Developmental induction, purification, and further characterization of 12:0-ACP thioesterase from immature cotyledons of Umbellularia californica

The fatty acyl content of developing cotyledons of Umbellularia californica (California Bay) changes from a long-chain composition to a predominance of 10:0 and 12:0 in just 4-5 days at the beginning of an approximately 100-day period of medium-chain deposition. This striking change occurs at the earliest appearance of 12:0-acyl-carrier protein (ACP) thioesterase activity. The coincidence of these rapid events is consistent with the hypothesis that the enzyme plays a major role in medium-chain biosynthesis. The 12:0-ACP thioesterase has been substantially purified; enzyme activity consistently comigrates in chromatographic and electrophoretic systems with a protein or pair of proteins having an apparent molecular weight of approximately 34 kDa. A native molecular weight of approximately 42 kDa has been estimated by gel filtration chromatography, suggesting that the enzyme is a monomer. Affinity chromatography on immobilized ACP is a critical step in the purification procedure, and resolves the 12:0-ACP and 18:1-ACP thioesterases sufficiently to confirm that the medium-chain enzyme has negligible action on 18:1-ACP.     

Broad-range and binary-range acyl-acyl-carrier protein thioesterases suggest an alternative mechanism for medium-chain production in seeds.

In the current model of medium-chain (C8-14) fatty acid biosynthesis in seeds, specialized FatB acyl-acyl-carrier-protein (ACP) thioesterases are responsible for the production of medium chains. We have isolated and characterized FatB cDNAs from the maturing seeds of elm (Ulmus americana) and nutmeg (Myristica fragrans), which accumulate predominantly caprate (10:0)- and myristate (14:0)-containing oils, respectively. In neither species were we able to find cDNAs encoding enzymes specialized for these chain lengths. Nutmeg FatB hydrolyses C14-18 substrates in vitro and expression in Brassica napus seeds leads to an oil enriched in C14-18 saturates. Elm FatB1 displays a binary specificity: one activity is centered on 10:0-ACP, and a second is centered on palmitate (16:0)-ACP. After expression in B. napus seeds the oil is enriched in C10-18 saturates, predominantly 16:0, 14:0, and 10:0. The composition of free fatty acids produced by elm FatB1 in Escherichia coli shifts from C14-16 to mostly C8-10 by increasing the rate of chain termination by this enzyme. These results suggest the existence of an alternative mechanism used in the evolution of medium-chain production, a model of which is presented.     

Production of high levels of 8:0 and 10:0 fatty acids in transgenic canola by overexpression of Ch FatB2, a thioesterase cDNA from Cuphea hookeriana

The Mexican shrub Cuphea hookeriana accumulates up to 75% caprylate (8:0) and caprate (10:0) in its seed oil. An acyl-ACP thioesterase cDNA from C. hookeriana , designated Ch FatB2 , has been identified, which, when expressed in Escherichia coli , provides thioesterase activity specific for 8:0- and 10:0-ACP substrates. Expression of this clone in seeds of transgenic canola, an oilseed crop that normally does not accumulate any 8:0 and 10:0, resulted in a dramatic increase in the levels of these two fatty acids accompanied by a preferential decrease in the levels of linoleate (18:2) and linolenate (18:3). The Ch FatB2 differs from Ch FatB1 , another Cuphea hookeriana thioesterase reported recently, in both substrate specificity and expression pattern. The Ch FatB1 has a broad substrate specificity with strong preference for 16:0-ACP and is expressed throughout the plant; whereas Ch FatB2 is specific for 8:0/10:0-ACP and its expression is confined to the seed. It is proposed that the amplified expression of Ch FatB2 in the embryo provides the hydrolytic enzyme specificity determining the fatty acyl composition of Cuphea hookeriana seed oil.     

Solution structures of spinach acyl carrier protein with decanoate and stearate

Acyl carrier protein (ACP) is a cofactor in a variety of biosynthetic pathways, including fatty acid metabolism. Thus, it is of interest to determine structures of physiologically relevant ACP-fatty acid complexes. We report here the NMR solution structures of spinach ACP with decanoate (10:0-ACP) and stearate (18:0-ACP) attached to the 4'-phosphopantetheine prosthetic group. The protein in the fatty acid complexes adopts a single conformer, unlike apo- and holo-ACP, which interconvert in solution between two major conformers. The protein component of both 10:0- and 18:0-ACP adopts the four-helix bundle topology characteristic of ACP, and a fatty acid binding cavity was identified in both structures. Portions of the protein close in space to the fatty acid and the 4'-phosphopantetheine were identified using filtered/edited NOESY experiments. A docking protocol was used to generate protein structures containing bound fatty acid for 10:0- and 18:0-ACP. In both cases, the predominant structure contained fatty acid bound down the center of the helical bundle, in agreement with the location of the fatty acid binding pockets. These structures demonstrate the conformational flexibility of spinach ACP and suggest how the protein changes to accommodate its myriad binding partners.     

Alteration of the specificity and regulation of fatty acid synthesis of Escherichia coli by expression of a plant medium-chain acyl-acyl carrier protein thioesterase.

The expression of a plant (Umbellularia californica) medium-chain acyl-acyl carrier protein (ACP) thioesterase (BTE) cDNA in Escherichia coli results in a very high level of extractable medium-chain-specific hydrolytic activity but causes only a minor accumulation of medium-chain fatty acids. BTE's full impact on the bacterial fatty acid synthase is apparent only after expression in a strain deficient in fatty acid degradation, in which BTE increases the total fatty acid output of the bacterial cultures fourfold. Laurate (12:0), normally a minor fatty acid component of E. coli, becomes predominant, is secreted into the medium, and can accumulate to a level comparable to the total dry weight of the bacteria. Also, large quantities of 12:1, 14:0, and 14:1 are made. At the end of exponential growth, the pathway of saturated fatty acids is almost 100% diverted by BTE to the production of free medium-chain fatty acids, starving the cells for saturated acyl-ACP substrates for lipid biosynthesis. This results in drastic changes in membrane lipid composition from predominantly 16:0 to 18:1. The continued hydrolysis of medium-chain ACPs by the BTE causes the bacterial fatty acid synthase to produce fatty acids even when membrane production has ceased in stationary phase, which shows that the fatty acid synthesis rate can be uncoupled from phospholipid biosynthesis and suggests that acyl-ACP intermediates might normally act as feedback inhibitors for fatty acid synthase. As the fatty acid synthesis is increasingly diverted to medium chains with the onset of stationary phase, the rate of C12 production increases relative to C14 production. This observation is consistent with activity of the BTE on free acyl-ACP pools, as opposed to its interaction with fatty acid synthase-bound substrates.     

Fat metabolism in higher plants. The function of acyl thioesterases in the metabolism of acyl-coenzymes A and acyl-acyl carrier proteins.

Extracts of avocado mesocarp rapidly desaturate stearyl-acyl carrier protein (ACP) to free oleic acid. In addition to stearyl-ACP desaturase activity, the extracts contained a very active acyl thioesterase. After this activity was separated by ammonium sulfate fractionation from stearyl-ACP desaturase, over 95% of the desaturase product (18:1) was recovered as 18:1-ACP. The thioesterase was much more active toward 18:1-ACP than toward the other acyl-ACPs and acyl-CoAs tested. Long chain acyl thioesterase activity was present in a variety of plant cells, photosynthetic as well as nonphotosynthetic. The possible role of acyl thioesterases in regulating plant biosynthetic reactions involving lipids is discussed.     

Characterization of acyl‐ACP thioesterases of mangosteen (Garcinia mangostana) seed and high levels of stearate production in transgenic canola

Acyl-acyl-carrier protein (ACP) thioesterases are, at least in part, responsible for the fatty acyl chain length composition of seed storage oils. Acyl-ACP thioesterases with specificity for each of the saturated acyl-ACP substrates from 8:0 through 16:0 have been cloned, with the exception of 18:0, and are members of the FatB class of thioesterases. The authors have determined that the tropical tree species mangosteen (Garcinia mangostana) stores 18:0 (stearate) in its seed oil in amounts of up to 56% by weight. Acyl-ACP thioesterase activity as measured in crude mangosteen seed extracts showed a preference for 18:1-ACP substrates, but had significant activity with 18:0 relative to that with 16:0-ACP, suggesting a thioesterase might be involved in the production of stearate. Three distinct acyl-ACP thioesterases were cloned from mangosteen seed cDNA; two representative of the FatA class and one representative of the FatB class. When expressed in vitro, the enzyme encoded by one of the FatAs (Garm FatA1) while preferring 18:1-ACP showed relatively low activity with 16:0-ACP as compared to 18:0-ACP, similar to the substrate preferences shown by the crude seed extract. Expression of Garm FatA1 in Brassica seeds led to the accumulation of stearate up to 22% in seed oil. These results suggest that Garm FatA1 is at least partially responsible for determining the high stearate composition of mangosteen seed oil and that FatA as well FatB thioesterases have evolved for specialized roles.     

Redirection of metabolic flux for high levels of omega‐7 monounsaturated fatty acid accumulation in camelina seeds

Seed oils enriched in omega‐7 monounsaturated fatty acids, including palmitoleic acid (16:1?9) and cis‐vaccenic acid (18:1?11), have nutraceutical and industrial value for polyethylene production and biofuels. Existing oilseed crops accumulate only small amounts (<2%) of these novel fatty acids in their seed oils. We demonstrate a strategy for enhanced production of omega‐7 monounsaturated fatty acids in camelina (Camelina sativa) and soybean (Glycine max) that is dependent on redirection of metabolic flux from the typical ?9 desaturation of stearoyl (18:0)‐acyl carrier protein (ACP) to ?9 desaturation of palmitoyl (16:0)‐acyl carrier protein (ACP) and coenzyme A (CoA). This was achieved by seed‐specific co‐expression of a mutant ?9‐acyl‐ACP and an acyl‐CoA desaturase with high specificity for 16:0‐ACP and CoA substrates, respectively. This strategy was most effective in camelina where seed oils with ~17% omega‐7 monounsaturated fatty acids were obtained. Further increases in omega‐7 fatty acid accumulation to 60–65% of the total fatty acids in camelina seeds were achieved by inclusion of seed‐specific suppression of 3‐keto‐acyl‐ACP synthase II and the FatB 16:0‐ACP thioesterase genes to increase substrate pool sizes of 16:0‐ACP for the ?9‐acyl‐ACP desaturase and by blocking C18 fatty acid elongation. Seeds from these lines also had total saturated fatty acids reduced to ~5% of the seed oil versus ~12% in seeds of nontransformed plants. Consistent with accumulation of triacylglycerol species with shorter fatty acid chain lengths and increased monounsaturation, seed oils from engineered lines had marked shifts in thermotropic properties that may be of value for biofuel applications.     

In vivo pools of free and acylated acyl carrier proteins in spinach. Evidence for sites of regulation of fatty acid biosynthesis

In order to examine potential regulatory steps in plant fatty acid biosynthesis, we have developed procedures for the analysis of the major acyl-acyl carrier protein (ACP) intermediates of this pathway. These techniques have been used to separate and identify acyl-ACPs with chain configurations ranging from 2:0 to 18:1 and to determine the relative in vivo concentrations of acyl-ACPs in spinach leaf and developing seed. In both leaf and seed as much as 60% of the total ACPs were nonesterified (free), with the remaining proportion consisting of acyl-ACP intermediates leading to the formation of palmitate, stearate, and oleate. In spinach leaf the proportions of the various acyl groups esterified to each ACP isoform were indistinguishable, indicating that these isoforms are utilized similarly in de novo fatty acid biosynthesis in vivo. However, the acyl group distribution pattern of seed ACP-II differed significantly from that of leaf ACP-II. The malonyl-ACP levels were less than the 4:0-ACP and 6:0-ACP levels in leaf, and in contrast, the malonyl-ACP-II levels in seed were approximately 3-fold higher than the 4:0-ACP-II and 6:0-ACP-II levels. In addition, the ratio of oleoyl-ACP-II (18:1) to stearoyl-ACP-II (18:0) was higher in seed than in leaf. These data suggest that the differences in acyl-ACP patterns reflect a tissue/organ-specific difference rather than an isoform-specific difference. In extracts prepared from leaf samples collected in the dark, the levels of acetyl-ACPs were approximately 5-fold higher compared to samples collected in the light. The levels of free ACPs showed an inverse response, increasing in the light and decreasing in the dark. Notably there was no concomitant increase in the malonyl-ACP levels. The most likely explanation for the major increase in acetyl-ACP levels in the dark is that light/dark control over the rate of fatty acid biosynthesis occurs at the reaction catalyzed by acetyl-CoA carboxylase.     

Exogenous myristic acid can be partially degraded prior to activation to form acyl-acyl carrier protein intermediates and lipid A in Vibrio harveyi.

To study the involvement of acyl carrier protein (ACP) in the metabolism of exogenous fatty acids in Vibrio harveyi, cultures were incubated in minimal medium with [9,10-3H]myristic acid, and labeled proteins were analyzed by gel electrophoresis. Labeled acyl-ACP was positively identified by immunoprecipitation with anti-V. harveyi ACP serum and comigration with acyl-ACP standards and [3H]beta-alanine-labeled bands on both sodium dodecyl sulfate- and urea-polyacrylamide gels. Surprisingly, most of the acyl-ACP label corresponded to fatty acid chain lengths of less than 14 carbons: C14, C12, C10, and C8 represented 33, 40, 14, and 8% of total [3H]14:0-derived acyl-ACPs, respectively, in a dark mutant (M17) of V. harveyi which lacks myristoyl-ACP esterase activity; however, labeled 14:0-ACP was absent in the wild-type strain. 14:0- and 12:0-ACP were also the predominant species labeled in complex medium. In contrast, short-chain acyl-ACPs (< or = C6) were the major labeled derivatives when V. harveyi was incubated with [3H]acetate, indicating that acyl-ACP labeling with [3H]14:0 in vivo is not due to the total degradation of [3H]14:0 to [3H]acetyl coenzyme A followed by resynthesis. Cerulenin increased the mass of medium- to long-chain acyl-ACPs (> or = C8) labeled with [3H]beta-alanine fivefold, while total incorporation of [3H]14:0 was not affected, although a shift to shorter chain lengths was noted. Additional bands which comigrated with acyl-ACP on sodium dodecyl sulfate gels were identified as lipopolysaccharide by acid hydrolysis and thin-layer chromatography. The levels of incorporation of [3H] 14:0 into acyl-ACP and lipopolysaccharide were 2 and 15%, respectively, of that into phospholipid by 10 min. Our results indicate that in contrast to the situation in Escherichia coli, exogenous fatty acids can be activated to acyl-ACP intermediates after partial degradation in V. harveyi and can effectively label products (i.e., lipid A) that require ACP as an acyl donor.     

A multifunctional acyl-acyl carrier protein desaturase from Hedera helix L. (English ivy) can synthesize 16- and 18-carbon monoene and diene products

A desaturase with 83% sequence identity to the coriander delta(4)-16:0-ACP desaturase was isolated from developing seeds of Hedera helix (English ivy). Expression of the ivy desaturase in Arabidopsis resulted in the accumulation of 16:1delta(4) and its expected elongation product 18:1delta(6) (petroselinic acid). Expression in Escherichia coli resulted in the accumulation of soluble, active protein that was purified to apparent homogeneity. In vitro assays confirmed delta(4) desaturation with 16:0-ACP; however, with 18:0-acyl acyl carrier protein (ACP) desaturation occurred at the delta(9) position. The ivy desaturase also converted 16:1delta(9)-ACP and 18:1delta(9)-ACP to the corresponding delta(4,9) dienes. These data suggest at least two distinct substrate binding modes, one placing C4 at the diiron active site and the other placing C9 at the active site. In the latter case, 18:0 would likely bind in an extended conformation as described for the castor desaturase with 9-carbons accommodated in the cavity beyond the dirron site. However, delta(4) desaturation would require the accommodation of 12 carbons for C16 substrates or 14 carbons for C18 substrates. The amino acids lining the substrate binding cavity of ivy and castor desaturases are conserved except for T117R and P179I (castor/ivy). Paradoxically, both substitutions, when introduced into the castor desaturase, favored the binding of shorter acyl chains. Thus, it seems likely that delta(4) desaturation would require a non-extended, perhaps U-shaped, substrate conformation. A cis double bond may facilitate the initiation of such a non-extended conformation in the monounsaturated substrates. The multifunctional properties of the ivy desaturase make it well suited for further dissection of the determinants of regiospecificity.     

What limits production of unusual monoenoic fatty acids in transgenic plants?

Unusual monounsaturated fatty acids are major constituents (greater than 80%) in seeds of Coriandrum sativum L. (coriander) and Thunbergia alata Bojer, as well as in glandular trichomes (greater than 80% derived products) of Pelargonium x hortorum (geranium). These diverged fatty acid structures are produced via distinct plastidial acyl-acyl carrier protein (ACP) desaturases. When expressed in Arabidopsis thaliana (L.) Heynh. under strong seed-specific promoters the unusual acyl-ACP desaturases resulted in accumulation of unusual monoene fatty acids at 1-15% of seed fatty acid mass. In this study, we have examined several factors that potentially limit higher production of unusual monoenes in transgenic oilseeds. (i) Immunoblots indicated that the introduced desaturases were expressed at levels equivalent to or higher than the endogenous delta9 18:0-ACP desaturase. However, the level of unusual fatty acid produced in transgenic plants was not correlated with the level of desaturase expression. (ii) The unusual desaturases were expressed in several backgrounds, including antisense 18:0-ACP desaturase plants, in fab1 mutants, and co-expressed with specialized ACP or ferredoxin isoforms. None of these experiments led to high production of expected products. (iii) No evidence was found for degradation of the unusual fatty acids during seed development. (iv) Petroselinic acid added to developing seeds was incorporated into triacylglycerol as readily as oleic acid, suggesting no major barriers to its metabolism by enzymes of glycerolipid assembly. (v) In vitro and in situ assay of acyl-ACP desaturases revealed a large discrepancy of activity when comparing unusual acyl-ACP desaturases with the endogenous delta9 18:0-ACP desaturase. The combined results, coupled with the sensitivity of acyl-ACP desaturase activity to centrifugation and low salt or detergent suggests low production of unusual monoenes in transgenic plants may be due to the lack of, or incorrect assemble of, a necessary multi-component enzyme association.     

Role of hydrophobic partitioning in substrate selectivity and turnover of the ricinus communis stearoyl acyl carrier protein delta(9) desaturase.

Stearoyl acyl carrier protein Delta(9) desaturase (Delta9D) uses a diiron center to catalyze the NADPH- and O(2)-dependent desaturation of stearoyl acyl carrier protein (ACP) to form oleoyl-ACP. The reaction of recombinant Ricinus communis Delta9D with natural and nonnatural chain length acyl-ACPs was used to examine the coupling of the reconstituted enzyme complex, the specificity for position of double-bond insertion, the kinetic parameters for the desaturation reaction, and the selectivity for acyl chain length. The coupling of NADPH and O(2) consumption and olefin production was found to be maximal for 18:0-ACP, and the loss of coupling observed for the more slowly desaturated acyl-ACPs was attributed to autoxidation of the electron-transfer chain. Analysis of steady-state kinetic parameters for desaturation of acyl-ACPs having various acyl chain lengths revealed that the K(M) values were similar ( approximately 2.5-fold difference) for 15:0-18:0-ACP, while the k(cat) values increased by approximately 26-fold for the same range of acyl chain lengths. A linear increase in log (k(cat)/K(M)) was observed upon lengthening of the acyl chain from 15:0- to 18:0-ACP, while no further increase was observed for 19:0-ACP. The similarity of the k(cat)/K(M) values for 18:0- and 19:0-ACPs and the retained preference for double-bond insertion at the Delta(9) position with 19:0-ACP (>98% desaturation at the Delta(9) position) suggest that the active-site channel past the diiron center can accommodate at least one more methylene group than is found in the natural substrate. The DeltaDeltaG(binding) estimated from the change in k(cat)/K(M) for increasing substrate acyl-chain length was -3 kJ/mol per methylene group, similar to the value of -3.5 kJ/mol estimated for the hydrophobic partition of long-chain fatty acids (C-7 to C-21) from water to heptane [Smith, R. , and Tanford, C. (1973) Proc. Natl. Acad. Sci. U.S.A. 70, 289-293]. Since the K(M) values are overall similar for all acyl-ACPs tested, the progressive increase in hydrophobic binding energy available from increased chain length is apparently utilized to enhance catalytic steps, which thus provides the underlying physical mechanism for acyl chain selectivity observed with Delta9D.     

Change in Levels of Acyl Carrier Proteins in Greening Plants

The levels of acyl carrier proteins (ACP) in greening spinachcotyledons and greening oat leaves were examined by immunoblottingwith antiserum raised against spinach ACP I. Two isoforms ofACP, ACP I and ACP II, were found in spinach cotyledons, asthey were in the green leaves. The level of ACP II was higherthan that of ACP I in etiolated cotyledons. The level of ACPI increased markedly with greening. In the greened cotyledons,the major isoform was ACP I as was the case in green spinachleaves. In oat leaves, two isoforms were also identified, oatACPI (about 12kDa) and ACP II (about 17kDa), which cross-reactedwith the antiserum against spinach ACP I, but which were differentfrom spinach ACPs I and II. The levels of oat ACPs I and IIwere very low in etiolated leaves. The increase in levels ofboth ACPs corresponded to the change in the activity of fattyacid synthesis during illumination for 24 h. During furtherillumination for 24 h, the level of ACP II increased a littlein parallel with the change in the activity of fatty acid synthesis,whereas the level of ACP I increased somewhat more. The functionof oat ACPs I and II is discussed in connection with the formationof chloroplast. (Received March 27, 1989; Accepted September 18, 1989)     

Beta-ketoacyl-acyl carrier protein synthase IV: a key enzyme for regulation of medium-chain fatty acid synthesis in Cuphea lanceolata seeds

With the aim of elucidating the mechanisms involved in the biosynthesis of medium-chain fatty acids in Cuphea lanceolata Ait., a crop accumulating up to 90% decanoic acid in seed triacylglycerols, cDNA clones of a beta-ketoacyl-acyl carrier protein (ACP) synthase IV (clKAS IV, EC 2.3.1.41) were isolated from C. lanceolata seed embryos. The amino acid sequence deduced from clKAS IV cDNA showed 80% identity to other plant KAS II-type enzymes, 55% identity towards plant KAS I and over 90% towards other Cuphea KAS IV-type sequences. Recombinant clKAS IV was functionally overexpressed in Escherichia coli, and substrate specificity of purified enzyme showed strong preference for elongation of short-chain and medium-chain acyl-ACPs (C4- to C10-ACP) with nearly equal activity. Further elongation steps were catalysed with distinctly less activity. Moreover, short- and medium-chain acyl-ACPs exerted a chain-length-specific and concentration-dependent substrate inhibition of clKAS IV. Based on these findings a regulatory mechanism for medium-chain fatty acid synthesis in C. lanceolata is presented.     

Medium-chain fatty acid biosynthesis and utilization in Brassica napus plants expressing lauroyl-acyl carrier protein thioesterase

We have examined production of mediumchain fatty acids by Brassica napus L. plants transformed with a California bay (Umbellularia californica) medium-chain acyl-acyl carrier protein (ACP) thioesterase (UcFatB1) cDNA under the control of the constitutive cauliflower mosaic virus 35S promoter. These plants were found to accumulate medium-chain fatty acids in seeds but not in leaves or roots. Assay of thioesterase activity in extracts of leaves indicated that lauroyl-ACP thioesterase activity is comparable to oleoyl-ACP thioesterase (EC 3.1.2.14) activity in transformant leaves. Furthermore, leaf lauroyl-ACP thioesterase activity was in excess of that which produced a significant increase in the amount of laurate (12:0) in seed. Studies in which isolated chloroplasts were ¹⁴C-labelled were used to evaluate whether medium-chain fatty acids were produced in transformed leaves. Up to 34% of the fatty acids synthesized in vitro by isolated chloroplasts were 12:0. These results demonstrate that the normally seed-localized lauroyl-ACP thioesterase can be expressed in active form in leaves, imported into chloroplasts and can access acyl-ACP intermediates of leaf de-novo fatty acid synthesis. The most likely explanation for the lack of accumulation of 12:0 in transformed leaves is its rapid degradation by -oxidation. In support of this hypothesis, isocitrate lyase (EC 4.1.3.1) activity was found to be significantly increased in plants transformed with 35S-UcFatB1.Abbreviations ACP acyl carrier protein - CaMV cauliflower mosaic virus - control Brassica napus cultivar 212/86 - event 8 pCGN3831-212/86-8 - event 11 pCGN3831-212/86-11 - FAS fatty acid synthase - IL isocitrate lyase - KAS -keto-acyl ACP synthase - MS malate synthase - OTE oleoyl-ACP thioesterase - TAG triacylglycerol - UcFatB1 California bay medium-chain acyl-ACP thioesterase We are indebted to Calgene's Brossica-transformation, growth-chamber, greenhouse, and lipid-analysis personnel. Maelor Davies conducted the initial tranformant analysis. We thank Laura Olsen for IL and MS Western blot analysis and advice on IL and MS activity assays. This work was supported in part by a grant from the U.S. Department of Energy (No. DE-FG02-87ER12729). Acknowledgement is made to the Michigan Agricultural Experiment Station for its support of this research.     

Medium chain acyl-thioester hydrolase activity in goat and rabbit mammary gland fatty acid synthetase complexes

The goat mammary gland fatty acid synthetase hydrolysed both medium (C_8:0, C_10:0) and long (C_16:0, C_18:0) chain length acyl CoA esters, whereas the enzyme from rabbit mammary gland only hydrolysed long chain length acyl CoA esters. The medium chain acyl-thioester hydrolase activity of goat mammary gland fatty acid synthetase was much less sensitive to inhibition by phenylmethanesulfonyl-fluorid than the long chain acylthioester hydrolase activity. These results indicate the presence of either two acyl-thioester hydrolases with different specificity or one acyl-thioester hydrolase containing two different active sites.     

Acyl CoA profiles of transgenic plants that accumulate medium-chain fatty acids indicate inefficient storage lipid synthesis in developing oilseeds

Several Brassica napus lines transformed with genes responsible for the synthesis of medium- or long-chain fatty acids were examined to determine limiting factor(s) for the subsequent accumulation of these fatty acids in seed lipids. Examination of a decanoic acid (10:0) accumulating line revealed a disproportionately high concentration of 10:0 CoA during seed development compared to long-chain acyl CoAs isolated from the same tissues, suggesting that poor incorporation of 10:0 CoA into seed lipids limits 10:0 fatty acid accumulation. This relationship was also seen for dodecanoyl (12:0) CoA and fatty acid in a high 12:0 line, but not for octadecanoic (18:0) CoA and fatty acid in a high 18:0 line. Comparison of 10:0 CoA and fatty acid proportions from seeds at different developmental stages for transgenic B. napus and Cuphea hookeriana, the source plant for the medium-chain thioesterase and 3-ketoacyl-ACP synthase transgenes, revealed that C. hookeriana incorporates 10:0 CoA into seed lipids more efficiently than transgenic B. napus. Furthermore, beta-oxidation and glyoxylate cycle activities were not increased above wild type levels during seed development in the 8:0/10:0 line, suggesting that lipid catabolism was not being induced in response to the elevated 10:0 CoA concentrations. Taken together, these data suggest that transgenic plants that are engineered to synthesize medium-chain fatty acids may lack the necessary mechanisms, such as specific acyltransferases, to incorporate these fatty acids efficiently into seed lipids.     

Preparative enzymatic synthesis and hydrophobic chromatography of acyl-acyl carrier protein.

We have used purified preparations of acyl-acyl carrier protein synthetase to prepare pure, native acyl-acyl carrier proteins (acyl-ACP) ranging in chain lengths from C10:0 to C delta 9 18:1. Factors affecting yield are explored and reaction conditions are presented that yield 0.8 to 0.9 mg of C16:0-ACP/ml of reaction mix. Ohter acyl groups, such as C10:0 and C delta 9 18:1 are poorer substrates and gave correspondingly lower yields. Acyl-Acp synthetase may be recovered from the reaction mixture using blue-Sepharose CL-6B and recycled. ACP and acyl-ACP are separated by hydrophobic chromatography on octyl-Sepharose CL-4B. Mixtures of acyl-ACPs could be resolved according to acyl chain length using octyl-Sepharose CL-4B columns eluted with a 2-propanol gradient. The high resolution obtained using 2-propanol gradients to separate acyl-ACP species suggests that similar techniques would be applicable to the chromatography of protein mixtures on hydrophobic supports.     

The role of acyl carrier protein isoforms from Cuphea lanceolata seeds in the de-novo biosynthesis of medium-chain fatty acids

To investigate the role of acyl carrier protein (ACP) in determining the fate of the acyl moieties linked to it in the course of de-novo fatty acid biosynthesis in higher plants, we carried out in vitro experiments to reconstitute the fatty acid synthase (FAS) reaction in extracts of spinach (Spinaciaoleracea L.) leaves, rape (Brassicanapus L.) seeds and Cuphea lanceolata Ait. seeds. The action of two major C. lanceolata ACP isoforms (ACP 1 and ACP 2) compared to ACP from Escherichia coli was monitored by saponification of the corresponding FAS products with subsequent analysis of the liberated fatty acids by high-performance liquid chromatography. In a second approach the preference of the medium-chain acyl-ACP-specific thioesterase (EC 3.1.2.14) of C. lanceolata seeds for the hydrolysis of acyl-ACPs prepared from the three ACP types was investigated. Both ACP isoforms from C. lanceolata seeds supported the synthesis of medium-chain fatty acids in a reconstituted FAS reaction of spinach leaf extracts. Compared to the isoform ACP 1, ACP 2 was more effective in supporting the synthesis of such fatty acids in the FAS reaction of rape seed extracts and caused a higher accumulation of FAS products in all experiments. No preference of the medium-chain thioesterase for one specific ACP isoform was observed. The results indicate that the presence of ACP 2 is essential for the synthesis of decanoic acid in C. lanceolata seeds, and its expression in the phase of accumulation of high levels of this fatty acid provides an additional and highly efficient cofactor for stimulating the FAS reaction. Received: 23 June 1997 / Accepted: 23 October 1997