The Role of Phosphatidylserine Decarboxylase in Brain Phospholipid Metabolism

In brain, phosphatidylethanolamine can be synthesized from free ethanolamine either by a pathway involving the formation of CDP-ethanolamine and its transfer to diglyceride, or by base-exchange of ethanolamine with existing phospholipids. Although de novo synthesis from serine has also been demonstrated, the metabolic pathway involved is not known. The enzyme phosphatidylserine decarboxylase appears to be involved in the synthesis of much of the phosphatidylethanolamine in liver, but the significance of this route in brain has been challenged. Our in vitro studies demonstrate the existence of phosphatidylserine decarboxylase activity in rat brain and characterize some of its properties. This enzyme is localized in the mitochondrial fraction, whereas the enzymes involved in base-exchange and the cytidine pathway are localized to microsomal membranes. Parallel in vivo studies showed that after the intracranial injection of L-[G-3H]serine, the specific activity of phosphatidylserine was greater in the microsomal fractions than in the mitochondrial fraction, whereas the opposite was true for phosphatidylethanolamine. When L-[U-14C]serine and [1-3H]ethanolamine were simultaneously injected, the 14C/3H ratio in mitochondrial phosphatidylethanolamine was 10 times that in microsomal phosphatidylethanolamine. The results demonstrate that serine is incorporated into the base moiety of phosphatidylethanolamine primarily through the decarboxylation of phosphatidylserine in brain mitochondria. A minimal value of 7% for the contribution of phosphatidylserine decarboxylase to whole-brain phosphatidylethanolamine synthesis can be estimated from the in vivo data.     

Characterization of the pathways for phosphatidylethanolamine biosynthesis in Chinese hamster ovary mutant and parental cell lines

A tritium suicide procedure was devised to facilitate the isolation of Chinese hamster ovary cell mutants defective in phosphatidylethanolamine biosynthesis. One mutant with a 20-50% reduction in [3H]ethanolamine incorporation was chosen for further analysis and was shown to have reduced activity of CTP: phosphoethanolamine cytidylyltransferase. Levels of phosphatidylethanolamine and rates of its biosynthesis were compared in the mutant and parent cell lines. Despite the reduced activity of the CDP-ethanolamine pathway in the mutant, levels of phosphatidylethanolamine were the same in mutant and parent cells. Rates of phosphatidylethanolamine synthesis de novo, as measured by incorporation of 32PO4 into phosphatidylethanolamine, were also the same in mutant and parent cells, as was the rate of incorporation of [3H]serine into both phosphatidylserine and phosphatidylethanolamine. After a long term labeling with [3H]serine, the specific radioactivity of phosphatidylserine was the same as that of phosphatidylethanolamine, and there was no difference in the specific radioactivities of the two lipids between mutant and parent cells. These results implicate decarboxylation of phosphatidylserine as the sole route for synthesis of phosphatidylethanolamine under normal culture conditions.     

Disruption of phosphatidylserine translocation to the mitochondria in baby hamster kidney cells

Phosphatidylserine synthase is found predominantly in the microsomal fraction, and phosphatidylserine decarboxylase is found predominantly in the mitochondrial fraction of baby hamster kidney (BHK-21) cells. This segregation of enzymes of phosphatidylserine metabolism allows serine metabolism to phosphatidylserine and phosphatidylethanolamine to be used as an indicator of the intracellular movement of phosphatidylserine. After BHK-21 cells were pulse-labeled with [3H]serine, phosphatidylserine was efficiently labeled, and subsequently 40-50% of this radiolabeled lipid turned over to form phosphatidylethanolamine during a 7.5-h chase. Treatment of cells with NaN3 plus NaF or cycloheximide at the end of the pulse labeling period markedly inhibited the rate and extent of phosphatidylserine turnover during the chase period. The inhibition of phosphatidylserine turnover could not be attributed to inhibition of either phosphatidylserine decarboxylase or phosphatidylserine exchange protein activity. Subcellular fractionation of the BHK-21 cells demonstrated that cells poisoned with NaN3 plus NaF accumulated phosphatidylserine in the microsomal fraction relative to unpoisoned cells. The results indicate that metabolic energy is required for the transport of phosphatidylserine to the mitochondria.     

Phosphatidylethanolamine biosynthesis in rat mammary carcinoma cells that require and do not require ethanolamine for proliferation

Epithelial cells and some of their transformed derivatives require ethanolamine to grow normally in defined culture medium. When these cells are cultured without ethanolamine, the amount of cellular phosphatidylethanolamine is considerably reduced. Using a set of rat mammary carcinoma cell lines whose growth is responsive (64-24 cells) and not responsive (22-1 cells) to ethanolamine, the biochemical mechanism of ethanolamine responsiveness was investigated. The biosynthesis and metabolism of phospholipid, particularly of those involving phosphatidylethanolamine, were thus compared between the two types of cells. The incorporation of [3H]serine into phosphatidylserine and phosphatidylethanolamine in 64-24 cells was 60 and 37%, respectively, of those in 22-1 cells. However, the activity of phosphatidylserine decarboxylase was virtually the same in these cell lines. When these cells were cultured in the presence of [32P]phosphatidylcholine and [32P]phosphatidylethanolamine, the rate of accumulation of 32P-labeled phosphatidylserine from the radioactive phosphatidylethanolamine was considerably reduced in 64-24 cells compared to that in 22-1 cells, although the rate of synthesis of phosphatidylserine and phosphatidylethanolamine from the radioactive phosphatidylcholine was similar between the two cell lines. The rate of labeling phosphatidylcholine from the radioactive phosphatidylethanolamine was also reduced in 64-24 cells, although the difference was not as great as that of phosphatidylserine. Incorporation of 32P into phosphatidylethanolamine was correlated with the concentration of ethanolamine in the culture medium in 64-24 cells, whereas in 22-1 cells the incorporation was not influenced by ethanolamine. Enzyme activities of the CDP-ethanolamine pathway were not significantly different between the two cell lines. The rate of degradation of phosphatidylethanolamine was also similar in these cell lines. These results show that ethanolamine responsiveness of 64-24 cells, and probably other epithelial cells, is due to a limited ability to synthesize phosphatidylserine resulting from a limited base-exchange activity utilizing phosphatidylethanolamine.     

Characterization of phosphatidylserine synthesis and translocation in permeabilized animal cells

The synthesis of phosphatidylserine and its translocation to the mitochondria were examined in permeabilized Chinese hamster ovary (CHO)-K1 cells by following the metabolism of a [3H]serine precursor to [3H] phosphatidylserine (PtdSer) and [3H]phosphatidylethanolamine (PtdEtn). In physiological salt solutions approximating the intracellular ionic composition, both the synthesis of PtdSer and its translocation required ATP. The ATP requirement for PtdSer synthesis could be completely bypassed, and that for translocation could be partially bypassed at Ca2+ concentrations 10(3)-10(4) times the intracellular physiological level (i.e. 1 mM). The ATP-dependent synthesis of PtdSer could be inhibited by chelation of Ca2+ with EGTA, inhibition of Ca2+ sequestration with 2,5-di(tert-butyl)hydroquinone, mobilization of sequestered Ca2+ with ionomycin, and competition for [3H]serine with ethanolamine. The inhibition of the ATP-dependent synthesis of PtdSer by the aforementioned inhibitors provided an efficient method to rapidly arrest the incorporation of [3H]serine into [3H]PtdSer. By pulse-labeling the [3H]PtdSer pool and arresting further synthesis with inhibitors, the translocation of nascent PtdSer could be uncoupled from synthesis. The results of these pulse-labeling-arrest experiments provide unambiguous evidence that PtdSer translocation to the mitochondria is not driven by PtdSer synthesis. The addition of apyrase to ATP-supplemented, permeabilized cells abruptly terminates [3H]serine incorporation into [3H]PtdSer and the decarboxylation of [3H]PtdSer to [3H]PtdEtn, thereby demonstrating that a specific ATP requirement exists for the translocation of nascent PtdSer to the mitochondria in permeabilized cells. The translocation of nascent PtdSer to the mitochondria was unaffected by 45-fold dilution of the standard reaction thus indicating that the translocation intermediate was unlikely to be a freely diffusible complex. The requirements for translocation of nascent phosphatidylserine are different from those for the vesicular movement of proteins insofar as the lipid movement does not require cytosol and is unaffected by the addition of Ca2+, GTP, or GTP gamma S. From these studies, we conclude that: 1) the synthesis and translocation of PtdSer can be readily studied in permeabilized cells, 2) the ATP-dependent synthesis of PtdSer is functionally coupled to the ATP-dependent sequestration of Ca2+ by the endoplasmic reticulum or closely related membranes, 3) PtdSer translocation is independent of its synthesis, and 4) there is a specific requirement for ATP in the translocation of PtdSer to the mitochondria.     

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.     

Biosynthesis of phosphatidylethanolamine via the CDP-ethanolamine route is an important pathway in isolated rat hepatocytes

In the present study pulse-label and pulse-chase experiments with isolated rat hepatocytes in suspension were designed to investigate the effects of the presence of either serine or ethanolamine in the medium on the rate of phosphatidylethanolamine synthesis via the CDPethanolamine pathway and by decarboxylation of phosphatidylserine. Addition of serine to the medium did not affect the incorporation of [1,2-14C]ethanolamine into phosphatidylethanolamine. Pulse-label experiments showed that the incorporation of [3H]serine into phosphatidylserine decreased in the presence of ethanolamine with a corresponding decrease of the incorporation of label into the ethanolamine base moiety of phosphatidylethanolamine. However, the radioactivity in the diacylglycerol part of phosphatidylethanolamine was considerably higher in the presence of ethanolamine than in its absence. Pulse-chase experiments with labelled serine demonstrated that the conversion of phosphatidylserine to phosphatidylethanolamine was not affected by varying concentrations of ethanolamine. Our observations indicate that in the presence of ethanolamine the biosynthesis of phosphatidylethanolamine via the CDPethanolamine pathway is enhanced relative to the synthesis by decarboxylation of phosphatidylserine.     

Phosphatidylserine biosynthesis in cultured Chinese hamster ovary cells. I. Inhibition of de novo phosphatidylserine biosynthesis by exogenous phosphatidylserine and its efficient incorporation

The effect of phosphatidylserine exogenously added to the medium on de novo biosynthesis of phosphatidylserine was investigated in cultured Chinese hamster ovary cells. When cells were cultured for several generations in medium supplemented with phosphatidylserine and 32Pi, the incorporation of 32Pi into cellular phosphatidylserine was remarkably inhibited, the degree of inhibition being dependent upon the concentration of added phosphatidylserine. 32Pi uptake into cellular phosphatidylethanolamine was also partly reduced by the addition of exogenous phosphatidylserine, consistent with the idea that phosphatidylethanolamine is biosynthesized via decarboxylation of phosphatidylserine. However, incorporation of 32Pi into phosphatidylcholine, sphingomyelin, and phosphatidylinositol was not significantly affected. In contrast, the addition of either phosphatidylcholine, sphingomyelin, phosphatidylethanolamine, or phosphatidylinositol to the medium did not inhibit endogenous biosynthesis of the corresponding phospholipid. Radiochemical and chemical analyses of the cellular phospholipid composition revealed that phosphatidylserine in cells grown with 80 microM phosphatidylserine was almost entirely derived from the added phospholipid. Phosphatidylserine uptake was also directly determined by using [3H]serine-labeled phospholipid. Pulse and pulse-chase experiments with L-[U-14C] serine showed that when cells were cultured with 80 microM phosphatidylserine, the rate of synthesis of phosphatidylserine was reduced 3-5-fold whereas the turnover of newly synthesized phosphatidylserine was normal. Enzyme assaying of extracts prepared from cells grown with and without phosphatidylserine indicated that the inhibition of de novo phosphatidylserine biosynthesis by the added phosphatidylserine appeared not to be caused by a reduction in the level of the enzyme involved in the base-exchange reaction between phospholipids and serine. These results demonstrate that exogenous phosphatidylserine can be efficiently incorporated into Chinese hamster ovary cells and utilized for membrane biogenesis, endogenous phosphatidylserine biosynthesis thereby being suppressed.     

Phosphatidylserine biosynthesis in mitochondria from the Morris 7777 hepatoma.

Mitochondria from the 7777 hepatoma incorporate substantial amounts of l-[U-(14)C]serine into phospholipid by a Ca(2+)-dependent base-exchange reaction. This reaction is virtually absent in normal liver mitochondria. The finding cannot be attributed to microsomal contamination of the sucrose gradient-purified 7777 hepatoma mitochondria. The reaction is also absent in the rapid-growth controls, fetal rat liver and regenerating rat liver. [(14)C]Serine incorporation into 7777 hepatoma mitochondrial phospholipid by base-exchange requires Ca(2+) and is inhibited by EDTA. Ca(2+) cannot be replaced by Mg(2+), Mn(2+), or Co(2+). The reaction is inhibited by a sulfhydryl reagent and by detergents and is abolished by heating to 70 degrees C for 10 min. Product analysis indicates that phosphatidylserine and its decarboxylation product, phosphatidylethanolamine, are formed by 7777 hepatoma mitochondria, while phosphatidylserine is the sole product with microsomes. The conversion of phosphatidylserine into phosphatidylethanolamine in 7777 hepatoma mitochondria is inhibited by KCN. This study provides further evidence of abnormal mitochondrial biogenesis in the 7777 hepatoma. Our earlier study indicated a greatly increased mitochondrial activity of CTP:phosphatidate cytidylyltransferase in the 7777 hepatoma (Hostetler, Zenner, and Morris. 1978. J. Lipid Res. 19: 553-560). The presence in mitochondria of these two enzymes, which are primarily microsomal in normal liver, does not appear to be due to rapid growth alone, since their intracellular distribution was not altered in fetal or regenerating rat liver.-Hostetler, K. Y., B. D. Zenner, and H. P. Morris. Phosphatidylserine biosynthesis in mitochondria from the Morris 7777 hepatoma.     

Intramitochondrial transfer of phospholipids in the yeast, Saccharomyces cerevisiae

Translocation of phosphatidylinositol, which is synthesized on the outer aspect of the outer membrane of isolated yeast mitochondria, to the inner membrane is linked to phosphatidylinositol synthesis and is therefore a vectorial process. Phosphatidylinositol once integrated into the inner mitochondrial membrane is not transferred back to the mitochondrial surface. Phosphatidylserine is also translocated from the outer to the inner mitochondrial membrane, where it is decarboxylated to phosphatidylethanolamine. We made use of this metabolic modification to characterize the intramitochondrial transfer of phosphatidylserine and phosphatidylethanolamine. Intramitochondrial phosphatidylserine transfer is insensitive to the uncoupler carbonyl cyanide m-chlorophenylhydrazone and to valinomycin and is thus independent of an electrochemical gradient across the inner membrane. Transfer of phosphatidylserine from the outer to the inner mitochondrial membrane occurs not only in intact mitochondria but also in mitoplasts which are devoid of intermembrane space proteins but have the outer membrane still adherent to the inner membrane. This result suggests that specific contact sites are involved in the intramitochondrial translocation of phospholipids. 3H-Labeled phosphatidylethanolamine synthesized from [3H]serine in isolated mitochondria is readily exported from the inner to the outer mitochondrial membrane without prior mixing with the pool of phosphatidylethanolamine of the inner membrane.     

Isolation and characterization of a Chinese hamster ovary cell line requiring ethanolamine or phosphatidylserine for growth and exhibiting defective phosphatidylserine synthase activity

A mutant cell line (designated M.9.1.1) requiring ethanolamine for growth was derived from Chinese hamster ovary (CHO-K1) cells using 5-bromodeoxyuridine enrichment. The ethanolamine requirement was readily replaced by 20 microM phosphatidylserine and 10 microM lysophosphatidylethanolamine. When M.9.1.1 cells were supplemented with phosphatidyl[3H]serine it was rapidly taken up, and subsequently decarboxylated to form phosphatidyl[3H]ethanolamine. The incorporation of [3H]serine into phosphatidylserine in the mutant cells was 57% of that in the parental cells. Phosphatidylethanolamine synthesis from [3H]serine in the mutant cells was 35% of that in parental cells. When M.9.1.1 cells were deprived of ethanolamine for 48 h the level of phosphatidylserine decreased 34% and the level of phosphatidylethanolamine decreased 26% compared to parental cells. At the same time the rate of turnover of phosphatidylserine was reduced to half that found in parental cells. Examination of the enzymes of phosphatidylserine metabolism indicated defective phosphatidylserine synthase activity in the mutant. When exogenous phosphatidylcholine was used as the phospholipid substrate for the reaction the apparent kinetic constants were Vmax (mutant) = 5.7 pmol/min/mg protein and Vmax (parental) = 17.5 pmol/min/mg protein. Measurement of the back reaction (ATP-independent incorporation of choline into phospholipid) gave no detectable activity in the mutant cells. The data indicate that the phosphatidylcholine-dependent synthesis of phosphatidylserine is the primary lesion in M.9.1.1.     

Chinese hamster ovary cells deficient in peroxisomes lack the nonspecific lipid transfer protein (sterol carrier protein 2)

Chinese hamster ovary cells deficient in intact peroxisomes were compared with wild type cells for the presence of the nonspecific lipid transfer protein (nsL-TP; sterol carrier protein 2). With the immunoblotting technique using the affinity purified antibody against rat liver nsL-TP, this protein was shown to be present in the homogenates from wild type cells, but could not be detected in mutant cells. In agreement with a previous study using livers from Zellweger patients it appears that there is a positive, as yet unknown, correlation between peroxisomes and the occurrence of nsL-TP in the cell. As a control using the affinity-purified antibody against the phosphatidylinositol transfer protein from bovine brain, levels of this protein were found to be normal in mutant cells. By use of metrizamide density gradients, nsL-TP was shown to cosediment with a membrane fraction different from peroxisomes. A protein of 58,000 daltons cross-reactive with the antibody against nsL-TP did cosediment with the peroxisomes in wild type cells and possibly with a "peroxisomal remnant" in the mutant cells. Incubation of wild type and mutant cells with L-[3-14C]serine showed that the biosynthesis of phosphatidylserine and the subsequent conversion into phosphatidylethanolamine was comparable in both cell types. This indicates that nsL-TP is not involved in the translocation of phosphatidylserine from the endoplasmic reticulum to the mitochondria as the site of decarboxylation.     

Phosphatidylserine biosynthesis in cultured Chinese hamster ovary cells. III. Genetic evidence for utilization of phosphatidylcholine and phosphatidylethanolamine as precursors

In the preceding paper, we reported that Chinese hamster ovary (CHO) cells contain two different serine-exchange enzymes (I and II) which catalyze the base-exchange reaction of phospholipid(s) with serine and that a phosphatidylserine-requiring mutant (strain PSA-3) of CHO cells is defective in serine-exchange enzyme I and lacks the ability to synthesize phosphatidylserine (Kuge, O., Nishijima, M., and Akamatsu, Y. (1986) J. Biol. Chem. 261, 5790-5794). In this study, we examined precursor phospholipids for phosphatidylserine biosynthesis in CHO cells. When mutant PSA-3 and parent (CHO-K1) cells were cultured with [32P]phosphatidylcholine, phosphatidylserine in the parent accumulated radioactivity while that in the mutant was not labeled significantly. On the contrary, when cultured with [32P]phosphatidylethanolamine, the mutant incorporated the label into phosphatidylserine more efficiently than the parent. Furthermore, we found that mutant PSA-3 grew normally in growth medium supplemented with 30 microM phosphatidylethanolamine as well as phosphatidylserine and that the biosynthesis of phosphatidylserine in the mutant was biosynthesis of phosphatidylserine in the mutant was normal when cells were cultured in the presence of exogenous phosphatidylethanolamine. The simplest interpretation of these findings is that phosphatidylserine in CHO cells is biosynthesized through the following sequential reactions: phosphatidylcholine----phosphatidylserine----phosphatidylethanolamine--- - phosphatidylserine. The three reactions are catalyzed by serine-exchange enzyme I, phosphatidylserine decarboxylase, and serine-exchange enzyme II, respectively.     

Specific pools of phospholipids are used for lipoprotein secretion by cultured rat hepatocytes

Since phospholipids are major components of all serum lipoproteins, the role of phospholipid biosynthesis in lipoprotein secretion from cultured rat hepatocytes has been investigated. In liver, phosphatidylcholine is made both by the CDP-choline pathway and by the methylation of phosphatidylethanolamine, which in turn is derived from both serine (via phosphatidylserine) and ethanolamine (via CDP-ethanolamine). Monolayer cultures of rat hepatocytes were incubated in the presence of [methyl-3H]choline, [1-3H] ethanolamine, or [3-3H]serine. The specific radioactivity of the phospholipids derived from each of these precursors was measured in the cells and in the secreted lipoproteins of the cultured medium. The specific radioactivities of phosphatidylcholine and phosphatidylethanolamine derived from [1-3H]ethanolamine were markedly lower (approximately one-half and less than one-tenth, respectively) in the secreted phospholipids than in the cellular phospholipids. Thus, ethanolamine was not an effective precursor of the phospholipids in lipoproteins. On the contrary, the specific radioactivity of phosphatidylcholine made from [methyl-3H]choline was approximately equal in cells and lipoproteins. In addition, over the first 4 h of incubation with [3-3H]serine, the specific radioactivities of phosphatidylcholine and phosphatidylethanolamine were significantly higher in the lipoproteins than in the cells. These data indicate that there is not a random and homogeneous labeling of the phospholipid pools from the radioactive precursors. Instead, specific pools of phospholipids are selected, on the basis of their routes of biosynthesis, for secretion into lipoproteins.     

Ethanolamine metabolism in cultured bovine aortic endothelial cells

The role of extracellular ethanolamine in phospholipid synthesis was examined in cultured bovine aortic endothelial cells. Serine and ethanolamine were both readily accumulated by these cells and incorporated into phospholipid. Exposing cells to extracellular ethanolamine for 4-6 weeks had no effect on cell growth, yet increased the phosphatidylethanolamine content of these cells by 31% as compared to control cells. The intracellular content of ethanolamine was measured by high performance liquid chromatography, and results showed that the ethanolamine-treated cells contained a significantly greater amount of free ethanolamine compared to control cells (0.62 +/- 0.07 nmol/mg of protein versus 0.27 +/- 0.05 nmol/mg of protein, respectively). Ethanolamine-treated cells also had decreased accumulation and incorporation into lipid of [3H]ethanolamine throughout a 48-h incubation and increased K'm and V'max parameters of ethanolamine transport as compared to control cells. Studies were also done to examine the effect of ethanolamine on the generation of free ethanolamine from phosphatidylserine. In pulse-chase experiments with [3H]serine, a physiological concentration of ethanolamine (25 microM) decreased the amount of 3H-labeled phosphatidylethanolamine produced from 3H-labeled phosphatidylserine by 12 h as compared to the amount of 3H-labeled phosphatidyl-ethanolamine produced in the absence of ethanolamine in the chase incubation. Furthermore, ethanolamine-treated cells accumulated 20% less labeled ethanolamine in the aqueous pool from [3H]serine after 24 h of incubation than did control cells. These results can be explained by isotope dilution with the ethanolamine pool that accumulates in these cells with time when exposed to media supplemented with a physiological concentration of ethanolamine and by an effect of ethanolamine on ethanolamine generation from phosphatidylserine. The results show that an extracellular source of ethanolamine significantly influences the phospholipid metabolism of cultured bovine aortic endothelial cells.     

Serine regulates phosphatidylethanolamine biosynthesis in the hamster heart.

The role of serine as a precursor and metabolic regulator for phosphatidylethanolamine biosynthesis in the hamster heart was investigated. Hearts were perfused with 50 microM [1-3H]ethanolamine in the presence or absence of serine for up to 60 min. Ethanolamine uptake was attenuated by 0.05-10 mM serine in a noncompetitive manner, and the incorporation of labeled ethanolamine into phosphatidylethanolamine was also inhibited by serine. Analysis of the ethanolamine-containing metabolites in the CDP-ethanolamine pathway revealed that the conversion of ethanolamine to phosphoethanolamine was reduced. The reduction was a result of an inhibition of ethanolamine kinase activity by an elevated pool of intracellular serine. Perfusion of the heart with 1 mM serine caused a 5-fold increase in intracellular serine pool. In order to examine the action of serine on other phosphatidylethanolamine metabolic pathways, hearts were perfused with [1-3H]glycerol in the presence and absence of serine. Serine did not cause any enhancement of phosphatidylethanolamine hydrolysis. The base-exchange reaction for phosphatidylserine formation or the decarboxylation of phosphatidylserine was not affected by serine perfusion. We conclude that circulating serine plays an important role in the modulation of phosphatidylethanolamine biosynthesis via the CDP-ethanolamine pathway in the hamster heart but does not affect the contribution of the decarboxylase pathway for phosphatidylethanolamine formation.     

Isolation and characterization of a Chinese hamster ovary cell mutant with altered regulation of phosphatidylserine biosynthesis

We have screened approximately 10,000 colonies of Chinese hamster ovary (CHO) cells immobilized on polyester cloth for mutants defective in [14C]ethanolamine incorporation into trichloroacetic acid-precipitable phospholipids. In mutant 29, discovered in this way, the activities of enzymes involved in the CDP-ethanolamine pathway were normal; however, the intracellular pool of phosphorylethanolamine was elevated, being more than 10-fold that in the parental CHO-K1 cells. These results suggested that the reduced incorporation of [14C]ethanolamine into phosphatidylethanolamine in mutant 29 was due to dilution of phosphoryl-[14C]ethanolamine with the increased amount of cellular phosphorylethanolamine. Interestingly, the rate of incorporation of serine into phosphatidylserine and the content of phosphatidylserine in mutant 29 cells were increased 3-fold and 1.5-fold, respectively, compared with the parent cells. The overproduction of phosphorylethanolamine in mutant 29 cells was ascribed to the elevated level of phosphatidylserine biosynthesis, because ethanolamine is produced as a reaction product on the conversion of phosphatidylethanolamine to phosphatidylserine, which is catalyzed by phospholipid-serine base-exchange enzymes. Using both intact cells and the particulate fraction of a cell extract, phosphatidylserine biosynthesis in CHO-K1 cells was shown to be inhibited by phosphatidylserine itself, whereas that in mutant 29 cells was greatly resistant to the inhibition, compared with the parental cells. As a conclusion, it may be assumed that mutant 29 cells have a lesion in the regulation of phosphatidylserine biosynthesis by serine-exchange enzyme activity, which results in the overproduction of phosphatidylserine and phosphorylethanolamine as well.     

Mitochondrial membrane contact sites of yeast. Characterization of lipid components and possible involvement in intramitochondrial translocation of phospholipids

Submitochondrial membrane fractions from yeast that are enriched in inner and outer membrane contact sites were analyzed with respect to their lipid composition. Characteristic features were the significantly reduced content of phosphatidylinositol, the decreased amount of phosphatidylcholine, and the enrichment in phosphatidylethanolamine and cardiolipin. Coisolation of phosphatidylserine synthase with the outer membrane portion and enrichment of phosphatidylserine decarboxylase in the inner membrane portion of isolated contact sites provided the basis for a metabolic assay to study phosphatidylserine transfer from the outer to the inner mitochondrial membrane via contact sites. The efficient conversion to [3H]phosphatidylethanolamine of [3H]phosphatidylserine synthesized from [3H]serine in situ supports the notion that mitochondrial membrane contact sites are zones of intramitochondrial translocation of phosphatidylserine.     

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).     

Effect of 1,25-dihydroxyvitamin D3 on phospholipid metabolism in a clonal osteoblast-like rat osteogenic sarcoma cell line

The effect of 1,25-dihydroxyvitamin D3 (1,25-(OH)2D3) on phospholipid metabolism was examined in clonal rat osteogenic sarcoma cells, UMR 106, of osteoblastic phenotype. Treatment of UMR 106 cells with 10(-8)M 1,25-(OH)2D3 for 48 h caused an increase in [14C]serine incorporation into phosphatidylserine (PS) and a decrease in [3H]ethanolamine, [3H]linositol, and [14C]choline incorporation into phosphatidylethanolamine (PE), phosphatidylinositol, and phosphatidylcholine, respectively; the decrease in [3H]ethanolamine incorporation into PE was the largest. The total contents of phospholipids were similarly affected by 10(-8)M 1,25-(OH)2D3 treatment, suggesting that the effects of 1,25-(OH)2D3 are due largely to alterations in the synthesis of these phospholipids. The effects of 1,25-(OH)2D3 were evident at 10(-10) M 1,25-(OH)2D3, and 10(-8)M 1,25-(OH)2D3 caused a maximal stimulation of [14C]PS synthesis (167% of control) and a maximal reduction in the [3H]PE synthesis (41% of control). The [14C]PS/[3H]PE ratio increased gradually and reached a maximum after 70 h of treatment with 10(-8)M 1,25-(OH)2D3. When the cells were cultured in calcium-free medium containing 0.5 mM EGTA or when 5 microM cycloheximide was added to the medium, the effect of 1,25-(OH)2D3 on phospholipid metabolism was almost completely inhibited. Neither 25-hydroxyvitamin D3 nor 24,25-dihydroxyvitamin D3 caused significant changes in phospholipid metabolism. These results suggest that 1,25-(OH)2D3 alters phospholipid metabolism by enhancing PS synthesis through a calcium-dependent stimulation of the base exchange reaction of serine with other phospholipids and that the effect of 1,25-(OH)2D3 requires the synthesis of new proteins. Because PS is thought to be important for apatite formation and bone mineralization by binding calcium and phosphate to form calcium-PS-phosphate complexes, the present data suggest that 1,25-(OH)2D3 may stimulate bone mineralization by a direct effect on osteoblasts, stimulating PS synthesis.