Elongation of acyl-CoAs by microsomes from etiolated leek seedlings

Long chain fatty acid synthesis was studied using etiolated leek seedling microsomes. In the presence of ATP, [2-¹⁴C]malonyl-CoA was incorporated into fatty acids of C₁₆C₂₆. The omission of ATP, even in the presence of acetyl-CoA, led to a complete loss of activity, which was restored by addition of exogeneous acyl-CoAs. Comparison of acyl-CoA (C₁₂C₂₄) elongation showed that stearoyl-CoA, in the presence of [2-¹⁴C]malonyl-CoA, was the more efficient precursor leading to the formation of fatty acids having a chain length of C₂₀C₂₆. [1-¹⁴C]C₁₆CoA and [1-¹⁴C]C₁₈CoA were elongated in the presence of malonyl-CoA, without degradation of the acyl chain. The time-course and the malonyl-CoA concentration curves showed that [1-¹⁴C]C₁₈CoA was a better primer than [1-¹⁴C]C₁₆CoA. Acyl-CoA elongation was also studied over the concentration range 4.5–45 μM [1-¹⁴C]C₁₈CoA. Comparison of the radioactivity incorporated into the fatty acids formed using [2-¹⁴C]malonyl-CoA in the presence of C₁₈CoA, on the one hand, and [1-¹⁴C]C₁₈CoA in the presence of malonyl-CoA, on the other, demonstrated clearly that the acyl chain of the acyl-CoA was elongated by malonyl-CoA.     

Biosynthesis of saturated very long chain fatty acids by purified membrane fractions from leek epidermal cells

Elongation of fatty acids by microsomal fractions obtained from leek epidermal cells was measured by the incorporation of [1-¹⁴C]stearate, [1-¹⁴C]stearyl CoA, and [1-¹⁴C]stearyl ACP in the presence of malonyl CoA and NADPH. Stearoyl CoA appears to be the primer of the elongase (s) rather than stearoyl ACP. There are at least two elongases, the first elongating C₁₈ to C₂₀, the second synthesizing C₂₂ to C₃₀ fatty acids from C₂₀. The main site of the elongase (s) is a subcellular fraction enriched in endoplasmic reticulum. The plasma membrane-enriched fraction, which contains large amounts of saturated very long chain fatty acids, synthesizes only minor amounts of them.     

Elongation of fatty acids by microsomal fractions from the brain of the developing rat.

Elongation of fatty acids by microsomal fractions obtained from rat brain was measured by the incorporation of [2-14C]malonyl-CoA into fatty in the presence of palmitoyl-CoA or stearoyl-CoA. 2. Soluble and microsomal fractions were prepared from 21-day-old rats; density gradient centrifugation demonstrated that the stearoyl-CoA elongation system was localized in the microsomal fraction whereas fatty acid biosynthesis de novo from acetyl-CoA occurred in the soluble fraction. The residual activity de novo in the microsomal fraction was attributed to minor contamination by the soluble fraction. 3. The optimum concentration of [2-14C]malonyl-CoA for elongation of fatty acids was 25 mum for palmitoyl-CoA or stearoyl-CoA, and the corresponding optimum concentrations for the two primer acyl-CoA esters were 8.0 and 7.2 muM respectively. 4. Nadph was the preferred cofactor for fatty acid formation from palmitoyl-CoA or stearoyl-CoA, although NADH could partially replace it. 5. The stearoyl-CoA elongation system required a potassium phosphate buffer concentration of 0.075M for maximum activity; CoA (1 MUM) inhibited this elongation system by approx. 30%. 6. The fatty acids formed from malonyl-CoA and palmitoyl-CoA had a predominant chain length of C18 whereas stearoyl-CoA elongation resulted in an even distribution of fatty acids with chain lengths of C20, C22 and C24. 7. The products of stearoyl-CoA elongation were identified as primarily unesterified fatty acids. 8. The developmental pattern of fatty acid biosynthesis by rat brain microsomal preparations was studied and both the palmitoyl-CoA and stearoyl-CoA elongation systems showed large increases in activity between days 10 and 18 after birth.     

Characterization and solubilization of an acyl chain elongation system in microsomes of leek epidermal cells

Microsomes prepared from leek epidermal tissue readily elongate stearoyl-CoA to very long chain fatty acid with malonyl-CoA as the C2 unit. In the absence of stearoyl-CoA, but in the presence of ATP, microsomes elongate endogenous free fatty acids. Endogenous CoA is the source of CoA. Palmitoyl, stearoyl, and higher saturated acyl-CoAs are readily elongated by the microsomal system but oleoyl-CoA is ineffective; however, the higher monounsaturated acyl-CoAs can be elongated. Since the very long chain fatty acids of the leek epidermis are all saturated, it would appear that the reaction controlling the nature of the final acyl product is the inactivity of oleoyl-CoA as a substrate. There is no evidence that acyl carrier protein participates in the elongation reactions. Evidence is also presented suggesting that (a) there may be two elongation systems, one responsible for the conversion of stearoyl-CoA to arachidonyl-CoA and the second involved in the conversion of arachidonyl-CoA to very long chain fatty acids, and that (b) the elongation activities may be associated with a large polypeptide.     

Nature of the reaction product of [1-14C]stearoyl-CoA elongation by etiolated leek seeding microsomes

The elongation of [1-14C]stearoyl-CoA by microsomes from etiolated leek seedlings, in the presence of malonyl-CoA and NADPH, has been studied at different substrate and enzyme concentrations. The HPTLC analysis of the whole reaction mixture, followed by the analysis of the label in the fatty acid methyl esters of long-chain acyl-CoAs, phosphatidylcholine (PC), and neutral lipids, showed that the acyl-CoA fraction contained most of the labeled very-long-chain fatty acids. The very-long-chain fatty acids were rapidly formed and released from the elongase(s) as acyl-CoAs. The label of long-chain acyl-CoAs increased for 20 min and then decreased, whereas it increased in PC. Labeled very-long-chain fatty acids appeared in the neutral lipid + free fatty acid fraction after a 20-min lag.     

The Endoplasmic reticulum-associated maize GL8 protein is a component of the acyl-coenzyme A elongase ivolved in the production of cuticular waxes

The gl8 gene is required for the normal accumulation of cuticular waxes on maize (Zea mays) seedling leaves. The predicted GL8 protein exhibits significant sequence similarity to a class of enzymes that catalyze the reduction of a ketone group to a hydroxyl group. Polyclonal antibodies raised against the recombinant Escherichia coli-expressed GL8 protein were used to investigate the function of this protein in planta. Subcellular fractionation experiments indicate that the GL8 protein is associated with the endoplasmic reticulum membranes. Furthermore, polyclonal antibodies raised against the partially purified leek (Allium porrum) microsomal acyl-coenzyme A (CoA) elongase can react with the E. coli-expressed GL8 protein. In addition, anti-GL8 immunoglobulin G inhibited the in vitro elongation of stearoyl-CoA by leek and maize microsomal acyl-CoA elongase. In combination, these findings indicate that the GL8 protein is a component of the acyl-CoA elongase. In addition, the finding that anti-GL8 immunoglobulin G did not significantly inhibit the 3-ketoacyl-CoA synthase, 3-ketoacyl-CoA dehydrase, and (E) 2,3-enoyl-CoA reductase partial reactions of leek or maize acyl-CoA elongase lends further support to our previous hypothesis that the GL8 protein functions as a beta-ketoacyl reductase during the elongation of very long-chain fatty acids required for the production of cuticular waxes.     

Fatty Acid Elongation Is Independent of Acyl-Coenzyme A Synthetase Activities in Leek and Brassica napus

In both animal and plant acyl elongation systems, it has been proposed that fatty acids are first activated to acyl-coenzyme A (CoA) before their elongation, and that the ATP dependence of fatty acid elongation is evidence of acyl-CoA synthetase involvement. However, because CoA is not supplied in standard fatty acid elongation assays, it is not clear if CoA-dependent acyl-CoA synthetase activity can provide levels of acyl-CoAs necessary to support typical rates of fatty acid elongation. Therefore, we examined the role of acyl-CoA synthetase in providing the primer for acyl elongation in leek (Allium porrum L.) epidermal microsomes and Brassica napus L. cv Reston oil bodies. As presented here, fatty acid elongation was independent of CoA and proceeded at maximum rates with CoA-free preparations of malonyl-CoA. We also showed that stearic acid ([1-¹⁴C]18:0)-CoA was synthesized from [1-¹⁴C]18:0 in the presence of CoA-free malonyl-CoA or acetyl-CoA, and that [1-¹⁴C]18:0-CoA synthesis under these conditions was ATP dependent. Furthermore, the appearance of [1-¹⁴C]18:0 in the acyl-CoA fraction was simultaneous with its appearance in phosphatidylcholine. These data, together with the s of a previous study (A. Hlousek-Radojcic, H. Imai, J.G. Jaworski [1995] Plant J 8: 803–809) showing that exogenous [¹⁴C]acyl-CoAs are diluted by a relatively large endogenous pool before they are elongated, strongly indicated that acyl-CoA synthetase did not play a direct role in fatty acid elongation, and that phosphatidylcholine or another glycerolipid was a more likely source of elongation primers than acyl-CoAs.     

Fatty acid biosynthesis by a particulate preparation from germinating pea

1. Fatty acid synthesis was studied in microsomal preparations from germinating pea (Pisum sativum). 2. The preparations synthesized a mixture of saturated fatty acids up to a chain length of C(24) from [(14)C]malonyl-CoA. 3. Whereas hexadecanoic acid was made de novo, octadecanoic acid and icosanoic acid were synthesized by elongation. 4. The products formed during [(14)C]malonyl-CoA incubation were analysed, and unesterified fatty acids and polar lipids were found to be major products. [(14)C]Palmitic acid represented a high percentage of the acyl-carrier protein esters, whereas (14)C-labelled very-long-chain fatty acids were mainly present as unesterified fatty acids. CoA esters were minor products. 5. The addition of exogenous lipids to the incubation system usually resulted in stimulation of [(14)C]malonyl-CoA incorporation into fatty acids. The greatest stimulation was obtained with dipalmitoyl phosphatidylcholine. Both exogenous palmitic acid and dipalmitoyl phosphatidylcholine increased the amount of [(14)C]-stearic acid synthesized, relative to [(14)C]palmitic acid. Addition of stearic acid increased the amount of [(14)C]icosanoic acid formed. 6. [(14)C]Stearic acid was elongated more effectively to icosanoic acid than [(14)C]stearoyl-CoA, and its conversion was not decreased by addition of unlabelled stearoyl-CoA. 7. Incorporation of [(14)C]malonyl-CoA into fatty acids was markedly decreased by iodoacetamide and 5,5'-dithiobis-(2-nitrobenzoic acid). Palmitate elongation was sensitive to arsenite addition, and stearate elongation to the presence of Triton X-100 or fluoride. The action of fluoride was not, apparently, due to chelation. 8. The microsomal preparations differed from soluble fractions from germinating pea in (a) synthesizing very-long-chain fatty acids, (b) not utilizing exogenous palmitate-acyl-carrier protein as a substrate for palmitate elongation and (c) having fatty acid synthesis stimulated by the addition of certain complex lipids.     

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.     

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.     

Incorporation of [214C]malonyl CoA into fatty acids by a cell-free extract of Catharanthus roseus suspension culture cells

A cell-free extract containing the enzymes for de-novo synthesis, elongation and desaturation of fatty acids was prepared from cultured cells of Catharanthus roseus G. Don. ¹⁴C-Fatty acids synthesized by the extract from [2-¹⁴C]malonyl CoA substrate were palmitic (16:0), stearic (18:0) and oleic (18:1). Dialyzed extract was active and stable at room temperature and at 4° C, but was inactivated on boiling. There was an absolute requirement for NADPH for incorporation of [2-¹⁴C]malonyl CoA into total fatty acids. Escherichia coli acyl carrier protein stimulated total fatty-acid synthesis without affecting the relative ratio of individual fatty acids. Total fatty-acid synthesis at a rate of 45 nmol·mg^-1 protein·h^-1 occurred at a substrate level of 73 M malonyl CoA, cofactor levels of 500 M NADPH, 30 g·ml^-1 E. coli ACP, and 1.0 mg·ml^-1 extract protein. Total fatty acid synthesis was also sensitive to cerulenin and CoA levels. Variations in the relative abundance of individual ¹⁴C-fatty acids were regulated by concentrations of [¹⁴C]malonyl CoA. NADPH and ferredoxin, as well as by pH, temperature and length of incubation. Fatty-acid synthetase enzymes responsible for [¹⁴C]palmitic acid were rapidly saturated at a low substrate level (0.3 M malonyl CoA). Increasing the level of [2-¹⁴C]malonyl CoA permitted further synthesis of [¹⁴C]stearate and [¹⁴C]oleate. Desaturation of [¹⁴C]stearate to [¹⁴C]oleate was stimulated by increasing the levels of NADPH and ferredoxin. The desaturase and elongase enzymes were sensitive to acidic pH. The desaturase was also unstable at 41° C, although fatty acid synthetase and elongase were unaffected by this temperature.Abbreviation ACP Acyl carrier protein     

Fatty acid biosynthesis in Erlich cells. The mechanism of short term control by exogenous free fatty acids.

We have examined the mechanism by which extracellular free fatty acids regulate fatty acid biosynthesis in Ehrlich ascites tumor cells. De novo biosynthesis in intact cells was inhibited by stearate greater than oleate greater than palmitate greater than linoleate. The amount of citrate and long chain acyl-CoA in the cells was not changed appreciably by the addition of free fatty acids to the incubation medium, indicating than free fatty acids do not regulate fatty acid biosynthesis by changing the total intracellular content of these metabolites. By measuring the incorporation of labeled free fatty acids into acyl-CoA, however, it was determined that the fatty acid composition of the acyl-CoA poolwas changed dramatically to reflect the composition of the exogenous free fatty acids. The relative inhibitory effects of different free fatty acids appear to depend on the ability of their acyl-CoA derivatives to regulate acyl-CoA carboxylase activity. The acyl-CoA concentration needed to produce 50% inhibition of purified Ehrlich cell carboxylase was found to be 0.68 mum for stearoyl-CoA, 1.6 mum for oleoyl-CoA, 2.2 mum for palmitoyl-CoA, 23 mum for myristoyl-CoA, 30 mum for lauroyl-CoA, and 37 mum for linoleoyl-CoA. In contrast to their effects on de novo synthesis, all of the free fatty acids added except stearate stimulated chain elongation in intact cells. Microsomal chain elongation, the major system for elongation in Ehrlich cells, also was regulated by the composition of the cellular acyl-CoA pool. Lauroyl-CoA, myristoyl-CoA, and palmitoyl-CoA were good substrates for elongation by isolated microsomes; oleoyl-CoA, and linoleoyl-CoA were intermediate; and stearoyl-CoA was a very poor substrate. We conclude that free fatty acids regulate fatty acid biosynthesis by changing the composition of the cellular acyl-CoA pool. These changes control the rate of malonyl-CoA production and, because of the acyl-CoA substrate specificity of the microsomal elongation system, modulate the amount of malonyl-CoA used for chain elongation.     

Synthesis of Long-Chain Acyl-CoA in Chloroplast Envelope Membranes

The chloroplast envelope is the site of a very active long-chain acylcoenzyme A (CoA) synthetase. Furthermore, we have recently shown that an acyl CoA thioesterase is also associated with envelope membrane (Joyard J, PK Stumpf 1980 Plant Physiol 65: 1039-1043). To clarify the interacting roles of both the acyl-CoA thioesterase and the acyl-CoA synthetase, the formation of acyl-CoA in envelope membranes was examined with different techniques which permitted the measurement of the actual rates of acyl-CoA formation. Using [¹⁴C]ATP or [¹⁴C]oleic acid as labeled substrates, it can be shown that the envelope acyl-CoA synthetase required both Mg²⁺ and dithiothreitol. Triton X-100 slightly stimulated the activity. The specificity of the acyl-CoA synthetase was determined either with [¹⁴C]ATP or with [³H]CoA as substrates. The results obtained in both cases were similar, that is, as substrates, the unsaturated fatty acids were more effective than saturated fatty acids, the velocity of the reaction increased from lauric acid to palmitic acid, and the maximum velocity was obtained with unsaturated C₁₈ fatty acids.     

Role of carnitine and carnitine palmitoyltransferase as integral components of the pathway for membrane phospholipid fatty acid turnover in intact human erythrocytes.

The deacylation and reacylation process of phospholipids is the major pathway of turnover and repair in erythrocyte membranes. In this paper, we have investigated the role of carnitine palmitoyltransferase in erythrocyte membrane phospholipid fatty acid turnover. The role of acyl-L-carnitine as a reservoir of activated acyl groups, the buffer function of carnitine, and the importance of the acyl-CoA/free CoA ratio in the reacylation process of erythrocyte membrane phospholipids have also been addressed. In intact erythrocytes, the incorporation of [1-14C]palmitic acid into acyl-L-carnitine, phosphatidylcholine, and phosphatidylethanolamine was linear with time for at least 3 h. The greatest proportion of the radioactivity was found in acyl-L-carnitine. Competition experiments using [1-14C]palmitic and [9,10-3H]oleic acid demonstrated that [9,10-3H]oleic acid was incorporated preferentially into the phospholipids and less into acyl-L-carnitine. When an erythrocyte suspension was incubated with [1-14C]palmitoyl-L-carnitine, radiolabeled palmitate was recovered in the phospholipid fraction, and the carnitine palmitoyltransferase inhibitor, 2-tetradecylglycidic acid, completely abolished the incorporation. ATP depletion decreased incorporation of [1-14C]palmitic and/or [9,10-3H]oleic acid into acyl-L-carnitine, but the incorporation into phosphatidylcholine and phosphatidylethanolamine was unaffected. In contrast, ATP depletion enhanced the incorporation into phosphatidylcholine and phosphatidylethanolamine of the radiolabeled fatty acid from [1-14C]palmitoyl-L-carnitine. These data are suggestive of the existence of an acyl-L-carnitine pool, in equilibrium with the acyl-CoA pool, which serves as a reservoir of activated acyl groups. The carnitine palmitoyltransferase inhibition by 2-tetradecylglycidic acid or palmitoyl-D-carnitine caused a significant reduction of radiolabeled fatty acid incorporation into membrane phospholipids, only when intact erythrocytes were incubated with [9,10-3H]oleic acid. These latter data may be explained by the differences in rates and substrates specificities between acyl-CoA synthetase and the reacylating enzymes for palmitate and oleate, which support the importance of carnitine palmitoyltransferase in modulating the optimal acyl-CoA/free CoA ratio for the physiological expression of the membrane phospholipids fatty acid turnover.     

Lipid biosynthesis in developing and germinating soybean cotyledons: The formation of palmitate and stearate by chopped tissue and supernatant preparations

Chopped tissue from developing soybean cotyledons incorporated [1-¹⁴C]acetate into palmitate, stearate, oleate, and linoleate, but with germinating cotyledons much less [1-¹⁴C]acetate was incorporated and the principal labeled products were palmitate, stearate, and oleate. When supernatant fractions from developing cotyledons were incubated with [1-¹⁴C]acetate or [2-¹⁴C]malonate the principal labeled products were palmitate and stearate. Supernatant fractions from germinating seed incorporated [2-¹⁴C]malonate into palmitate and also into short chain fatty acids including decanoate, laurate, and myristate. Supernatants from developing cotyledons required acyl carrier protein (ACP), ATP, CoA, and reduced pyridine nucleotides for maximal rates of incorporation of either [1-¹⁴C]acetate or [2-¹⁴C]malonate into palmitate and stearate. The de novo fatty acid synthetase which converts acetyl- and malonyl-ACP's to palmityl ACP was active in supernatant fractions from both young and old developing cotyledons. The elongation system, converting palmityl ACP to stearyl ACP, was more active in supernatants from younger than from older developing cotyledons. In experiments with chopped tissue the elongation system appeared equally active throughout the development process. These results are consistent with the view that the de novo and elongation systems are separate entities and that the elongation system in older cotyledons is less stable to the methods used to prepare supernatant fractions.     

The elongation of exogenous fatty acids and the control of phospholipid acyl chain length in Micrococcus cryophilus.

The synthesis of fatty acids de novo from acetate and the elongation of exogenous satuated fatty acids (C12-C18) by the psychrophilic bacterium Micrococcus cryophilus (A.T.C.C. 15174) grown at 1 or 20 degrees C was investigated. M. cryophilus normally contains only C16 and C18 acyl chains in its phospholipids, and the C18/C16 ratio is altered by changes in growth temperature. The bacterium was shown to regulate strictly its phospholipid acyl chain length and to be capable of directly elongating myristate and palmitate, and possibly laurate, to a mixture of C16 and C18 acyl chains. Retroconversion of stearate into palmitate also occurred. Fatty acid elongation could be distinguished from fatty acid synthesis de novo by the greater sensitivity of fatty acid elongation to inhibition by NaAsO2 under conditions when the supply of ATP and reduced nicotinamide nucleotides was not limiting. It is suggested that phospholipid acyl chain length may be controlled by a membrane-bound elongase enzyme, which interconverts C16 and C18 fatty acids via a C14 intermediate; the activity of the enzyme could be regulated by membrane lipid fluidity.     

Evidence that oleoyl-CoA and ATP-dependent elongations coexist in rapeseed (Brassica napus L.).

The elongation of different substrates was studied using several subcellular fractions from Brassica napus rapeseed. In the presence of malonyl-CoA, NADH and NADPH, very-long-chain fatty acid (VLCFA) synthesis was observed from either oleoyl-CoA (acyl-CoA elongation) or endogenous primers (ATP-dependent elongation). No activity was detected using oleic acid as precursor. Acyl-CoA and ATP-dependent elongation activities were mainly associated with the 15 000 g/25 min membrane fraction. Reverse-phase TLC analysis showed that the proportions of fatty acids synthesized by these activities were different. Acyl-CoA elongation increased up to 60 microM oleoyl-CoA, and ATP-dependent elongation was maximum at 1 mM ATP. Both activities increased with malonyl-CoA concentration (up to 200 microM). Under all conditions tested, acyl-CoA elongation was higher than ATP-dependent elongation, and, in the presence of both ATP and oleoyl-CoA, the elongation activity was always lower. ATP strongly inhibited acyl-CoA elongation, whereas ATP-dependent elongation was slightly stimulated by low oleoyl-CoA concentrations (up to 15 microM) and decreased in the presence of higher concentrations. CoA (up to 150 microM) had no effect on the ATP-dependent elongation, whereas it inhibited the acyl-CoA elongation. These marked differences strongly support the presence in maturing rapeseed of two different elongating activities differently modulated by ATP and oleoyl-CoA.     

Epicuticular Wax Accumulation and Fatty Acid Elongation Activities Are Induced during Leaf Development of Leeks

Epicuticular wax production was evaluated along the length of expanding leek (Allium porrum L.) leaves to gain insight into the regulation of wax production. Leaf segments from the bottom to the top were analyzed for (a) wax composition and load; (b) microsomal fatty acid elongase, plastidial fatty acid synthase, and acyl-acyl carrier protein (ACP) thioesterase activities; and (c) tissue and cellular morphological changes. The level of total wax, which was low at the bottom, increased 23-fold along the length of the leaf, whereas accumulation of the hentriacontan-16-one increased more than 1000-fold. The onset of wax accumulation was not linked to cell elongation but, rather, occurred several centimeters above the leaf base. Peak microsomal fatty acid elongation activity preceded the onset of wax accumulation, and the maximum fatty acid synthase activity was coincident with the onset. The C16:0- and C18:0-ACP-hydrolyzing activities changed relatively little along the leaf, whereas C18:1-ACP-hydrolyzing activity increased slightly prior to the peak elongase activity. Electron micrographic analyses revealed that wax crystal formation was asynchronous among cells in the initial stages of wax deposition, and morphological changes in the cuticle and cell wall preceded the appearance of wax crystals. These studies demonstrated that wax production and microsomal fatty acid elongation activities were induced within a defined and identifiable region of the expanding leek leaf and provide the foundation for future molecular studies.     

Coenzyme A-dependent transacylation system in rabbit liver microsomes

The activities of cofactor-independent and CoA-dependent transacylation were examined for various rabbit tissues. Liver microsomes were found to exhibit relatively high CoA-dependent transacylation activity, while the cofactor-independent transacylation activity was low. The apparent Km values for CoA were 1.4 microM (acceptor, 1-acyl-sn-glycero-3-phosphocholine (1-acyl-GPC] and 3.8 microM (acceptor, 1-acyl-sn-glycero-3-phosphoethanolamine (1-acyl-GPE], respectively. The apparent Vmax values were 2.6 nmol/min/mg (1-acyl-GPC) and 1.2 nmol/min/mg (1-acyl-GPE), respectively. The CoA-dependent transacylation reaction shows a distinct fatty acid specificity. [14C]18:2 and [14C]20:4 at the 2-positions and [14C]18:0 at the 1-positions of donor phospholipids were transferred to lysophospholipids in the presence of CoA. We observed the formation of considerable amounts of acyl-CoA from these fatty acids during the reaction, without the participation of ATP. The transfer of other fatty acids between phospholipids was shown to be almost nil. The very low transfer of 18:1 was in marked contrast to the effective utilization of 18:1-CoA by acyl-CoA:1-acyl-GPC acyltransferase. The effects of several compounds and heat treatment on these two acylation reactions were also examined. The CoA-dependent transacylation reaction may be important for the selective acylation of certain lysophospholipids, such as 1-acyl-GPE, in living cells with the cooperation of acyl-CoA:lysophospholipid acyltransferase, which generates CoA for the former reaction.