Incorporation of 32P-labelled intermediates into the phospholipids of cell-free preparations of rat brain

The metabolism of phospholipids in mouse brain slices

1. Slices of mouse brain grey matter were incubated with [(32)P]phosphate and [1-(14)C]acetate. Doubly labelled phospholipids were extracted from subcellular fractions prepared from the slices in a mixture of metabolic inhibitors, under conditions where there was negligible change in radioactive labelling during the preparation. Two tissue fractions were studied in detail; one contained a high proportion of mitochondria and the other was mainly microsomal. 2. In all tissue fractions the highest incorporations of both [(32)P]phosphate and [1-(14)C]acetate occurred into phosphatidylcholine. 3. After incubation for 1hr., the (32)P/(14)C ratios for phosphatidylcholine, phosphatidylethanolamine and phosphatidic acid in the mitochondrial fraction were similar to those in the microsomal fraction. 4. The (32)P/(14)C ratios were similar in phosphatidylcholine and phosphatidylethanolamine and much lower than those in phosphatidic acid and phosphatidylinositol.

Transport of phosphatidylserine from microsomes to the inner mitochondrial membrane in brain tissue

Phosphatidylserine was labeled by incubating rat brain homogenates with [3-14C]serine in the presence of Ca2+ (base-exchange conditions). Some labeled phosphatidylethanolamine also forms, in spite of the inhibition of Ca2+ on phosphatidylserine decarboxylase. Phosphatidylserine labeling and decarboxylation also occur on incubating a mixture of purified mitochondria and microsomes, suggesting that no soluble factors are necessary for the synthesis and the decarboxylation of phosphatidylserine. Ca2+ favors the transfer of phosphatidylserine from microsomes (where it forms) to mitochondria (where it is decarboxylated). The specific radioactivity of the phosphatidylserine transferred to mitochondria is higher than that of microsomal phosphatidylserine. This finding supports the hypothesis that the lipid is compartmentalized in microsomes and that radioactive, newly synthesized phosphatidylserine is much better exported than the bulk of microsomal phospholipid.

Triacylglycerol synthesis in developing seeds of groundnut (Arachis hypogaea): pathway and properties of enzymes of sn-glycerol 3-phosphate formation

The enzymatic pathway for the synthesis of sn-glycerol 3-phosphate was investigated in developing groundnut seeds (Arachis hypogaea). Glycerol-3-phosphate dehydrogenase was not detected in this tissue but an active glycerokinase was demonstrated in the cytosolic fraction. It showed an optimum pH at 8.6 and positive cooperative interactions with both glycerol and ATP. Triosephosphate isomerase and glyceraldehyde-3-phosphate phosphatase were observed mainly in the cytosolic fraction while an active glyceraldehyde reductase was found mainly in the mitochondrial and microsomal fractions. The glyceraldehyde 3-phosphate phosphatase showed specificity and positive cooperativity with respect to glyceraldehyde 3-phosphate. The glyceraldehyde reductase was active toward glucose and fructose but not toward formaldehyde and showed absolute specificity toward NADPH. It is concluded that in the developing groundnut seed, sn-glycerol 3-phosphate is synthesized essentially by the pathway dihydroxyacetone phosphate----glyceraldehyde 3-phosphate Pi----glyceraldehyde NADPH----glycerol ATP----glycerol 3-phosphate. All the enzymes of this pathway showed activity profiles commensurate with their participation in triacylglycerol synthesis which is maximal during the period 15-35 days after fertilization. Glycerokinase appears to be the rate-limiting enzyme in this pathway.

Ethanolamine glycerophospholipid formation by decarboxylation of serine glycerophospholipids in myelinating organ cultures of cerebellum

Serine decarboxylation as a source of glycerophospholipid ethanolamine is known to occur in mammals. However, early investigators failed to demonstrate the pathway in brain. In the present study serine is shown to be decarboxylated to glycerophospholipid ethanolamine in myelinating organ cultures of rat cerebellum up to 32 days in vitro. The pattern of incorporation of L-[3-14C]serine into culture phospholipids strongly suggests a precursor-product relationship between serine glycerophospholipids (SGP) and ethanolamine glycerophospholipids (EGP), with serine label appearing in the ethanolamine moiety of EGP. The time course of labelling was similar for both acid-stable and acid-labile EGP. In contrast DL-[1-14C]serine failed to label EGP significantly due to the loss of serine carbon C1 on decarboxylation. Through the systematic hydrolysis of phospholipids from cerebellar cultures incubated with L-[3-14C], it was clear that in SGP, acid-stable EGP, and acid-labile EGP greater than to 70% of radiolabel resides in the base moiety of each of these molecular species. It is proposed that serine decarboxylation as a source of EGP ethanolamine may be important in the early stages of brain development.

Incorporation of choline and inositol into phospholipids of isolated bovine oligodendrocyte perikarya

Oligodendrocyte perikarya have been prepared from fresh and frozen bovine corpus callosum by a slight modification of previously published methods. The properties of the cells which we have obtained appear to be very similar to those previously described in other laboratories. Oligodendrocyte homogenates have been incubated with radioactive choline and inositol in the presence of a number of possible cofactors of phospholipid synthesis. Choline was incorporated into oligodendrocyte phosphatidylcholine both by synthesis de novo and by Ca2+-stimulated base exchange. There was no detectable incorporation of choline into sphingomyelin by either of these routes. Inositol was incorporated into oligodendrocyte phosphatidylinositol by synthesis de novo and by Mn2+-stimulated exchange. Oligodendrocyte homogenates were found to contain sufficient endogenous Ca2+ both to stimulate significant incorporation of choline into lecithin by base exchange and to produce considerable inhibition of lecithin synthesis de novo.

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.

Effect of undernutrition on the metabolism of phospholipids and gangliosides in developing rat brain

1. Phospholipid content of brains of 3- or 8-week-old undernourished rats was 7--9% less than that for the corresponding control animals and this deficit could not be made up by rehabilitation. Phosphatidyl ethanolamine and plasmalogen were the components most affected in brains of undernourished rats. 2. Incorporation of 32P into phospholipids by brain homogenates was 28% higher in 3-week-old undernourished rats. It is suggested that enhanced phospholipid metabolism in undernourished animals may be related to behavioural alterations noted previously (Sobotka, Cook & Brodie, 1974). 3. Ganglioside concentrations in 3- and 8-week-old undernourished animals were 14% and 11.5% less respectively than those of the control animals and this difference could be made up by rehabilitation. [14C]Glucosamine incorporation in vivo into brain gangliosides was not affected by undernutrition.

Regulation by cytidine nucleotides of the acylation of sn-(14C)glycerol 3-phosphate. Regional and subcellular distribution of the enzymes responsible for phosphatidic acid synthesis de novo in the central nervous system of the rat

1. The regional and subcellular distribution of the incorporation of sn-[(14)C]glycerol 3-phosphate into rat brain lipids in vitro was investigated and compared with the relative specific activity of various chemical and enzyme markers. The similarity between the subcellular distribution of this incorporation and of NADPH-cytochrome c reductase activity indicated that the synthesis of phosphatidic acid via this route correlated with the presence of endoplasmic reticulum. 2. Experiments in which various amounts of the microsomal fraction were added to fixed amounts of nuclear, myelin, nerve-ending and mitochondrial preparations clearly demonstrated that the endoplasmic-reticulum contamination of these fractions was entirely responsible for the incorporation of sn-[(14)C]glycerol 3-phosphate. 3. The presence of CMP or CTP inhibited the incorporation of sn-[(14)C]glycerol 3-phosphate into the whole homogenate. Similar effects were observed with individual fractions, except for the mitochondria. With the mitochondrial fraction the effect of these cytidine nucleotides varied with the preparation, stimulating in some preparations and inhibiting with other preparations. The presence of CDP-choline stimulated the incorporation into the whole homogenate and to a lesser extent into the subcellular fractions. 4. These results indicate that the various organelles of the central nervous system are more dependent on endoplasmic reticulum for the production of glycerolipids de novo than has previously been appreciated.

Can mitochondria and synaptosomes of guinea-pig brain synthesize phospholipids?

1. The use of ;marker' enzymes for investigating the contamination by endoplasmic reticulum of mitochondrial and synaptosomal (nerve-ending) fractions isolated from guinea-pig brain was examined. NADPH-cytochrome c reductase appeared to be satisfactory. With the synaptosomal preparation there was a non-occluded enzymic activity believed to arise from contaminating microsomes and an occluded form released by detergent, which probably was derived from some type of intraterminal smooth endoplasmic reticulum. 2. Isolated brain mitochondria, both intact and osmotically shocked, could not synthesize more labelled phosphatidylcholine from CDP-[Me-(14)C]choline or phosphoryl[Me-(14)C]choline than could be accounted for by microsomal contamination. They could synthesize only phosphatidic acid and diphosphatidylglycerol from a [(32)P]P(i) precursor and not nitrogen-containing phosphoglycerides or phosphatidylinositol. 3. The synaptosomal outer membrane and the intraterminal mitochondria could not synthesize phosphatidylcholine from CDP-[Me-(14)C]choline but the synaptic vesicles and probably the intraterminal ;endoplasmic reticulum' appeared to be capable of catalysing the incorporation of label from this substrate into their phospholipids. 4. Microsomal fractions and synaptosomes from guinea-pig brain could incorporate [Me-(14)C]choline into their phospholipids by a non-energy-requiring exchange process, which was catalysed by Ca(2+). Fractionation of the synaptosomes after such an exchange had taken place revealed that the label was predominantly in the intraterminal mitochondria and not associated with membranes containing NADPH-cytochrome c reductase. 5. On the intraperitoneal injection of [(32)P]P(i) into guinea pigs, incorporation of radioactivity into phosphatidylinositol and phosphatidic acid was much faster than into the nitrogen-containing phosphoglycerides. Mitochondria and microsomal fractions showed a roughly equivalent incorporation into individual phospholipids, and that into synaptosomes was appreciably less, whereas the phospholipids of myelin showed little (32)P incorporation up to 10h.

Phospholipid metabolism in intact and modified erythrocyte membranes

Erythrocyte membranes incorporated labeled phosphate from gamma-adenosine triphosphate (AT(32)P) into phosphatidic acid and the polyphosphoinositides. Inositol-(3)H and palmitate-(14)C were also incorporated into the phospholipids but alpha-glycerophosphate-(32)P was not. The incorporation of gamma-AT(32)P into phospholipids was increased when the erythrocyte ghosts were incubated in hypotonic media which lysed the cells. Lysis had little or no effect on the incorporation of inositol-(3)H and palmitate-(14)C into the phospholipids. If erythrocyte membranes were prepared in 1 mM ethylenediaminetetraacetate (EDTA), instead of 1 mM MgCl(2), then the tonicity of the incubating medium did not influence the incorporation of gamma-AT(32)P into the phospholipids. Erythrocyte ghosts, prepared by lysis in water, EDTA, or 1 mM calcium, lead, mercury, zinc, or cadmium, failed to reconstitute when placed in isotonic medium, inasmuch as they did not retain potassium against a chemical gradient. Ghosts prepared by lysis in 1 mM magnesium, barium, or strontium could be reconstituted. Ghosts which failed to reconstitute incorporated more labeled phosphate from gamma-AT(32)P into the phospholipids than did intact or reconstituted ghosts. The larger incorporation of labeled phosphate by leaky ghosts was not due to a greater entrance of gamma-AT(32)P into those cells. Primaquine phosphate and digitonin, at concentrations which are known to cause cells to form smaller vesicles or to lyse cells by removing cholesterol, did not increase the incorporation of labeled phosphate into the phospholipids. It is suggested that the increased metabolism of phospholipids may be involved in a membrane repair mechanism.

The diglyceride kinase of rat cerebral cortex

1. Formation of phosphatidic acid by diglyceride kinase (EC 2.7.1.-) in the presence of ATP and Mg(2+) was shown in a homogenate and subcellular fractions of rat cerebral cortex. 2. The kinase was activated by Mg(2+). Ca(2+) activated to a smaller extent but was inhibitory in the presence of optimum concentration of Mg(2+). Activity was greatly increased in the presence of added 1,2-diglyceride. 3. Sodium deoxycholate markedly stimulated the reaction, but other detergents (Cutscum and Triton X-100) did not. 4. Diglyceride kinase was concentrated in the supernatant and microsomal fractions from rat cerebral cortex. The distribution of the kinase in the particulate fractions resembled that of acetylcholinesterase and 5'-nucleotidase. 5. The rate of phosphatidic acid synthesis by the diglyceride kinase route was much greater than reported rates for acylation of 3-glycerophosphate and was also very rapid in comparison with the rates of other steps in the synthesis of phosphoinositides. 6. Acetylcholine had no stimulatory effect on diglyceride kinase of isolated intact nerve-ending particles or of nerve-ending membranes obtained after osmotic shock.

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.

The incorporation of the phosphate esters of N-substituted aminoethanols into the phospholipids of brain and liver

1. The phosphate esters of dimethylaminoethanol and monomethylaminoethanol can be incorporated from their cytidine diphosphate esters into the phospholipids of brain and liver dispersions; the deoxycytidine nucleotides of the same bases are less effective precursors. 2. The cytidylyltransferases of brain and liver are less effective in forming the cytidine diphosphate esters of monomethylaminoethanol and dimethylaminoethanol than those of ethanolamine and choline.

LIPID SYNTHESIS IN RAT LIVER PARTICLES: DIVERSION OF SYNTHESIS FROM TRIGLYCERIDE TO LECITHIN BY THE IN VITRO ADDITION OF CYTIDINE DIPHOSPHATE CHOLINE

When particle preparations from rat or chicken liver were incubated in a suitable medium containing α-glycerophosphate-C14, radioactivity was recovered from lecithin, phosphatidyl inositol, phosphatidic acid, and triglyceride. Whole homogenate and various particle preparations catalyzed the dephosphorylation of a number of phosphatidic acids, with the liberation of inorganic P.It is currently believed that liver preparations are capable of catalyzing the esterification of L-α-glycerophosphate, with the formation of L-α-phosphatidic acid, which subsequently may be dephosphorylated to form D-α,β-diglyceride. The diglyceride so formed may then give rise either to lecithin, by combining with phosphorylcholine from cytidine diphosphate choline, or to triglyceride, by combining with fatty acid from fatty acyl coenzyme A. If these reactions occur in liver particle preparations, it should be possible, by the addition in vitro of unlabelled cytidine diphosphate choline, to divert the synthesis of lipid from the formation of triglyceride to the formation of lecithin. In experiments designed to put this hypothesis to the experimental test, such a diversion of lipid synthesis was achieved.

LIPID SYNTHESIS IN RAT LIVER PARTICLES: DIVERSION OF SYNTHESIS FROM TRIGLYCERIDE TO LECITHIN BY THE IN VITRO ADDITION OF CYTIDINE DIPHOSPHATE CHOLINE

When particle preparations from rat or chicken liver were incubated in a suitable medium containing α-glycerophosphate-C14, radioactivity was recovered from lecithin, phosphatidyl inositol, phosphatidic acid, and triglyceride. Whole homogenate and various particle preparations catalyzed the dephosphorylation of a number of phosphatidic acids, with the liberation of inorganic P.It is currently believed that liver preparations are capable of catalyzing the esterification of L-α-glycerophosphate, with the formation of L-α-phosphatidic acid, which subsequently may be dephosphorylated to form D-α,β-diglyceride. The diglyceride so formed may then give rise either to lecithin, by combining with phosphorylcholine from cytidine diphosphate choline, or to triglyceride, by combining with fatty acid from fatty acyl coenzyme A. If these reactions occur in liver particle preparations, it should be possible, by the addition in vitro of unlabelled cytidine diphosphate choline, to divert the synthesis of lipid from the formation of triglyceride to the formation of lecithin. In experiments designed to put this hypothesis to the experimental test, such a diversion of lipid synthesis was achieved.