Analysis of the condensation step in elongation of very-long-chain saturated and tetraenoic fatty acyl-CoAs in swine cerebral microsomes

The condensation products in the elongation of exogenous arachidoyl-CoA (20:0-CoA) and endogenous fatty acids in adult swine cerebral microsomes were isolated and purified by using HPLC and a radioanalyzer. A saponification product of the condensation reaction of 20:0-CoA with malonyl-CoA was identified by gas chromatography-mass spectrometry as 2-heneicosanone (21:0-2-one). The endogenous substrates (16:0-CoA and 20:4-CoA) were likewise identified as 2-heptadecanone (17:0-2-one) and 2-heneicosatetraenone (21:4-2-one). Quantitative analysis of condensation activity was performed using electron-impact mass fragmentography. A characteristic fragment ion (m/z 59) of 21:0-2-one was used to estimate the condensation activity for 20:0-CoA, and fragment ions at m/z 58 and 80 were monitored for the endogenous substrates (16:0-CoA and 20:4-CoA, respectively). The molecular ion for each product was detected using chemical ionization. A comparative study of the condensation of 20:0-CoA and endogenous substrates was carried out for microsomes obtained from white matter, gray matter, and isolated neuronal cells; the activity for 20:0-CoA was significantly lower in gray matter and neuronal cells than in white matter, whereas the activity for endogenous substrates was almost the same for microsomes obtained from gray and white matter. This result suggests that the condensation enzyme for 20:0-CoA may be different from that for endogenous 16:0-CoA or 20:4-CoA in swine cerebral microsomes.     

Comparison between condensation and overall chain elongation of arachidoyl-CoA and arachidonoyl-CoA in swine cerebral microsomes

The condensation and overall elongation products of exogenous arachidoyl-CoA (20:0-CoA) and endogenous fatty acids in swine cerebral microsomes were detected by radio gas chromatography. In addition, the condensation products with malonyl-CoA as substrate were analyzed by radio high-performance liquid chromatography. Three main condensation products were detected; the overall elongation products of exogenous 20:0-CoA were 22:0 and 24:0, and those of endogenous substrates were 18:0, 22:4, and 24:4. The yield was estimated for the conversion of 3-ketoacyl-CoAs to the corresponding saponification products (methyl ketones or R-2-one; e.g., 2-heptadecanone = 17:0-2-one); these products were identified in the preceding paper (S. Yoshida and M. Takeshita (1987) Arch. Biochem. Biophys. 254, 170-179). The extraction of R-2-one by hexane depended on the acyl chain length. The yield of 2-heneicosanone (21:0-2-one) detected by radio gas chromatography was 80% whereas the yields of 17:0-2-one and 2-heneicosatetraenone (21:4-2-one) from the corresponding 3-ketoacyl-CoAs were 56 and 48%, respectively. A quantitative comparison was performed for the condensation and overall elongation activity; it was noticed that the condensation activity for the system which simultaneously produced two elongation products was nearly the same as that of the corresponding overall elongation activity. This result suggests that the condensation step may be at least one of the rate-limiting steps in the overall elongation of very-long-chain fatty acyl-CoA.     

Effect of fatty-acyl-CoAs on the elongation of saturated fatty acid in porcine aorta microsomes

The microsomal elongation system from porcine aorta for longchain fatty-acyl-CoAs was investigated. Palmitoleoyl-CoA (16:1-CoA), oleoyl-CoA (18:1-CoA), and eicosenoyl-CoA (20:1-CoA) remarkably depressed the elongation activity for 16:0-CoA in aorta microsomes by 44.8, 52.4, and 43.7% of the control activity, respectively. Saturated and polyunsaturated fatty-acyl-CoAs had little effect on the 16:0-CoA elongation activity. These results indicate that monounsaturated long-chain fatty acyl-CoAs can regulate the synthesis of saturated fatty acids in the vessel walls.     

Long-chain and very long-chain fatty acyl-coa synthetase activity in microsomes of jimpy mouse brain

The objective of this study was to determine whether the conversion of free, very long chain fatty acids (C₂₂–C₂₆) to their CoA-esters are involved in cerebroside synthesis, since cerebrosides are uniquely rich in very long chain fatty acids including lignoceric acid (C_24:0). We have studied lignoceroyl-CoA synthetase activity in the microsomes isolated from normal and jimpy mouse brain. The jimpy mouse lacks the ability to make myelin and is deficient in enzyme activities involved in the synthesis of myelin components, including cerebrosides. Unexpectedly, the lignoceroyl-CoA synthetase activity in jimpy brain microsomes was slightly higher than that in control microsomes. The palmitoyl (C_16:0)-CoA synthetase activity in jimpy brain was not different from the control. The level of cerebrosides in microsomes was grossly lower in jimpy brain. The implication of these findings and the involvement of lignoceric acid activation in cerebroside synthesis is discussed.     

Effect of phospholipase A2 and free fatty acids on lipid-protein interactions in long- and very-long-chain fatty acyl-CoA elongation enzyme systems of brain microsomes

The elucidation of the mechanism of phospholipase A2-induced inactivation of the condensation enzyme provided evidence concerning the important role of lipid-enzyme interactions in maintaining the condensation activity in swine cerebral microsomes. A quantitative analysis of fatty acid release by phospholipase A2 from the microsomal membrane revealed that only 5 nmol of free fatty acid per mg microsomal protein was released, including oleic acid and arachidonic acid, by treatment with 0.4 unit of phospholipase A2 per mg microsomal protein for 15 s at 23 degrees C. Under these conditions, the condensation activity for endogenous 16:0-CoA and 20:4-CoA decreased to half and that for exogenous 20:0-CoA decreased to 75%. However, the addition of free fatty acids and lysophospholipids or a mixture of them at 5-10 nmol/mg protein did not change the condensation activity for endogenous 16:0-CoA and 20:4-CoA, or for exogenous 20:0-CoA. These results indicated that phospholipase A2 inhibited the condensation activity by acting directly on phospholipids that are indispensable to maintaining the function of the condensation enzyme. The Arrhenius plot for the condensation of endogenous 16:0-CoA showed a break at around 16 degrees C, whereas no break of the plot was observed for the condensation of 20:0-CoA and 20:4-CoA. The activation energy for the condensation of 16:0-CoA and 20:4-CoA was decreased by the addition of free fatty acids such as oleic acid and stearic acid, with disappearance of the Arrhenius break for 16:0-CoA condensation, whereas the activation energy for the condensation of 20:0-CoA was not changed. These results suggest that the type of lipid-protein interaction in the condensation enzyme for 20:0-CoA is different from that for 16:0-CoA and 20:4-CoA.     

Decreased Long-Chain Fatty Acyl CoA Elongation Activity in Quaking and Jimpy Mouse Brain: Deficiency in One Enzyme or Multiple Enzyme Activities?

Using long-chain fatty acyl CoAs (arachidoyl CoA and behenoyl CoA), a decrease in overall fatty acid chain elongation activity was observed in the quaking and jimpy mouse brain microsomes relative to controls. Arachidoyl CoA (20:0) and behenoyl CoA (22:0) elongation activities were depressed to about 50% and 80% of control values in quaking and jimpy mice, respectively. Measurement of the individual enzymatic activities of the elongation system revealed a single deficiency in enzyme activity; only the condensation activity was reduced to the same extent as total elongation in both quaking and jimpy mice. The activities of the other three enzymes, beta-ketoacyl CoA reductase, beta-hydroxyacyl CoA dehydrase, and trans-2-enoyl CoA reductase, in both mutants were similar to the activities present in the control mouse. In addition, the activities of these three enzymes were more than two to three orders of magnitude greater than the condensing enzyme activity in all three groups, establishing that the condensing enzyme catalyzes the rate-limiting reaction step of total elongation. When the elongation of palmitoyl CoA was measured, only a 25% decrease in total elongation occurred in both mutants; a similar percent decrease in the condensation of palmitoyl CoA also was observed. The activities of the other three enzymes were unaffected. These results support the concept of either multiple elongation pathways or multiple condensing enzymes.     

Tissue and chain length specificity of the fatty acyl-CoA elongation system in the American cockroach

The elongation of fatty acyl-CoAs, reactions involved in hydrocarbon biosynthesis, was examined in the cockroach, Periplaneta americana. Products were analyzed by radio-HPLC and radio-GLC. The majority of the elongation activity was observed in microsomes prepared from abdominal epidermal tissue. Linoleoyl-CoA (18:2-CoA) was elongated most efficiently followed by stearoyl-CoA (18:0-CoA), linolenoyl-CoA (18:3-CoA; n-3) and oleoyl-CoA (18:1-CoA). The products of 18:2-CoA elongation included all even numbered acyl groups up to 28 carbons, and the products of 18:0-CoA included all even numbered acyl groups to 26 carbons. The 18:3-CoA was elongated only to 20 and 22 carbons. Radioactivity from both 18:2-CoA (5.4%) and 18:0-CoA (1.2%) was recovered in the hydrocarbon fraction. Analysis of this hydrocarbon fraction showed that the radio-activity from 18:2-CoA was present in (Z,Z)-6,9-heptacosadiene and that the radioactivity from 18:0-CoA was present in n-pentacosane. These data demonstrate for the first time in an in vitro insect system that the fatty acid elongation reactions are coupled with the conversion of the elongated product to hydrocarbon. Thus, each of the expected intermediates in the conversion of 18:0 and 18:2 to 25 and 27 carbon hydrocarbons, respectively, was observed, and the results demonstrate high tissue, substrate, and product specificity.     

Condensation activity for polyunsaturated fatty acids with malonyl-CoA in rat brain microsomes. Characteristics and developmental change.

Condensation activities for gamma-linolenic acid (18:3(n-6)), octadecatetraenoic acid (18:4(n-3)) and eicosapentaenoic acid (20:5(n-3)) with malonyl-CoA were measured and compared with the condensation activities for 16:0-CoA, 18:1-CoA, 18:2(n-6)-CoA and 18:3(n-3)-CoA in rat brain microsomes of various ages. The age-dependence of condensation activities for 18:3(n-6), 18:4(n-3) and 20:5(n-3) showed a maximum at 1- to 2-month-old and were still higher at 3-month-old 2- to 3-fold than the activities in microsomes of pups. Conversely, the age-dependence of condensation activity for 16:0-CoA showed a peak around 1 month-old, but decreased at 3-month-old to the level of the activities in pups. The condensation activity for 20:5(n-3) was inhibited by 18:3(n-6) or 18:4(n-3) and the inhibition was not competitive. The condensation of 18:3(n-6) was also inhibited by 18:4(n-3) in the same manner. A physiological implication of the inhibition system at the substrate level was discussed.     

Chain elongation of fatty acid in brain: a comparison of mitochondrial and microsomal enzyme activities

The activities of mitochondrial and microsomal fatty acid-elongating enzymes have been measured in rat brain during postnatal development and in brains of jimpy, msd, and quaking mice. The microsomal enzyme activity rose from a low in the immature brain to a maximum at 21 days of age and then declined to low levels in the mature brain. The developmental patterns were similar for all acyl-CoAs tested. The maximum activity fell sharply from C₁₆ to C₁₈ and then fell gradually with increase in fatty acid chain length up to C₂₄. The activities for monounsaturated acyl-CoAs were slightly higher than for corresponding saturated esters. The mitochondrial enzyme activity was high in the immature brain and remained virtually unchanged during further brain development. This activity steadily decreased with increasing chain length from C₁₆ to C₂₄. The microsomal enzyme activity was reduced in myelin-deficient mutants compared to their controls. The extent of reduction was most severe for C₂₀- to C₂₄-CoAs followed by C₁₈-CoA and then C₁₆-CoA, for which the activity was reduced only in the jimpy mouse. The activities for C₂₀- to C₂₄-CoAs in jimpy, msd, and quaking mice were 12, 38, and 52% of the control, respectively. The mitochondrial enzyme activity was not affected by these mutations. Fatty acid synthetase activity was similar in the mutant and control mice. These results suggest that the deficiency of long-chain fatty acids in the central nervous system of myelin-deficient mouse mutants is due to reduced synthesis by the microsomal enzyme, which is directly related to myelination. The brain mitochondrial enzyme appears to be unrelated to myelination.     

Characterization of fatty acid elongation system in porcine neutrophil microsomes

Microsomes purified from porcine neutrophils containing the fatty acid chain-elongation system for long- and very-long-chain fatty acyl-CoAs, and several enzymatic characters for the elongation of palmitoyl-CoA (16:0-CoA) and arachidoyl-CoA (20:0-CoA) were examined. The heat-inactivation profile for the elongation of 16:0-CoA was different from that of 20:0-CoA, suggesting the presence of different enzyme systems for palmitoyl-CoA and arachidoyl-CoA. Contrary to the elongation system of brain microsomes, the successive synthesis of lignoceric acid (24:0) from 20:0-CoA at 60 microM was not prominent under normal conditions in the neutrophil microsomes. The synthesis of behenic acid (22:0) was slightly inhibited by 0.5 mM N-ethylmaleimide (NEM) present in the assay mixture, whereas the pre-treatment of microsomes with 0.5 mM NEM largely inhibited the synthesis of 22:0 from 20:0-CoA. The synthesis of 24:0, however, was enhanced by 0.5 mM NEM in the elongation of 20:0-CoA and the rate of 24:0 synthesis became dominant over the synthesis of 22:0. These results suggested that the elongation enzyme for very-long-chain fatty acyl-CoA, especially for 20:0-CoA elongation to 22:0 in the neutrophil microsomes contained NEM-sensitive sulfhydryl groups in the active center and the mechanism for the synthesis of 24:0 through successive elongation from 20:0-CoA was different from that of 22:0, as the former was enhanced by NEM whereas the latter was strongly inhibited.     

Changes of free fatty acids and acyl-CoAs in rat brain hippocampal slice with tetraethylammonium-induced long-term potentiation

We investigated the role of acyl-CoAs during induction and maintenance of long-term potentiation in rat brain hippocampus. Changes of acyl-CoA and free fatty acids (FFA) in hippocampus were measured during tetraethylammonium (TEA)-induced LTP. Results indicated that concentrations of acyl-CoAs and FFAs in slices were changed during TEA-induced LTP and 16:0-CoA and 18:0-CoA were increased in the early phase of stimulation, whereas free fatty acids in this phase were rather decreased. The increase of 20:4-CoA was delayed more than saturated acyl-CoAs. To examine the role of acyl-CoA in LTP of evoked transmitter release, we measured the glutamate release from hippocampal slice with the addition of acyl-CoA using glutamate electrode. Acyl-CoA (16:0-, 18:1-, and 20:4-CoA) could enhance glutamate release in hippocampal slice. It is suggested that saturated acyl-CoAs may play a functional role in the early phase of LTP.     

Inhibitory effect of very-long-chain monounsaturated fatty-acyl-CoAs on the elongation of long-chain fatty acid in swine cerebral microsomes

Characteristics of condensation and overall elongation of very-long-chain fatty-acyl-CoAs in swine cerebral microsomes were studied using radio high-performance liquid chromatography (RHPLC) and gas chromatography-mass spectrometry (GC-MS). The monounsaturated fatty-acyl-CoA depressed both the condensation and overall elongation activities of endogenous substrates and also of exogenous saturated fatty-acyl-CoA. The extent of the decrease of the elongation activity was dependent on the concentration and the chain length of the exogenous fatty-acyl-CoAs. The dependence of the condensation activity of monounsaturated fatty-acyl-CoA on the concentration of malonyl-CoA suggested that the non-Michaelis-Menten type kinetics was dominant for oleoyl-CoA, however, a normal kinetic pattern was obtained for endogenous palmitoyl-CoA and arachidonoyl-CoA with Km = 37 microM to malonyl-CoA. The condensation activity for icosanoyl-CoA (20:0-CoA) was inhibited by icosenoyl-CoA (20:1-CoA) in a non-competitive manner, which suggested that the condensation enzyme, or at least the active center of the enzyme for icosenoyl-CoA, was different from that for icosanoyl-CoA.     

Chain elongation in the formation of polyunsaturated fatty acids by brain: Some properties of the microsomal system

Chain elongation of polyunsaturated acids has been investigated using microsomes from developing rat brain. With 18:3(n ? 6) in 0.05% detergent as an acceptor and [2-¹⁴C]malonyl-coenzyme A (CoA) as a two-carbon donor, incorporation of radioactivity into 20:3 was optimal (and incorporation into other acyl chains was minimal) in the presence of 100 μm substrate, 200 μmp-bromophenacylbromide and 10 mm KCN. Up to 30% of the labeled products were incorporated into phospholipids and triacylglycerol. Maximal microsomal elongation activity was observed at 3–4 weeks of age. Several other fatty acid or acyl-CoA acceptors tested in this system were elongated at slower rates compared to 18:3(n ? 6) [e.g., 16:0-CoA, 75%; 20:4(n ? 6), 57%; 18:3(n ? 3), 13%; 18:2(n ?6), 10%; 20:3(n ? 6), 6%]. The rate of elongation of chemically synthesized 18:3-CoA was only 50% of the detergent-suspended acid and was optimal at 6 μm substrate; inhibition above 6 μm 18:3-CoA was reduced by bovine serum albumin, but incorporation of label into palmitate was greatly stimulated. CoA markedly inhibited elongation of 18:3(n ? 6) or 18:3-CoA; N-ethylmaleimide at equimolar amounts reversed this CoA inhibition but did not alter the inhibition caused by concentrations of 18:3-CoA above 6 μm. ATP was absolutely required for elongation of either the free acid or the acyl-CoA derivative, whereas exogenous MgCl₂ had little effect.     

Phosphatidyl choline fatty acid remodeling in the hepatic cell nuclei

This study was performed to determine whether fatty acids incorporated into liver cell nuclei phosphatidylcholine (PtdCho) could be remodeled in the isolated nuclear. For this reason, rat liver cell nuclei were incubated in vitro with [1-14C]20:4n-6-CoA. PtdCho molecular species with the highest specific activity had an unsaturated fatty acid at sn-1 and sn-2 positions (20:4-20:4>18:2-20:4>18:1-20:4). 16:0-20:4 and 18:0-20:4 PtdChos showed a minor specific activity. When labeled nuclei were reincubated in the absence of labeled substrate with the addition of cytosol, ATP and CoA, the specific activity of 20:4-20:4, 18:2-20:4 and 18:1-20:4 species decreased, while that of 16:0-20:4 and 18:0-20:4 increased. In conclusion, the asymmetric fatty acid distribution of saturated fatty acids at sn-1 position, and unsaturated fatty acids at sn-2 position of nuclear PtdCho molecular species was re-established by an acyl-CoA-dependent remodeling process.     

Lipid hydrogenation induces elevated 18:1-CoA desaturase activity in Candida lipolytica microsomes.

Microsomal membranes prepared from the mesophilic yeast Candida lipolytica grown at 10 degrees C were hydrogenated by the homogeneous Pd-catalyst, palladium di (sodium alizarine sulfonate) (Pd(QS)2). After hydrogenation to various levels, the microsomes were washed free of the Pd-complex and transferred to a reaction mixture (containing NADH, MgCl2, ATP, CoA and [14C]18:1-CoA) for assay of 18:1-CoA desaturase activity. Microviscosity alterations were also followed by measuring changes in DPH fluorescence polarization. Rapid catalytic hydrogenation of unsaturated fatty acids of the lipids occurred within 20-120 s, resulting in large increases in 16:0, 18:0 and 18:1 acids and decreases in 18:2 acid. In the range 7-20% 18:0 content, a pronounced increase in desaturase activity was observed, with a maximum of greater than 2-fold at a 18:0 content of 12%, followed by a decrease to the initial activity at 33% 18:0 content. These changes were well-correlated with changes in microviscosity, maximal desaturase activity occurring in the DPH fluorescence anisotropy range of 0.23-0.24; above and below this range, desaturase activities were close to the initial control values. It is suggested that the hydrogenation-induced increase in the formation of 18:2 from 18:1-CoA (proceeding partly through direct desaturation of PC) may be due to changes in conformation of the membrane-bound desaturase enzyme complex as a result of controlled rigidification of the surrounding lipids. The operation of such a self-regulating control mechanism would be consistent with a previously proposed model for microsomal desaturase action.     

Oleoyl-CoA is not an immediate substrate for fatty acid elongation in developing seeds of Brassica napus

The substrate specificity of fatty acid elongase was studied using an oil body fraction from developing seeds of Brassica napus. ATP was essential for high rates of elongase activity, but there was no apparent requirement for oleoyl-CoA, oleic acid (18:1) or CoA. Furthermore, ¹⁴C from 18:1-CoA was incorporated into eicosenoic (20:1) and erucic (22:1) acids at a much slower rate than ¹⁴C from malonyl-CoA. Incubation of [¹⁴C]18:1-CoA with the oil body fraction resulted in a rapid loss of [¹⁴C]18:1-CoA into several lipid fractions whether in the absence or presence of ATP, but the loss of 18:1-CoA had a comparatively small effect on the overall rate of elongation. Acyl-CoAs were derivatized to their respective acylbutylamide and analyzed by gas chromatography-mass spectrometry. This analysis of acyl-CoAs demonstrated that there was no detectable 20:1-CoA or 22:1-CoA at 0 min incubation, while newly synthesized 20:1-CoA and 22:1-CoA were present at 10 min. Analysis of the %¹⁴C of the substrates and products of the elongation reaction revealed that the endogenous pool of 18:1-CoA is quite small in elongase preparations. In addition, [¹⁴C]18:1-CoA added to the incubation, although incorporated into lipids, was not significantly diluted by turnover or new synthesis. In contrast, the %¹⁴C of the 20:1-CoA was two- to threefold less than that of the 18:1-CoA. Taken together, these results indicate that the [¹⁴C]18:1 from the [¹⁴C]18:1-CoA was diluted in an intermediate 18:1 pool and that the 18:1-CoA was not the major donor of the acyl group to the elongase reaction.     

Arachidoyl- and arachidonoyl-CoA elongation mechanism in swine cerebral microsomes

Long-chain saturated and polyunsaturated fatty acyl-CoA elongations were studied in swine cerebral microsomes. The elongation of endogenous palmitoyl-CoA to stearate was highly active in both cerebral and liver microsomes, whereas those of arachidoyl-CoA (20:0-CoA) and endogenous arachidonoyl-CoA (20:4-CoA) were high in cerebral microsomes, but negligible in liver microsomes. The elongation of 22:4 to 24:4 was also observed in cerebral microsomes. Both NADPH and NADH at 500 microM were effective in elongation of 16:0-, 20:0- and 20:4-CoA, whereas NADPH was more effective in elongation of 22:4 to 24:4 than NADH. The incorporation of deuterium atoms to the elongated product was detected by the technique of mass fragmentography when the NADPH-dependent elongations of 20:0-CoA and 20:4-CoA were performed in 2H2O medium upon cerebral microsomes. The number of incorporated deuterium atoms into 22:0 elongated from 20:0-CoA was mainly two, and that into 22:4 elongated from 20:4-CoA was mainly three. These results indicated that part of hydrogens in elongated arachidoyl- and arachidonoyl-CoA were transferred from NADPH.     

MpFAE3, a beta-ketoacyl-CoA synthase gene in the liverwort Marchantia polymorpha L., is preferentially involved in elongation of palmitic acid to stearic acid

Fatty acid chain elongation is a crucial step in the biosynthesis of long chain fatty acids. An essential reaction in the elongation process is condensation of malonyl-CoA with acyl-CoA, which is catalyzed by beta-ketoacyl-CoA synthase (KCS) in plants. We have isolated and characterized the MpFAE3 gene, one of the KCS gene family in the liverwort Marchantia polymorpha. Transgenic M. polymorpha plants overexpressing MpFAE3 accumulate fatty acids 18:0, 20:0, and 22:0. In these plants, the amount of 16:0 is reduced to 50% of wild type. In a heterologous assay, transgenic methylotrophic yeast expressing the MpFAE3 gene accumulates fatty acid 18:0 and generates several longer fatty acids which are not detectable in the control, accompanied by a decrease of 16:0. These observations indicate that the MpFAE3 protein is preferentially involved in the elongation of 16:0 to 18:0 and also in the subsequent steps of 18:0 to 20:0 and 20:0 to 22:0 in M. polymorpha.     

Characteristics of Synthesis of Very-Long-Chain Saturated and Tetraenoic Fatty Acids in Swine Cerebral Microsomes

The elongation of arachidoyl-CoA (20:0-CoA) yielded 22:0 and 24:0 concomitantly, whereas the elongation of behenoyl-CoA (22:0-CoA) yielded only a negligible amount of 24:0 in adult swine cerebral microsomes. The dependence on time, pH, and the substrate concentrations were examined for the synthesis of 22:0 and 24:0 from 20:0-CoA. A microcomputer-aided simulation study suggested that there were two parallel pathways in the elongation of 20:0-CoA to 22:0 and 24:0. The elongation of 22:0-CoA could not be observed in adult swine cerebral microsomes; however, it was observed clearly in newborn swine and rat brain microsomes. A dilution experiment with the addition of cold 22:0-CoA in the reaction of elongation of 20:0-CoA confirmed the above suggestion that no intermediate 22:0 appeared during the synthesis of 24:0 from 20:0-CoA. The elongation of endogenous 20:4-CoA to 22:4 and 24:4 was examined in newborn swine cerebral microsomes, and the presence of two parallel pathways in the elongation of 20:4-CoA to 22:4 and 24:4 similar to those involved in the elongation of 20:0-CoA to 22:0 and 24:0 was suggested.     

Functional differentiation and selective inactivation of multiple <Emphasis Type="Italic"> Saccharomyces cerevisiae </Emphasis>genes involved in very-long-chain fatty acid synthesis

While de novo fatty acid synthesis uses acetyl-CoA, fatty acid elongation uses longer-chain acyl-CoAs as primers. Several mutations that interfere with fatty acid elongation in yeast have already been described, suggesting that there may be different elongases for medium- and long-chain acyl-CoA primers. In the present study, an experimental approach is described that allows differential characterization of the various yeast elongases in vitro. Based on their characteristic primer specificities and product patterns, at least three different yeast elongases are defined. Elongase I extends C12-C16 fatty acyl-CoAs to C16-C18 fatty acids. Elongase II elongates palmitoyl-CoA and stearoyl-CoA up to C22 fatty acids, and elongase III synthesizes 20-26-carbon fatty acids from C18-CoA primers. Elongases I, II and III are specifically inactivated in, respectively, elo1, elo2 and elo3 mutants. Elongases II and III share the same 3-ketoacyl reductase, which is encoded by the YBR159w gene. Inactivation of YBR159w inhibits in vitro fatty acid elongation after the first condensation reaction. Although in vitro elongase activity is absent, the mutant nevertheless contains 10-30% of normal VLCFA levels. On the basis of this finding, an additional elongating activity is inferred to be present in vivo. ybr159Delta cells show synthetic lethality in the presence of cerulenin, which inactivates fatty acid synthase. An involvement of FAS in VLCFA synthesis may account for these findings, but remains to be demonstrated directly. Alternatively, a vital role for C18 and C20 hydroxyacids, which are dramatically overproduced in ybr159Delta cells, may be postulated.