of phospholipid from (32)P-labelled mitochondria to microsomes, indicating that the process was one of exchange. 2. The transfer from microsomes was greatly stimulated by a non-dialysable heat-labile macromolecular component in the brain supernatant fraction but not by the concentration of the particulate fractions. 3. Phospholipid-exchange processes occurred most readily between pH7 and 7.5 and were inhibited by the presence of myelin and on the addition of lysophosphatidylcholine. 4. The rates of transfer of individual phospholipids from brain microsomes to mitochondria were similar. 5. (32)P-labelled microsomes could slowly donate phospholipid to the isolated synaptosomal (nerve-ending) fraction but the phospholipids of the myelin fraction did not exchange. 6. Subfractionation of the synaptosomal fraction after [(32)P]phospholipid transfer showed that the mitochondria were most actively labelled during the incubation. All of the isolated individual synaptosomal membranes were capable of acquiring phospholipid on incubation with a (32)P-labelled brain supernatant fraction although a greater percentage was again exchanged by the mitochondrial fraction.     

A phosphatidyl choline exchange protein isolated from germinated castor bean endosperms

A phospholipid exchange protein (PLEP) functioning between theendoplasmic reticulum and the mitochondrion was purified fromthe cytosolic fraction of germinated castor bean endosperms.In the protein fraction eluted from Sephadex G-100 column, theexchange rate reached 7.3µg phospholipids exchanged/mgprotein/15 min, which was 60-fold that of pota to tuber PLEP.The lipid transfer by this protein was specific for phosphatidylcholine and the transfer rate from microsomes to mitochondriawas as high as that from mitochondria to microsomes. Castorbean PLEP transferred phospholipid from castor bean microsomesto mitochondria from other sources such as potato tubers, cauliflowerinflorescences, pumpkin hypocotyls and rat livers, and to liposomes,but not to Avena etioplasts. In addition, it transferred phospholipidfrom potato microsomes to potato mitochondria. (Received November 17, 1978; )     

Non-protein-mediated transfer of phosphatidic acid between microsomal and mitochondrial membranes

The transfer of phosphatidic acid between rat liver microsomes loaded with [32P]-phosphatidic acid and rat liver mitochondria was studied in the absence of added lipid transfer proteins. It was found that during 1 h at 37 degrees C in the medium containing 100 mM KCl, 20-30% of phosphatidic acid but only 2.5% of phosphatidylcholine were transferred. This spontaneous transfer of phosphatidic acid remained the same after pretreatment of microsomes and mitochondria with 125 mM KCl or microsomes alone with 1 mM Tris, pH 8.6, procedures reported to remove adsorbed lipid transfer proteins. This transfer was insensitive to thiol-blocking reagents. The initial rate of this non-protein-mediated transfer of phosphatidic acid was virtually independent of the concentration of the acceptor membranes (mitochondria), thus indicating that it occurs by diffusion of the phospholipid through the aqueous phase rather than by membrane collision. About 80% of phosphatidic acid synthesized in the outer mitochondrial membrane was recovered in the inner membrane after a 1-h incubation, pointing to a high rate of the intermembrane transfer of this phospholipid within intact mitochondrion.