Studies of rat liver microsomal diglyceride acyltransferase and cholinephosphotransferase using microsomal-bound substrate: effects of high fructose intake.

Radiolabeled phosphatidate and diglyceride were prepared bound to rat liver microsomes. These compounds were used as substrates in studies of diglyceride acyltransferase, cholinephosphotransferase, and CTP:phosphatidic acid cytidylyltransferase. Optimum incubation conditions for these reactions in microsomes from normal male rats are described. High fructose diets were fed to rats for 11 days; this resulted in an increased rate of neutral lipid formation from sn-glycerol-3-phosphate by liver microsomal preparations. This was attributed, in part, to a previously reported increase in liver phosphatidate phosphatase activity. The significance of this increase is supported by the finding of a fall in microsomal phosphatidate content and a doubling in microsomal diglyceride. In addition, diglyceride acyltransferase measured with microsomal-bound diglyceride was increased twofold with no equivalent change in cholinephosphotransferase activity. Such a change should result in preferential triglyceride formation from the increased microsomal diglyceride pool. CTP:phosphatidic acid cytidylytransferase activity was depressed by the high fructose diet. These combined alterations would lead to an accelerated hepatic triglyceride formation, a result found in vivo during high fructose feeding. The high fructose diet decreased slightly the total microsomal phospholipid content and markedly depressed phosphatidylethanolamine levels.     

Studies on the formation by rat brain preparations of CDP-diglyceride from CTP and phosphatidic acids of varying fatty acid compositions.

The enzyme, CTP:phosphatidate cytidylyltransferase (EC2.7.7.41) which catalyses formation of CDP-diglyceride from CTP and phosphatidic acid has been studied in rat brain preparations and other tissues. Improvement, as judged by the higher tissue activities obtained, in the assay method for this enzyme was achieved through use of phosphatidic acids sonicated in buffer-detergent solution saturated with ether and containing bovine serum albumin and use of short incubation times which essentially provided a measure of initial rates. The enzyme of rat brain microsomes yielded with 1,2-dioleolphosphatidic acid as substrate a pH optimum of 6.8 with maleate buffer and optimal concentrations of 60mM for MG2+, 6MM for CTP and 250 mug per 0.8 ml for phosphatidic acid. Enzyme activity was mainly located in the 90,000 X g fraction (microsomal) with small but significant activity in the 12,000 X g fraction. Comparison of activities (nanomoles CTP incorporated per milligram protein per minute) amongst tissues showed the following order: brain, 1.87; liver, 1.32; lung, 1.19; small intestine, 1.00; kidney, 0.69; heart, 0.41; diaphragm, 0.07; skeletal muscle, 0.02. Examination of the effect of varying the fatty acid composition in the phosphatidic acids added exogenously gave the following order (activities in parentheses); 1-stearoyl-2-oleoyl- (5.58), 1-oleoyl-2-stearoyl- (5.37), 1,2-dioleoyl- (4.49) 1-palmitoyl-2-oleoyl-(3.85), 1-stearoyl-2-arachidonoyl-(3.31), 1-arachidonoyl-2-stearoyl-(3.16), 1,2-diarachidonoyl-(0.72), 1,2-dicaproyl-(0.67), 1,2-dipalmitoyl-(0.67) and 1,2-distearoyl-(0.18). The single bis- and lysophosphatidic acids tested were inactive as substrates. Apart from a possible preference for one or more unsaturated fatty acids the transferase enzyme showed no selectivity in respect to the fatty acid distribution of phosphatidic acids.     

CDP-diacylglycerol synthase activity in Clostridium perfringens

CTP:phosphatidate cytidylyltransferase (CDP-diacylglycerol synthase; EC 2.7.7.41) was identified in the cell envelope fraction of the gram-positive anaerobe Clostridium perfringens. The association of this enzyme with the cell envelope fraction of cell extracts was demonstrated by glycerol density gradient centrifugation and by activity sedimenting with the 100,000 x g pellet. The enzyme exhibited a broad pH optimum between pH 6.5 and pH 7.5. Enzyme activity was dependent on magnesium (5 mM) or manganese (1 mM) ions. Activity was also dependent on the addition of the nonionic detergent Triton X-100 (5 mM). The apparent Km values for CTP and phosphatidic acid were 0.18 mM and 0.22 mM, respectively. Thioreactive agents inhibited activity, indicating that a sulfhydryl group is essential for activity. Maximal enzyme activity was observed at 50 degrees C.     

CDP-diacylglycerol synthase activity in Clostridium perfringens.

CTP:phosphatidate cytidylyltransferase (CDP-diacylglycerol synthase; EC 2.7.7.41) was identified in the cell envelope fraction of the gram-positive anaerobe Clostridium perfringens. The association of this enzyme with the cell envelope fraction of cell extracts was demonstrated by glycerol density gradient centrifugation and by activity sedimenting with the 100,000 x g pellet. The enzyme exhibited a broad pH optimum between pH 6.5 and pH 7.5. Enzyme activity was dependent on magnesium (5 mM) or manganese (1 mM) ions. Activity was also dependent on the addition of the nonionic detergent Triton X-100 (5 mM). The apparent Km values for CTP and phosphatidic acid were 0.18 mM and 0.22 mM, respectively. Thioreactive agents inhibited activity, indicating that a sulfhydryl group is essential for activity. Maximal enzyme activity was observed at 50 degrees C.     

Altered subcellular and submitochondrial localization of CTP:phosphatidate cytidylyltransferase in the Morris 7777 hepatoma.

The subcellular and submitochondrial localization of CTP:phosphatidate cytidylyltransferase is altered in the Morris 7777 hepatoma. Mitochondria in this poorly differentiated tumor are the principal sites of CDP-diacylglycerol synthesis, in contrast to normal rat liver where the endoplasmic reticulum is most active. This enzyme activity was increased 17-fold in the outer mitochondrial membrane, and a 22% increase was noted in the inner mitochondrial membrane of the 7777 hepatoma as compared with the corresponding fractions from normal rat liver. Increased mitochondrial CTP:phosphatidate cytidylyltransferase was present in six other Morris hepatomas, but it was not found in fetal rat liver mitochondria, suggesting that rapid growth alone is not responsible for the difference. Evidence is presented which indicates that mitochondrial lipid degradation is similar in normal liver and the 7777 hepatoma, in vitro. The increased activity of CTP: phosphatidate cytidylytransferase is thought to be responsible in part for the moderately increased diphosphatidylglycerol content of 7777 hepatoma mitochondria.     

Regulation of fatty acid oxidation and triglyceride and phospholipid metabolism by hypolipidemic sulfur-substituted fatty acid analogues

The mechanisms behind the hypotriglyceridemic effect of 1,10-bis(carboxymethylthio)decane (3-thiadicarboxylic acid) and tetradecylthioacetic acid and the development of fatty liver caused by 3-tetradecylthiopropionic acid (Aarsland et al. 1989. J. Lipid Res. 30: 1711-1718.) were studied in the rat. Repeated administration of S-substituted non-beta-oxidizable fatty acid analogues to normolipidemic rats resulted in a time-dependent decrease in plasma triglycerides, phospholipids, and free fatty acids. This was accompanied by an acute reduction in the liver content of triglycerides and an increase in the hepatic concentration of phospholipids. Mitochondrial fatty acid oxidation was stimulated, whereas lipogenesis was inhibited. The activity of phosphatidate phosphohydrolase decreased while the activity of CTP:phosphocholine cytidylyltransferase increased. These results suggest that the observed triglyceride-lowering effect was due to increased mitochondrial fatty acid oxidation accompanied by a reduction in the availability of the substrate i.e., free fatty acid, along with an enzymatic inhibition (phosphatidate phosphohydrolase). Administration of 3-tetradecylthiopropionic acid led to a drastic increase in the hepatic triglyceride content. Levels of plasma triglyceride phospholipid and free fatty acid also increased. Phosphatidate phosphohydrolase activity was stimulated whereas CTP:phosphocholine cytidylyltransferase was inhibited. Mitochondrial fatty acid oxidation was decreased. These data indicate that the development of fatty liver as an effect of 3-tetradecylpropionic acid is probably due to accelerated triglyceride biosynthesis, which is mediated by an increase in the availability of fatty acid along with stimulation of phosphatidate phosphohydrolase. The results of the present study speak strongly in favor of the hypothesis that phosphatidate phosphohydrolase is a major rate-limiting enzyme in triglyceride biosynthesis. Furthermore, they point out that the biosynthesis of triglycerides and phospholipids might be coordinately regulated. Such regulation is possibly mediated via phosphatidate phosphohydrolase and CTP:phosphocholine cytidylyltransferase. Whether the increase in hepatic phospholipids via increased CDP-pathway accounts for an increase of lipid components for proliferation of peroxisomes (3-thiadicarboxylic acid and tetradecylacetic acid) should be considered.     

Studies on the synthesis of CDP-diacylglycerol: Stimulation by GTP and inhibition by ATP and fluoride

The rat liver microsomal enzyme CTP: phosphatidate cytidylyltransferase (EC 2.7.7.41) which catalyzes the formation of CDP-diacylglycerol has been found to be markedly stimulated by GTP. The requirement for GTP is absolute, the novel GTP analogues such as guanosine 5′-[β,γ-methylene]-triphosphate, guanosine 5′-[α,β-methylene]-triphosphate, guanosine 5′-[β,γ-imido]-triphosphate and guanosine 3′-diphosphate 5′-diphosphate are without significant effect. Maximal stimulation occurs at 1 mM GTP. ATP at a concentration of 5 mM totally inhibits the formation of CDP-diacylglycerol even in the presence of optimal GTP concentration. Analogues of ATP such as adenosine 5′-[α,β-methylene]-triphosphate, adenosine 5′-[β,γ-methylene]-triphosphate and adenosine 5′-[β,γ-imido]-triphosphate are without effect on the reaction. The addition of fluoride (8 mM) likewise abolishes the stimulatory effect of GTP.     

Purification and characterization of the nuclear cytidine 5'-monophosphate N-acetylneuraminic acid synthetase from rat liver.

N-Acetylneuraminic acid cytidylyltransferase (EC 2.7.7.43) (CAMP-NeuAc synthetase) from rat liver catalyzes the formation of cytidine monophosphate N-acetylneuraminic acid from CTP and NeuAc. We have purified this enzyme to apparent homogeneity (241-fold) using gel filtration on Sephacryl S-200 and two types of affinity chromatographies (Reactive Brown-10 Agarose and Blue Sepharose CL-6B columns). The pure enzyme, whose amino acid composition and NH2-terminal amino acid sequence are also established, migrates as a single protein band on non-denaturing polyacrylamide gel electrophoresis. The molecular mass of the native enzyme, estimated by gel filtration, was 116 +/- 2 kDa whereas its Mr in sodium dodecyl sulfate-polyacrylamide gel electrophoresis was 58 +/- 1 kDa. CMP-NeuAc synthetase requires Mg2+ for catalysis although this ion can be replaced by Mn2+, Ca2+, or Co2+. The optimal pH was 8.0 in the presence of 10 mM Mg2+ and 5 mM dithiothreitol. The apparent Km for CTP and NeuAc are 1.5 and 1.3 mM, respectively. The enzyme also converts N-glycolylneuraminic acid to its corresponding CMP-sialic acid (Km, 2.6 mM), whereas CMP-NeuAc, high CTP concentrations, and other nucleotides (CDP, CMP, ATP, UTP, GTP, and TTP) inhibited the enzyme to different extents.     

Phospholipid Biosynthesis in Myelin: Presence of CTP: Phosphoethanolamine Cytidylyltransferase in Purified Myelin of Rat Brain

Highly purified myelin from rat brain was previously shown to contain the ethanolaminephosphotransferase which completes the synthesis of phosphatidyl ethanolamine. We have now obtained evidence for the presence in myelin of CTP:phosphoethanolamine cytidylyltransferase, the enzyme catalyzing formation of CDP-ethanolamine. Myelin was isolated by two different procedures, one based on the Norton-Poduslo method and the other involving repetitive gradients with osmotic shocking deferred to the end. The fact that activity remained constant through all but the earliest steps suggested that the enzyme is intrinsic to myelin. Comparison of subcellular fractions revealed that approximately half the total activity was in the supernatant, the remainder being distributed among the particulate fractions. Relative specific activity of myelin was 27-31% that of microsomes, thus eliminating the possibility of appreciable contamination by the latter. The possibility of adsorption of the soluble enzyme by myelin was rendered unlikely by retention of activity after washing the myelin with buffered sodium chloride or sodium taurocholate. Furthermore, relative specific activity of the cytidylyltransferase was 10-fold higher than that of lactate dehydrogenase (a cytosolic marker) in myelin. The apparent Km for CTP was approximately the same for myelin and microsomes, but that for phosphoethanolamine was significantly higher for myelin.     

Activation of rat liver cytosolic phosphatidic acid phosphatase by nucleoside diphosphates

Phosphatidic acid phosphatase (EC 3.1.3.4) was purified 30-fold by ammonium sulfate fractionation and hydroxyapatite chromatography from the soluble fraction of rat liver. ADP was found to stimulate the enzyme activity with half-maximal stimulation at 0.2 mM. Similar effects were seen when ADP was replaced by GDP or CDP. In contrast, ATP inhibited the enzyme; half-maximal inhibition observed at 0.2 mM. Again, the degree of inhibition did not differ when GTP or CTP replaced ATP. Thus, the structure of the base part of the nucleotide was not critical for mediating these effects. The positions of the phosphate groups in the nucleotide structure were however found to be of importance for the enzyme activity. Variations in the structure of the phosphate ester bound at the 5'-position had a pronounced effect on phosphatidic acid phosphatase activity. The effect of nucleotides depended on pH, and the inhibition by ATP was more pronounced at pH levels lower than 7.0, whereas the stimulatory effect of ADP was virtually the same from pH 6.0 to pH 8.0. The enzyme showed substrate saturation kinetics with respect to phosphatidic acid, with an apparent Km of 0.7 mM. Km increased in the presence of ATP, whereas both apparent Vmax and Km increased in the presence of ADP, suggesting different mechanisms for the action of the two types of nucleotides. The results indicated that physiological levels of nucleotides with a diphosphate or a triphosphate ester bound at the 5'-position of the ribose moiety influenced the activity of phosphatidic acid phosphatase. The possibility is discussed that these effects might be of importance for the regulation of triacylglycerol biosynthesis.     

Coordinate increases in the enzyme activities responsible for phosphatidylglycerol synthesis and CTP:cholinephosphate cytidylyltransferase activity in developing rat lung

The enzymes responsible for the biosynthesis of phosphatidylglycerol, CTP:phosphatidate cytidylyltransferase, CDP-diacylglycerol: glycerophosphate phosphatidyltransferase and phosphatidylglycerophosphate phosphatase demonstrated a coordinate increase in activity in fetal rat lung at term when the demand for pulmonary surfactant increases. The activity of CTP:cholinephosphate cytidylyltransferase, the enzyme responsible for CDP-choline production also increased in the perinatal period. The activity of cholinephosphate cytidylyltransferase in fetal and neonatal cytosol was stimulated by the addition of phosphatidylglycerol but no effect was noted with cytosol from adult lung. These results are consistent with the suggestion that the activity of cholinephosphate cytidylyltransferase, a potential rate-determining enzyme in pulmonary phosphatidylcholine synthesis, may be regulated in the perinatal period both through an activation by phosphatidylglycerol and by an increase in total enzyme units.     

The purification and characterization of CTP:phosphorylcholine cytidylyltransferase from rat liver

We have purified CTP:phosphorylcholine cytidylyltransferase from rat liver cytosol 2180-fold to a specific activity of 12,250 nmol/min/mg of protein. The purified enzyme was stable at -70 degrees C in the presence of Triton X-100 and 0.2 M phosphate. The purified enzyme gave a single protein and activity band on nondenaturing polyacrylamide electrophoresis. Separation by sodium dodecyl sulfate-polyacrylamide electrophoresis indicated that the purified enzyme contained subunits with Mr of 39,000 and 48,000. Gel filtration analysis indicated that the native enzyme was a tetramer containing two 39,000 and two 48,000 subunits. The purified enzyme appeared to bind to Triton X-100 micelles, one molecule of tetramer/micelle. Maximal activity was obtained with 100 microM phosphatidylcholine-oleic acid vesicles (8-10-fold stimulation). Phosphatidylglycerol produced a 4-5-fold increase in activity at 10 microM. The pH optimum and true Km values for CTP and phosphorylcholine were similar to those reported previously for crude preparations of cytidylyltransferase. The overall behavior of cytidylyltransferase during purification and subsequent analysis suggested that it has hydrophobic properties similar to those exhibited by membrane proteins.     

Microsomal CTP:choline phosphate cytidylyltransferase: kinetic mechanism of fatty acid stimulation.

Fatty acids are known to cause an increase in the incorporation of radioactive choline into phosphatidylcholine. A coincident increase in membrane cytidylyltransferase activity is well documented. The purpose of the present studies was to determine the direct effects of oleic acid on the kinetic properties of membrane cytidylyltransferase. An examination of the reaction characteristics of membrane cytidylyltransferase revealed that membranes from adult rat lung contained high CTPase activity. This activity prevented the determination of reaction velocities at low CTP concentrations. The CTPase activity was blocked by the addition of ADP or ATP to the reaction. The addition of 6.0 mM ADP to the assay mixture enabled us to determine the effect of oleate on the CTP Km. Oleate (122 microM) caused a significant decrease in CTP Km for microsomal cytidylyltransferase (0.99 mM to 0.33 mM) and H-Form cytidylyltransferase (1.04 mM to 0.27 mM). Oleate did not decrease the CTP Km for L-Form cytidylyltransferase. Oleate had no effect on the choline phosphate Km in microsomal, H-Form or L-Form cytidylyltransferase. Oleate also increased the Vmax for cytidylyltransferase. The increase was dependent upon the concentration of oleate with a maximal increase of 50-60% at 100-130 microM oleate. We conclude that oleate has a direct stimulatory effect on cytidylyltransferase when it is in the active form (membrane bound or H-Form lipoprotein complex). We suggest that the kinetic effects operate synergistically with other regulatory mechanisms such as translocation or conversion of inactive to active species. The direct effect of oleate on the cytidylyltransferase may be an important regulatory mechanism when CTP concentrations are limiting.     

Interactions of thiophosphatidic acid with enzymes which metabolize phosphatidic acid. Inhibition of phosphatidic acid phosphatase and utilization by CDP-diacylglycerol synthase

Thiophosphatidic acid (1,2-diacyl-sn-glycero-3-phosphorothioate; thioPA) was chemically synthesized from egg phosphatidylcholine-derived 1,2-diacylglycerol and PSCl3 and tested for its effects on enzymes which utilize phosphatidic acid (PA) in phospholipid biosynthesis. The compound was not a substrate for rat liver cytosolic PA phosphatase and strongly inhibited this enzyme activity. ThioPA was also a potent inhibitor of purified membrane-associated PA phosphatase from Saccharomyces cerevisiae in a competitive manner and exhibited an apparent Ki = 60 microM. In contrast, purified CDPdiacylglycerol synthase (PA:CTP cytidylyltransferase) from this organism was able to convert thioPA to CDP-diacylglycerol. The apparent Vmax for thioPA was 7-fold lower than that for PA, whereas the apparent Km for thioPA (70 microM) was 4-fold lower than that for PA. Calculation of the specificity constant (Vmax/Km) demonstrated that PA was the preferred substrate. These properties of thioPA indicate that this substance may prove useful in studies of phospholipid metabolism and function.     

Factors controlling the activities of phosphatidate phosphohydrolase and phosphatidate cytidylyltransferase. The effects of chlorpromazine, demethylimipramine, cinchocaine, norfenfluramine, mepyramine and magnesium ions.

1. Microsomal membranes from rat liver were incubated with ATP, CoA, Mg2+, [14C]palmitate, F- and sn-glycerol 3-phosphate in order to label them with [14C]phosphatidate. These membranes were isolated and used in a second incubation in which [3H]CTP was present, and the simultaneous synthesis of [14C]diacylglycerol and [3H]CDP-diacylglycerol was measured. 2. The addition of phosphatidate phosphohydrolase, which had been partially purified from the particle-free supernatant, supplemented the activity of the endogenous phosphohydrolase, but it did not alter the rate of CDP-diacylglycerol formation. 3. Adding EDTA inhibited phosphatidate cytidylyl-transferase activity and stimulated the activity of the phosphohydrolases by removing excess of Mg2+. 4. Increasing the concentration of Mg2+, norfenfluramine or chlorpromazine in the assay system stimulated cytidylyltransferase activity, but decreased the activities of both phosphohydrolases. 5. The mechanism for the stimulation of cytidylyl=transferase activity by the cationic drugs and Mg2+ was investigated with emulsions of phosphatidate and the microsomal fraction of rat liver. 6. There was a threshold concentration of about 5mM-MgCl2 below which no cytidylyltransferase activity was detected in the presence or absence of norfenfluramine. Just above this threshold concentration norfenfluramine stimulated cytidylyltransferase activity, but this stimulation disappeared as the Mg2+ concentration was raised to its optimum of 20mM. Norfenfluramine therefore partially replaced the bivalent-cation requirement. 7. At 30 mM-MgCl2 amphiphilic cationic drugs inhibited cytidylyltransferase activity at relatively high concentrations in a non-competitive manner with respect to phosphatidate. 8. The implications of these results are discussed with respect to the regulation of the synthesis of the acidic phospholipids compared with the synthesis of phosphatidylcholine, phosphatidylethanolamine and triacylglycerol.     

CTP-dependent lipid kinases of yeast

Membrane fractions from yeast Saccharomyces cerevisiae catalyzed a transfer of gamma-phosphate from [gamma-32P]CTP into membranous lipids. Phosphorylated compounds were identified as phosphatidic acid and dolichyl phosphate (DolP). The membrane fraction also catalyzed phosphorylation of the exogenous dolichol. The activity of the phosphorylating enzymes could be modified by the yeast growing conditions; i.e., the enzyme from yeast grown aerobically favored the synthesis of phosphatidate over dolichyl phosphate in the ratio of 3:1, whereas the membrane fraction from anaerobically grown yeast synthesized PA and DolP in the ratio of 0.5:1. The activity of the phosphorylating enzymes could also be modified by divalent cations and the concentration of detergents. Phosphorylation of lipids does not occur in the presence of [gamma-32P]ATP and is not influenced by the presence of UTP or GTP. This result points to the specific role of CTP as a gamma-phosphate donor for the synthesis of phosphatidate and dolichyl phosphates in the yeast system.     

Rapid hydrolysis of diacylglycerol formed during phosphatidate phosphatase assay by lipase activities in rat liver cytosol and microsomes

Side reactions which may affect the determination of phosphatidate phosphatase activity were investigated in rat liver cytosol and microsomes. Incubation of these subcellular fractions with either 14C-labeled phosphatidate bound to microsomal membranes (PAmb) or that coemulsified with microsomal lipids resulted in rapid formation of water-soluble products, most of which were identified as glycerol, in addition to diacylglycerol. Neither lysophosphatidate nor glycerol 3-phosphate accumulated under any of the conditions used and only a minute amount of activity catalyzing hydrolysis of glycerol 3-phosphate could be detected in cytosol and microsomes, suggesting that glycerol was not formed by the deacylation of phosphatidate to glycerol 3-phosphate and subsequent dephosphorylation. On the other hand, pretreatment of cytosol or microsomes with diisopropylfluorophosphate abolished the formation of water-soluble products, indicating that glycerol was formed from diacylglycerol, the product of the phosphatidate phosphatase reaction, by lipase-type activities. Rapid deacylation of diacylglycerol by these subcellular fractions was also observed with an emulsion of phosphatidate, which has been purified from the total lipid extract of PAmb as substrate. The rate of hydrolysis of diacylglycerol was maximum when the concentration of diacylglycerol was less than 20 microM with either cytosol or microsomes. The present results suggest that it is essential to characterize the reaction products before employing specific assay conditions for phosphatidate phosphatase. At least under the conditions we tested, reliable measurement of the enzyme activity in rat liver cytosol and microsomes can be achieved only by determining the release of Pi or that of water-soluble activity from 32P-labeled phosphatidate.     

The influence of exogenous and of membrane-bound phosphatidate concentration on the activity of CTP: phosphatidate cytidylyltransferase and phosphatidate phosphohydrolase.

Rat liver microsomes were treated with phospholipase D to obtain microsomal membranes with varying amounts of membrane-bound phosphatidate. This treatment did not impair the activity of two microsomal-bound enzymes acting with phosphatidate as substrate, i.e. CTP: phosphatidate cytidylyltransferase and phosphatidate phosphohydrolase. The dependency of the activity of these enzymes on the concentration of membrane-bound phosphatidate was determined. Both enzymes showed a linear increase in activity with membrane-bound phosphatidate concentrations up to at least 100 nmol phosphatidate/mg microsomal protein. These results indicate that both enzymes have a large reserve capacity and suggest that the enzymes are operating intracellularly, i.e. at phosphatidate concentrations of 5-10 nmol/mg endoplasmic reticulum protein, far below their maximal capacity. The ratio of phosphatidate conversion into CDP-diglyceride and 1,2-diglyceride seems to be constant for a large range of membrane-bound phosphatidate concentrations. The membrane-bound enzymes cannot utilize phosphatidate substrate present in heat-denatured membranes, but are active on phosphatidate incorporated into membranes of phospholipid vesicles.     

Pulmonary phosphatidic acid phosphatase. Properties of membrane-bound phosphatidate-dependent phosphatidic acid phosphatase in rat lung.

1. The membrane-bound phosphatidate-dependent phosphatidic acid phosphatase activity of rat lung has been investigated in cytosol and microsomal fractions using as a substrate [32P]phosphatidate bound to heat inactivated rat liver microsomes. Both activities demonstrated broad pH optima with a maximum of 7.4--8 for the cytosol and a maximum of 6.5--7.5 with microsomal preparations. 2. At low concentrations (0--5 mM) Mg2+ produced a slight stimulation of the cytosol activity but at higher concentrations an inhibition was observed. Low concentrations (1.0--2.0 mM) of EDTA abolished the cytosol activity and reduced the microsomal activity to half. In both cases, the addition of Mg2+ in the presence of EDTA resulted in an activity which was more than 2-fold greater than that observed in the absence of chelator or divalent cation. 3. The cytosol activity was relatively resistant to the addition of ionic and nonionic detergents. In general, the addition of a number of phosphate esters increased rather than decreased the release of 32Pi, indicating a relative specificity for phosphate groups associated with a hydrophobic environment. The addition of aqueous dispersions of phosphatidate, lysophosphatidic acid or phosphatidylglycerophosphate markedly reduced the hydrolysis of membrane-bound [32P]phosphatidate. The cytosol activity was slightly inhibited by the addition of phosphatidylcholine. 4. In an attempt to estimate the relative contributions of the cytosol and microsomal activities in vivo, these activities were assayed using [32P]phosphatidate endogenously generated on rat lung microsomes. With the 32P-labelled microsomes, the hydrolysis remained linear over the 45 min of the experiment. Addition of high speed supernatant produced a rapid release of 32Pi during the first 10 min followed by a more gradual release similar to that oberved with the microsomes alone. The cytosol activity remained greater than the microsomal activity at all times studied. 5. When [14C]phosphatidate-labelled microsomes were incubated in the presence of nonradioactive CDPcholine, the addition of cytosol markedly stimulated the incorporation of radioactivity into phosphatidylcholine. This observation suggests that the phosphatidic acid phosphatase activity associated with the cytosol has a role in phosphatidylcholine (and presumably surfactant) biosynthesis in rat lung.     

Choline deficiency causes translocation of CTP:phosphocholine cytidylyltransferase from cytosol to endoplasmic reticulum in rat liver

The choline-deficient rat liver has been chosen as a physiologically relevant model system in which to study the regulation of phosphatidylcholine biosynthesis. When 50-g rats were placed on a choline-deficient diet for 3 days, the activity of CTP:phosphocholine cytidylyltransferase (CT) was increased 2-fold in the microsomes and decreased proportionately in the cytosol. A low titer antibody to CT was obtained from chickens and used to identify the amount of CT protein in cytosol from rat liver. The amount of CT recovered from the choline-deficient cytosol was significantly less than in cytosol from choline-supplemented rats. When hepatocytes were prepared from choline-deficient livers, supplementation of the medium of the cells with choline caused CT to move from the membranes to cytosol within 1-2 h. The activity of another translocatable enzyme of glycerolipid metabolism, phosphatidate phosphohydrolase, was unchanged in cytosol from choline-deficient rat livers, and the microsomal activity of this enzyme was only minimally increased. When the livers were fractionated into endoplasmic reticulum and Golgi, there was a 2-fold increase in the activity on the endoplasmic reticulum from choline-deficient livers but no change in activity associated with Golgi. Thus, the increased association of CT with endoplasmic reticulum in choline-deficient livers appears to be specific to that subcellular fraction, and the subcellular location of other enzymes may not be affected.