Degradation and restoration of mitochondria upon deaeration and subsequent aeration of aerobically grown Saccharomyces Cerevisiae cells

Changes in the mitochondria of aerobically grown Saccharomyces cerevisiae cells upon deaeration and subsequent aeration of the medium were studied.

1. It is shown that removal of oxygen at the end of the exponential phase of growth (after completion of mitochondria formation) causes a decrease in activity of the respiratory enzymes. The activity of the complete respiratory system decreases much more rapidly than the activities of its fragments (NADH: ferricyanide reductase, succinate:ferricyanide reductase, NADH:cytochrome c reductase, succinate:cytochrome c reductase and cytochrome oxidase). The activities are restored to their initial level upon aeration of the cell suspension. The addition of Tween-80 and ergosterol to the medium prior to deaeration does not prevent inactivation of the respiratory system.

All the changes in mitochondria described occurred under conditions where cell division was insignificant.

2. Deaeration of the medium decreases the content of cytochromes b and aa₃ in the mitochondrial fraction, cytochrome aa₃ “disappearing” more quickly. The concentration of cytochromes in this fraction increases upon subsequent aeration of the cells. The total cytochromal content of the cells remains practically unchanged under the same conditions.

3. According to electron microscopic data, anaerobiosis causes a certain disorganization of mitochondrial cristal membranes. The mitochondrial structures are recovered upon aeration of the yeast cell suspension. It may be reasoned that inactivation and reactivation of the respiratory system are associated with reversible changes in mitochondrial membrane structure.

4. The effect of protein synthesis inhibitors on the restoration of mitochondria was investigated. It is shown that chloramphenicol does not suppress this process. In the presence of cycloheximide, oxygen induces reactivation of the respiratory system and simultaneously the appearance of particles resembling mitochondria. However, these particles gradually undergo morphological changes and the respiratory activity of the mitochondrial fraction decreases. Cycloheximide added to yeast cells that had not been deaerated, did not affect their mitochondria.

5. The results described suggest that the functions of oxygen in the formation of mitochondria are not restricted to the induction of mitochondrial protein synthesis and to the participation in the synthesis of certain non protein membrane components. Evidently, oxygen has a direct effect on the assembly of the respiratory system and mitochondrial membranes as a whole.     

Inhibition of conjugation in Tetrahymena pyriformis by cerulenin. Possible requirement for de novo lipid synthesis.

Conjugation in Tetrahymena pyriformis is induced by the mixing of two starved complementary mating types. Addition of the antibiotic cerulenin, a specific inhibitor of de novo lipid synthesis, upon mixing of the mating types inhibited the conjugation process. The inhibition of conjugation was found to be reversible upon washing the cells. Cerulenin inhibited [14C]acetate incorporation into the lipid fraction of the cells, while it did not affect the incorporation of [3H]leucine into proteins. Analysis of the fatty acid composition of the whole cells revealed that during conjugation the ratio of saturated to unsaturated fatty acids is markedly changed. While the ratio of saturated:unsaturated fatty acids is 0.30 in unconjugated cells, it reached a value of 0.45 in conjugated cells.     

Reduced plasma membrane permeability in a multiple cross-resistant strain of Saccharomyces cerevisiae.

Single nuclear gene inheritance was shown to be responsible for increased resistance to: eight diverse inhibitors of mitochondrial function (antimycin, carbonylcyanide-m-chlorophenylhydrazone, chloramphenicol, oligomycin, tetracycline, triethyltin bromide, triphenylmethylphosphonium bromide and triton-X-165); and an inhibitor of cytoplasmic protein synthesis (cycloheximide). Continuous monitoring of oxygen uptake during respiratory adaptation showed that anerobic pretreatment of resistant cells sensitized respiratory adaptation to chloramphenicol and antimycin. However, since a depression of mitochondrial function by catabolite repression did not result in sensitization to antimycin, alteration of the mitochondrial membrane does not appear to be responsible for resistance to mitochondrial inhibition. Alteration of cellular binding sites was not responsible for resistance since in vitro mitochondrial protein synthesis was sensitive to chloramphenicol and in vitro mitochondrial respiration was sensitive to oligomycin, carbonylcyanide-m-chlorophenylhydrazone, and antimycin. Autoradiography of an ethylacetate-ethanol extract of [14C]chloramphenicol-treated resistant cells indicated that resistance was not due to enzymatic modification of inhibitors. The maintenance of an antimycin-resistant respiration by protoplasts of resistant cells ruled out the involvement of the cell wall in cellular resistance. The reduced transport of [14C]chloramphenicol by resistant cells (1% of normal cells) indicated that a single nuclear gene mutation can alter the permeability of the plasma membrane to many diverse inhibitors.     

Amino acid incorporation into the protein of mitochondrial preparations from cerebral cortex and spinal cord

1. Washed guinea-pig cerebral-cortex mitochondria incorporate [(14)C]leucine into their protein at a rate comparable with the rates reported for liver or heart mitochondria only if the mitochondria are separated from myelin and nerve endings by density-gradient centrifugation. 2. The non-mitochondrial components (myelin and nerve endings) of brain mitochondrial preparations incorporated [(14)C]leucine at a negligible rate. 3. The mitochondria do not require an exogenous supply of energy or a full supply of amino acids to support the process. 4. The incorporation rate was linear up to 2hr. aerobic incubation at 30 degrees and was inhibited by chloramphenicol, only slightly by actinomycin D and not by penicillin or pretreatment with ribonuclease. The observed incorporation is considered to be unlikely to be due to contaminating cytoplasmic ribosomes or bacteria. 5. The process was also studied in mitochondrial preparations from rabbit cerebral cortex and spinal cord.     

Inhibition of conjugation in Tetrahymena pyriformis by cerulenin. Possible requirement for de novo lipid synthesis

Conjugation in Tetrahymena pyriformis is induced by the mixing of two starved complementary mating types. Addition of the antibiotic cerulenin, a specific inhibitor of de novo lipid synthesis, upon mixing of the mating types inhibited the conjugation process. The inhibition of conjugation was found to be reversible upon washing the cells.Cerulenin inhibited [¹⁴C]acetate incorporation into the lipid fraction of the cells, while it did not affect the incorporation of [³H]leucine into proteins. Analysis of the fatty acid composition of the whole cells revealed that during conjugation the ratio of saturated to unsaturated fatty acids is markedly changed. While the ratio of saturated:unsaturated fatty acids is 0.30 in unconjugated cells, it reached a value of 0.45 in conjugated cells.     

Synthesis of mitochondrial protein in the flight muscles of the Colorado beetle. Differentiation in vivo between extra- and intra-mitochondrial contributions to the amino acid incorporation into mitochondrial protein

By using cycloheximide, an inhibitor of cytoplasmic protein synthesis, conditions were investigated to estimate in vivo the extra- and intra-mitochondrial contributions to the synthesis of organelle protein in the flight muscles of Colorado beetles. With 4-day-old beetles about 15% of the [(14)C]leucine incorporation into mitochondrial protein is resistant to the action of cycloheximide. The incorporation into cytosol protein is inhibited by more than 99.5% with cycloheximide. During the first hour after precursor administration the incorporation into mitochondrial protein proceeds, in both the presence and the absence of cycloheximide, at a more-or-less linear rate with time. The cycloheximide-resistant amino acid incorporation is sensitive to the inhibitor of mitochondrial protein synthesis, chloramphenicol. The uncertainties inherent in the use of cycloheximide were discussed in arriving at the conclusion that about 15% of the mitochondrial protein is formed inside the organelle.     

Mitochondrial biogenesis during fungal spore germination: effects of the antilipogenic antibiotic cerulenin upon Botryodiplodia spores.

Germination of spores of the fungus Botryodiplodia theobromae was inhibited by the antilipogenic antibiotic cerulenin. The spores remained viable in the presence of the antibiotic, however, and after prolonged incubation they were able to overcome the inhibition. Cerulenin inhibition of germination was reversed by Tween 40 and Tween 60 (derivatives of palmitate and stearate, respectively), but not by representatives of a range of free fatty acids or their soaps. Cerulenin abolished incorporation of [14C]acetate into sterols and triglycerides and reduced its incorporation into fatty acids by 69%. Cyanide-sensitive oxygen consumption by spores incubated in the presence of cerulenin was greatly reduced throughout germination, and the activity of cytochrome c oxidase was no more than 13% of the activity in untreated spores, even after prolonged incubation. However, low-temperature difference spectra of mitochondrial extracts showed that the cerulenin-treated spores accumulated a threefold excess of cytochrome a, whereas the cellular concentrations of cytochroms c and b were identical to those of untreated spores. Cerulenin treatment sharply reduced the rates of whole spore protein and RNA synthesis. Cerulenin had no effects upon mitochondrial morphology which could be discerned with an electron microscope.     

Effect of temperature on protein synthesis and leucine transport by yeast mitochondria

Protein synthesis in yeast mitochondria shows biphasic Arrhenius plots both in vivo and in vitro, with a twofold increase in the activation energy below the transition temperature suggesting a functional association between mitochondrial protein synthesis and the inner membrane. Analysis by gel electrophoresis of mitochondrial translation products labeled in vivo showed that the same proteins are synthesized and then inserted into the membrane above and below the transition temperature of the membrane. The rate of leucine uptake into mitochondria was decreased at least fivefold in the presence of chloramphenicol, suggesting that leucine is used mainly for protein synthesis. In the absence of chloramphenicol, the rate of leucine uptake was always slightly higher but comparable to the incorporation rate of leucine into protein at all temperatures studied, suggesting that the transport of leucine into mitochondria is not rate-limiting for protein synthesis. The ionophore valinomycin or the uncoupler carbonyl phenylhydrazone (CCCP) inhibited 75-80% of the leucine uptake in the presence of chloramphenicol. In addition, the omission of respiratory chain substrates and the ATP-regenerating system led to a 93% inhibition of uptake, suggesting that leucine uptake may occur by an active transport mechanism.     

Effect of inhibition of protein synthesis on lipid metabolism in Lactobacillus plantarum.

In Lactobacillus plantarum 17-5, lipid synthesis appears to be correlated with protein synthesis. Inhibition of protein synthesis by chloramphenicol (50 mug/ml) caused the nearly simultaneous inhibition of incorporation of radioactive oleic acid into polar lipids before the cessation of growth. In addition, de novo fatty acid synthesis, as determined by the incorporation of radioactive acetate into cellular lipids, was also inhibited. Removal of the antibiotic resulted in the resumption of growth, protein synthesis, and polar lipid synthesis. Inhibition of protein synthesis by leucine deprivation also produced a marked reduction in the incorporation of radioactive oleic acid into the total polar lipids at about the same time that growth stopped (30 to 60 min after the removal of leucine). However, the different classes of lipids behaved differently. For example, the incorporation of oleic acid into cardiolipin was inhibited immediately upon removal of leucine from the cultures, whereas incorporation into phosphatidyl-glycerol was maintained at near normal rates for 60 min after the removal of leucine and then ceased. In contrast, the accumulation of radioactive oleic acid in a neutral lipid identified as diglyceride occurred to a much greater extent in leucine-deprived cultures than in control (+ leucine) cultures. Upon addition of leucine to leucine-deprived cultures, the rates of synthesis of phosphatidyl-glycerol and cardiolipin returned to normal; the amount of radioactivity in the diglyceride fraction decreased to normal levels concomitantly with increased phospholipid synthesis.     

Effects of chloramphenicol isomers and erythromycin on enzyme and lipid synthesis induced by oxygen in wild-type and petite yeast

The synthesis of mitochondrial enzymes induced by exposure of anaerobically grown, lipid-depleted Saccharomyces cerevisiae to oxygen is inhibited by d(-)-threo-chloramphenicol and erythromycin. The concentration of these antibiotics required to cause 50% inhibition of this synthesis is less than 1 mm; this is also approximately the concentration required to inhibit by the same amount mitochondrial protein synthesis in situ. The synthesis of unsaturated fatty acids, ergosterol, and phospholipid induced by aeration is inhibited by d(-)-threo-chloramphenicol at high concentrations (12 mm) but is unaffected by erythromycin. l(+)-threo-Chloramphenicol affects neither enzyme nor lipid synthesis and is without effect on mitochondrial protein synthesis in situ. All three compounds inhibit the oxidative activity of isolated mitochondria; the chloramphenicol isomers also inhibit phosphorylation. In a euflavine-derived petite mutant, lacking mitochondrial protein synthesis and respiration, aeration results in the normal development of lipid in the cells, but no synthesis of mitochondrial enzymes. d(-)-threo-Chloramphenicol does not inhibit lipid synthesis in these cells. Thus inhibition of mitochondrial protein synthesis with erythromycin or genetic deletion of mitochondrial protein synthesis results in loss of the capacity to synthesize enzymes during aeration. d(-)-threo-Chloramphenicol, as well as inhibiting induced enzyme formation, inhibits lipid synthesis induced by oxygen. It is unlikely that the latter effect of chloramphenicol is due to inhibition of energy production and transformation, to direct effects on lipid synthesis, or to an inhibition of mitochondrial protein synthesis. It is, however, an effect not shared with the l isomer.     

Catabolite repression of the formation of precursors of electron transfer complexes III and IV in adapting bakers' yeast: dependence upon a mitochondrially translated repressor.

When bakers' yeast cells which had been grown anaerobically in galactose were aerated in the presence of 10% glucose, they showed a 40% decrease in $\text{in}\text{vivo}$ [¹⁴C]-leucine incorporation into a washed mitochondrial membrane fraction compared with cells which had been aerated in a low glucose medium. The observed catabolite repression of membrane protein synthesis was primarily due to a decrease in cytoplasmic translational activity, but this repression was entirely dependent upon concomitant mitochondrial translation. The inductions of reduced coenzyme Q cytochrome $\text{c}$ reductase (complex III) and of cytochrome $\text{c}$ oxidase (complex IV) activities were repressed 30 and 60%, respectively, by aeration of the cells for 8 hours in 10% glucose. The catabolite repression of the formation of these two inner membrane complexes was again shown to be dependent upon concomitant mitochondrial translation. Both the amino acid incorporation and enzyme induction data suggest that catabolite repression of both cytoplasmically and mitochondrially translated mitochondrial membrane proteins is mediated through a mitochondrially translated repressor.     

Brugia pahangi: inhibition of protein synthesis

The effects of inhibitors of protein synthesis and electron transport on the incorporation of [14C]leucine and [35S]methionine into protein by the filarial worm Brugia pahangi have been investigated. Cycloheximide inhibits the accumulation of both [14C]leucine and [35S]methionine by the worms and their incorporation into protein. In addition, inhibitors of electron transport and some anti-parasitic compounds also significantly inhibit filarial protein synthesis. Antimycin A and cyanide inhibit [14C]leucine incorporation into protein 63 and 72%, respectively, without affecting either motility or lactate production. Interestingly, the anti-malarial compounds chloroquine and quinacrine also significantly inhibit both accumulation and incorporation of [14C]leucine by B. pahangi. In addition, fluorographs of sodium dodecyl sulfate-polyacrylamide gels of homogenates from filariids incubated in [35S]methionine and cycloheximide with and without chloramphenicol indicate that there is a discrete population of proteins, possibly mitochondrial in origin, that are synthesized in the presence of cycloheximide and are not inhibited by chloramphenicol.     

Effect of drugs which inhibit cholesterol synthesis on syncytia formation in vero cells infected with measles virus

We found that nontoxic doses of two inhibitors of cholesterol synthesis, namely W-7 and cerulenin, delayed syncytia formation in vero cells infected with measles virus. To correlate syncytia formation and lipidic membrane changes induced by these drugs, we labelled cell lipids with [14C]acetate. Measles virus infection increased the incorporation of radiolabel into fatty acids, triacylglycerol, cholesterol ester, and decreased its incorporation into cholesterol and 1,2-diacylglycerol. The ratios phosphatidylcholine/sphingomyelin and free cholesterol/lanosterol-dihydrolanosterol also decreased during the infection. W-7 and cerulenin greatly altered lipid metabolism. Both decreased the phosphatidylcholine to sphingomyelin and the cholesterol to lanosterol-dihydrolanosterol ratios. Z-D-Phe-L-Phe-L-Gly, a tripeptide which corresponds to the N-terminal sequence of the viral fusion protein (responsible for syncytia formation) and which inhibits virus-induced cell fusion without affecting virus synthesis also perturbed cholesterol metabolism. The tripeptide reversed the phosphatidylcholine to sphingomyelin ratio in infected cells. At non-toxic doses, W-7 inhibited the synthesis of infectious virus. Cerulenin which inhibited strongly the lipid synthesis did not. Finally, the well characterized inhibitors of cholesterol synthesis, mevinolin, ketoconazole and miconazole were shown to inhibit the syncytia formation. We conclude that the inhibition of syncytia by W-7 and cerulenin is associated with their capacity to alter the cholesterol metabolism, whereas the antiviral effect of W-7 does not seem related to this capacity.     

Adriamycin disrupts phosphatidylserine import into the mitochondria of permeabilized CHO-K1 cells

The action of adriamycin (an inhibitor of precursor protein import into mitochondria) upon phosphatidylserine (PtdSer) import into mitochondria was examined in permeabilized CHO-K1 cells. The decarboxylation of nascent PtdSer to phosphatidylethanolamine was used as an indicator reaction for the lipid translocation process. Adriamycin was without effect upon new PtdSer synthesis but blocked the time- and translocation-dependent decarboxylation of this lipid at the mitochondrial inner membrane of permeabilized cells. The effect of adriamycin was concentration-dependent with an IC50 of 150 microM and was not due to direct inhibition of PtdSer decarboxylase. To determine at which level of PtdSer transport adriamycin was working, the adriamycin-treated permeabilized cells were incubated with 1-acyl-2-[N-(6-[(7-nitrobenz-2-oxa-1,3-diazo-4-yl)] aminocaproyl)]phosphatidyl[1'-14C] serine (NBD-Ptd[1'-14C]Ser), and its decarboxylation was determined. Since the NBD-Ptd[1'-14C]Ser freely partitions into all cell membranes, it can partition into the outer mitochondrial membrane in an ATP-independent fashion. The NBD-Ptd[1'-14C]Ser was readily decarboxylated in an ATP-independent manner in permeabilized cells. Adriamycin inhibited the decarboxylation of NBD-Ptd[1'-14C]Ser, thereby indicating that it can act upon lipid transport processes between the outer and inner mitochondrial membrane.     

A possible ribosomal-directed regulatory system in Euglena gracilis. Chlorophyll synthesis

Cycloheximide at concentrations of 0.1-100mum stimulated chlorophyll synthesis when dark-grown cells of Euglena were illuminated. Chloramphenicol (1-4mm) inhibited chlorophyll synthesis. The effect of cycloheximide on the incorporation of [(14)C]leucine into material insoluble in trichloroacetic acid, and its failure to affect the incorporation of [(32)P]orthophosphate into such material in short incubations, are interpreted as evidence that cycloheximide specifically inhibits protein synthesis by 80S ribosomes. Since the inhibitory effect of chloramphenicol on chlorophyll synthesis is counteracted by the presence of cycloheximide, it is suggested that chlorophyll synthesis is subject to control by a cytoplasmic repressor synthesized on 80S ribosomes, and to a de-repressor synthesized on 70S ribosomes.     

Differential long-term effects of d-chloramphenicol on the biogenesis of mitochondria in normal and regenerating rat liver

1. Normal and partially hepatectomized rats (150g) were injected daily with d-chloramphenicol (20mg) for a period of 4 weeks, in order to investigate whether defective mitochondria could be induced in vivo in higher organisms as in yeast, and to measure the degree of inhibition of the mitochondrial function thus obtained. 2. The antibiotic did not affect growth and increased the amount of liver protein without changing the mitochondrial yield. 3. The respiration of isolated mitochondria from regenerated liver (regeneration completed) with succinate, α-oxo-glutarate, isocitrate and malate, was decreased in the chloramphenicol-treated rats, whereas in normal liver the antibiotic increased the mitochondrial oxygen consumption with succinate and did not significantly change the respiration with other substrates. 4. Mitochondrial cytochromes and respiratory enzymes were also decreased in amount in regenerated liver from the treated rats and enhanced in normal liver. 5. The protein specific radioactivities of most mitochondrial and microsomal subfractions, 30min after an injection of [¹⁴C]leucine, were decreased in regenerated liver under the action of chloramphenicol. Conversely, the incorporation of [¹⁴C]leucine into proteins of most subfractions in incubations of liver slices was enhanced in the case of normal rats treated with the antibiotic. 6. It is concluded that in regenerated liver chloramphenicol induces functionally defective mitochondria by inhibiting their biogenesis, whereas in normal liver the stimulation of respiration and protein synthesis is probably a secondary detoxication response.     

Effect of cycloheximide on protein and ribonucleic acid synthesis in cultured human lymphocytes

1. Phytohaemagglutinin stimulates the transformation into blast cells of human lymphocytes incubated in vitro. This transformation is accompanied by an increase in the incorporation of [(14)C]leucine into protein and [(3)H]uridine into RNA. 2. The incorporation of [(14)C]leucine by cultures grown in the presence or absence of phytohaemagglutinin is inhibited to the same extent by cycloheximide, a known inhibitor of protein synthesis. 3. Lymphocytes grown without phytohaemagglutin synthesize mainly non-ribosomal RNA. [(3)H]Uridine incorporation by these cells was increased by cycloheximide. 4. Lymphocytes incubated with phytohaemagglutinin begin to synthesize substantial quantities of ribosomal RNA. Under these conditions [(3)H]uridine incorporation was partially inhibited by cycloheximide. This inhibition is shown to be largely a result of inhibition of the synthesis of ribosomal RNA.     

Effect of cobalt on the synthesis and degradation of hepatic catalse in vivo

1. The administration of CoCl(2) to rats caused a decrease in hepatic catalase activity as well as a decrease in the amount of catalase protein as measured by immunological assay. The mitochondrial enzyme decreased progressively over 2 days, whereas the cytosol enzyme decreased over 12h and then remained essentially unchanged for 2 days after a single injection of cobalt. 2. Incorporation of [(14)C]glycine into catalase haem was dramatically decreased by a single injection of cobalt, but that into catalase protein remained essentially unaltered. 3. Incorporation of [(3)H]leucine into liver protein increased in rats in a steady state receiving a daily injection of cobalt, which was in contrast with a marked inhibition observed in 5-amino[(3)H]laevulinate incorporation. 4. The initial rate of [(3)H]leucine incorporation into mitochondrial and cytosol catalase did not alter or was slightly depressed in the cobalt-treated animals, whereas the incorporation of 5-amino[(3)H]laevulinate into mitochondrial and cytosol catalase was conspicuously decreased, indicating that haem synthesis was limiting catalase formation. 5. The degradation rate of catalase protein, as measured by a double-labelling method, was not changed by the cobalt treatment.     

Metabolism of tween-Fatty Acid esters by cultured soybean cells : kinetics of incorporation into lipids, subsequent turnover, and associated changes in endogenous Fatty Acid synthesis

Uptake of Tween-fatty acid esters and incorporation of the fatty acids into lipids by soybean (Glycine max [L.] Merr.) suspension cultures was investigated, together with subsequent turnover of the incorporated fatty acids and associated changes in endogenous fatty acid synthesis. Tween uptake was saturable, and fatty acids were rapidly transferred from Tweens to all acylated lipids. Patterns of incorporation into glycerolipids were similar in cells treated with Tweens carrying [1-¹⁴C]-fatty acids and in cells treated with [1-¹⁴C]acetate, indicating that exogenous fatty acids were used for glycerolipid synthesis essentially as if they had been made by the cell. In Tween-treated cells neutral lipids (which include Tweens) initially accounted for the majority of lipid radioactivity. Radioactivity was then rapidly transferred to glycerolipids. A transient pool of free fatty acids accounting for up to 10% of lipid radioactivity was observed. This was consistent with the hypothesis that fatty acids are transferred from Tweens to lipids by deacylation of the Tweens, creating a pool of free fatty acids which are then used for lipid synthesis. Sterols were only slightly labeled in cells treated with Tweens, but accounted for nearly 50% of lipid radioactivity in cells treated with acetate. This suggested very little degradation and reutilization of the radioactive fatty acids in cells treated with Tweens. In cells treated with either [1-¹⁴C]acetate or Tween-[1-¹⁴C]-18:1, 70% of the initial fatty acid radioactivity remained in fatty acids after a 100 hour chase. By contrast, fatty acids not normally present disappeared more rapidly, suggesting differential treatment of such fatty acids compared with those normally present. Cells which had incorporated large amounts of exogenous fatty acids altered fatty acid synthesis in three distinct ways: (a) amounts of [1-¹⁴C]acetate incorporated into fatty acids were reduced; (b) cells incorporating exogenous unsaturated fatty acids increased the proportion of [1-¹⁴C]acetate partitioned into saturated fatty acids, while the converse was true of cells which had incorporated exogenous saturated fatty acids; (c) desaturation of 18:1 to 18:2 and 18:3 was reduced in cells which had incorporated unsaturated fatty acids. These results suggest that Tween-fatty acid esters will be useful for supplying fatty acids to cells for a variety of studies related to fatty acid or membrane metabolism.     

Lipid metabolism in human endothelial cells

Although lipids are largely involved in cardiovascular physiopathology, the lipid metabolism in endothelial cells remains largely unknown. Human umbilical vein endothelial cells (HUVECs) were used to investigate the metabolism of complex lipids. The membrane phospholipid homeostasis results from both de novo synthesis and remodelling that ensures the fine tuning of the phospholipid fatty acid composition. Using [(3)H]-glycerol and phosphoderivatives we showed the efficiency of glycerolipid synthesis from glycerol (0.9 nmol h(-1) mg proteins(-1)), but not from its phosphorylated form suggesting the requirement of a functional glycerol kinase in HUVECs. Conversely, the synthesis of triacylglycerols was very low (less than 5% of phospholipid synthesis). The incorporation rate of fatty acids into phospholipids showed that there is a specific fate for each fatty acid in respect to its chain length and saturation level. Moreover in steady state condition, increasing the long chain omega3 polyunsaturated fatty acids in the medium resulted in an increased polyunsaturated/saturated ratio in phospholipids (from 0.42 to 0.63). [(14)C]O(2) was produced form either [(14)C]-glucose or [(14)C]-palmitate indicating the functionality of the oxidation pathways, although beta-oxidation was less efficient than glucose oxidation. The endothelial cell lipid metabolism involves conventional pathways, with functional rates largely slower than in hepatocytes or in cardiomyocytes.