A novel synthesis of ceramide from lignoceric acid and sphingosine by rat brain preparation; the amide formation requires a pyridine nucleotide.

The conversion of free lignoceric acid and sphingosine to lignoceroyl sphingosine (ceramide) by rat brain particulate fraction and two cytosolic factors, one heat-stable and the other heat-labile, requires pyridine nucleotide. This enzymatic reaction is apparently different from two previously published enzymic reactions, microsomal sphingosine:acyl CoA acyltransferase and the reverse reaction of lysosomal ceramidase. The reaction is strongly inhibited by common respiratory chain inhibitors, KCN, Antimycin A and sodium azide, this indicates the involvement of an electron-transfer system. From these observations it appears that the brain ceramide synthesis described above is catalyzed by an enzyme system which involves a mechanism for amide formation which has not been previously characterized.     

α-Hydroxylation and oxidation of lignoceric acid in brain: The role of heat-stable and heat-labile factors

Our previous investigations disclosed that the heat-stable and heat-labile factors obtained from brain cytosol are required for -hydroxylation and oxidation of lignoceric acid by rat brain particulate fraction. The heat-stable factor was recently found to contain glucose-6-phosphate, N-acetylaspartate, glutamate, aspartate, glutamine, inorganic phosphate and low levels of adenosine nucleotide as active components. A combination of these compounds was as effective as the crude heat-stable factor for enzymic activity. Using these compounds, we reinvestigated the requirement for the heat-labile factor. With crude heat-stable factor there was an absolute requirement for the heat-labile factor; however, with various combinations of the individual components of the heat-stable factor, some degree of activity was obtained without the heat-labile factor. When aspartate or one of its derivatives, N-acetylaspartate or oxaloacetate, was used in place of the heat-stable factor, the activity was relatively low but highly stimulated by the addition of heat-labile factor. On the other hand, higher activity was obtained when glutamate or one of its derivatives, glutamine or -ketoglutarate, was used without heat-labile factor. The addition of heat-labile factor to this system did not stimulate the activity. When studying the aspartate family, we discovered that the requirement for the heat-labile factor varied in a descending order: N-acetylaspartate > aspartate > oxaloacetate. Lignoceric acid oxidation was further characterized with rat brain particulate fraction, NADPH, Mg²⁺, glutamate, inorganic phosphate, and AMP without heat-stable and heat-labile factors. It was found that the requirement for NADPH was also partially eliminated with glutamate but not aspartate. The effects of various inhibitors, such as inhibitors of the electron transfer system, oxidative phosphorylation, the enzymes involved in citric acid cycle, and glycolysis, suggest that the heat-stable factor is involved in producing ATP or other high energy compounds to be used for the activation of lignoceric acid. ATP added to the system in place of heat-stable factor resulted in less than one-half of the lignoceric acid oxidation.     

α-Hydroxylation of Fatty Acids in Brain: Characterization of Heat-Labile Factor

Abstract: The particulate fraction, heat-labile factor, heat-stable factor, and NADPH are essential for the conversion of lignoceric acid (tetracosanoic acid) to cerebronic acid (α-hydroxylignoceric acid). The heat-labile factor was extracted from calf cerebellum and partially purified in four steps: ammonium sulfate precipitation, hydroxylapatite chromatography, isoelectric focusing, and NAD-Agarose affinity chromatography. The specific activity of the heat-labile factor was increased 105-fold during the last three steps, with a yield of 37% of the activity. One major and several minor bands were visible when the preparation was examined by SDS-polyacrylamide gel electrophoresis with Coomassie blue staining. The major band corresponded to a protein of molecular weight 32,700, and the minor bands corresponded to proteins of molecular weights 62,000 and 67,000. The activity was lost when the heat-labile factor was incubated with 1 mM- N -ethylmaleimide. This inhibition was prevented by preincubating the heat-labile factor with 1 mM-NADH. These observations indicate that the heat-labile factor contains a sulfhydryl group which is essential for activity, and that it is located at or near the binding site for the pyridine nucleotide.     

Purification and Characterization of the Heat-Stable Factors Essential for the Conversion of Lignoceric Acid to Cerebronic Acid and Glutamic Acid: Identification of N-Acetyl-l-Aspartic Acid

Abstract: The conversion of lignoceric acid to cerebronic acid, ceramides, cerebrosides, and glutamic acid is catalyzed by a rat brain particulate preparation. The heat-stable factor, prepared from calf cerebellum, together with the heat-labile factor, a pyridine nucleotide, and Mg²⁺ are essential to all of these metabolic pathways. Our previous work showed that the heat-stable factor is composed of at least two components, HSF-1 and HSF-2, and identified HSF-2 as d -glucose-6-phosphate. In the current investigation, HSF-1 was further purified and found to be N -acetyl- l -aspartic acid. In addition, it was discovered that a third component, HSF-3, is also required for heat-stable factor activity. A reconstituted system composed of N -acetylaspartic acid, glucose-6-phosphate, and HSF-3 fully replaced the heat-stable factor essential for the conversion of lignoceric acid to cerebronic acid and glutamic acid. The reconstituted heat-stable factor did not show the initial time lag always observed with the crude heat-stable factor.     

CONVERSION OF [1-14C]PALMITIC ACID TO [1-14C]HEXADECANOL BY DEVELOPING RAT BRAIN CELL-FREE PREPARATIONS

—The conversion of [l-¹⁴C]palmitic acid to [1-¹⁴C]hexadecanol has been demonstrated with a cell-free system from developing rat brain. ATP, Coenzyme A and Mg²⁺ were required for the activity. Fatty aldehyde was found to be an intermediate in this reaction. The conversion of fatty acid to fatty alcohol was mainly localized in the microsomal fraction and the formation of hexadecanol showed absolute specificity towards NADPH while fatty aldehyde was formed even in the absence of exogenous reduced pyridine nucleotides. The brain microsomes showed maximal activity with stearic acid and the activities with palmitic and oleic acids were 65% and 38% respectively of that with stearic acid. This enzymic reduction increased with age and showed a maximum in the 15-day old rat brain.     

A microsomal fatty acid synthetase coupled to acyl-CoA reductase in Euglena gracilis

Microsomal particles from dark-grown Euglena gracilis incorporated malonyl-CoA into fatty acids and fatty alcohols in the presence of acetyl-CoA, NADH, NADPH, and ATP with an optimum pH of 8.0. Schmidt degradation of the individual fatty acids derived from [l,3-¹⁴C]malonyl-CoA showed that the microsomal fatty acid synthesis was a de novo type. Detailed analysis of the products formed in the absence of various cofactors showed that the role of ATP was specifically in the formation of fatty alcohols and that fatty acid reduction specifically required NADH.The major aliphatic chains synthesized by the microsomes were C₁₆, C₁₈, and C₁₄ in both the acyl portions and alcohols. Although relative concentrations of acetyl-CoA and malonyl-CoA influenced the chain length distribution of products, C₁₆remained the major product in both the alcohol and the acid fractions. Effects of NADPH and NADH concentrations on malonyl-CoA incorporation suggested that the two reductive steps involved in the microsomal fatty acid synthesis have different pyridine nucleotide specificity. The apparent K_m for malonyl-CoA was 4.2 × 10^?4m. Based on the experimental results a mechanism is suggested by which carbon is channeled into wax esters under conditions of nutritional abundance in dark-grown E. gracilis.     

Fatty acid α-hydroxylation and its relation to myelination

Summary -Hydroxylation is an enzymatic reaction by which long-chain fatty acids are converted to their -hydroxy derivatives. This reaction, in animals, can be detected only in developing brain and is the rate-determining step in the synthesis of hydroxycerebroside, which is an indispensable and abundant myelin lipid. In addition to a particulate fraction from brain, two cytoplasmic factors, one heat-stable and the other heat-labile, are required for -hydroxylation. During the past eight years we have been investigating -hydroxylation. Our progress is summarized and discussed here.     

Metabolism of glucose-6-phosphate and utilization of multiple metabolites for fatty acid synthesis by plastids from developing oilseed rape embryos

The aim of this work was to investigate the partitioning of imported glucose 6-phosphate (Glc6P) to starch and fatty acids, and to CO₂ via the oxidative pentose phosphate pathway (OPPP) in plastids isolated from developing embryos of oilseed rape (Brassica napus L.). The ability of the isolated plastids to utilize concurrently supplied substrates and the effects of these substrate combinations on the Glc6P partitioning were also assessed. The relative fluxes of carbon from Glc6P to starch, fatty acids, and to CO₂ via the OPPP were close to 2∶1∶1 when Glc6P was supplied alone. Under these conditions NADPH generated via the OPPP was greater than that required by the concurrent rate of fatty acid synthesis. Fatty acid synthesis was unaffected by the presence or absence of exogenous NADH and/or NADPH and the requirement of fatty acid synthesis for reducing power is therefore met entirely by intraplastidial metabolism. When Glc6P was supplied in the presence of either pyruvate or pyruvate and acetate, the total flux from these metabolites to fatty acids was up to threefold greater than that from either Glc6P or pyruvate when they were supplied singly. In these experiments there was little competition between Glc6P and pyruvate in fatty acid synthesis and the flux to starch was unchanged. This implies that the starch and fatty acid biosynthesis pathways did not compete for the exogenously supplied ATP on which they were strongly dependent. When Glc6P and pyruvate were provided together, the NADPH generated by the OPPP pathway was less than that required by the concurrent rate of fatty acid synthesis. This suggests that the metabolism of exogenous Glc6P via the OPPP can contribute to the NADPH demand created during fatty acid synthesis but it also indicates that other intraplastidial sources of reducing power must be available under the in-vitro conditions used.     

A Particulate Phospholipid Synthesizing System from Escherichia coli B

The phosphatidate formed by glycerol 3-phosphate acyltransferase present in a particulate fraction from E. coli remained associated with the particulate material and was converted to phosphatidylethanolamine and phosphatidylglycerol by other enzymes contained in the particulate fraction. Those enzymes required a heat-labile factor for the synthesis of phosphatidylethanolamine and a heat-stable factor for the synthesis of phosphatidylglycerol. Both of these phospholipids like their precursor remained bound to the particulate fraction.     

Fatty acid synthesis in mitochondria from Saccharomyces cerevisiae

The ability of purified mitochondria isolated from S. cerevisiae to synthesize fatty acids and especially very long chain fatty acids (VLCFA) has been investigated. The VLCFA synthesis requires malonyl-CoA as the C2 unit donor and NADPH as the reducing agent. Moreover the yeast mitochondrial elongase is able to accept either exogenous long chain fatty acyl-CoAs as substrates or elongate endogenous substrates. In the latter case, ATP is required for full activity. Besides this important VLCFA formation, the mitochondria from S. cerevisiae were also able to synthesize C16 and C18.     

Hydroxymethylglutaryl coenzyme A reductase activity of adult Hymenolepis diminuta

The occurrence of hydroxymethylglutaryl coenzyme A (HMG-CoA) reductase in adult Hymenolepis diminuta was demonstrated. This activity was negligible in the cestode's cytosolic fraction but was noted when the mitochondrial or microsomal fraction served as the enzyme source. The predominant localization of HMG-CoA reductase activity was with the microsomal fraction. This fraction did not contain appreciable mitochondrial contamination based on the distribution of marker enzymes. The enzymatic nature of HMG-CoA conversion to mevalonic acid by either fraction was apparent because the reaction was heat labile and responded linearly to time of assay and protein content. The enzymatic reduction of HMG-CoA absolutely required NADPH when either fraction was assayed. The lesser activity of the mitochondrial fraction was membrane-associated. The predominant localization of HMG-CoA reductase activity with microsomal membranes and its separation with the membranous component of the mitochondrial fraction suggest that mitochondrial activity reflects the presence of microsomal membranes. In its predominant localization and pyridine nucleotide requirement, the cestode's HMG-CoA reductase activity resembles that of mammalian systems. The finding of HMG-CoA reductase provides an enzymatic mechanism for the intermediate conversion of HMG-CoA to mevalonic acid that would be needed for acetate-dependent isoprenoid lipid synthesis by adult H. diminuta.     

Relationship between fatty acid binding proteins,acetyl-CoA formation and fatty acid synthesis in developing human placenta

The relationship between fatty acid binding proteins, ATP citrate lyase activity and fatty acid synthesis in developing human placenta has been studied. Fatty acid binding proteins reverse the inhibitory efect of palmitoyl-CoA and oleate on ATP citrate lyase and fatty acid synthesis. In the absence of these inhibitors fatty acid binding proteins activate ATP citrate lyase and stimulate [ 1-¹⁴ C] acetate incorporation into placental fatty acids indicating binding of endogenous inhibitors by these proteins. Thus these proteins regulate the supply of acetyl-CoA as well as the synthesis of fatty acids from that substrates. As gestation proceeds and more lipids are required by the developing placenta fatty acid binding protein content, activity of ATP citrate lyase and rate of fatty acid synthesis increase indicating a cause and efect relationship between the demand of lipids and supply of precursor fatty acids during human placental development.     

alpha-Hydroxylation of newly synthesised fatty acids by a soluble fraction from germinating pea.

A soluble fraction from germinating pea (Pisum sativum) seeds alpha-hydroxylated newly-synthesised fatty acids to form alpha-hydroxypalmitic and alpha-hydroxystearic acids. In contrast to fatty acid synthesis from [14C] malonyl CoA, alpha-hydroxylation was inhibited by exogenous phospholipids. alpha-Hydroxylation was optimal at pH 8, required reduced pyridine nucleotides and was inhibited by EDTA and imidazole.     

Fatty-acid-induced activation of NADPH oxidase in plasma membranes of human neutrophils depends on neutrophil cytosol and is potentiated by stable guanine nucleotides

Both cis and trans unsaturated fatty acids and sodium dodecyl sulfate activated NADPH oxidase in plasma membranes of human neutrophils in the presence of neutrophil cytosol. In contrast, 5,8,11,14-icosatetraynoic acid, saturated fatty acids, esters, peroxides and 4 beta-phorbol 12-myristate 13-acetate, a potent activator of protein kinase C, were inactive. 5,8,11,14-icosatetraynoic acid inhibited superoxide formation elicited by fatty acids. Guanosine 5'[gamma-thio]triphosphate (GTP[gamma S]), a potent activator of guanine-nucleotide-binding proteins (N-proteins) enhanced superoxide formation elicited by fatty acids up to fourfold, supporting our previous suggestion that NADPH oxidase is regulated by an N-protein [Seifert, R. et al. (1986) FEBS Lett. 205, 161-165]. Cytosols from various tissues, soybean lipoxygenase and protein kinase C, purified from chicken stomach, did not substitute neutrophil cytosol. The activity of neutrophil cytosol was destroyed by heating at 95 degrees C. Superoxide formation was not affected by the inhibitor of protein kinase C 1-(5-isoquinolinesulfonyl)-2-methylpiperazine (H-7). Removal of cytosolic ATP by preincubation with hexokinase and glucose, dialysis of neutrophil cytosol or chelation of calcium with EGTA did not abolish the stimulatory effect of arachidonic acid and GTP[gamma S]. Thus, the cytosolic cofactor appears to be a neutrophil-specific and heat-labile protein, which is neither a lipoxygenase nor protein kinase C.     

Interrelationship and control of glucose metabolism and lipogenesis in isolated fat-cells. Effect of the amount of glucose uptake on the rates of the pentose phosphate cycle and of fatty acid synthesis

In order to study the quantitative relationship between fatty acid synthesis and pentose phosphate-cycle activity under different hormonal and dietary conditions affecting the extent of glucose uptake, cells isolated from rat epididymal adipose tissue were incubated in bicarbonate buffer containing [U-(14)C]-, [1-(14)C]- or [6-(14)C]-glucose. From the amount of glucose taken up, the production of lactate and pyruvate, and the incorporation of (14)C from differently labelled [(14)C]glucose into CO(2), fatty acids and glyceride glycerol, the rates of glucose metabolism via different pathways and the extent of lipogenesis under various experimental conditions were determined. The contribution of the pentose phosphate-cycle to glucose metabolism under normal conditions was calculated to be 8%. Starvation and re-feeding, and the presence of insulin, caused an enhancement of glucose uptake, pentose phosphate-cycle activity and fatty acid synthesis. Plots of both pentose phosphate-cycle activity and fatty acid synthesis versus glucose uptake revealed that the extent of glucose uptake, over a wide range, determines the rates of fatty acid synthesis and glucose metabolism via the pentose phosphate cycle. A balance of formation and production of nicotinamide nucleotides in the cytoplasm was established. The total amount of cytoplasmic NADH and NADPH formed was only in slight excess over the hydrogen equivalents required for the synthesis of fatty acids, glyceride glycerol and lactate. Except in cells from starved animals, the pentose phosphate cycle was found to provide only about 60% of the NADPH required for fatty acid synthesis. The results are discussed with respect to an overall control of the different metabolic and biosynthetic reactions in the fat-cells by the amount of glucose transported into the cell.     

Inhibition of fatty acid oxidation by etomoxir impairs NADPH production and increases reactive oxygen species resulting in ATP depletion and cell death in human glioblastoma cells

Normal differentiated cells rely primarily on mitochondrial oxidative phosphorylation to produce adenosine triphosphate (ATP) to maintain their viability and functions by using three major bioenergetic fuels: glucose, glutamine and fatty acids. Many cancer cells, however, rely on aerobic glycolysis for their growth and survival, and recent studies indicate that some cancer cells depend on glutamine as well. This altered metabolism in cancers occurs through oncogene activation or loss of tumor suppressor genes in multiple signaling pathways, including the phosphoinositide 3-kinase and Myc pathways. Relatively little is known, however, about the role of fatty acids as a bioenergetic fuel in growth and survival of cancer cells. Here, we report that human glioblastoma SF188 cells oxidize fatty acids and that inhibition of fatty acid β-oxidation by etomoxir, a carnitine palmitoyltransferase 1 inhibitor, markedly reduces cellular ATP levels and viability. We also found that inhibition of fatty acid oxidation controls the NADPH level. In the presence of reactive oxygen species scavenger tiron, however, ATP depletion is prevented without restoring fatty acid oxidation. This suggests that oxidative stress may lead to bioenergetic failure and cell death. Our work provides evidence that mitochondrial fatty acid oxidation may provide NADPH for defense against oxidative stress and prevent ATP loss and cell death.     

Biosynthesis of Long-Chain Alcohols by Developing and Regenerating Rat Sciatic Nerve

Abstract: Cell-free preparations of rat sciatic nerve were found to catalyze the reduction of fatty acid to alcohol in the presence of NADPH as reducing cofactor. The reductase was membrane-bound and associated primarily with the microsomal fraction. When fatty acid was the substrate, ATP, coenzyme A (CoA), and Mg²⁺ were required, indicating the formation of acyl CoA prior to reduction. When acyl CoA was used as substrate, the presence of albumin was required to inhibit acyl CoA hydro-lase activity. Fatty acid reductase activity was highest with palmitic and stearic acids, and somewhat lower with lauric and myristic acids. It was inhibited by sulfhydryl reagents, indicating the participation of thiol groups in the reduction. Only traces of long-chain aldehyde could be detected or trapped as semicarbazone. Fatty acid reductase activity in rat sciatic nerve was highest between the second and tenth days after birth and decreased substantially thereafter. Microsomal preparations of sciatic nerve from 10-day-old rats exhibited about four times higher fatty acid reductase activity than brain or spinal cord microsomes from the same animals. Wallerian degeneration and regeneration of adult rat sciatic nerve resulted in enhanced fatty acid reductase activity, which reached a maximum at about 12 days after crush injury.     

Fatty acid synthesis by isolated chromoplasts from the daffodil. Energy sources and distribution patterns of the acids

1. Fatty acid synthesis in isolated intact chromoplasts from [1-¹⁴C]acetate was made possible by using ATP, ADP (via adenylate kinase), and, with decreasing efficiency, UTP, CTP, and GTP as energy sources. 2. The glycolytic path from dihydroxyacetone phosphate to acetyl-CoA operates within the chromoplasts. The glycolytic intermediates, especially 2-phosphoglycerate and phosphoenolpyruvate, served as very effective energy donors for fatty acid synthesis by phosphorylating the endogenous adenine nucleotide pool. 3. In the presence of exogenous ATP or ADP, appreciable amounts of in vitro formed fatty acids were found as acyl-CoA and subsequent products, mainly phosphatidylcholine. When other energy sources were used most of the acids formed were in the free form, and to a minor extent, in the phosphatidic acid and diacylglycerol fractions. Similar results have recently been reported for spinach chloroplasts (Kleinig and Liedvogel 1979, FEBS Lett.101, 339–342).Abbreviations ATP adenosine triphosphate - ADP adenosine diphosphate - UTP uridine triphosphate - CTP cytidine triphosphate - GTP gnanosine triphosphate     

The human FA2H gene encodes a fatty acid 2-hydroxylase

2-Hydroxysphingolipids are a subset of sphingolipids containing 2-hydroxy fatty acids. The 2-hydroxylation occurs during de novo ceramide synthesis and is catalyzed by fatty acid 2-hydroxylase (also known as fatty acid alpha-hydroxylase). In mammals, 2-hydroxysphingolipids are present abundantly in brain because the major myelin lipids galactosylceramides and sulfatides contain 2-hydroxy fatty acids. Here we report identification and characterization of a human gene that encodes a fatty acid 2-hydroxylase. Data base searches revealed a human homologue of the yeast ceramide 2-hydroxylase gene (FAH1), which we named FA2H. The FA2H gene encodes a 372-amino acid protein with 36% identity and 46% similarity to yeast Fah1p. The amino acid sequence indicates that FA2H protein contains an N-terminal cytochrome b5 domain and four potential transmembrane domains. FA2H also contains the iron-binding histidine motif conserved among membrane-bound desaturases/hydroxylases. COS7 cells expressing human FA2H contained 3-20-fold higher levels of 2-hydroxyceramides (C16, C18, C24, and C24:1) and 2-hydroxy fatty acids compared with control cells. Microsomal fractions prepared from transfected COS7 cells showed tetracosanoic acid 2-hydroxylase activities in an NADPH- and NADPH: cytochrome P-450 reductase-dependent manner. FA2H lacking the N-terminal cytochrome b5 domain had little activity, indicating that this domain is a functional component of this enzyme. Northern blot analysis showed that the FA2H gene is highly expressed in brain and colon tissues. These results demonstrate that the human FA2H gene encodes a fatty acid 2-hydroxylase. FA2H is likely involved in the formation of myelin 2-hydroxy galactosylceramides and -sulfatides.     

Mycolic acid synthesis by Mycobacterium aurum cell-free extracts

The first cell-free system capable of synthesizing whole mycolic acids: (R1CH(OH)CH(R2)COOH, with 60 to 90 carbon atoms) from [1-14C]acetate is described and preliminary investigations into some of its requirements and properties are reported. Biosynthetic activity for mycolic acids occurred in an insoluble fraction (40 000 X g pellet) from disrupted cells of Mycobacterium aurum (ATCC 23366-type strain); it produced mycolic acids, but a very small amount of non-hydroxylated fatty acids. The predominant product was unsaturated mycolic acid (type I), while oxo- (type IV) and dicarboxy- (type VI) mycolic acids were synthesized to a lesser extent. When [1-14C]palmitic acid was used as a marker, no labelled mycolic acid was detected. The reaction required a divalent cation (Mg2+ or Mn2+), KHCO3 and O2. Neither CoA, NADH, NADPH nor ATP were necessary, but CoA rather increased the synthesis of non-hydroxylated fatty acids. Glucose or trehalose were not required. Avidin inhibited the biosynthesis of the three types of mycolic acid indicating the presence of a biotin-requiring enzyme in the reaction sequence and therefore a carboxylation step, but citrate had no allosteric effect. Iodoacetamide inhibited the system. These first data are in favor of a complex multienzyme system.