THE METABOLISM OF LABELLED ETHANOLAMINE IN NEURONAL AND GLIAL CELLS OF THE RABBIT IN VIVO1

Abstract— Adult rabbits were injected intraventricularly with [¹⁴C]ethanolamine and the incorporation of the base into the phosphatidylethanolamine and ethanolamine plasmalogen (and their water-soluble precursors) of isolated neuronal and glial cells was investigated. All the radioactivity was incorporated into the base moiety of the ethanolamine lipids for the time intervals examined in both types of cells. In neurons, maximum labelling of the two ethanolamine lipids occurred at 7 h after administration, whereas the highest specific radioactivity for glial phosphatidylethanolamine and ethanolamine plasmalogen was reached at 20 and 36 h, respectively. The two lipids had a faster turnover in neurons than in glia, and in both populations incorporated the base at a faster rate than did whole brain tissue. The maximum incorporation rates for phosphorylethanolamine and CDP-ethanolamine were reached in both types of cell at about 6 h after administration but the content of radioactivity per unit protein for phosphorylethanolamine was much higher in glial than in neuronal cells. It is concluded that the site of most active synthesis of ethanolamine phospholipids in vivo is the neuronal cell, with a possible transfer of intact lipid molecule to the glial compartment.     

INCORPORATION OF 32P INTO THE PHOSPHOLIPIDS OF NEURONAL AND GLIAL CELL ENRICHED FRACTIONS ISOLATED FROM RABBIT CEREBRAL CORTEX: EFFECT OF NOREPINEPHRINE

Abstract— Glial cells isolated from rabbit cerebral cortex contained approximately one-third more phospholipids per unit protein than the neuronal cell bodies. The pattern of individual phospholipids was rather similar in both cell types. The incorporation of intracisternally administered ³²P into neuronal and glial phospholipid classes of rabbit brain was studied at intervals ranging from 5 to 60min. In general, for all investigated phospholipids the incorporation of the label was somewhat faster in neurons than in glial cells. Phosphatidylinositol showed the fastest and ethanolamine plasmalogen the slowest incorporation of ³²P in both neurons and glial cells. A lag phase of about 10 min could be observed before labelling of the glial phosphatidylcholine, phosphatidylethanolamine, ethanolamine plasmalogen, phosphatidylserine and sphingomyelin had occurred. Among the neuronal phospholipids a lag phase was found only for the labelling of the ethanolamine plasmalogen. Norepinephrine increased the incoropration of ³²P into phosphatidylinositol of both glia and neurons but had no effect on the specific radioactivity of ethanolamine plasmalogen and sphingomyelin. Labelling of phosphatidylcholine was slightly inhibited in both cell types by the administration of norepinephrine.     

LIPID COMPOSITION AND METABOLISM OF CULTURED HAMSTER BRAIN ASTROCYTES

Abstract— The lipid composition and metabolism of confluent cultures of cells derived from newborn hamster brain and having morphology characteristic of immature astrocytes or spongioblasts was investigated and compared to that of newborn hamster brain dispersions and cloned glioma cells (C6). The cells displayed stable morphology for at least 30 subcultures; thereafter spontaneous transformation occurred. No appreciable changes were observed in either composition or metabolic characteristics of any major neutral lipid or phospholipid class in successive subcultures or following transformation. The overall lipid composition of the hamster astrocyte cultures closely resembled that of newborn hamster brain, but the phospholipid composition showed substantial differences. The cells contained as a percent of lipid P relatively more ethanolamine plasmalogen, choline plasmalogen and sphingomyelin and somewhat less phosphatidylcholine and phosphatidylethanolamine. The phospholipids of the hamster astrocyte and C6 cells were similar. Of the lipid precursors examined, [U-¹⁴C]glucose was incorporated best into all preparations. C6 glioma cells incorporated both [U-¹⁴C]glucose and [1-¹⁴C]acetate most actively. From 69–88% of ³²P incorporated into hamster astrocyte phospholipids was present in choline phosphoglycerides, whereas the corresonding figure for hamster brain dispersions was 53%. The ratio of specific activities of phosphatidylcholine to phosphatidylinositol was substantially higher in the cultured cells than in the brain preparations. The small pool of choline plasmalogen in the hamster astrocytes usually achieved the highest specific activity of any phospholipid. When [U-¹⁴C]glucose and [1-¹⁴C]acetate were precursors, the bulk of label in the astrocytes appeared in choline phosphoglycerides and triacyglycerol. Our results indicate that the hamster astrocyte cell line as grown expresses distinctive features of lipid composition and metabolism which are nearly constant through many generations.     

Regulation of phospholipid metabolism in differentiating cells from rat brain cerebral hemipheres in culture. II. Incorporation of [U-14C]ethanolamine into 1-alkenyl,2-acyl-and 1,2 diacyl-ethanolamine phosphoglycerides.

Cultured dissociated cells from rat embryo cerebral hemisphere incorporate [3H]-and [U-14C]ethanolamine into cellular lipids. Nearly all radioactivity in the lipid fractions is incorporated into 1,2-diacylethanolamine phosphoglycerides and 1-alkenyl,2-acylethanolamine phosphoglycerides (plasmalogen). Kinetic data suggest that the rate of labeling of both ethanolamine phospholipids from the phosphorylethanolamine is similar. A relative increase of the plasmalogen labeling is observed when free ethanolamine is continually present in the medium. The rate of incorporation of label from ethanolamine and phosphorylethanolamine into lipids was measured using a double label technique. Based upon these studies, an independent labeling pattern of the ethanolamine moiety of plasmalogens is suggested. A relative delay for the incorporation of label in plasmalogens could be explained by the presence of a variety of cell types which may differ in their capacity for phospholipid biosynthesis. The rate of incorporation of phosphorylethanolamine into the phosphatidylethanolamine was not affected by the presence of high concentrations of either choline or serine.     

KINETICS OF THE BIOSYNTHESIS OF PHOSPHOLIPIDS IN NEURONS AND GLIAL CELLS ISOLATED FROM RAT BRAIN CORTEX

—³²P incorporation into different rat-brain cortex neuronal and glial phospholipids was investigated. The half life of each compound was measured. Neuronal phospholipids had a faster turnover than glial phospholipids. Phosphatidyl-inositol and choline plasmalogen had the fastest, diphosphatidylglycerol the lowest turnover in both cell-types. Phosphatidylcholine, ethanolamine phospholipids and serine phospholipids had turnover intermediate with that of the previously described compounds. Turnover of neuronal sphingomyelin was similar to that of phosphatidylcholine, whereas in glial cells it was much lower.     

The utilization of ethanolamine and serine for ethanolamine phosphoglyceride synthesis by human Y79 retinoblastoma cells

Phospholipid synthesis was investigated in human Y79 retinoblastoma cells, a cultured cell line of retinal origin that retains many neural characteristics. Ethanolamine is taken up by Y79 cells through a high-affinity transport system and is utilized to synthesize ethanolamine and choline phosphoglycerides. High-affinity ethanolamine uptake has a K'm of 40.6 microM and a V'max of 1.06 nmol/min/mg protein, and the process is Na+ dependent. Choline is the only compound tested that reduced ethanolamine uptake, and very high choline concentrations were required to produce this effect. The cells incorporate ethanolamine into phosphatidylethanolamine and ethanolamine plasmalogen at equivalent rates, and the rates of catabolism of these phospholipids are similar. Only a small quantity of ethanolamine is incorporated into phosphatidylcholine, but the amount is not reduced by the addition of choline. Serine is incorporated into phosphatidylserine, which then is converted to phosphatidylethanolamine. Ethanolamine reduces but does not abolish this conversion. Unlike ethanolamine, only a small amount of serine is incorporated into ethanolamine plasmalogen. It is possible that the ethanolamine high-affinity uptake system is necessary to provide a neural cell with enough free ethanolamine for ethanolamine plasmalogen synthesis.     

Anabolic action of prolactin on phosphatidylcholine metabolism in guinea pig adrenocorticocytes]

Isolated adrenocortical cells of guinea pigs whom injected with prolactin (PRL) during 3 days incorporated [3H] choline into phosphatidylcholine more intensively than those cells of animals in control. Labelling of intracellular pools of choline and phosphorylcholine remained unchanged, though a part of radioactivity represented by the water-soluble precursors decreased due to PRL influence. The rate of disappearance of labelled phosphatidylcholine in adrenocortical cells prelabelled with [3H] choline was lower in cells obtained from PRL-treated animals. The discharge of [3N] choline accumulated during prelabeling accelerated simultaneously. Rate of the phosphorylcholine radioactivity fall remained unchanged. The obtained data showed that prolonged influence of PRL caused a shift of the phosphatidylcholine metabolism to anabolism. That effect might be a part of the mechanism of proliferative PRL action in the adrenal cortex.     

Action of phospholipase A2 of rabbit neuronal and glial cells on 1,2-diacyl-, 2-acyl-1-alk-1′-enyl-, and 2-acyl-1-alkyl-glycerophosphatides

Pronounced differences in the phospholipase A₂ activities were found in neurons and glia, the enzyme activity being two- to threefold higher in neurons than in glial cells. Both phospholipases A₂ hydrolyzed the 1,2-diacylglycerophosphatides more rapidly than the acylalkyl and acylalkenyl compounds. Choline plasmalogen and the corresponding alkyl derivative were cleaved at similar rates by the phospholipase A₂ from both glia and neurons. There was a tendency by the neuronal phospholipase A₂ to release arachidonic acid faster than linolenic acid from both phosphatidylcholine and ethanolamine, while arachidonic acid was removed less actively from phosphatidylethanolamine by the glial enzyme. The glial phospholipase A₂ showed a lag period of 10 or 20 min. Norepinephrine, injected into the lateral ventricle of the rabbit brain, stimulated the hydrolysis of the various 1,2-diacyl-, acylalkyl-, and acylalkenyl-glycerophosphatides by the phospholipase A₂ from both glia and neurons.     

Polyunsaturated fatty acid metabolism in neuroblastoma cells in culture.

Neuroblastoma cell cultures took up linoleic and linolenic acids at approximately equal rates, and incorporated them into a variety of lipid fractions, principally cellular phospholipids. Linoleic acid was preferentially incorporated into choline phosphoglycerides, while most of the radioactivity derived from linolenic acid entered ethanolamine phosphoglycerides. There was no evidence for direct transfer of fatty acids between these two phosphoglyceride fractions. When, after the addition of cytosine arabinoside, cell division was arrested, the entry of labelled fatty acids into ethanolamine and serine phosphoglycerides was reduced, suggesting that these lipids are involved in the formation of new cell membranes. In the ethanolamine phosphoglyceride fraction, phosphatidal ethanolamine (plasmalogen) was the principal acceptor for the higher polyunsaturated fatty acids of the φ 3 series. The ratio of labelled fatty acids entering ethanolamine plasmalogens to that entering ethanolamine phosphoglycerides increased following the addition of cytosine arabinoside, suggesting plasmalogens to be involved in formation of cell processes. The first step in the metabolism of both linoleic and linolenic acid was the addition of a two-carbon unit. Conversion of linoleic acid to higher polyunsaturated fatty acids was slower than the conversion of linolenic acid to its higher analogues. This contrasted with the behaviour of dissociated cultures of normal brain cells which were able to form higher analogues of linoleic and linolenic acids at nearly equal rates.     

Regulation of phospholipid metabolism in differentiating cells from rat brain cerebral hemispheres in culture. Patterns of acetylcholine phosphocholine, and choline phosphoglycerides labeling from (methyl-14C)choline.

The uptake and metabolism of [14C]choline in dissociated rat brain embryo cell cultures was examined as a function of the extracellular choline concentration. Choline uptake did not follow normal Michaelis-Menten kinetics, but rather exhibited two components with apparent Km of 0.016 mM and 0.96 mM. At low choline concentrations (high affinity uptake) most of the [14C]choline label was present in the phosphocholine fraction prior to the appearance of label in phospholipids. At high choline concentrations (low affinity uptake) a large proportion of the radioactivity was converted into acetylcholine. The dissimilarities between the formation of phosphocholine and acetylcholine as a function of choline concentration might be explained by the existence of two mutually independent enzymatic activities with different Km affinities for choline. Kinetic data augmented by double label studies, suggested that formation of choline phosphoglyceride proceeds entirely via a phosphocholine intermediate. Nearly all radioactivity in the lipid fraction is incorporated into choline phosphoglycerides. A higher turnover rate of choline incorporation into choline phosphoglycerides, accompanied by an increase in the levels of glycerophosphocholine, was observed in older cultures as compared to younger cultures. The metabolic implications of these findings in cultured brain cells in comparison with other in vitro systems are discussed.     

The synthesis of choline and ethanolamine phosphoglycerides in neuronal and glial cells of rabbit in vitro

Abstract— The de novo synthesis of phosphatidylcholine and phosphatidylethanolamine in isolated neuronal and glial cells from adult rabbit brain cortex was investigated in vitro, using labelled phosphorylcholine (phosphorylethanolamine) or cytidine-5′-phosphate choline (cytidine-5′-phosphate ethanolamine), as lipid precursors. Synthesis of phospholipid from phosphorylcholine and phosphorylethanolamine in both fractions was extremely low when compared to that derived from the corresponding cytidine nucleotides. The neuronal cell-enriched fraction was found to possess a much higher rate of synthesis of both lipids from all precursors. Neuronal/glial ratios of about 5–9 were found for the synthesis of phosphatidylcholine and phosphatidylethanolamine from cytidine-5′-phosphate choline and cytidine-5′-phosphate ethanolamine, respectively. Several kinetic properties of the choline-phosphotransferase (EC 2.7.8.2) and ethanolaminephosphotransferase (EC 2.7.8.1) were found to be similar both in neurons and in glia (e.g. K_m of cytidine-5′-phosphate ethanolamine, K_m of diacyl glycerol, pH optimum, need for divalent cations), but the K_m value for cytidine-5′-phosphate choline in glial cells was much lower (2.3 × 10^?4m ) than in neurons (1 × 10^?3m ). The K_mfor cytidine-5′-phosphate ethanolamine in both cells was much lower than in whole brain microsomes. It is concluded that the cytidine-dependent enzymic system for phosphatidylcholine and phosphatidylethanolamine synthesis is concentrated mostly in the neuronal cells, as compared to glia.     

Serine and ethanolamine incorporation into different plasmalogen pools: Subcellular analyses of phosphoglyceride synthesis in cultured glioma cells

In cultured glioma cells, plasma membrane (PM) is enriched in phosphatidylserine (PtdSer) and plasmalogens (1-O-alk-1-enyl-2-acyl-sn-glycero-3-phosphoethanolamine). Serine can be a precursor of headgroups of both ptdSer and ethanolamine phosphoglycerides (PE) including plasmalogens and non-plasmalogen PE (NP-PE). Synthesis of phospholipids was investigated at the subcellular level using established fractionation procedures and incorporation of [³H(G)]L-serine and [1,2-¹⁴C]ethanolamine. Specific radioactivity of PtdSer from [³H]serine was 2-fold greater in PM than in microsomes, reaching maximum by 2–4 h. Labeled plasmalogen from [³H]serine appeared in PM by 4 h and increased to 48 h, whereas almost no plasmalogen accumulated in microsomes within 12 h. In contrast, labeled plasmalogen from [1,2-¹⁴C]ethanolamine appeared in both PM and microsomes at early incubation times and became enriched in PM beyond 12 h. Thus, in glioma cells: (1) greater and faster accumulation of labeled PtdSer in PM may reflect direct synthesis from serine within PM; (2) PM is a major source of PtdSer for decarboxylation and PE synthesis; (3) NP-PE in both PM and microsome provides headgroup for synthesis of plasmalogen; and, (4) plasmalogen synthesis may involve different intracellular pools depending on headgroup origin.Abbreviations NP-PE nonplasmenylethanolamine phosphoglycerides including both diacyl and alkylacyl species - PE total ethanolamine phosphoglycerides: plasmalogen-plasmenylethanolamine or alkenylacyl ethanolamine phosphoglyceride (1-O-alk-1-enyl-2-acyl-sn-glycero-3-phosphoethanolamine) - PL phospholipid - PM plasma membrane - PtdCho phosphatidylcholine - PtdSer phosphatidylserine     

On the Phospholipid Metabolism of Glial Cell Primary Cultures.

Abstract: Primary cultures were prepared from newborn rat brain. After 16-18 days, they consisted mainly of mature and immature astrocytes and oligodendrocytes, as judged by immunohistochemistry. To study the metabolism of ethanolamine glycerophospholipids, the cells were incubated with 1-[1-³H]alkyl- sn -glycero-3-phosphoethanolamine (1-alkyl-GPE), for 1–20 h. Five main products were formed: 1-alkyl-2-acyl-GPE; 1-alkyl-2-acyksn-glycero-3-phosphocholine (1-alkyl-2-acyl-GPC); 1-alkenyl-2-acyl-GPE (ethanolamine plasmalogen); 1-alkenyl-2-acyl-GPC (choline plasmalogen); and 1-alkyl-glycerol. Acylation of the substrate was the main reaction during the first 3 h of incubation, whereas desaturation to plasmaiogen reached a maximum after 12 h. Greater amounts of radioactivity were observed in the phosphatidylcholine fraction after longer incubation times. Only small amounts of choline plasmalogen were observed. The phosphatidylethanolamine fraction consisted of 26.5% diacyl-, 27.5% alkyl-acyl-, and 46.0% alkenyl-acyl- compounds, whereas the corresponding data for the phosphatidylcholine fraction were 78.5, 16.4, and 5.1%, respectively, after 20 h of incubation. Hydrolysis of the substrate to 1-alkyl-glycerol was a minor reaction.     

Lipid composition and metabolism in testicular and ejaculated ram spermatozoa

1. Spermatozoa collected directly from the testis of the conscious ram contain 25% more phospholipid than ejaculated spermatozoa. The concentration of lecithin, phosphatidylethanolamine and ethanolamine plasmalogen was greater in testicular spermatozoa; little difference was observed in choline plasmalogen. Both types of spermatozoa had significant amounts of cardiolipin and alkyl ether phospholipid. 2. The fatty acids in the phospholipid extracted from testicular spermatozoa have a very high content of palmitic acid. The phospholipids of ejaculated spermatozoa contained less palmitic acid, but more myristic acid. 3. Ejaculated spermatozoa contained less acyl ester and cholesterol. It is suggested that lipids are a source of substrate for spermatozoa during their passage through the epididymis. 4. Testicular spermatozoa when incubated with [U-¹⁴C]glucose incorporated more radioactivity into the glycerol part of the phospholipid and neutral lipid fractions than did ejaculated cells. The distribution of radioactivity in the individual phospholipids and neutral lipids was similar for both cell types. No radioactivity was detected in choline plasmalogen, which accounted for approx. 40% of the total phospholipid. 5. Testicular spermatozoa incorporated more radioactivity from glucose into formate than into acetate, whereas a higher proportion of radioactivity was found in acetate in ejaculated cells. 6. The implications of these lipid changes in the process of spermatozoal maturation are discussed.     

Protein synthesis in neurons and glial cells of the developing rat brain: an in vivo study

Abstract— A technique for the isolation of pure neuronal perikarya and intact glial cells from cerebral cortex has been developed for routine use. The yield of neuronal perikarya and glial cells was greater from highly immature (5–10 days) rat cerebral cortex than from the cortex of older rats (18–43 days). The perikarya/glia yield ratio decreased with age indicating that, as the glial population matured, the procedure succeeded in isolating a gradually smaller proportion of the existing neurons. The perikarya/glia ratio was highest for the 5-day-old cortex in which no mature glial cells could be identified. After a 10-min pulse in vivo of intrathecally injected [¹⁴C]phenylalanine, the specific radioactivity of the neuronal proteins was higher than that of the glial proteins in the 5-, 10- and 18-day-old rat but was lower in the 43-day-old rat. The values for absolute specific radioactivity of the ¹⁴C-labelled proteins in both cell types were greater, the younger the brain. The ¹⁴C-labelling of neuronal and glial proteins in the 18-day-old rat was assessed in vivo as a function of time by determining the incorporation of [¹⁴C]phenylalanine into such proteins at 5, 10, 20 and 45 min after administration of the amino acid. The rate of incorporation of [¹⁴C]phenylalanine into the glial cells was faster than into the neurons since higher specific radioactivities of the glial proteins could be achieved at earlier times. Also, a biphasic pattern of ¹⁴C-labelling of the glial proteins was noted, suggesting, perhaps, a sequential involvement of the oligodendrocytes and astrocytes. Homogenates of prelabelled neuronal perikarya were fractionated into the nuclear, mitochondrial microsomal and soluble cell sap fractions. In the 18-day-old cerebral cortex, the proteins of the microsomal fraction exhibited the highest specific radioactivity at the end of 10 min, whereas by 20 min proteins of the mitochondrial fraction were most highly labelled. The specific radioactivity of the nuclear proteins increased over the entire 45-min experimental period. On the contrary, the proteins of the soluble cell sap, in which the specific radioactivity was at all times by far the lowest, were maximally labelled by 5 min. Examination of the labelling of the neuronal subcellular fractions as a function of age revealed that at 10 min after administration of [¹⁴C]phenylalanine, the specific radioactivities of all ¹⁴C-labelled proteins were highest in the youngest (5-day-old) neurons. The proteins of the microsomal fraction were most rapidly labelled at all ages. During this interval the proteins of the soluble cell sap were only moderately labelled in the 5-day-old neurons and were totally unlabelled in the 43-day-old neurons, indicating age-dependent differences in the rate of utilization of the amino acid precursor by the neurons.     

Phospholipid metabolism in neuronal and glial cells during aging

The incorporation of cytidine-containing precursors (CDP-Cho and CDP-Etn) into the main phospholipid classes of cellular fractions enriched in neurons and glial cells from whole rat brains of different ages was examined. The rate of synthesis of choline phosphoglycerides in neuronal homogenates significantly decreased with age up to 18 months; after this time no additional decrease was found. The decrease of CDP-Etn incorporation in neurons was found to be less significantly affected by age up to 18 months, but the enzymic activity decreased after 18 months of age. No changes were found in the corresponding glial activity at any age. Biochemical phenomena that occur in 18-month-old rat brain (aged animals) were compared with phenomena occurring in 2-month-old rat brain (adult animals). No significant variations of lipid composition were found in neurons from either 18-month-old or 2-month-old rat brain. These results, together with some kinetic parameters, suggest that ethanolamine and choline phosphotransferases are affected differently by aging.     

The uptake and metabolism of plasma lysophosphatidylcholine in vivo by the brain of squirrel monkeys

1. Adult squirrel monkeys were injected intravenously with doubly labelled lysophosphatidylcholine (a mixture of 1-[1-(14)C]palmitoyl-sn-glycero-3-phosphorylcholine and 1-acyl-sn-glycero-3-phosphoryl[Me-(3)H]choline; (3)H:(14)Cratio 3.75) complexed to albumin, and the incorporation into the brain was studied at times up to 3h. 2. After 20min, 1% of the radioactivity injected as lysophosphatidylcholine had been taken up by the brain. 3. Approx. 70% of the doubly labelled lysophosphatidylcholine taken up by both grey and white matter was converted into phosphatidylcholine, whereas about 30% was hydrolysed. 4. The absence of significant radioactivity in the phosphatidylcholine, free fatty acid and water-soluble fractions of plasma up to 30min after injection of doubly labelled lysophosphatidylcholine rules out the possibility that the rapid labelling of these compounds in brain could be due to uptake from or exchange with their counterparts in plasma. 5. The similarity between the (3)H:(14)C ratios of brain phosphatidylcholine and injected lysophosphatidylcholine demonstrates that formation of the former occurred predominantly via direct acylation. 6. Analysis of the water-soluble products from lysophosphatidylcholine catabolism revealed that appreciable glycerophosphoryl-[Me-(3)H]choline did not accumulate in the brain and that radioactivity was incorporated into choline, acetylcholine, phosphorylcholine and betaine. 7. The role of plasma lysophosphatidylcholine as both a precursor of brain phosphatidylcholine and a source of free choline for the brain is discussed.     

Composition of gangliosides and phospholipids of neuronal and glial cell enriched fractions

Abstract— Fractions enriched in neuronal cell bodies and in glial cells were isolated from rabbit cerebral cortex by discontinuous gradient centrifugation. The ratio of total lipid to protein was approx. 50 per cent higher in the glial fraction than in the neuronal fraction. The fatty acid composition for the major phosphoglycerides was with few exceptions, similar for neurons and glia. The ganglioside concentration was very low for both cell types, but was approx. twice as high in the glial cells as in the neurons. The pattern of individual gangliosides was, however, very similar for the glial and neuronal fractions and did not differ from that of unfractionated cerebral cortex, synaptosomes and mitochondria. The latter results are discussed in relation to the estimated amounts of plasma membrane in the neuronal and glial fractions.     

Incorporation and turnover of phospholipid precursors in normal and tumoral glial cells in culture

The incorporation and turnover of phospholipid precursors in cultured normal and tumoral glial cells was investigated during the plateau phase of growth. Glycerol was incorporated similarly by all cell types, and was renewed with a half-life of 19-37 hr. Acetate had a much longer half-life in primary cultures (50-75 hr) than in proliferative tumor cells (20-40 hr). Phosphate had a more rapid turnover rate in primary cultures (25 hr) than in proliferative tumor cells (50 hr). For all precursors, inositol- and choline phosphoglycerides had a faster turnover rate than other phospholipids.     

Lipid metabolism in the testis of the ram

1. Analysis of rams testes revealed that phosphatidylcholine was the major phospholipid and accounted for about 40% of the total. Only small amounts of choline plasmalogen were present. 2. The ratio of phosphatidylcholine to choline plasmalogen in the testis was very different from that occurring in the spermatozoa. This result was in contrast with those for rat testis and rat spermatozoa (obtained from the head of the epididymis), where the ratio of the two lipids was very similar. 3. Infusions of [(32)P]orthophosphate into the testicular artery of rams resulted in incorporation of radioactivity into most phospholipids; phosphatidylinositol labelling accounted for 68% and 39% of the radioactivity after infusions lasting 3hr. and 5hr. respectively. 4. With the exception of phosphatidic acid the specific radioactivity of phosphatidylinositol was higher than that of any other lipid. 5. After the infusion of [U-(14)C]glucose, triglycerides accounted for about 60% of the radioactivity in testicular neutral lipids, whereas diglycerides had only about 15% of the radioactivity. 6. Palmitic acid (16:0) was the major component both in neutral lipids and phospholipids of ram testes. 7. The effects of gonadotrophic hormones (luteinizing hormone and follicle-stimulating hormone) on the incorporation of [(32)P]orthophosphate into total testicular phospholipids in vivo were also examined.