Biosynthesis of Very-Long-Chain Polyunsaturated Fatty Acids in Transgenic Oilseeds: Constraints on Their Accumulation

doi:10.1105/tpc.104.026070

Biosynthesis of Very-Long-Chain Polyunsaturated Fatty Acids in Transgenic Oilseeds: Constraints on Their Accumulation

Amine Abbadi^a^,1, Fréderic Domergue^a, Jörg Bauer^b, Johnathan A. Napier^c, Ruth Welti^d, Ulrich Zähringer^e, Petra Cirpus^b and Ernst Heinz^a

^a Institut für Allgemeine Botanik, Universität Hamburg, 22609 Hamburg, Germany
^b BASF Plant Science, BPS-A30, Ludwigshafen, Germany
^c Crop Performance and Improvement, Rothamsted Research, Harpenden, AL5 2JQ, United Kingdom
^d Division of Biology, Kansas State University, Manhattan, Kansas 66506
^e Forschungszentrum Borstel, 23485 Borstel, Germany

^¹ To whom correspondence should be addressed. E-mail abbadi{at}botanik.uni-hamburg.de; fax 49-4042816-254.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

${omega}$ 6- and ${omega}$ 3-polyunsaturated C20 fatty acids represent importantcomponents of the human diet. A more regular consumption andan accordingly sustainable source of these compounds are highlydesirable. In contrast with the very high levels to which industrialfatty acids have to be enriched in plant oils for competitiveuse as chemical feedstocks, much lower percentages of very-long-chainpolyunsaturated fatty acids (VLCPUFA) in edible plant oils wouldsatisfy nutritional requirements. Seed-specific expression intransgenic tobacco (Nicotiana tabacum) and linseed (Linum usitatissimum)of cDNAs encoding fatty acyl-desaturases and elongases, absentfrom all agronomically important plants, resulted in the veryhigh accumulation of ${Delta}$ 6-desaturated C18 fatty acids and up to5% of C20 polyunsaturated fatty acids, including arachidonicand eicosapentaenoic acid. Detailed lipid analyses of developingseeds from transgenic plants were interpretated as indicatingthat, after desaturation on phosphatidylcholine, ${Delta}$ 6-desaturatedproducts are immediately channeled to the triacylglycerols andeffectively bypass the acyl-CoA pool. Thus, the lack of available ${Delta}$ 6-desaturated acyl-CoA substrates in the acyl-CoA pool limitsthe synthesis of elongated C20 fatty acids and disrupts thealternating sequence of lipid-linked desaturations and acyl-CoAdependent elongations. As well as the successful productionof VLCPUFA in transgenic oilseeds and the identification ofconstraints on their accumulation, our results indicate alternativestrategies to circumvent this bottleneck.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

Very-long-chain polyunsaturated fatty acids (VLCPUFA) have 20or 22 carbon atoms and 4, 5, or 6 methylene-interrupted cis-doublebonds in ${omega}$ 6- or ${omega}$ 3-arrangements. The nutritionally most importantVLCPUFA are arachidonic (ARA; ${omega}$ 6-20:4^5,8,11,14), eicosapentaenoic(EPA; ${omega}$ 3-20:5^5,8,11,14,17), and docosahexaenoic acid ( ${omega}$ -3 22:6^{4,7,10,13,16,19}).Human physiology depends in various ways on these VLCPUFA, eitheras components of membrane phospholipids in specific tissuesor as precursors for the synthesis of the different groups ofeicosanoid effectors (e.g., prostaglandins) (Jump, 2002). VLCPUFAare not only required for the development of the fetal neuronalsystem but also contribute via a multiplicity of beneficialroles to the maintenance of health with increasing developmentand age, particularly by reducing the incidence of cardiovasculardiseases (Demaison and Moreau, 2002). These fatty acids areeither directly available as components of the diet or producedfrom the two essential ${omega}$ 6- and ${omega}$ 3-C18 fatty acids, linoleic ( ${omega}$ 6-C18:2^9,12)and ${alpha}$ -linolenic acid ( ${omega}$ 3-C18:3^9,12,15) (Okuyama et al., 1996).Official organizations recommend that the intake of EPA shouldbe 0.2 to 0.5 g per day (Trautwein, 2001). Thus, the daily consumptionof $~$ 10 g (i.e., a spoonful) of a plant oil with 2 to 5% of thisfatty acid would meet the recommended dietary intake. By contrast,levels of so called industrial fatty acids for use in the chemicalindustry have to represent $~$ 90% of the fatty acids in seed oilsto be considered commercially viable, which is 10 to 20 timeshigher than the nutritionally important proportion of VLCPUFAin edible oils.

Reliable dietary sources of VLCPUFA are fish oils, whereas linoleicand linolenic acid predominate in green vegetables and someplant oils, all of which do not contain VLCPUFA. On the otherhand, most processed food items with extended shelf life arecharacterized by high proportions of saturated fatty acids anda very high ratio of ${omega}$ 6/ ${omega}$ 3-polyunsaturated C18 fatty acids, farabove the recommended ratio of $~$ 6:1 (Trautwein, 2001). Therefore,the fatty acid profiles of modern western diets represent arather unfavorable situation for the endogenous biosynthesisof a balanced proportion of ${omega}$ 6/ ${omega}$ 3-VLCPUFA, particularly of EPAand docosahexaenoic acid (Sprecher, 2002). Because of the continuousdecrease of marine resources by overfishing and the environmentalimpact of fish farming (Pauly et al., 2002; Hites et al., 2004),neither farmed nor caught fish can be considered a sustainablesource of the VLCPUFA quantities required for a healthy nutritionof the growing human population. A solution to this predictedshortcoming may be realized by implementation of VLCPUFA biosynthesisinto annual oilseed crops (Galili et al., 2002). This sourcewould be more sustainable than production from single cell culturesof fungi or algae (Lopez Alonso and Garcia Maroto, 2000). Onthe other hand, these microorganisms are the most efficientprimary producers of VLCPUFA and express all the enzymes requiredfor their synthesis from C18:2 and C18:3 (Beaudoin et al., 2000;Abbadi et al., 2001; Domergue et al., 2002).

Previous experiments to change the fatty acid profiles of plantreserve triacylglycerols (TAG) by seed-specific expression ofvarious enzymes have shown that the success of these manipulationscannot be reliably predicted, and a central question remainsas to the mechanism(s) by which unusual fatty acids are accumulatedin TAG (Voelker and Kinney, 2001; Drexler et al., 2003a). Fora conversion of the polyunsaturated C18 fatty acids into ARAor EPA, formally three consecutive enzymatic steps are required: ${Delta}$ 6-desaturation, ${Delta}$ 6-elongation, and ${Delta}$ 5-desaturation (Figure 1).In a previous study, we demonstrated the reconstitution of ARAbiosynthesis in yeast and showed that the front-end desaturasesand elongases have strict acyl carrier specificities (Domergueet al., 2003). Here, we report experiments on the productionof C20-PUFA in seeds of transgenic tobacco (Nicotiana tabacum)and linseed expressing appropriate heterologous enzymes underthe control of seed-specific promoters and our effort to understandthe channeling of acyl groups to TAG synthesis.

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Figure 1. Simplified ${omega}$ 6- and ${omega}$ 3-Pathways for the Biosynthesis of VLCPUFA from Linoleic (18:2) and ${alpha}$ -Linolenic (18:3) Acid, Respectively.

	RESULTS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

Engineering of ARA and EPA Biosynthesis in Transgenic Plants
In the following, we report experiments on the production ofARA and EPA in seeds of transgenic higher plants. As heterologouscoding sequences we used cDNAs encoding two regiospecificallydifferent desaturases ( ${Delta}$ 6 and ${Delta}$ 5) and a ${Delta}$ 6-elongase, each underthe control of up to three different seed-specific promoters.The protein sequences were selected from a wide variety of VLCPUFA-producingorganisms such as fungi (Mortierella alpina; Ma) (Michaelsonet al., 1998

), algae (Phaeodactylum tricornutum; Pt) (Domergueet al., 2002

), mosses (Physcomitrella patens; Pp) (Girke etal., 1998

; Zank et al., 2002

), plants (Borago officinalis; Bo)(Sayanova et al., 1997

), and lower animals (Caenorhabditis elegans;Ce) (Napier et al., 1998

; Beaudoin et al., 2000

). Four differentcombinations of these sequences were placed in binary vectors(Figure 2) and used for transformation of N. tabacum (high inlinoleic acid, 18:2^9,12) and Linum usitatissimum (high in ${alpha}$ -linolenicacid, 18:3^9,12,15) to identify a useful combination and a suitableexpression host. For a first round of analysis, seeds of regeneratedtransgenic plants were collected at maturity and used for fattyacid analysis by gas–liquid chromatography (GLC)/massspectrometry (MS).

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Figure 2. T-DNA of the Binary Vectors Used for Plant Transformation.

LB and RB, left and right T-DNA borders, respectively; USP, promoter region of the unknown seed protein of Vicia faba; LeB4, promoter of the legumin gene of V. faba; Dc3, promoter of the helianthinin gene of Daucus carota; OCS, terminator region of octopin synthase gene of A. tumefaciens; 35S, 35S promoter of Cauliflower mosaic virus (CaMV); 35S ter, CaMV 35S terminator; Npt II, neomycin phosphotransferase gene; Pp ${Delta}$ 6, Bo ${Delta}$ 6, and Pt ${Delta}$ 6, ${Delta}$ 6-desaturases from P. patens (AJ222980), B. officinalis (U79010), and P. tricornutum (AY082393), respectively; Ma ${Delta}$ 5 and Pt ${Delta}$ 5, ${Delta}$ 5-desaturases from M. alpina (AF054824) and P. tricornutum (AY082392), respectively; PSE1 and PEA-1, ${Delta}$ 6-elongase from P. patens (AF428243) and C. elegans (F56H11.4), respectively.

Of the four combinations tested, only the expression of constructsC and D in tobacco and linseed were successful (Figure 3). Fiftyindependent transgenic tobacco and 46 independent linseed linesexpressing the construct C were obtained by Agrobacterium tumefaciens–mediatedtransformation. The fatty acid compositions of pooled T2 seedsfrom a selection of transgenic lines (Figure 3) showed highproportions of the two ${Delta}$ 6-C18-PUFAs ${gamma}$ -linolenic (18:3^6,9,12) andstearidonic acid (18:4^6,9,12,15) (2 to 29% in tobacco and 3to 37% in linseed) as well as significant but disproportionatelylow levels of C20-PUFA (1 to 3% in tobacco and 0.5 to 8.3% inlinseed; Figures 3A and 3B). These results indicate the following:(1) the promoters used enable sufficient expression in tobaccoand linseed; (2) the plant enzymes (algal desaturases and mosselongase) seem to be more efficient than animal and fungal enzymesin the hosts selected; (3) to obtain significant proportionsof C20-PUFA, the host plants should have high endogenous levelsof linoleic and/or ${alpha}$ -linolenic acid in their untransformed seeds.

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Figure 3. ${Delta}$ 6-C18- and C20-Polyunsaturated Fatty Acid Proportions in a Selection of Seeds from Primary Transformants of Tobacco and Linseed Transformed with Construct C.

Seeds were collected at 40 d after flowering (DAF) from transgenic tobacco (A) and linseed (B). FAMEs were prepared from whole seeds and analyzed by gas chromatography (GC) as indicated in Methods. Open bars, ${Delta}$ 6-C18-polyunsaturated fatty acid proportions; closed bars, C20-polyunsaturated fatty acid proportions.

Next, groups of the most promising linseed and tobacco transformantswith the construct C were subjected to DNA gel blot analysisfor a selection of plants with single copy integration to facilitatecomparative studies and the generation of homogeneous T3 progenyfor breeding. Fatty acid analysis of transgenic T3 seed mixturesshowed that in tobacco the ${omega}$ 6-pathway (Figure 4A) and in linseedboth the ${omega}$ 6- and ${omega}$ 3-pathways (Figure 4B) were successfully reconstituted.Several new fatty acids were detected in the chromatograms offatty acid methyl esters (FAMEs) from transgenic tobacco andlinseed, respectively (Figures 4A and 4B) that are not presentin the control plants. Mass spectra of their 4,4-dimethyloxazolinederivatives identified them as ${gamma}$ -18:3^6,9,12, 18:4^6,9,12,15, 20:3^8,11,14( ${omega}$ 6-20:3), 20:4^5,8,11,14 ( ${omega}$ 6-20:4), 20:4^8,11,14,17 ( ${omega}$ 3-20:4, ARA),and 20:5^5,8,11,14,17 ( ${omega}$ 3-20:5, EPA) (data not shown). The fattyacid compositions of wild-type and transgenic seeds are givenin Table 1. Among the new fatty acids produced in transgenicseeds, ${gamma}$ -18:3^6,9,12 is the most abundant and accounted for $~$ 30and 17% in tobacco and linseed, respectively. In linseed, 18:4^6,9,12,15was the next most abundant fatty acid and accounts for $~$ 13%.The presence of both ${gamma}$ -18:3^6,9,12 and 18:4^6,9,12,15 indicatesthat the ${Delta}$ 6-desaturase from P. tricornutum used both 18:2^9,12and ${alpha}$ -18:3^9,12,15 as substrates in plants. This leads to a decreasein 18:2^9,12 in transgenic tobacco and of 18:2^9,12 and ${alpha}$ -18:3^9,12,15in transgenic linseed. On the other hand, the various C20-PUFAfatty acids totaled 5%. ARA accumulated up to 2% in tobacco,whereas in linseed, both ARA (up to 1.5%) and EPA (up to 1%)were found (Figure 4, Table 1). The proportions of VLCPUFA inthe T3 seeds were comparable to those found in the T2 progeny,indicating that a stable phenotype was transferred to the nextgeneration. These data demonstrate that oilseeds can in factbe transformed to produce VLCPUFA and that the proportions weobserved in linseed are already close to the nutritionally relevantlevels described above. For that reason, all the following experimentswere conducted with linseed because of its importance as anoilseed crop.

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Figure 4. Fatty Acid Profiles of Seeds from Wild-Type and Single-Copy Tobacco and Linseed Transformants.

Seeds were collected at 40 DAF from wild-type ([A] and [C]) and transgenic ([B] and [D]) tobacco and linseed transformed with construct C (Figure 1). FAMEs were prepared from whole seeds and analyzed by GC as indicated in Methods. In this particular linseed plant, C20-polyunsaturated fatty acids accounted for 5% of the total fatty acids. It should be pointed out that none of the major peaks shown go off scale.

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Table 1. Fatty Acid Composition of Seeds from Wild-Type and Transgenic Tobacco and Linseed Plants

Why Not More ARA and EPA in the Transgenic Seeds: Is the Elongase Step Limiting?
The high proportions of ${Delta}$ 6-desaturated C18-polyunsaturated fattyacids found in transgenic linseed ( ${gamma}$ -18:3 and 18:4 totaling insome plants a maximum of 33%) contrasted with the low proportionsof C20-PUFA, indicating that the elongating activity may limitthe accumulation of C20-PUFAs. Using the same promoter in theconstruct C for the expression of all three genes could conceivablyinduce gene silencing of one of the transgenes. To see whetherthe low elongation can be ascribed to reduced elongase transgenetranscription in seeds, transcript levels of all three heterologousgenes were tested by semiquantitative RT-PCR during three differentstages of seed development. RT-PCR experiments showed that thethree heterologous genes ( ${Delta}$ 6-desaturase, ${Delta}$ 6-elongase, and ${Delta}$ 5-desturase)were transcribed at similar levels (data not shown). Furthermore,a nonradioactive assay has been developed to probe the elongaseactivity in total extracts and microsomes of the transgenicseeds. Incubation of microsomes from the transgenic seeds with18:4-CoA as the elongase substrate without malonyl-CoA and reducingequivalents (NADH and NADPH) showed that 18:4-CoA was recoveredafter extraction of total acyl-CoAs (Figure 5A). By contrast,when 18:4-CoA was incubated in the presence of malonyl-CoA andreducing equivalents with microsomes, an additional peak correspondingto 20:4-CoA (coeluting with 18:2) appeared in the chromatogramof the extracted acyl-CoAs, indicating that 18:4-CoA has beenelongated efficiently to 20:4. A corresponding assay was conductedwith ${gamma}$ -18:3-CoA. In this case, a similar extent of elongationresulted in the formation of 20:3-CoA (data not shown). Accordingto these data, both the transcript levels and, hence, the enzymeactivity of the elongase are unlikely to limit the accumulationof C20-PUFA. Therefore, we performed additional experimentsto identify the cause(s) of this putative bottleneck.

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Figure 5. In Vitro Assay of Elongase Activity.

Microsomes from developing embryos were incubated with 18:4-CoA in the absence (A) and presence (B) of malonyl-CoA, NADH, and NADPH. After purification of the acyl-CoAs, they were converted to their etheno-derivatives and analyzed by HPLC. In the assay in (B), $~$ 50% of 18:4-CoA is elongated to 20:4-CoA.

Role of the Acyl-CoA Pool: Availability of ${Delta}$ 6-Desaturated Fatty Acids Is Limiting
Recent studies with elongase and desaturases expressed in yeastsuggest that plant and fungal desaturases (and in particularthe front-end desaturases used in this approach) use phosphatidylcholine(PC)-linked acyl groups as actual substrates, whereas the elongaseuses acyl-CoAs for condensation. Therefore, the desaturationwill produce ${Delta}$ 6-desaturated acyl groups as ester components of(phospho)lipids, whereas the ${Delta}$ 6-elongase requires acyl-CoA thioestersas substrates (Domergue et al., 2003

). For a better understandingof this aspect of metabolic interactions in transgenic linseed,we analyzed the acyl-CoA pools of untransformed and transgenicflax seeds at different developmental stages. After extraction,the intact thioesters were converted to their fluorescent etheno-derivativesand analyzed by HPLC. In the control thioester samples (Figure 6A),palmitic, stearic, oleic, linoleic, and ${alpha}$ -linolenic acidwere present, with palmitoyl-CoA being predominant. This profilediffers from the fatty acid pattern of TAG mainly by the elevatedproportions of palmitic (16:0) and stearic (18:0) acid. Theoccurrence of linoleic and ${alpha}$ -linolenic acid in the acyl-CoA poolconfirms previous data (Stymne and Stobart, 1984

) describingthe acyl-CoA:lysophosphatidylcholine acyltransferase (LPCAT)activity in microsomes from developing linseeds. On the otherhand, the acyl-CoA sample from transgenic tissue (Figure 6B)differed only by the presence of trace levels of stearidonicacid during all stages investigated. This indicates either avery low exchange of 18:4 between the site of desaturation inPC and the acyl-CoA pool or a rapid removal of this fatty acidfrom the acyl-CoA pool. The same conclusion can be drawn for ${gamma}$ -18:3, which coelutes as a correspondingly small proportionin the ${alpha}$ -18:3 peak. In addition, if we assume that linoleic and ${alpha}$ -linolenic acid residues in lipids will be desaturated equallywell by the ${Delta}$ 6-desaturase, then both should be equally well elongatedby the ${Delta}$ 6-elongase after transfer into the acyl-CoA pool. However,in the acyl-CoA profile, we did not detect di-homo- ${gamma}$ -linolenicacid ( ${omega}$ 6-C20:3, the elongation product of ${gamma}$ -C18:3, eluting between16:0 and 18:1), elongated stearidonic acid ( ${omega}$ 3-C20:4), or anyother C20-PUFAs. Addition of various C18- and C20-PUFA-CoAsto seed extracts and microsomes from the transgenic plants andsubsequent extraction of total acyl-CoAs indicate that the addedacyl-CoAs are recovered by extraction and are not oxidized orsubjected to hydrolysis by an acyl-CoA thioesterase (Figure 5;data not shown). Therefore, the most obvious discrepancyto be explained in transgenic linseed is the following: ${Delta}$ 6-desaturatedC18-PUFAs are found in high proportions in TAG, but they arealmost completely absent from the acyl-CoA pool, whereas ${Delta}$ 9-unsaturatedC18 fatty acids are present in roughly similar proportions inboth TAG and the acyl-CoA pool. Such a distribution could bebecause of several mechanisms: (1) ${Delta}$ 6-C18-PUFAs are incorporatedinto TAG either via routes bypassing the acyl-CoA pool; (2)by highly efficient removal from the acyl-CoA pool giving theelongase no chance for a substantial conversion of its substrates;(3) by different subcellular compartmentation of desaturationand elongation reactions. Whatever the mechanism, the availabilityof ${Delta}$ 6-desaturated C18-CoA esters seems to prevent efficient reconstitutionof VLCPUFA biosynthesis via the ${Delta}$ 6-elongating activity.

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Figure 6. Profiles of Acyl-CoAs from Developing Wild-Type and Transgenic Linseed.

Immature seeds were harvested at 14, 24, and 35 DAF from wild-type (A) and transgenic (B) linseed expressing construct C and subjected to acyl-CoA extraction. The acyl-CoAs were converted to their etheno-derivatives and analyzed by HPLC.

Channeling of VLCPUFA between Major Acyl Pools
As outlined above, all ${Delta}$ 6-desaturated C18-fatty acids have tobe generated in PC as the primary site of desaturation beforedelivery into the acyl-CoA pool or channeling into TAG. To provethe role of PC in ${Delta}$ 6-C18- and in ${Delta}$ 5-C20-desaturation, we nextanalyzed the fatty acid profile of this central metabolite andcompared it with representative components of lipid groups consideredas receiving fatty acids or diacylglycerol (DAG) moieties fromPC. For this purpose, the developing seeds at the stage of maximallipid deposition (24 DAF) from wild-type and T3 transgenic linseedlines were subjected to extraction of lipids followed by separationinto three classes: neutral lipids, glycolipids, and phospholipids(see Supplemental Table 1 online). This fractionation schemewas chosen to ensure that no significant component escaped detection.In all three classes, the fatty acid profiles of the transgenicsamples differed from those of the wild type qualitatively onlyby the presence of ${Delta}$ 6-C18-PUFA and C20-VLCPUFA, but a closerinspection reveals additional differences between the variouslipid groups. ${gamma}$ -18:3 was nearly equally abundant in neutral lipids(15%), phospholipids (12%), and glycolipids (13%). On the otherhand, 18:4 accumulated in neutral lipids (11%), whereas a reductionto equally low proportions is found in phospholipids (3.5%)and glycolipids (3%; see Supplemental Table 1 online). Furthermore,the proportion of the two ${omega}$ 6-C20-fatty acids derived from ${gamma}$ -18:3( ${omega}$ 6-20:3 and ${omega}$ 6-20:4) was twice as high in phospholipids (total10%) as in neutral lipids (total 5%) and five times higher thanin glycolipids (2%). By contrast, the two ${omega}$ 3-C20-fatty acidsderived from 18:4 ( ${omega}$ 3-20:4 and ${omega}$ 3-20:5) were found in the neutrallipids (total 2.7%) but were hardly detected in phospholipidsand glycolipids (see Supplemental Table 1 online). On the otherhand, despite the fact that the ${omega}$ -3 precursor ${alpha}$ -18:3 was fivetimes more abundant than the ${omega}$ -6 precursor linoleic acid in wild-typelinseed, the downstream products of the ${omega}$ 3-pathway were presentin lower proportions than their ${omega}$ -6 counterparts in the transgenicplants. This unexpected observation encouraged us to conducta more detailed analysis of the different lipid pools.

The three lipid fractions were used to purify TAG, DAG, twoindividual phospholipids (PC and phosphatidylethanolamine [PE]),and the two galactolipids monogalactosyldiacylglycerol (MGDG)and digalactosyldiacylglycerol (data not shown) because plastidialglycolipids of eukaryotic origin represent another pool of DAGderived from microsomal PC. Before considering the differencesin fatty acid methyl esters between wild-type and transgenicsamples (Figure 7), it is useful to compare in wild-type seedsthe fatty acid profiles of PC with the two major lipid poolsreceiving fatty acids from PC:MGDG and TAG (Figure 7). It isobvious that ${alpha}$ -18:3 is the predominant component in the acceptinglipids MGDG and TAG, whereas the PC profile is dominated by18:1, which originates from the plastid-derived acyl-CoA pool(Figure 7A). The lipids from transgenic seeds differ by thepresence of ${Delta}$ 6-C18-PUFA and C20-PUFA but reflecting to some extentthe observations made with wild-type lipids. Figure 7B showsthat 18:4 and ${omega}$ 3-C20-PUFAs were concentrated in TAG contrastingwith their low proportions in PC, DAG, PE, and MGDG. ${gamma}$ -18:3 wasfound nearly evenly distributed in all lipids. The major C20-PUFAswere ${omega}$ 6-C20-PUFAs 20:3- ${omega}$ 6 and 20:4- ${omega}$ 6 (4.2 and 5.3%, respectively),which were present in much greater proportions than the two ${omega}$ 3-C20-PUFAs and which were enriched in PC and DAG. ${gamma}$ -18:3 and18:4 in MGDG (Figure 7B) must be considered as being of eukaryotic(i.e., microsomal) origin. In addition, very low proportionsof ${omega}$ 6-C20-PUFAs were also present. These results indicate thatmajor fluxes of VLCPUFA to glycolipids may occur via DAG. However,it is noteworthy that 18:4 and its derived products are concentratedin TAG (Figure 7B) but not in PC, DAG, PE, and MGDG. This inturn indicates that, in addition to the contribution of theDAG pool derived from PC, these fatty acids might be channeledby other enzymatic mechanisms. From Figure 7 it is also evidentthat the proportion of 16:0 in TAG is rather low compared withPC and the acyl-CoA pool, which both feed TAG synthesis.

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Figure 7. Fatty Acid Profiles of PC, DAG, PE, MGDG, and TAG from Developing Wild-Type and Transgenic Linseed Seeds (24 DAF).

PC, DAG, PE, MGDG, and TAGs were purified by high-performance thin-layer chromatography (HPTLC) from the respective lipid fractions as indicated in Methods and directly subjected to transesterification for GC analysis.

(A) Wild-type seeds.

(B) Transgenic seeds.

Positional Distribution and Pairing of Fatty Acids
To better understand the acyl group channeling between PC, acyl-CoAs,and TAG, we performed a positional analysis of fatty acids inPC and TAG. In the latter case, we used a method allowing thedifferentiation of all three positions (sn-1, sn-2, and sn-3)because their acyl profiles may point to the enzymatic reactionscontributing most to filling up a particular position. Furthermore,the analysis of PC was extended to a study of the molecularspecies to find out whether all or only specific pools of PCparticipate in these metabolic conversions. Figure 8 shows thepositional distribution of fatty acids from PC and TAG of seedsfrom transgenic linseed (24 DAF). The acyl groups of PC canbe separated into three groups (Figure 8, top row, right): sn-1–confinedsaturated fatty acids (16:0 and 18:0); acyl groups equally distributedbetween the sn-1 and sn-2 positions (18:1, 18:2, and ${alpha}$ -18:3);acyl groups concentrated in the sn-2 position (all carryinga ${Delta}$ 6-double bond as well as their elongated derivatives). Thisdistribution supports the sn-2 regiospecificity of the ${Delta}$ 6- and ${Delta}$ 5-desaturase (Domergue et al., 2003

) and suggests that the productsafter elongation are returned with high preference into thesame position. More details will be discussed below in comparisonwith the TAG positions.

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Figure 8. Regiospecific Distribution of Fatty Acids in PC and TAG from Developing Seeds of Transgenic Linseed (24 DAF).

The positional analysis of fatty acids from PC and TAG were determined as indicated in Methods. In all plots, except for the right PC plot, mol % refers to the percentage of each acyl group in the lipid class or at a particular position in that lipid class. In the right PC plot, "%" refers to the percentage of each fatty acid found in the sn-1 or sn-2 position. Each value is the mean from three independent experiments.

To find out whether the ${Delta}$ 6-desaturated and elongated acyl groupsare combined with preferred acyl groups in the sn-1 position,we analyzed the fatty acid combinations occurring in PC fromwild-type and transgenic seeds. As seen in Figure 9, wild-typePC is made up of 16/18 and 18/18 combinations. Together withthe positional analysis (Figure 9), the 16/18 combinations arefully identified with regard to regiospecificity. A similarassignment is not possible with 18/18 combinations because theMS technique used can only identify the most predominant regioisomerspresent in mixtures with isobaric and regiospecific isomers.Therefore, only 36:6 (18:3/18:3), 36:2 (18:1/18:1), and 36:1(18:0/18:1) are fully assigned, whereas all other combinationscontain several species. The predominant combinations with thetwo constituent fatty acids in roughly similar proportions inboth sn-positions are 18:3/18:2 (36:5), 18:3/18:1 (36:4), and18:2/18:1 (36:3). A detailed analysis is provided in the supplementaldata (see Supplemental Table 2 online). From these patterns,we conclude that the normal ${Delta}$ 12- and ${Delta}$ 15-desaturases as well asthe LPCAT accept both 16/18 and 18/18 combinations. In PC fromthe transgenic seeds, additional 18/20 and 20/20 combinationsand the new 16:0/18:4 (34:4) and 18:3/18:4 (36:7) occur. Theproportions of the new 18/20 combinations show that most ofthe ${Delta}$ 6-desaturated and subsequently elongated acyl groups arecombined with a C18-PUFA and not with C16:0. Nevertheless, 16:0/20combinations can be detected in very low proportions in thecorresponding 36:x combinations. From these data, we concludethat the large majority of the elongated ${Delta}$ 6-desaturated acylgroups are combined with an unsaturated C18-fatty acid. Unfortunately,we cannot extend this conclusion to ${gamma}$ -18:3 itself because theMS technique used does not differentiate between ${alpha}$ - and ${gamma}$ -18:3.

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Figure 9. Molecular Species of PC from Developing Wild-Type and Transgenic Linseed (24 DAF).

Finally, we performed a stereospecific analysis of TAG fromwild-type (see Supplemental Figure 1 online) and transgeniclinseed, but only the data from the transformants are includedin Figure 8 for an immediate comparison with the profiles inequivalent PC positions. Our analysis of the wild-type TAG supportsprevious data (Mattson and Volpenhein, 1963

) and shows the exclusionof saturated fatty acids from the sn-2 position but a more orless random distribution of 18:1 and 18:3 over all three positions,whereas 18:2 is enriched at the sn-2 position. By contrast,the three sn-positions of the transgenic TAG show differentprofiles. Confining the positional analysis to a lipase hydrolysiswould not differentiate between sn-1 and sn-3, emphasizing theneed for the more complicated analysis described here. The sn-1profile is dominated by ${alpha}$ -18:3, whereas 16:0 and 18:0 are significantlyreduced when compared with the sn-1 position of PC. ${Delta}$ 6-Desaturatedfatty acids and their derivatives are nearly absent from thisposition paralleling the corresponding PC pattern. In the sn-2profile, 16:0 and 18:0 are nearly absent, similar to the sn-2position of PC. This similarity extends to the presence of ${gamma}$ -18:3and 18:4 as well as to the C20 series. The proportion of ${gamma}$ -18:3is highest in this position, but the two C20- ${omega}$ 6-members (in contrastwith the ${omega}$ 3-members) are reduced compared with the PC pattern.Nevertheless, the pairs of sn-1 and sn-2 profiles of PC andTAG display some basic similarity. By contrast (and as mightbe expected from the complicated biochemical interactions tobe discussed below), the acyl mixture at the sn-3 position ofTAG differs most from all the others. It contains significantlyless 16:0 and 18:0 than the sn-1 positions and also less 18:1than any other TAG positions and the acyl donor pools (acyl-CoAthioesters, free DAG, PC-bound DAG, and its different sn-positions).The sn-3 profile is dominated by ${alpha}$ -18:3 followed by significantand approximately equal proportions of 18:4 and ${gamma}$ -18:3. The fourdifferent C20 fatty acids are present in roughly equal proportionssimilar to the sn-2 profile but significantly different fromthe sn-2 position of PC with the characteristically uneven proportionsof the C20- ${omega}$ 6- and C20- ${omega}$ 3-pairs.

Some of the important results of this stereospecific TAG analysisare the following: (1) all the new (i.e., non-native) C18 andC20 fatty acids are not present at the sn-1 position, (2) ${gamma}$ -18:3is most abundant at the sn-2 position, and (3) by contrast,18:4 is highest in the sn-3 position.

Taken together, these data show that the various pools (acyl-CoAthioesters, backbones, and the different sn-positions of PC,free DAG, galactolipids, and TAG) display fatty acid profileswith significant differences, in particular regarding the proportionsof the heterologously expressed new fatty acids. This suggeststhe operation of selectivity and preference in the exchangeof single acyl groups and/or complete DAG moieties between thesepools. Thus, ${omega}$ 3-C18- and ${omega}$ 3-C20-PUFA are depleted in PC and efficientlymoved to TAG. Compared with this, ${omega}$ 6-18:3 and in particular its ${omega}$ 6-C20-PUFA metabolites, appear to be effectively retained inthe PC pool. In addition, a considerable proportion of 18:1,18:2, and ${alpha}$ -18:3 is moved through the acyl-CoA pool, whereas ${Delta}$ 6-desaturated C18-PUFA and their elongation products can hardlybe detected in this pool. The significance of these observationswill be discussed in the next section.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

The goal of our study was to produce transgenic plant oils enrichedwith VLCPUFA. The data presented demonstrate a successful reconstitutionof C20-VLCPUFA biosynthesis in oil-synthesizing seeds of higherplants. The genetic basis of this implementation in linseedwas the heterologous expression of three genes encoding a ${Delta}$ 6-desaturase,a ${Delta}$ 6-elongase, and a ${Delta}$ 5-desaturase, the primary enzymes of VLCPUFAbiosynthesis. Of particular significance is the fact that, accordingto the dietary values recommended by nutritional organizations,the proportions of $~$ 5% C20-PUFA reached in our transgenic seedoils would already be sufficient to satisfy these requirements.However, for expanded agricultural use, the current reportedlevels of ARA and EPA may still require some enhancement. Onthe other hand and perhaps of equal or greater significance,our data now offer new insights into the metabolic fluxes governingthe production and deposition of these new fatty acids in seeds.

In previous experiments with the enzymes used in this study,we demonstrated that the ${Delta}$ 6- and ${Delta}$ 5-desaturation take place atthe sn-2 position of PC and that the ${Delta}$ 6-elongase uses acyl-CoAsas substrates (Domergue et al., 2003). In addition, when expressedin yeast and supplemented with an exogenous fatty acid mixturereflecting that present in linseed, the moss ${Delta}$ 6-elongase veryefficiently elongated ${gamma}$ -C18:3 and 18:4, converting >50% ofthese substrates to C20-PUFAs (Zank et al., 2002). However,despite the accumulation of high proportions of ${Delta}$ 6-desaturatedC18-fatty acids in this study, our transgenic linseed linesdid not use these substrates efficiently for elongation; therefore,the heterologous biosynthesis of VLCPUFA did not proceed significantlybeyond the first desaturation step. Analysis of the acyl-CoApool of the transgenic seeds at different developmental stagesshowed that ${gamma}$ 18:3- and 18:4-CoAs and their elongation productswere hardly detectable, whereas 18:2- and ${alpha}$ -18:3-CoA were present.This can be interpreted in two ways: either there was a selectivelyslow exchange of ${Delta}$ 6-desaturated acyl groups between PC and theacyl-CoA pool, or the ${Delta}$ 6-desaturated acyl groups were removedvery rapidly from this pool by enzymes having higher affinitiesfor these substrates than the elongase and simultaneously discriminatingagainst 18:1, 18:2, and ${alpha}$ -18:3. On the other hand, RT-PCR andthe results presented in Figure 5 indicate that the elongasewas transcribed correctly during seed development, resultingin high enzymatic activity during the main phase of lipid accumulation.Therefore, we assume that substrate availability rather thancatalytic activity limited the elongation. This in turn suggeststhat additional mechanisms may contribute to the channelingof most of the ${Delta}$ 6-C18-PUFA from PC to TAG by enzymes not dependenton the presence of these PUFA in the acyl-CoA pool. Our additionalexperiments were directed to understand these metabolic fluxesand to find out which of various alternatives contributed mostto the acyl channeling in TAG synthesis.

Current understanding suggests that several reactions contributeto the flow of acyl groups between the various pools relevantin TAG biosynthesis, and some of them are in fact acyl-CoA independent(Figure 10). Several different mechanisms may be involved inthe synthesis of DAG and TAG. DAG may be released from phosphatidicacid after de novo synthesis, but DAG may also be released fromPC in the reverse cholinephosphotransferase (CPT) reaction.On the other hand, PC synthesis itself requires acyl-CoA–dependentde novo synthesis of DAG via phosphatidic acid. In addition,DAG may also result from an acyl-CoA-dependent acylation ofmonoacylglycerol (Beaudoin and Napier, 2004). The final conversionof DAG to TAG may be catalyzed by the acyl-CoA:DAG acyltransferase(DAGAT) (Voelker and Kinney, 2001) and by two acyl-CoA–independentreactions, for example, those catalyzed by the DAG:DAG transacylase(DDAT; not included in Figure 10) (Stobart et al., 1997) andthe phospholipid:DAG acyltransferase (PDAT). This enzyme transfersthe acyl-chain from the sn-2 position of PC to DAG yieldingTAG and sn-2-lyso-PC (Dahlqvist et al., 2000). The acyl-CoApool is fed mainly by acyl group export from plastids (16:0,18:0, and 18:1) but changed in composition by the reverse reactionof the LPCAT (Stymne et al., 1983; Stymne and Stobart, 1984)by elongases and acyl-CoA synthases. These activities resultin a dynamic and heterogenous acyl-CoA pool that is subjectto further modification because of more or less selective removalby acyltransferases for de novo synthesis of phosphatidic acidand the deposition of acyl groups in TAG (Beaudoin and Napier,2004). Thus, there are several acyl-CoA–independent routesby which PC-bound ${Delta}$ 6- and ${Delta}$ 5-desaturated acyl groups could beincorporated into TAG, explaining their absence from the acyl-CoApool. The enzymes responsible for this channeling are CPT ( ${Delta}$ 6-desaturatedacyl groups at least in the sn-2 position of TAG), DDAT ( ${Delta}$ 6-desaturatedacyl groups at least in the sn-2 and sn-3 positions of TAG),and PDAT ( ${Delta}$ 6-desaturated acyl groups in addition in the sn-3position of TAG).

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Figure 10. Accumulation of Linseed TAG by Channeling of Acyl Groups through PC.

The stepwise acylation of glycerol-3-phosphate (G3P) by acyl-CoA:1-glycerol-3-phosphate acyltransferase (G3PAT; 1) and acyl-CoA:1-acyl-glycerol-3-phosphate acyltransferase (2) yields 1-acyl-glycerol-3-phosphate (LPA) and phosphatidic acid (PA), which is hydrolyzed by phosphatidic acid phosphatase (3) to give DAG. Its conversion to TAG by acyl-CoA:diacylglycerol acyltransferase (5) immediately after the primary formation of DAG by the Kennedy pathway represents a minor alternative for TAG synthesis in linseed (indicated by the dotted arrow). The major part of DAG is converted to PC in a reversible reaction catalyzed by CDP-choline:diacylglycerol cholinephosphotransferase (CPT; 4). PC is the substrate for acyl group desaturases (6). They may accept both the sn-1 and sn-2–localized acyl groups (the genuine enzymes), or their action may be confined to the sn-2–bound acyl chains (the heterologously expressed ${Delta}$ 6- and ${Delta}$ 5-desaturase). In a reversible reaction, the acyl-CoA:lyso-phosphatidylcholine acyltransferase (8) equilibrates the sn-2–bound acyl group with the acyl-CoA pool. The formation of C20-polyunsaturated fatty acids by the heterologously expressed acyl-CoA elongase (9) occurs by elongation of ${Delta}$ 6-C18–polyunsaturated acyl-CoA and thus depends on their release from PC into the acyl-CoA pool by the LPCAT (8). The activities of the desaturases (6) and elongase (9) together with the reversibility of LPCAT (8) and CPT (4) result in a continuous change of the acyl groups of the acyl-CoA pool, PC, and DAG, which all participate in this equilibration. Only after passage through PC, a highly desaturated DAG is finally converted into TAG. This channeling is catalyzed by two enzymes, the DAGAT (5) mentioned before and the phospholipid:diacylglycerol acyltransferase (PDAT; 7) that transfers the sn-2–bound acyl group from PC to the sn-3 position of TAG. These major routes, deduced by labeling studies with wild-type linseed (Slack et al., 1983; Stymne and Stobart, 1984), are supported by the acyl profiles of the various pools (acyl-CoA, PC, DAG, and TAG) studied in this investigation with transgenic linseed.

Earlier studies (Slack et al., 1978

, 1983

; Somerville and Browse,1991

) suggested that in linseed the DAG and PC pools are essentiallykept in equilibrium by the action of CPT. The major flux ofglycerol and fatty acids incorporated into TAG proceeds predominantlyvia PC rather than depending on the stepwise use of 18:2- and18:3-CoAs (derived from PC by exchange) for the uninterruptedand sequential formation of phosphatidic acid, DAG, and TAGvia the classical Kennedy pathway. Taking into account thatthe ${Delta}$ 6-desaturase is specific for the sn-2 position of PC andthat ${Delta}$ 6-C18-PUFA may not be efficiently exchanged from the sn-2position of PC by the LPCAT, the DAG pool becomes enriched withthe sn-2–bound ${Delta}$ 6-C18-PUFA by conversion of PC to DAG byCPT. The fact that the fatty acid profile of total DAG resembledthat of PC supports this assumption. These DAG molecules canthen be incorporated into TAG by the action of DAGAT, PDAT,and DDAT or serve as substrates for the synthesis of other phospholipids(PE) and of glycolipids in the plastids (Figure 10).

On the other hand, the low level of 18:4 in PC and DAG and itsabundance in TAG suggests that after desaturation this fattyacid is immediately shuttled to TAG. A possible mechanism forthis channeling could be a high activity of the PDAT enzymein addition to the channeling via the CPT-catalyzed releaseof DAG backbones. Positional analyses of PC and TAG from developingseeds indicate that ${gamma}$ -18:3 and 18:4 were absent from the sn-1positions of both lipids. ${gamma}$ -18:3 was confined to the sn-2 positionin PC and found at the sn-2 and sn-3 positions of TAG with somepreference for the sn-2 position. By contrast, 18:4 was foundto accumulate preferentially at the sn-3 position of TAG (Figure 8).The enrichment of 18:4 at the sn-3 position of TAG can beexplained in two ways. One possibility is that the DAGAT prefers18:4-CoA as substrate to form TAG rich in this fatty acid. Thiscould explain the observation that in developing transgenicseeds 18:4-CoA is hardly detected in the acyl-CoA pool. An alternativepossibility is that a PDAT-like enzyme is responsible for thedirect channeling of 18:4 from the sn-2 position of PC to thesn-3 position of TAG. This alternative would be in line withthe fact that 18:4 is a major component in the sn-3 positionof TAG, but only a minor component in PC, absent in the acyl-CoApool and only marginally elongated.

At this point it is interesting to compare our data on the positionaldistribution of ${Delta}$ 6-desaturated fatty acids in transgenic linseedwith those determined previously in TAG from two transgenicBrassica species and the well known ${gamma}$ -18:3–rich oils (Gunstone,1992) from evening primrose (Oenothera biennis), black currant(Ribes nigrum), and borage (B. officinalis). The last threeplants direct ${gamma}$ -18:3 into the sn-2 and sn-3 positions with onlyvery minor proportions in sn-1. The ${Delta}$ 6-desaturases of these plantsalso seem to be specific for the sn-2 position of PC (Stymneand Stobart, 1986; Domergue et al., 2003). In transgenic Brassicajuncea expressing a ${Delta}$ 6-desaturase from Pythium irregulare, ${gamma}$ -18:3produced in the seeds was not found in polar lipids, but almostall of it was targeted preferentially to the sn-2 position ofTAG, whereas 18:4 was equally present in sn-2 and combined (sn-1+ sn-3) positions (Hong et al., 2002). In the related speciesB. napus, coexpression of ${Delta}$ 12- and ${Delta}$ 6-desaturases from M. alpinaresulted also in a high accumulation of ${gamma}$ -18:3 in TAG. But inthis case three-quarters of this fatty acid were located atsn-1 + sn-3 positions (not differentiated) of the TAG (Liu etal., 2001). These unexpected differences demonstrate that evenamong closely related plant species different mechanisms dooccur for the channeling of ${Delta}$ 6-desaturated acyl groups into TAG.

A further complication results from the fact that TAG synthesisoccurs in parallel to phospholipid synthesis in the endoplasmicreticulum rather than in a separate compartment such as thedifferentiated oil body itself (Beaudoin and Napier, 2004).Therefore, the confinement of specifically desaturated fattyacids to TAG has to be ascribed to the specificity of the enzymesmentioned above, which in addition may prefer (or be associatedwith) pools of specific molecular species. Whether this couldbe because of a lateral heterogeneity of endoplasmic reticulummembranes is still an open question (Vogel and Browse, 1996).Our analysis of the molecular species of PC from wild-type andtransgenic seeds (24 DAF) indicates that the C20 fatty acidsin the transgenic samples are found to be primarily combinedwith C18 fatty acids rather than with 16:0. These species seemto be precursors for the enrichment of C20 fatty acids in TAG.Therefore, the different pools of PC may not contribute to thesame extent to TAG synthesis and its enrichment with polyunsaturatedfatty acids. This has been suggested in previous studies dealingwith plants accumulating polyunsaturated fatty acids (Roughanand Slack, 1982; Beaudoin and Napier, 2004).

Our data with linseed indicate that after desaturation, ${Delta}$ 6-C18-PUFAare likely to be channeled from PC directly to other lipids,preventing their exchange with the acyl-CoA pool and efficientsubsequent elongation. Accordingly, the introduction of lipid-linked ${Delta}$ 6-desaturation products into the acyl-CoA pool represents themost severe bottleneck for the production of VLCPUFA in transgeniclinseed. A possible candidate enzyme regulating the above mentionedbottleneck (i.e., making available the ${Delta}$ 6-desaturated C18-PUFAfor elongation) may be LPCAT (Stymne and Stobart, 1984). Inlinseed cotyledons, this enzyme was shown to discriminate againstsaturated fatty acids, whereas 18:2 and ${alpha}$ -18:3 produced in PCwere rapidly returned to the acyl-CoA pool (Stymne and Stobart,1984). Our new data confirm this observation and can be interpretedas showing that the linseed LPCAT enzyme may discriminate inaddition against non-native ${Delta}$ 6-polyunsaturated fatty acids, inparticular for the intrinsically slower reverse (PC to acyl-CoA)reaction (Stymne et al., 1983). At present, we do not know whetherthe same activity in different oilseed crops displays a similarselectivity. However, we would expect a significant increasein ${Delta}$ 6-elongation by the coexpression in linseed of a LPCAT activityaccepting ${Delta}$ 6-desaturated C18 fatty acids.

Strategies to Improve VLCPUFA Synthesis in Transgenic Plants
The identification of the bottleneck in our approach raisesadditional interest in alternative strategies for VLCPUFA biosynthesis,as briefly outlined here (Figure 11). For example, the alternativeshown in Figure 11B makes use of animal ${Delta}$ 6- and ${Delta}$ 5-front end desaturasesthat have been shown to use acyl-CoA as substrates (Okayasuet al., 1981; Irazu et al., 1993). With such enzymes, the conversionof linoleic or ${alpha}$ -linolenic acid to ARA or EPA would be accomplishedexclusively on the acyl-CoA track and thus avoid the switchingbetween lipids and acyl-CoA (Figure 11B). Analyses of acyl-CoAprofiles in developing seeds from linseed (our data) and rapeseed(Larson et al., 2002) have shown that this pool is indeed nearlyin equilibrium with regard to the primarily lipid-linked ${Delta}$ 9-polyunsaturateddesaturation products, such as linoleoyl and ${alpha}$ -linolenoyl residues.

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Figure 11. Differences in the Interplay between Desaturases, Elongases, and Acyltransferases in the Biosynthesis of VLCPUFA in Transgenic Plants.

Three different strategies can be used to generate VLCPUFA.

(A) The lipid-linked desaturation pathway was followed by our approach and requires both forward and reverse reactions of a ${Delta}$ 6-specific LPCAT, which is the limiting step in linseed.

(B) The acyl-CoA pathway, where both the elongation and desaturation occur in the acyl-CoA pool, requires acyl-CoA front-end desaturases so far only known from mammals. PC, phosphatidylcholine; Elo, elongase; Des, desaturase; light gray shading represents the membrane environment.

(C) An alternative pathway relying on the initiating ${Delta}$ 9-elongation step in the acyl-CoA pool followed by lipid-linked desaturations has been verified in leaves (Qi et al., 2004).

The abundance of these ${Delta}$ 9-polyunsaturated C18 fatty acids inplant acyl-CoA pools suggests that the bottleneck observed inthe lipid-linked ${Delta}$ 6-desaturation/ ${Delta}$ 6-elongation sequence (Figure 11A)could be circumvented by yet another alternative depictedin Figure 11C. It depends on the sequential action of a ${Delta}$ 9-elongaseand a ${Delta}$ 8-desaturase. cDNA sequences for both enzymes have beencloned from algae (Wallis and Browse, 1999

; Qi et al., 2002

).On expression in developing seeds this ${Delta}$ 9-elongase would haveaccess to the pool of ${Delta}$ 9-C18–polyunsaturated acyl-CoAsand produce ${Delta}$ 11-C20–polyunsaturated acyl-CoAs, which aftera presumed incorporation into PC would become substrates forthe subsequent desaturation by the ${Delta}$ 8-desaturase forming lipid-linked ${Delta}$ 8-C20-PUFA. They in turn would serve immediately as substratefor a lipid-linked ${Delta}$ 5-desaturase. This ${Delta}$ 9-elongation/ ${Delta}$ 8-desaturationsequence requires an additional acyltransferase (LPCAT) forincorporation of the ${Delta}$ 11-C20-PUFA into phospholipids to makethem acceptable by the ${Delta}$ 8-desaturase. This forward acylationof lyso-phospholipids may be less selective than the reversereaction required for releasing lipid-bound acyl groups intothe acyl-CoA pool. Recently, a successful implementation ofthis strategy in nonseed tissues of Arabidopsis thaliana ledindeed to the accumulation of C20-PUFAs in leaves (Qi et al.,2004

). Whatever strategy used, the selectivity of a LPCAT seemsto play a critical role in the successful reconstitution ofthe conventional C20-PUFA biosynthetic pathway.

Further efforts will be directed toward increasing the levelsof C20-PUFAs reported in this study. However, our data clearlydemonstrate the feasibility of the production of these nutritionallyimportant fatty acids in transgenic oilseeds. A supporting approachmight be to produce similar levels of these beneficial fattyacids in green vegetables, which are particularly rich in theprecursor ${alpha}$ -18:3 (Qi et al., 2004). The availability of suchoils and vegetables enriched in VLCPUFA will be a new additionto the list of functional food items of plant origin designedfor increased levels of minor, but nutritionally highly relevant,components such as ß-carotenes (Ye et al., 2000),tocopherols (Shintani and DellaPenna, 1998), and vitamin C (Agiuset al., 2003).

METHODS

TOP
ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

Materials
Restriction enzymes, polymerases, and DNA modifying enzymeswere obtained from New England Biolabs (Frankfurt, Germany).Linum usitatissimum (cv Flanders) was obtained from CEBECO (Vlijmen,The Netherlands). All components for plant media were obtainedfrom Duchefa (Haarlem, The Netherlands). The Agrobacterium tumefaciensstrain C58C1 ATHV, a derivative of strain EHA 101 (Hood et al.,1986), was kindly provided by J. Dettendorfer (KWS, Einbeck,Germany). All other chemicals were from Sigma (St. Louis, MO)unless indicated otherwise.

Plant Transformation Constructs
The binary vectors pCAMBIA2300 (CAMBIA, Canberra, Australia)and pGPTV (AJ251014), which both use the nptII gene with theCaMV 35S promoter as the selectable marker, were used for theconstruction of plasmids for plant transformation. For the generationof constructs A, B, and C (Figure 2), a triple cassette containingthe USP promoter (Bäumlein et al., 1991), the OCS terminator,and three different polylinkers between each promoter and terminatorwere first inserted into the pUC19 vector (Pharmacia, Erlangen,Germany), yielding the USP123OCS plasmid. The open reading framesof the different desaturases and elongases were modified byPCR to create appropriate restriction sites adjacent to thestart and stop codons, cloned into the pGEMT-T vector (Promega,Madison, WI), and sequenced to confirm their identity. The openreading frames were then released using the restriction sitescreated by PCR and successively inserted into the same sitesof the polylinkers of the USP123OCS plasmid. The resulting cassette,containing the three genes each under the control of the USPpromoter, was released by digesting the USP123OCS plasmid withAscI or EcoRI and HindIII and cloned into the correspondingsites of the binary vectors pGPTV and pCAMBIA2300, respectively.For the generation of construct D (Figure 2), the USP promoterat the second and third positions of the cassette in the USP123OCSplasmid was replaced by the LeB4 promoter (Fiedler and Conrad,1995) and the Dc3 promoter (Thomas, 1993), respectively. Thecorresponding plant construct was then generated as describedabove. Plasmid DNA from all constructs was isolated and purifiedaccording to standard methods. All vectors were transferredinto the Agrobacterium strain C58C1 ATHV via electroporation.

Plant Transformation
Linseed transformation was performed according to Drexler etal. (2003b). Regenerated shoots were selected on MS medium with1.5% (w/v) sucrose, 400 mg/L of carbenicillin, and 60 mg/L ofG418. After rooting they were transferred to pots and grownat 22°C under 16-h daylight in a growth chamber. The flowerswere labeled at anthesis, and immature and mature seeds wereharvested at 24 and 40 d after flowering (DAF), respectively.The tobacco (Nicotiana tabacum) transformation was conductedas described previously (Jongsma et al., 1995).

Fatty Acid Analysis
Ten milligrams of seeds from wild-type and transgenic plantswere used for preparation and analysis of fatty acid methylesters as described before (Domergue et al., 2002). For theanalysis of immature seeds, seed probes were used to prepareparallel samples of cell debris, the wash fraction, and theacyl-CoA extract (see below), which were subjected to acidictransesterification and analyzed by GLC as described (Domergueet al., 2002). FAMEs were identified by comparison with appropriatereference substances and by GLC/MS of their 4,4-dimethyloxazolinederivatives as described previously (Sperling et al., 2000).

Preparation of Cell-Free Homogenates and Microsomes
Transgenic embryos (20 to 24 DAF, 100 to 200 mg fresh weight)were isolated at 0°C and homogenized in grinding medium(100 mM Hepes buffer, 0.32 M sucrose, 0.1% BSA, and 10 mM 2-mercaptoethanol,pH 7.2). After filtration through Miracloth (Merck, Darmstadt,Germany), protein was estimated according to Bradford (1976),and an aliquot of the cell-free homogenate was directly usedfor assaying elongation activity. Microsomes were prepared asindicated by Dahlqvist et al. (2000).

Assay of Elongation Activity
An aliquot of the cell-free extract (200 µL, 200 µgprotein) or microsomes (500 µL, 150 µg protein)was incubated at 30°C for 1 h with 90 mM Hepes, pH 7.2,10 mg/mL of BSA, 1 mM ATP, 0.5 mM NADH, 0.5 mM NADPH, 2 mM MgCl₂,100 µM malonyl-CoA, and 23.2 µM 18:4-CoA in a finalvolume of 1 mL. The reaction was stopped by adding 200 µLof 3 M acetic acid and 25 µL of a saturated (NH₄)₂SO₄solution. The mixture was briefly centrifuged, and the acyl-CoAfraction was purified on a Sep-pak column (Strata C18-E; Phenomenex,Torrance, CA) using acetonitrile as the eluting solvent. Thesamples were dried under argon and derivatized as indicatedbelow.

Acyl-CoA Analysis
Saturated and monounsaturated acyl-CoA esters with acyl chainlengths from C12 to C18 were obtained from Sigma. Polyunsaturatedacyl-CoAs (18:2-, ${alpha}$ 18:3-, ${gamma}$ 18:3-, 18:4-, 20:2-, 20:3 ${omega}$ 6-, 20:3 ${omega}$ 3-,20:4 ${omega}$ 6-, and 20:4 ${omega}$ 3-CoAs) were synthesized enzymatically usingan acyl-CoA synthetase from Pseudomanas sp (Sigma). The reactionmixture (200 µL) containing 100 mM Tris-HCl, pH 8.1, 10mM MgCl_2, 5 mM ATP, 5 mM CoASH, 2 mM DTT, 25 µM free fattyacid, and 2.5 units of acyl-CoA synthetase was incubated at37°C for 2 h. The reaction was stopped with 50 µLof glacial acetic acid/ethanol 1:1 (v/v), and the samples werewashed with petroleum ether to extract residual free fatty acids.After purification of the acyl-CoAs on a Sep-pak column (StrataC18-E; Phenomenex) using acetonitrile as the eluting solvent,the samples were dried under argon and dissolved in 50 mM Mes,pH 5.0.

Acyl-CoA analysis was performed as described by Larson and Graham(2001) with slight modifications: acyl-CoAs were extracted from20 mg of immature seeds (24 DAF) and washed with petroleum ether.The resulting extract was dried under argon at 50°C. Chloracetaldehydereagent (300 µL) was then added to the samples, and thederivatization of acyl-CoAs to their etheno-derivatives wasconducted at 85°C for 20 min.

HPLC analysis was performed with Thermoquest HPLC equipment(Thermoquest, Egelsbach, Germany) using a LUNA 150 x 2.0 columnwith phenyl-hexyl coated 5-µm silica particles (Phenomenex)under the same conditions as described by Larson and Graham(2001).

Lipid Analysis
Lipid extracts from developing seeds of wild-type and transgenicplants were prepared as follows: between 0.5 and 1 g of seedswere heated in water at 90°C for 2 min and homogenized in15 mL of chloroform/methanol (1:2). The lipids were extractedon a shaker for 4 h and then for 20 h with 15 mL of chloroform/methanol(2:1). The resulting organic phases were combined and then extractedwith 9 mL of 0.45% NaCl, dried with Na₂SO₄, and evaporated undervacuum. The residue was dissolved in 1 mL of chloroform/methanol(2:1) representing the total lipid extract. Separation of lipidclasses (neutral lipids, glycolipids, and phospholipids) wasachieved using a Sep-pak column. Lipid extracts were loadedon the Sep-pak column pre-equilibrated with chloroform and thenfractionated into the three lipid classes by elution as follows:neutral lipids with chloroform, glycolipids with acetone:isopropanol(9:1), and phospholipids with methanol. The isolation of individualcomponents from the different lipid classes was achieved byHPTLC using a horizontal development tank (Camag, Berlin, Germany)with appropriate running solvents and standards.

Regiospecific Analysis of PC and TAG
Positional analysis of PC was conducted using the Rhizopus arrhizuslipase from Sigma as described previously (Domergue et al.,2003). The regiospecific analysis of TAGs was based on the partialdegradation with Grignard reagent according to Becker et al.(1993) except that ethyl magnesium bromide (Merck, Rahway, NJ)was used instead of allyl magnesium bromide. For this purpose,30 mg of purified TAG were dissolved in diethyl ether (1.4 mL)in a glass tube, and ethyl magnesium bromide (3 M in 100 µLof diethyl ether) was added. After 1 min of vigorous agitation,the reaction was stopped by addition of 4 mL of an acidic buffer(1 volume of 37% HCl and 36 volumes of 0.4 M boric acid solutionin water). Five milliliters of diethyl ether were added, andthe organic phase was washed twice with 0.4 M boric acid. Afterdiscarding the aqueous phase, the organic phase was dried withNa₂SO₄ and evaporated to dryness under argon without heatingto avoid isomerization of the DAG. The residue was dissolvedin chloroform and separated by HPTLC using chloroform-acetone(96:4 [v/v]) as solvent. The zone corresponding to 1,2-DAG and2,3-DAG (unresolved) was scraped off the plate and extractedfrom the silica with chloroform/methanol (2:1 [v/v]), driedunder argon without heating, and dissolved in 1 mL of anhydrouspyridine (Merck). The DAG mixture was converted to phosphatidylphenolderivatives by incubation with 100 µL of phenyldichlorophosphate(Merck) overnight at room temperature. Phosphatidylphenols wereextracted according to Hajra (1974) and purified by HPTLC usingchloroform/methanol/water (70:20:3 [v/v]) as solvent. Afterextraction from the silica (Hajra, 1974), the residue was evaporatedto dryness, dissolved in 0.5 mL of diethylether, and sonicatedfour times for 20 s. Positional analysis was then conductedwith a phospholipase A₂ from bee venom (Sigma) by adding 1 mLof buffer (0.1 M boric acid, 5 mM CaCl₂, and 0.1% Triton X-100,pH 8.9) and 10 µL of phospholipase A₂. The mixture wasincubated at 25°C for 8 h under agitation to ensure completenessof the reaction. Lipolysis products were separated by HPTLCusing as solvent chloroform/methanol/aqueous ammonia (65/25/5).The spots corresponding to free fatty acids (sn-2), lyso-phosphatidylphenols(sn-1), and 2,3-phosphatidylphenols were subjected directlyto transmethylation and GC analysis. Reincubation of the recovered2,3-phosphatidylphenols with phospholipase A₂ did not resultin any lyso-compounds, indicating complete hydrolysis of 1,2-phosphatidylphenols.The distribution of fatty acids in the sn-3 position of TAGwas deduced using the following formula: sn-3 (mol %) = [3 xTAG (mol %)] – [sn-1 (mol %)] – [sn-2 (mol %)] sn-3(mol %) = [2 x 2,3-acyl-sn-phosphatidylphenol (mol %)] –[sn-2 (mol %)].

Analysis of PC Molecular Species
Molecular species analysis of PC was performed by electrospraytandem MS by scanning the precursors of the ions with the mass-to-chargeratio 184 in the positive mode, as previously described (Weltiet al., 2002). Analyses of the acyl species in the PC speciesof each mass were performed by analyzing the acyl ion productsof the acetate anions of the PC species (Welti et al., 2002).

Sequence data from this article have been deposited with theEMBL/GenBank data libraries under the following accession numbers. ${Delta}$ 6-desaturases: Pp ${Delta}$ 6 (AJ222980), Bo ${Delta}$ 6 (U79010), and Pt ${Delta}$ 6 (AY082393). ${Delta}$ 5-desaturases: Ma ${Delta}$ 5 (AF054824) and Pt ${Delta}$ 5 (AY082392). ${Delta}$ 6-elongases:PSE1 (AF428243) and PEA-1 (AX035537).

Acknowledgments

This research was supported financially by grants from the Bundesminesteriumfür Bildung and Forschung (Napus 2000, FK 0312252F) andBASF Plant Science (Ludwigshafen, Germany), which are gratefullyacknowledged. We thank B. Dies, A. Fahl, and C. Ott for excellentassistance. R.W. thanks Mary Roth for technical assistance andKansas National Science Foundation Experimental Program to StimulateCompetitive Research and Kansas Technology Enterprise Corporationfor support of the Kansas Lipidomics Research Center.

Footnotes

The author responsible for distribution of materials integralto the findings presented in this article in accordance withthe policy described in the Instructions for Authors (www.plantcell.org)is: Ernst Heinz (eheinz{at}botanik.uni-hamburg.de).

Online version contains Web-only data.

Article, publication date, and citation information can be foundat www.plantcell.org/cgi/doi/10.1105/tpc.104.026070.

Received July 14, 2004; accepted July 31, 2004.

REFERENCES

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ABSTRACT
INTRODUCTION
RESULTS
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