The fatty acid composition of sphingolipids from bovine CNS axons and myelin

Abstract— Cerebrosides, sulphatides and sphingomyelin were isolated from bovine CNS myelin and from myelin-free axons derived from myelinated axons. The fatty acid composition of each sphingolipid was determined by gas-liquid chromatography of the fatty acid methyl esters. In each case the fatty acids of the axonal sphingolipids were of shorter average chain length than those from the corresponding myelin lipids. These differences, however, were small and the fatty acids of the axonal cerebrosides and sulphatides were similar in average chain length to those reported previously for bovine myelin. The principal unsubstituted acid of both cerebroside and sulphatide from axons was 24: 1, with the total long chain acids (> C₁₈) amounting to 80 and 85 per cent, respectively. The corresponding figures for myelin galactolipids were 94 and 95 per cent long chain acids. The principal α-hydroxy acid of both axonal galactolipids was 24 h:0, with cerebroside having 80 per cent and sulphatide 92 per cent long chain acids, compared to the figures of 87 and 97 per cent for the corresponding myelin lipids. In axonal sphingomyelin the major acid was 18:0 (compared to 24:1 in myelin) and the long chain acids were 61 per cent of the total vs 76 per cent of the total for myelin sphingomyelin. The non-identity of axonal and myelin sphingolipid fatty acids substantiates the belief that they are intrinsic axonal constituents. These findings do not rule out the possibility of a close metabolic relationship between the sphingolipids of the axon and its myelin sheath.     

Different metabolic recycling of the lipid components of exogenous sulphatide in human fibroblasts.

Cultured human fibroblasts were fed with two differently labelled sulphatide molecules [one labelled on C-3 of the sphingosine (Sph) moiety [( Sph-3H]sulphatide), the second on C-1 of stearic acid [( stearoyl-14C]sulphatide)], and the intracellular metabolic fate of radioactivity was monitored. Incorporated radioactivity was almost all recovered in the total lipid extract, regardless of the labelling position of the added sulphatide; however, large differences in the level of incorporation occurred among labelled glycosphingolipids. For example, sphingomyelin was present as the major radiolabelled lipid after [Sph-3H]-sulphatide incubation, but was detectable only in trace amounts after [stearoyl-14C]sulphatide administration; in the latter case the radioactivity was located predominantly in glycerophospholipids. From this finding it can be inferred that the free long-chain base (sphingosine) that originates from lysosomal catabolism of sulphatide is mainly, and quite specifically, utilized for sphingomyelin biosynthesis, whereas the ceramide moiety is not; conversely the fatty acid released from ceramide is non-specifically re-utilized for phospholipid biosynthesis.     

The characterization of sphingolipids from neurons and astroglia of immature rat brain

Abstract— Isolated neuronal cell bodies and astroglia of young (15–20-day-old) rat brains were both found to contain small concentrations of a variety of glycosphingolipids, including glucosylceramide, galactosylceramide, sulphatide, dihexosylceramide and gangliosides. These sphingolipids, plus sphingomyelin, were isolated, quantitated and their fatty acid and long chain base patterns determined. These data were compared to similar data obtained on these lipids isolated from whole brain and myelin of rats of the same age range. Glucosylceramide was found in an amount equal to galactosylceramide in neurons, and accounted for 35 per cent of the total monohexosylceramide in astroglia. Dihexosylceramide was present in nearly the same amount as sulphatide in both cell types. The sphingolipids of each cell type had characteristic fatty acid patterns. Generally the whole brain fatty acid patterns resembled those of astroglial lipids rather than neuronal lipids. In no case did the cell sphingolipid fatty acids resemble those of myelin. However, the galactosylceramide and sulphatides of both cells had unsubstituted and α-hydroxy acids, both of which had appreciable quantities of C₂₄ acids. The ganglioside fatty acids of each cell type were similar and not unusual, but were quite different from those of glucosylceramide and dihexosylceramide; the latter having appreciable quantities of 16:0 and acids longer than 18:0. The ganglioside patterns of these cells were similar and only slightly different from that of whole brain. Long chain bases of sphingolipids were mainly C₁₈-sphingosine in both cell types, and those of ganglioside and sphingomyelin contained small amounts of C₂₀-sphingosine.     

Chemical compositions of brain and myelin in two patients with multiple sulphatase deficiency (a variant form of metachromatic leukodystrophy)

The lipid composition of the brain, including myelin, was studied in detail in two cases with a variant form of metachromatic leukodystrophy (multiple sulphatase deficiency type). In the white matter, the sulphatide concentration was 3-4 times higher than the normal level in both cases. There was a significant accumulation of cholesterol sulphate in the brain, liver and kidney of both cases. The ganglioside pattern in the grey and white matter was abnormal, with a higher proportion of GM3, GM2 and GD3-gangliosides. Non-lipid hexosamine contents were increased 1.5-2 times in brain, 8-10 times in liver and 2-3 times in kidney. Increased amounts of glucocerobroside, ceramide lactoside and ceramide trihexoside were present in grey and white matter of both cases. Recovery of purified myelin from two patients' brains was much less than from control (1-2% in case 1 and 20-30% in case 2). The lipid composition of myelin was almost normal except for a higher proportion of sulphatide, with a decreased amount of cerebroside. The fatty acid compositions of myelin sulphatide and sphingomyelin were almost normal, while non-hydroxy fatty acids of cerebroside contained less long-chain fatty acids, as characterized by a significant increase of C16:0 and C18:0 fatty acids. The myelin polypeptide pattern by SDS-disc gel electrophoresis showed a relative decrease of basic protein and of proteolipid protein. A possible mechanism of myelin loss in MSD is discussed.     

Uptake and metabolism of fluorescent ceramide analogs by rat oligodendrocytes in culture.

We studied the metabolism of sphingolipids by oligodendrocytes derived from rat spinal cord by providing lipid vesicles with either N-lissamine-rhodaminyl-ceramide (LRh-Cer) or N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-ceramide (NBD-Cer) to the cells cultured in a chemically-defined medium. With both probes the major fluorescent product turned out to be sphingomyelin (SM). Most of LRh-SM was not cell-associated but recovered from the culture medium, probably due to back-exchange to the lipid vesicles. The accumulation of LRh-SM, both in the cells and in the medium, was inhibited in the presence of monensin or brefeldin A, whereas the production of NBD-SM was much less affected by these Golgi perturbing drugs. With LRh-Cer as substrate, LRh-labelled fatty acid (FA), galactosyl- and sulfogalactosyl-ceramides (GalCer and SGalCer) were also formed. NBD-Cer, however, was metabolized to glucosylceramide (GlcCer) and GalCer but not to SGalCer or NBD-FA. These data demonstrate that chemical modifications of ceramide alter its metabolism in oligodendrocytes and that the metabolites of LRh-Cer reflect the glycolipid composition of myelin more closely than those of NBD-Cer.     

THE FATTY ACID COMPOSITION OF PHOSPHOLIPIDS AND GLYCOLIPIDS IN JIMPY MOUSE BRAIN

Abstract— Phospholipids and sphingolipids from brains of normal and Jimpy mice were isolated in a pure form by thin-layer chromatographic procedures. The fatty acid composition of the major phospholipids, i.e. ethanolamine glycerophospholipids, serine glycerophospholipids, choline glycerophospholipids and inositol glycerophospholipids, as well as sphingomyelin, cerebrosides and sulphatides was determined by gas-liquid chromatography. A specific fatty acid pattern for each of the four glycerophospholipids was found. The fatty acid composition of inositol glycerophospholipid, which has not previously been studied in mouse brain, was characterized by a high concentration of arachidonic acid. After 16 days of age, fatty acid analysis showed definite differences between the phospholipids from normal and mutant brains. A small increase of polyunsaturated fatty acids in glycerophospholipids of ethanolamine, serine and choline from the Jimpy central nervous system was found, which has been explained by the myelin deficiency. Sphingomyelin, cerebrosides and sulphatide analyses showed a wide distribution of saturated and mono-unsaturated fatty acids in both normal and mutant mice. A reduction in the amount of long-chain fatty acids was demonstrated in mutant brain sphingolipids; in sulphatides and cerebrosides, the amount of non-hydroxy fatty acids was reduced to a greater extent than in sphingomyelin. The distribution of fatty acids in sphingolipids from the myelin and microsomal fractions was also investigated in both types of mice. Cerebrosides were characterized by a high content of long-chain fatty acids in myelin as well as in microsomes. Sulphatides and sphingomyelin, on the other hand, showed a higher content of medium-chain fatty acids in microsomes than in myelin. In the mutant brain, the amount of long-chain fatty acids was reduced in both subcellular fractions. The deviation from normal in the pattern of fatty acid distribution in Jimpy brain is discussed in relation to the current concepts of glycolipid biosynthesis.     

GANGLIOSIDES OF HUMAN MYELIN: SIALOSYLGALACTOSYLCERAMIDE (G7) AS A MAJOR COMPONENT

Abstract— Gangliosides were isolated from purified human myelin in a yield of 62 μg of lipid-bound sialic acid per 100 mg of dry myelin. Sialosylgalactosyl ceramide (G₇) was found to be a major component of the ganglioside fraction, amounting to 15 per cent of the total sialic acid. It accounted for 10 per cent of lipid-bound sialic acid in adult human white matter, making it the third most abundant ganglioside on a molar basis. These results were obtained with an improved method for isolating total gangliosides in high yield, by employing DEAE-Sephadex column chromatography. Myelin from other mammalian species had considerably less G₇, and there were also indications of maturational changes. Both 2-hydroxy and unsubstituted fatty acids were components of the ceramide unit, in a ratio of 3:2, respectively. The overall fatty acid pattern was very similar to that for myelin cerebroside and sulphatide. Long-chain bases included only C₁₈ species, with sphingosine predominating (>90 per cent). These observations suggest a metabolic relationship between G₇ and either cerebroside or sulphatide.     

Uptake and intracellular degradation of fluorescent sphingomyelin by fibroblasts from normal individuals and a patient with Niemann-Pick disease

Sphingomyelin, labelled with a fluorescent probe, pyrene, in the fatty acyl residue was associated with fetal calf serum; approx. 80% of the sphingomyelin was found in the low- and high-density lipoproteins. This was added to the growth medium of cultured human skin fibroblasts from normal individuals and a patient with Niemann-Pick disease type A, devoid of acid sphingomyelinase activity. The fluorescent sphingomyelin was taken up by both cell types, but only the former degraded it to produce fluorescent ceramide. Differences between normal and Niemann-Pick cells in sphingomyelin content or ceramide production were observed after several hours uptake. A more pronounced difference was noted when cells were incubated for 1 day with fluorescent sphingomyelin and then for two to three days in medium devoid of this compound. Under these conditions, the fluorescence intensity of the Niemann-Pick cells remained practically constant while that of their normal counterparts was almost completely eliminated from the cells. Comparison of fluorescence intensities of these two cell types could be made directly on aqueous suspensions of whole cells or, alternatively, on their lipid extracts. For evaluation of the degradation of fluorescent sphingomyelin to ceramide within the cells, several procedures were developed for the rapid isolation of the latter compound from the total lipid extract. The results suggest that when associated with the constituents of the fetal calf serum, sphingomyelin is taken up by the cells and transported into the lysosomal compartment where it is degraded to ceramide. Use of the fluorescent derivative of sphingomyelin provided a simple and rapid procedure for following the uptake by and degradation within the cultured cells. It also permitted the establishment of differences in the rates of degradation of the fluorescent sphingomyelin by cells with a normal metabolism and others lacking sphingomyelinase (i.e., Niemann-Pick disease type A cells).     

Characterization of sulphatide-containing lipoproteins in rat brain

—(1) Water-soluble [³⁵S]sulphatide is found in the 105,000 g supernatant (SN) of rat brain after intraperitoneal injection of Na₂³⁵SO₄. This labelled sulphatide has a density between those of free lipid and free protein. (2) Fractionation of SN by preparative acrylamide gel electrophoresis indicates that the [³⁵S]sulphatide is not distributed among all SN proteins, but is associated with certain specific proteins. One of the isolated [³⁵S]sulphatide-containing proteins appears homogeneous by analytical acrylamide gel electrophoresis at several pH values. (3) Comparison of the turnover of [³⁵S]sulphatide in microsomes, SN, and myelin indicates that these three subcellular fractions behave as distinct metabolic pools, which meet the requirements for a precursor-product relationship between microsomes and SN and between SN and myelin. (4) These results suggest that sulphatide, synthesized in the microsomes, is transported to the myelin membrane as water-soluble sulphatide containing Iipoproteins in SN.     

Effect of docosahexaenoic acid on membrane fluidity and function in intact cultured Y-79 retinoblastoma cells.

Considerable metabolic energy is expended in ensuring that membranes possess a characteristic fatty acid composition. The nature of the specific requirement of the retina for high levels of docosahexaenoic acid (DHA) is as yet undefined. Previous work has speculated that DHA is required to maintain the fluid nature and permeability necessary for optimal retinal function. Cultured Y-79 retinoblastoma cells were grown in serum-containing media with and without supplemental DHA. Resultant changes in membrane fluidity were assessed using fluorescent probes. No differences were observed in rotational probe mobility as assessed by fluorescence polarization despite a fourfold increase in cellular DHA content. Lateral probe mobility as assessed by pyrene eximer formation was significantly enhanced in DHA-supplemented cells. Both the DHA content and total fatty acid unsaturation index in retinoblastoma cells were directly correlated with membrane fluidity as reported by eximer formation (Pearson's rho = 0.96 and 0.92, respectively). DHA supplementation also resulted in a significant increase in cellular choline uptake. We speculate that the effect of DHA content on retinal function may be mediated by changes in membrane fluidity and associated enzyme and transport activities.     

Uptake and metabolism of a fluorescent sulfatide analogue in cultured skin fibroblasts.

The sulfatide fluorescent analogue N-lissamine rhodaminyl-(12-aminododecanoyl) cerebroside 3-sulfate was administered in the form of albumin complex to normal human skin fibroblasts and its metabolic fate was investigated. Ceramide, galactosylceramide, glucosylceramide, sphingomyelin and free acid, all containing the fluorophore lissamine rhodamine, have been synthesized as reference standards for the identification of the metabolic products. Ceramide appeared to be the main metabolic product present both in cell extract and medium, followed by galactosylceramide and sphingomyelin. Fluorescence microscopy of cells showed a marked perinuclear fluorescence.     

Uptake and interconversion of fluorescent lipid analogs in the protozoan parasite, Perkinsus marinus, of the oyster, Crassostrea virginica

Uptake, distribution, and interconversion of fluorescent lipid analogs (phosphatidylcholine, PC; cholesteryl ester, CHE; phosphatidylethanolamine, PE; palmitic acid, C16; sphingomyelin, SM) by the two life stages, meront and prezoosporangium, of the oyster protozoan parasite, Perkinsus marinus, were investigated. Class composition of these two life stages and lipid contents in meront cells were also examined. Both meronts and prezoosporangia incorporated and modified fluorescent lipids from the medium, but their metabolic modes differ to some extent. Results revealed that among the tested analogs, neutral lipid components (CHE and C16) were incorporated to a greater degree than the phospholipids (PC, PE, and SM). HPLC analysis of meront lipids showed that while the majority of the incorporated PC, CHE, and PE remained as parent compounds, most of the incorporated C16 was in triacylglycerol (TAG) and SM was in ceramide and free fatty acids. The cellular distribution of fluorescent labels varied with lipid analogs and the extent of their metabolism by the parasite. Fluorescence distribution was primarily in cytoplasmic lipid droplets of both life stages after 24 h incubation with PC. After 24 h incubation with SM, fluorescence appeared in the membrane and cytosol. Total lipid contents in meront cultures increased during proliferation and TAG accounted for most of the increased total lipids. Since total lipid content per meront cell did not increase until the day of culture termination, the lipid increase in the meront culture was mainly a result of increased cell numbers. Both life stages contain relatively high levels of phospholipids, 53.8% in 8-day-old meronts and 39.4% in prezoosporangia. PC was the predominant phospholipid.     

Changes in fatty acid composition of peripheral nerve myelin in essential fatty acid deficiency

Severe essential fatty acid deficiency (EFAD) was induced by feeding weanling rats a diet free of essential fatty acids 8 months after weaning. The fatty acid compositions of phospholipids and glycosphingolipids in peripheral nerve myelin were compared in rats with and without EFAD. With the deficient diet, 20:3ω9 was found in the major myelin phospholipids. The level of 18:1 was increased and the levels of 18:2ω6, 20:4ω6, and 22:4ω6 were decreased. Both sphingomyelin and cerebroside showed higher proportion of 24:1 and lower proportions of 24:0 in EFA-deficient rats than in control rats. The fatty acid chain elongating system in myelin cerebroside was also depressed by EFAD. A two- to sevenfold increase of the ratio 20:4ω6 to 20:3ω6 was found in myelin phospholipids of regenerated nerve from rats fed control diet. However, this ratio was suppressed by EFAD diet. The biochemical index (20:3ω9/20:4ω6) for EFAD was not affected by crush injury. These results suggest that dietary EFAD in postweaning rats can induce fatty acid alterations in peripheral nerve myelin without resulting in detectable changes in function or structure and that myelin lipids may be sequestered and reused during nerve degeneration and regeneration.     

The Effect of Specific Sterols on Cell Size and Fatty Acid Composition of Tetrahymena pyriformis W

The size and fatty acid composition of Tetrahymena pyriformis W cells were influenced by the provision of a nutritional supplement of ergosterol, cholesterol, or tetrahymanol, but not of 20-isocholesterol. Ergosterol and cholesterol addition led to a reduction in cellular volume, an increase in glycerophospholipid saturated fatty acid content, and an increase in palmitoleic acid and its metabolic products when compared to unsupplemented controls. Tetrahymanol supplementation resulted in an increase in cellular volume, a decrease in saturated fatty acid content, and a reduction in palmitoleic acid and derivatives. 20-Isocholesterol was accumulated by the cells; however, this compound had no effect on any of the parameters followed in this investigation and had only a small depressant effect on tetrahymanol biosynthesis. Ergosterol and cholesterol had the same impact on the ciliates, even though the ergosterol-supplemented cells contained approximately three times as much free sterol as did cholesterol-grown cells. The amount of the free cholesterol and metabolic products in supplemented cultures was similar to the amount of tetrahymanol present in control cultures. This observation suggests that the cells recognize qualitative differences among the various polycyclic alcohols rather than responding to the amount of sterol present. Increased cellular levels of tetrahymanol led to a response unlike that of the true sterols, which again suggests that the high degree of specificity depends on the structure of the added polycyclic alcohol. The changes in fatty acid composition may be required to maintain proper interaction of the polar lipids and the polycyclic alcohols to give an appropriate degree of membrane fluidity.     

Kinetics of entry of galactolipids and phospholipids into myelin.

Abstract— Brain slices from 17 day rats were incubated with [³H]galactose and [³⁵S]sulphate to label cerebroside and sulphatide. Myelin was isolated by centrifugation on a sucrose density gradient. Following lipid extraction and alkaline methanolysis, cerebroside and sulphatide were isolated by tic, and radioactivity was measured. Appearance of [³H]cerebroside and [³H]sulphatide in myelin showed a lag of less than 15min, while appearance of [³⁵S]sulphatide in myelin showed a longer lag of about 30min. In chase experiments, the rate of appearance of [³H]cerebroside and [^3SS]sulphatide in the non-myelin fraction and of [³H]cerebroside in the myelin fraction slowed markedly after the chase. In contrast, [³⁵S]sulphatide continued to increase in myelin at a normal rate for 30min after the chase, then stopped, while ³H from galactose continued to accumulate in myelin sulphatides for 60 min. These data are interpreted to demonstrate an interval of 30 min between synthesis of cerebroside and its sulphation in the non-myelin fraction, and another delay of 30 min between sulphation and appearance in myelin. The distribution of newly synthesized cerebroside and sulphatide between myelin and non-myelin fractions also supported the concept that a complex metabolic pool of cerebroside in the non-myelin fraction is precursor to sulphatide of myelin. For comparison, entry of phosphatidyl choline and phosphatidyl ethanolamine into myelin was followed with [2-³H]glycerol as precursor. Like cerebroside, both phospholipids showed little delay in their initial appearance in myelin, and prompt cessation of their addition after a chase with unlabeled precursor. These results are consonant with either rapid entry of these three lipids into myelin after synthesis at an extra-myelin site, or synthesis of the lipids within myelin itself.     

Alterations in the Fatty Acid Composition of Rat Brain Cells (Neurons, Astrocytes, and Oligodendrocytes) and of Subcellular Fractions (Myelin and Synaptosomes) Induced by a Diet Devoid of n-3 Fatty Acids

Abstract: Rats were fed through four generations with a semisynthetic diet containing 1.0% sunflower oil (6.7 mg/ g n-6 fatty acids, 0.04 mg/g n-3 fatty acids). Ten days before mating, half of the animals received a diet in which sunflower was replaced by soya oil (6.6 mg/g n-6 fatty acids, 0.8 mg/g n-3 fatty acids) and analyses were performed on their pups. Fatty acid analysis in isolated cellular and subcellular material from sunflower-fed animals showed that the total amount of unsaturated fatty acids was not reduced in any cellular or subcellular fraction (except in 60-day-old rat neurons). All material from animals fed with sunflower oil showed an important reduction in the docosahexaenoic acid content, compensated (except in 60-day-old rat neurons) by an increase in the n-6 fatty acids (mainly C22:5 n-6). When comparing 60-day-old animals fed with soya oil or sunflower oil, the n-3/n-6 fatty acid ratio was reduced 16-fold in oligodendrocytes, 12-fold in myelin, twofold in neurons, sixfold in synaptosomes, and threefold in astrocytes. No trienes were detected. Saturated and monounsaturated fatty acids were hardly affected. This study provides data on the fatty acid composition of isolated brain cells.     

Effects of fluorophore structure and hydrophobicity on the uptake and metabolism of fluorescent lipid analogs

Cellular transport and metabolism of fatty acids are integral components of lipid metabolism, but the mechanisms and regulation involved are poorly understood. A variety of commercially available fluorescent analogs of fatty acids, are potentially useful probes for the study of lipid metabolism by such techniques as cell sorting and fluorescence microscopy. We have screened a series of fluorescent fatty acids to identify analogs that would reliably simulate the metabolic behavior of natural fatty acids; i.e., similar kinetics of transport, of intracellular movement, and of metabolic fate. The metabolic behavior of these analogs was compared with those of some naturally occurring fatty acids in HepG2 cells, which are a good model of some aspects of hepatic function. Fluorescent analogs containing polar fluorophores yielded the lowest rates of cellular uptake and conversion to acylated lipid products. Similarly, fluorescent analogs with the fluorophore located near the carboxylic acid group were poorly metabolized. Fatty acid analogs containing anthracene or pyrene at the n-terminus of the acyl chain were the most extensively incorporated into cellular lipids. The types and amounts of labeled lipid products formed from these analogs and from natural fatty acids were similar. Pyrene-labeled analogs have spectral properties that can be measured fluorometrically at very low concentrations. Therefore, we compared the cellular metabolism of 12-(1-pyrenyl)dodecanoic acid with those of palmitic and oleic acids.(ABSTRACT TRUNCATED AT 250 WORDS)     

Turnover rate of molecular species of sphingomyelin in rat brain

Turnover rate of individual molecular species of sphingomyelin of adult rat brain myelin and microsomal membranes was determined after an intracerebral injection of 100 Ci of [C³H₃]choline. Myelin and microsomal membrane sphingomyelins were isolated from the rest of the lipids. The individual molecular species of benzoylated sphingomyelin were separated and quantitated by reversed-phase high performance liquid chromatography. All individual major molecular species of microsomal and myelin sphingomyelin had maximum incorporation at 6 and 15 days, respectively, after the injection. The specific radioactivity of all the various molecular species of both myelin and microsomal sphingomyelin declined at a similar rate after reaching a maximum. There was no significant difference in the turnover rate of short chain (16:0, 18:0) and long chain (>22:0) fatty acid containing sphingomyelin. The average apparent turnover rate of myelin and microsomal sphingomyelin molecular species was about 14–16 days for the fast pool and about 45 days for the slow pool. It is concluded that individual molecular species of sphingomyelin of myelin and microsomal membranes turned over at a similar rate. Thus, turnover rate of sphingomyelin in myelin and microsomal membranes is not affected by the fatty acyl composition of the lipid.     

Fatty acid metabolism of isolated mammalian cells

It is now clear that a wide variety of differentiated cells in culture exhibit essentially the full spectrum of mammalian fatty acid metabolism. These cells readily incorporate free fatty acids into membrane phosphoglycerides, modify exogenous fatty acids by desaturation and elongation, and store excess fatty acyl groups, primarily as triacylglycerols. Similarly, many different types of cells synthesize cyclooxygenase and lipoxygenase derivatives of long chain polyunsaturated fatty acids. Furthermore, although the fatty acid composition of cellular phospholipids can be modified by medium supplementation, cells in culture exhibit definite fatty acyl specificities for the various steps of fatty acid activation, transesterification and release. As the extensive repertoire of fatty acid metabolism in mammalian cells has been elucidated, and as the ability to grow differentiated cells in culture has increased, new questions have arisen. There is still much to be learned about the enzymes involved in synthesizing and maintaining the unique fatty acid composition of the different cellular phospholipids and the processes which regulate the desaturation, elongation and retroconversion of polyunsaturated fatty acids. Other areas of great current interest are the mechanisms by which certain long chain polyunsaturated fatty acids are made available for conversion to oxygenated, biologically-active derivatives, the metabolic interactions between different polyunsaturated fatty acids, particularly n-3 and n-6 fatty acids, the cellular roles of the C22 polyunsaturated fatty acids, and the functions of particular molecular species of phospholipids in membrane-mediated events. Further research in these areas will contribute to unravelling the role of fatty acids and fatty acid derivatives in the physiological processes of mammalian cells.     

Membrane instability induced by purified myelin components. Its possible relevance to experimental allergic encephalomyelitis.

The fusogenic properties of purified myelin components in a system employing chicken erythrocytes were studied. Sulphatides, myelin basic protein and the apoprotein of Folch-Lees proteolipid were capable of individually inducing membrane fusion in the presence of Ca2+. By contrast, cerebrosides or a mixture of sulphatides and myelin basic protein (molar ratio 19 : 1) did not show such effect. The fusogenic ability of sulphatide was correlated to its behaviour in mixed monolayers with phospholipids at the air-water interface. Mixed films of sulphatides with phosphatidylcholine or sphingomyelin but not with phosphatidylethanolamine showed reductions of molecular packing and surface potential similar to those found for other fusogenic compounds. The effects of myelin components described could be of importance in the membrane instability and vesicular disruption of myelin occurring in demyelinative disorders.