Uptake of Glucose-1-14C by Pullularia pullulans

Pullularia pullulans cells were grown in a medium containing yeast extract, malt extract, glucose, and nutrient salts, in addition to glucose-1-(14)C. The lipids extracted from the cells were fractionated by use of a single column packed with silicic acid. Of the total radioactive carbon added to the culture medium, the neutral lipid fractions contained 24.8%, whereas the phospholipid portions contained only 2.1%. The largest amount (16.5%) of (14)C among the neutral lipids was found in the fraction containing the free sterols. Among the phospholipids, the largest amount (1.1%) was found in phosphatidylserine and phosphatidylethanolamine. The second largest amount (9.6%) of the total (14)C used was found in trehalose, followed by carbon dioxide (7.3%).     

Characterization of a long-chain 14C-labelled alcohol resulting from a plant enzyme-catalysed reaction with S-adenosyl[methyl-14C]methionine

A particulate enzyme from Phaseolus aureus seedlings catalyses the incorporation of radioactivity from S-adenosyl[Me-(14)C]methionine into several lipid acceptors present in the enzyme preparation. The structure of one of the radioactive lipids has been elucidated by using mass, n.m.r. and i.r. spectral data. This compound has a molecular formula C(28)H(57)OH, is a saturated primary alcohol and has a single branch of one methyl group in the interior of the hydrocarbon chain. The results of a Kuhn-Roth degradation demonstrate that the branch methyl group is the one derived from S-adenosylmethionine.     

Phospholipid composition and [14C]glycerol incorporation into glycerolipids of toad retina and brain

The phospholipid composition as well as the in vivo [14C]glycerol uptake in lipids was found to be similar in the toad brain and retina. The choroid lipid labeling was markedly different. An in vitro time-course study of [14C]glycerol incorporation in toad retina lipids disclosed that under the conditions of these experiments: (1) retina is able to rapidly synthesize phosphatidic acid from the radioactive precursor; (2) the sequence phosphatidic acid-diacylglycerol-triacylglycerol operates; (3) a high rate of phosphatidylinositol de novo biosynthesis takes place; (4) phosphoglycerides of choline and of ethanolamine are also heavily labeled after a lag period; (5) in vivo labeling profiles resembled those obtained in vitro mainly regarding phosphatidylinositol biosynthesis; and (6) the presence of glycerol kinase in the CNS is suggested.     

Synthesis of nuclear lipids in L2C leukemic lymphocytes

We previously reported that propiconazole strongly inhibits cholesterol synthesis, but not cell division in a stimulated cell, the human lymphocyte cultured with phytohemagglutinin, showing that newly synthesized cholesterol is not necessary for cell division. In this study we labeled the L2C leukemic guinea pig lymphocyte, a naturally stimulated cell, with [2-14C]acetate, and compared the composition of newly synthesized lipids isolated from nuclei and whole cells (or microsomes). We observed that the proportion of cholesterol in labeled non-saponifiable lipids extracted from nuclei was lower than in non-saponifiable lipids isolated from whole cells, whereas the proportion of squalene and polar lipids was higher. By analyzing total lipid extracts, the polar lipids were identified as alkylglycerols, and the above mentioned distribution of constituents was confirmed. The identification of alkylglycerols was also supported by the comparison of radioactive lipid composition after labeling cells with three different lipid precursors: [2-14C]mevalonate, [2-14C]acetate and [2-14C]stearate. When cells were labeled in the presence of dodecylimidazole, the percentage of squalene and alkylglycerols decreased in nuclear lipids, but was not altered when cells were cultured in the presence of propiconazole, a cholesterol synthesis inhibitor which does not affect cell division of human stimulated lymphocytes. We have shown that dodecylimidazole inhibited alkylglycerol biosynthesis and squalene uptake by the nucleus, suggesting that these compounds could play a role in the regulation of cell division.     

In vitro synthesis of a lipid-linked trisaccharide involved in synthesis of enterobacterial common antigen.

The heteropolysaccharide chains of enterobacterial common antigen (ECA) are made up of linear trisaccharide repeat units with the structure----3)-alpha-D-Fuc4NAc-(1----4)- beta-D-ManNAcA-(1----4)-alpha-D-GlcNAc-(1----, where Fuc4NAc is 4-acetamido-4,6-dideoxy-D-galactose, ManNAcA is N-acetyl-D-mannosaminuronic acid, and GlcNAc is N-acetyl-D-glucosamine. The assembly of these chains involves lipid-linked intermediates, and both GlcNAc-pyrophosphorylundecaprenol (lipid I) and ManNAcA-GlcNAc-pyrophosphorylundecaprenol (lipid II) are intermediates in ECA biosynthesis. In this study we demonstrated that lipid II serves as the acceptor of Fuc4NAc residues in the assembly of the trisaccharide repeat unit of ECA chains. Incubation of Escherichia coli membranes with UDP-GlcNAc, UDP-[14C]ManNAcA, and TDP-[3H]Fuc4NAc resulted in the synthesis of a radioactive glycolipid (lipid III) that contained both [14C]ManNAcA and [3H]Fuc4NAc. The oligosaccharide moiety of lipid III was identified as a trisaccharide by gel-permeation chromatography, and the in vitro synthesis of lipid III was dependent on prior synthesis of lipids I and II. Accordingly, the incorporation of [3H]Fuc4NAc into lipid III from the donor TDP-[3H]Fuc4NAc was dependent on the presence of both UDP-GlcNAc and UDP-ManNAcA in the reaction mixtures. In addition, the in vitro synthesis of lipid III was abolished by tunicamycin. Direct conversion of lipid II to lipid III was demonstrated in two-stage reactions in which membranes were initially incubated with UDP-GlcNAc and UDP-[14C]ManNAcA to allow the synthesis of radioactive lipid II. Subsequent addition of TDP-Fuc4Nac to the washed membranes resulted in almost complete conversion of radioactive lipid II to lipid III. The in vitro synthesis of lipid III was also accompanied by the apparent utilization of this lipid intermediate for the assembly of ECA heteropolysaccharide chains. Incubation of membranes with UDP-[3H]GlcNAc, UDP-ManNAcA, and TDP-Fuc4NAc resulted in the apparent incorporation of isotope into ECA polymers, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography. In addition, the in vitro incorporation of [3H]Fuc4NAc into ECA heteropolysaccharide chains was demonstrated with ether-treated cells that were prepared from delta rfbA mutants of Salmonella typhimurium. These mutants are defective in the synthesis of TDP-Fuc4NAc; as a consequence, they are also defective in the synthesis of lipid III and they accumulate lipid II. Accordingly, incubation of ether-permeabilized cells of delta rfbA mutants with TDP-[3h]Fuc4NAc resulted in the incorporation of isotope into both lipid III and ECA heteropolysaccharide chains.     

Microbial transformation of 14C-labeled 2,4,6-trinitrotoluene in an activated-sludge system

The fate of 14C-labeled 2,4,6-trinitrotoluene (TNT) in an activated-sludge system was investigated. No [14C]TNT could be detected in the contents of an aerated reactor after 3 to 5 days of incubation. No significant 14CO2 was formed, and the radioactivity was about equally divided between the floc and the supernatant. The radioactive carbon present in the microflora was mainly associated with the lipid and protein components, but the characteristic constituents of these compounds (e.g., fatty acids and amino acids) were not radioactive. The major part of the 14C present in the lipid and protein fractions was found in precipitates that formed in both fractions. The solubility properties and infrared spectra of these precipitates suggested that they are macromolecular structures of the polyamide type formed by the reaction of TNT biotransformation products with lipids, fatty acids, and protein constituents of the microbial flora. This hypothesis is further supported by the correspondence of the infrared spectrum of the lipid precipitate with that of a model compound synthesized from TNT transformation products and lipid precursors. The resistance of these macromolecules to further biodegradation was paralleled by the reported resistance to microbial attack of polyamides containing similar linkages.     

Microbial transformation of 14C-labeled 2,4,6-trinitrotoluene in an activated-sludge system.

The fate of 14C-labeled 2,4,6-trinitrotoluene (TNT) in an activated-sludge system was investigated. No [14C]TNT could be detected in the contents of an aerated reactor after 3 to 5 days of incubation. No significant 14CO2 was formed, and the radioactivity was about equally divided between the floc and the supernatant. The radioactive carbon present in the microflora was mainly associated with the lipid and protein components, but the characteristic constituents of these compounds (e.g., fatty acids and amino acids) were not radioactive. The major part of the 14C present in the lipid and protein fractions was found in precipitates that formed in both fractions. The solubility properties and infrared spectra of these precipitates suggested that they are macromolecular structures of the polyamide type formed by the reaction of TNT biotransformation products with lipids, fatty acids, and protein constituents of the microbial flora. This hypothesis is further supported by the correspondence of the infrared spectrum of the lipid precipitate with that of a model compound synthesized from TNT transformation products and lipid precursors. The resistance of these macromolecules to further biodegradation was paralleled by the reported resistance to microbial attack of polyamides containing similar linkages.     

Signals in the activation of opioid mu-receptors by loperamide to enhance glucose uptake into cultured C2C12 cells.

In an attempt to understand the signal pathways of opioid mu-receptors for glucose metabolism, we used loperamide to investigate the glucose uptake into the myoblast C2C12 cells. Loperamide enhanced the uptake of radioactive deoxyglucose into C2C12 cells in a concentration-dependent manner that was abolished in cells pre-incubated with naloxone or naloxonazine at concentrations sufficient to block opioid mu-receptors. Pharmacological inhibition of phospholipase C (PLC) by U73122 resulted in a concentration-dependent decrease in loperamide-stimulated uptake of radioactive deoxyglucose into C2C12 cells. This inhibition of glucose uptake by U73122 was specific since the inactive congener, U73343, failed to modify loperamide-stimulated glucose uptake. Moreover, both chelerythrine and GF 109203X diminished the action of loperamide at concentrations sufficient to inhibit protein kinase C (PKC). The obtained data suggest that an activation of opioid mu-receptors in C2C12 cells by loperamide may increase glucose uptake via the PLC-PKC pathway.     

Desaturation of oleate-[14C] in leaves of barley

Etiolated barley leaves when exposed to light desaturate oleate-[¹⁴C] to linoleate. The production of substantial amounts of radioactive linolenate was found only in very young, tightly rolled leaves. In oleate-[¹⁴C] pulse experiments, radioactive linolenate first appeared in phosphatidylcholine (PC) and only after a lag period did it begin to accumulate in monogalactosyldiacylglycerol (MGDG). The results indicate that in young, immature barley leaves linolenate is synthesized from oleate on the parent lipid, PC, and is then transferred to MGDG.     

Distribution of radioactive glycerol and fatty acids among adipose tissue triglycerides after administration of glucose-U-14C

Adipose lipid obtained from fed rats 15 or 60 min after injection of radioactive glucose was separated into 10 triglyceride classes of differing fatty acid compositions. The distribution among these classes of total and radioactive triglyceride-glycerol was determined and found to be the same. Thus newly synthesized adipose triglycerides resemble in kind and proportion the triglycerides which exist in the tissue. This finding is in accord with the concept that the structures of adipose triglycerides are stable over long periods and that the turnover rate of the several triglyceride species are similar. After administration of radioactive glucose, the specific activity of saturated fatty acids was higher in the more saturated triglyceride species. These data indicate that newly formed saturated acids do not mix completely with all adipose tissue fatty acids available for esterification. Fatty acids derived from plasma triglyceride influenced the composition of newly synthesized adipose tissue triglyceride and thus constitute an important source of adipose tissue lipid.     

Selective degradation with phospholipases D and C of radioactive isomeric spin-labelled lipids bound to guinea pig liver microsomal membranes.

Membrane-bound lipids of isolated guinea pig liver microsomal membranes were selectively enzymatically labelled with isomeric (5-, 12-, and 16-)doxyl stearic acid. After reisolation, the membranes were degraded with phospholipases D and C under conditions not requiring detergents or organic solvent activators. The degradation of membrane-bound lipids occurred according to the recognized specificity of phospholipases D and C. Temperature-induced changes of degraded membranes containing radioactive spin-labelled isomeric lipids were followed by the electron spin resonance and spectral changes correlated with the lipid composition of membranes. Discontinuities in plots of experimental spectral parameters versus temperature detected in the case of microsomal membranes before and after degradation with phospholipases D and C were attributed to lipid-protein and lipid-lipid interaction(s). On the basis of these and control experiments, discontinuity at around 10-12 degrees C was attributed to the microsomal membrane phosphatidylcholine intrinsic microsomal membrane protein interaction(s), while discontinuities detected at 19-21 degrees C approximately and at 20-30 degrees C approximately were attributed to the phase separation of Ca or Zn salts of membranous phosphatidic acid and to the similar phenomenon involving membrane-bound diglycerides respectively.     

What is the origin of the lipids of potato tuber plasmalemma?

Plasmalemma isolated from potato tuber cells was prepared according to a flotation method in a sucrose density gradient. When incubated in vitro with various radioactive lipid precursors, the plasmalemma fragments were unable to synthesize any lipid. When labelled lipid precursors ([¹⁴C]acetate of [³²P]phosphate) were furnished to potato slices, radioactive fatty acids or phospholipids were integrated into plasmalemma lipids. When incubated in a suspension of [³²P]liposomes, plasmalemma fragments accepted labelled lipids from the suspension; this exchange process was markedly stimulated by the phospholipid exchange protein prepared from the potato cytoplasmic supernatant. These results suggest that potato tuber plasmalemma is dependent on other cellular fractions for lipid synthesis and exchange.     

Transmembrane lipid transport between lecithin liposomes and neuroblastoma C1300 N18 cells

The method of double isotopic labels was used to study dynamics of lipid metabolism between neuroblastoma C 1300 N 18 A 1 cells and lecithin liposomes which contained 4.5-5 mumol of lecithin in 1 ml of the suspension. The cell lipids were labelled by radioactive carbon and cultivated on the medium with [1-14C] sodium acetate, phosphatidylcholine of liposomes was labelled by tritium. It is shown that 15-30 min long incubation with liposomes causes a sharp decrease of the cholesterol esters amount with a simultaneous fall of the free cholesterol level. The total content of phospholipids in this case remains unchanged though there occurs the noticeable exchange of labelled phospholipids between cells and liposomes. The cholesterol content in the plasma membranes of cells lowers sharply. The neuroblastoma cells are able to compensate arising changes in the cholesterol level for 45-60 min after which they progressively die. 90 min later only an insignificant part of the population (about 10% of cells) is retained.     

Effects of glycerol on VLDL secretion by the isolated rat liver.

Stimulation of VLDL production by increasing fatty acid availability is now well established. However, a possible regulatory role of glycerol, another lipid precursor, in VLDL synthesis by the liver has not yet been substaniated. The present experiments investigate this problem using the isolated perfused rat liver. [14C] Glycerol uptake and metabolism were studied at two different glycerol concentrations: 1 mumol/perfusate (control) or 1.6 mmol/perfusate. VLDL production and lipid synthesis were investigated using [14C]leucine and several labelled fatty acids as precursors in control and glycerol-overloaded livers. Neoglycogenesis and lipogenesis from glycerol carbons are negligible in our conditions. The absolute amount of glycerol, but not the precentage, taken up by the liver, increased after raising its concentration in the perfusate. A major part of exogenous (plasmatic) glycerol was esterified with endogenous (non plasmatic) fatty acids. Incorporation of radioactive fatty acids into liver or plasma lipids was lower than in the the control group. Significant differences were observed between saturated and unsaturated fatty acids used as lipid precursors. Production of VLDL as assessed by radioactive leucine and fatty acid incorporation in the VLDL of the perfusate was depressed by glycerol. Glycerol partly inhibits the normal stimulation of VLDL production by plasmatic fatty acid overload.     

The C1 and C2 domains target human type 6 adenylyl cyclase to lipid rafts and caveolae

Previous data has shown that adenylyl cyclase type 6 (AC6) is expressed principally in lipid rafts or caveolae of cardiac myocytes and other cell types while certain other isoforms of AC are excluded from these microdomains. The mechanism by which AC6 is localized to lipid rafts or caveolae is unknown. In this study, we show AC6 is localized in lipid rafts of COS-7 cells (expressing caveolin-1) and in HEK-293 cells or cardiac fibroblasts isolated from caveolin-1 knock-out mice (both of which lack prototypical caveolins). To determine the region of AC6 that confers raft localization, we independently expressed each of the major intracellular domains, the N-terminus, C1 and C2 domains, and examined their localization with various approaches. The N-terminus did not associate with lipid rafts or caveolae of either COS-7 or HEK-293 cells nor did it immunoprecipitate with caveolin-1 when expressed in COS-7 cells. By contrast, the C1 and C2 domains each associated with lipid rafts to varying degrees and were present in caveolin-1 immunoprecipitates. There were no differences in the pattern of localization of either the C1 or C2 domains between COS-7 and HEK-293 cells. Further dissection of the C1 domain into four individual proteins indicated that the N-terminal half of this domain is responsible for its raft localization. To probe for a role of a putative palmitoylation motif in the C-terminal portion of the C2 domain, we expressed various truncated forms of AC6 lacking most or all of the C-terminal 41 amino acids. These truncated AC6 proteins were not altered in terms of their localization in lipid rafts or their catalytic activity, implying that this C-terminal region is not required for lipid raft targeting of AC6. We conclude that while the C1 domain may be most important, both the C1 and C2 domains of AC6 play a role in targeting AC6 to lipid rafts.     

Lipid Metabolism in Dehydrating Peanut Kernels

Metabolism of radioactive lipids in kernels from peant plants subjected to ¹⁴C₂ under field conditions was studied during dehydration (curing) of the seeds at 22°C or 50°C. Synthesis of lipid was predominant during the first 6 to 12 hours of dehydration whereas degradation dominated between 12 to 24 hours of curing. These changes were related to the moisture content of the dehydrating kernels; a moisture range of 42 to 47% was found to be an important factor influencing the observed pattern of lipid metabolism. The results from the present study also indicate compartmentalization of lipid metabolism in dehydrating peanut kernels.     

Metabolism of [14C]citrulline in the perfused sheep and goat udder

1. A lactating-sheep mammary gland was perfused for 12h in the presence of l-[2-(14)C]-citrulline and received adequate quantities of glucose, acetate and amino acids. Two lactating-goat udders were similarly perfused in the presence of either l-[carbamoyl-(14)C,-2-(14)C]citrulline or l-[carbamoyl-(14)C,1-(14)C]citrulline and l-[4-(3)H]arginine. 2. In these experiments, [(14)C]citrulline was substantially oxidized to CO(2) and converted into arginine and proline of casein. 3. The specific radioactivities of arginine, ornithine and proline of the plasma increased after passage through the udders, demonstrating that [(14)C]citrulline is metabolized by the mammary gland. 4. The presence of two unknown radioactive metabolites of [(14)C]citrulline was detected in the perfusate. These substances were not found after incubation in vitro of oxygenated blood in the presence of the radioactive precursor. 5. From these experiments, it is concluded that citrulline is metabolized in mammary tissue by way of arginine to urea, ornithine and proline.     

The effect of cadmium on lipid and fatty acid biosynthesis in tomato leaves

This research aims to examine the effect of cadmium uptake on lipid composition and fatty acid biosynthesis, in young leaves of tomato treated seedlings (Lycopersicon esculentum cv. Ibiza F1). Results in membrane lipids investigations revealed that high cadmium concentrations affect the main lipid classes, leading to strong changes in their composition and fatty acid content. Thus, the exposure of tomato plants to cadmium caused a concentration-related decrease in the unsaturated fatty acid content, resulting in a lower degree of fatty acid unsaturation. The level of lipid peroxides was significantly enhanced at high Cd concentrations. Studies of the lipid metabolism using radioactive labelling with [1-¹⁴C]acetate as a major precursor of lipid biosynthesis, showed that levels of radioactivity incorporation in total lipids as well as in all lipid classes were lowered by Cd doses. In total lipid fatty acids, [1-¹⁴C]acetate incorporation was reduced in tri-unsaturated fatty acids (C16:3 and C18:3); While it was enhanced in the palmitic (C16:0), palmitoleic (C16:1), stearic (C18:0) and linoleic (C18:2) acids. [1-¹⁴C]acetate incorporation into C16:3 and C18:3 of galactolipids [monogalactosyldiacylglycerol (MGDG) and digalactosyldiacylglycerol (DGDG)] and some phospholipids [phosphatidylcholine (PC) and phosphatidylglycerol (PG)] was inhibited by Cd stress. Our results showed that in tomato plants, cadmium stress provoked an inhibition of polar lipid biosynthesis and reduced fatty acid desaturation process.     

Elongation of (omega-14C)oleic acid and (omega-14C)nervonic acid.

During feeding experiments with [omega-14C]oleic acid and [omega-14c]nervonic acid to adult rats, 14C-labelled C26, C28 and C30 fatty acids were recovered from the intestinal mucosa, liver, plasma, kidney and stools. The structures of these fatty acids were determined by g.l.c., radio-g.l.c. and mass spectrometry. The Schmidt and Ginger degradation methods indicated that most of the 14C found in these extra-long fatty acids remained in the omega position. These radioactive extra-long fatty acids were found mainly in the polar lipids of rats killed 3 or 15 h after being fed on labelled oleic acid or nervonic acid. Rats killed 63 h later yielded only traces of these extra-long fatty acids. When the rats were given antibiotics or received the same radioactive fatty acids by intravenous injection, the labelled extra-long fatty acids could not be detected in any of the tissues. We conclude that they were probably synthesized by elongation of oleic acid and nervonic acid by intestinal micro-organisms (probably yeasts) and then absorbed by the intestinal mucosa.