Identification of novel acyl-ACP thioesterase gene ClFATB1 from Cinnamomum longepaniculatum

A putative fatty acyl-acyl carrier protein (acyl-ACP) thioesterase (thioesterase) full-length cDNA sequence named as ClFATB1 was obtained from the seed cDNA library of Cinnamomum longepaniculatum by the SMART-RACE method. The novel gene encodes a protein of 382 amino acid residues with close homology to fatty acid thioesterase type B (FATB) enzymes of other plants, with two essential residues (His285 and Cys320) for thioesterase catalytic activity. The gene was transcribed in all tissues of C. longepaniculatum, the highest being in seeds. Recombinant ClFATB1 in Escherichia coli had higher specific activities against saturated 16:0- and 18:0-ACPs than on unsaturated 18:1-ACP. Overexpression of ClFATB1 in transgenic tobaccos upregulated thioesterase activities of crude proteins against 16:0-ACP and 18:0-ACP by 20.3 and 5.7%, respectively, and resulted in an increase in the contents of palmitic and stearic acids by 15.4 and 10.5%, respectively. However, ectopic expression of this gene decreased the substrate specificities of crude proteins to unsaturated 18:1-ACP by 12.7% in transgenic tobacco and lowered the contents of oleic, linoleic, and linolenic acids in transgenic leaves. So ClFATB1 would potentially upregulate the synthesis of saturated fatty acids and downregulate unsaturated ones in the fatty acid synthesis pathway of plants.     

Stearoyl-ACP and oleoyl-PC desaturase genes cosegregate with quantitative trait loci underlying high stearic and high oleic acid mutant phenotypes in sunflower

The genetic control of the synthesis of stearic acid (C18:0) and oleic acid (C18:1) in the seed oil of sunflower was studied through candidate-gene and QTL analysis. Two F₂ mapping populations were developed using the high C18:0 mutant CAS-3 crossed to either HA-89 (standard, high linoleic fatty acid profile), or HAOL-9 (high C18:1 version of HA-89). A stearoyl-ACP desaturase locus (SAD17A), and an oleoyl-PC de-saturase locus (OLD7) were found to cosegregate with the previously described Es1 and Ol genes controlling the high C18:0 and the high C18:1 traits, respectively. Using linkage maps constructed from AFLP and RFLP markers, these loci mapped to LG1 (SAD17A) and to LG14 (OLD7) and were found to underlie the major QTLs affecting the concentrations of C18:0 and C18:1, explaining around 80% and 56% of the phenotypic variance of these fatty acids, respectively. These QTLs pleiotropically affected the levels of other primary fatty acids in the seed storage lipids. A minor QTL affecting both C18:0 and C18:1 levels was identified on LG8 in the HAOL-9×CAS-3 F₂. This QTL showed a significant epistatic interaction for C18:1 with the QTL at the OLD7 locus, and was hypothesized to be a modifier of Ol. Two additional minor C18:0 QTLs were also detected on LG7 and LG3 in the HA-89×CAS-3 and the HAOL-9×CAS-3 F₂ populations, respectively. No association between a mapped FatB thioesterase locus and fatty acid concentration was found. These results provide strong support about the role of fatty acid desaturase genes in determining fatty acid composition in the seed oil of sunflower. Received: 7 December 2000 / Accepted: 21 May 2001     

Transgenic expression of a Δ12-epoxygenase gene in Arabidopsis seeds inhibits accumulation of linoleic acid

The Crepis palaestina cDNA Cpal2 encodes a Δ12-epoxygenase that can catalyse the synthesis of 12,13-epoxy-cis-9-octadecenoic acid (18:1E) from linoleic acid (18:2). When the Cpal2 gene was expressed under the control of the napin seed-specific promoter in Arabidopsis thaliana (L.) Heynh., the seed lipids accumulated only low levels of 18:1E and also 12,13-epoxy-cis-9,15-octadec-2-enoic acid (18:2E). Despite the fact that the levels of these epoxy fatty acids comprised only up to 6.2% of the total fatty acids, there was a very marked increase in oleic acid (18:1) and decrease in linoleic (18:2) and α-linolenic (18:3) acids in these plants, indicating that endogenous Δ12-desaturation was greatly reduced in these plants. Significant between-line differences in the levels of Cpal2 mRNA were observed during seed development, but were not associated with any major variation in mRNA levels for the endogenous ArabidopsisΔ12-desaturase (Fad2). This suggests that if an unfavourable interaction occurs between the transgenic Δ12-epoxygenase and the endogenous Δ12-desaturase, which decreases the level of desaturation, it occurs at either the translational or post-translational level. We further show that the co-expression of a Δ12-desaturase gene from C. palaestina in Cpal2 transgenic Arabidopsis returns the relative proportions of the C18 seed fatty acids to normal levels and results in an almost twofold increase in total epoxy fatty acids. Received: 11 August 2000 / Accepted: 7 September 2000     

Heterologous expression of Brassica juncea microsomal ω-3 desaturase gene (BjFad3) improves the nutritionally desirable ω-6:ω-3 fatty acid ratio in rice bran oil

Rice bran oil (RBO), being naturally rich in antioxidants, is currently regarded as one of the health-beneficial edible oils. However, the RBO has essential linoleic acid (ω-6, C18:2) and α-linolenic acid (ω-3, C18:3) in nutritionally disproportionate level (~25:1), contrary to the WHO/FAO’s recommendation of ~5:1. Among few naturally occurring C18:3 enriched oil-seeds, Brassica juncea (Indian mustard) has almost equal proportion of ω-6 and ω-3 fatty acids in its oil due to the activity of microsomal ω-3 desaturase (Fad3), which converts C18:2–C18:3. Therefore, the full length Fad3 coding DNA sequence (CDS) was isolated from the developing seeds of B. juncea, functionally characterized and heterologously expressed for the nutritional enhancement of RBO. Sequence analysis revealed that the 1,134 bp long BjFad3 CDS corresponds to a polypeptide of 377 amino acids, which is highly (85–95 %) homologous to other known Fad3 enzymes of plant kingdom. The BjFad3 gene was initially characterized in transgenic tobacco to establish its linoleate desaturase activity. Thereafter, rice bran-specific expression of the BjFad3 was carried out to alter the fatty acid profile of RBO. Several independent transgenic lines of tobacco and rice plants were developed by Agrobacterium-mediated transformation. Standard molecular biological techniques were used to confirm the transgene integration in the respective genomes and subsequent in planta expression. The BjFad3 transgene expression correlated to the significant increase in C18:3 fatty acid content (up to tenfold) in both tobacco seed oil and RBO, and thereby improving the nutritionally desirable ω-6:ω-3 ratio (~2:1) in one of the transgenic rice lines.     

Overexpression of <Emphasis Type="Italic">FAD2</Emphasis> promotes seed germination and hypocotyl elongation in <Emphasis Type="Italic">Brassica napus</Emphasis>

The enzyme fatty acid desaturase 2 (FAD2) transforms oleic acid (C18:1) to linoleic acid (C18:2) in plants and as such is involved in fatty acid synthesis. It is also involved in plant development and self-defense, such as seed germination, leaf expansion and cold resistance. We have cloned the full coding region of the Brassica napus FAD2 gene and ectopically expressed it in B. napus expressing low levels of FAD2. Overexpression of FAD2 under the control of the CaMV 35S promoter resulted in an up-regulated FAD2 mRNA level in B. napus as expected. Further analysis revealed that the FAD2 transgenic lines varied greatly in terms of their physiological characteristics, such as enhanced seed germination and increased hypocotyl length, compared to non-transgenic plants, suggesting that up-regulated FAD2 can promote seed germination and hypocotyl elongation in B. napus. Our results demonstrate the possible roles of FAD2 in plant development and also provide a platform for further analysis of fatty acid synthesis in plants.     

A fatty acyl-CoA reductase highly expressed in the head of honey bee (Apis mellifera) involves biosynthesis of a wide range of aliphatic fatty alcohols

Honey bees (Apis mellifera) are social insects which have remarkable complexity in communication pheromones. These chemical signals comprise a mixture of hydrocarbons, wax esters, fatty acids, aldehydes and alcohols. In this study, we detected several long chain aliphatic alcohols ranging from C18-C32 in honey bees and the level of these alcohols varied in each body segment. C18:0Alc and C20:0Alc are more pronounced in the head, whereas C22:0Alc to C32Alc are abundant in the abdomen. One of the cDNAs coding for a fatty acyl-CoA reductase (AmFAR1) involved in the synthesis of fatty alcohols was isolated and characterized. AmFAR1 was ubiquitously expressed in all body segments with the predominance in the head of honey bees. Heterologous expression of AmFAR1 in yeast revealed that AmFAR1 could convert a wide range of fatty acids (14:0–22:0) to their corresponding alcohols, with stearic acid 18:0 as the most preferred substrate. The substrate preference and the expression pattern of AmFAR1 were correlated with the level of total fatty alcohols in bees. Reconstitution of the wax biosynthetic pathway by heterologous expression of AmFAR1, together with Euglena wax synthase led to the high level production of medium to long chain wax monoesters in yeast.     

Effects of Feeding Pigs Increasing Levels of C 18:1 Trans Fatty Acids on Fatty Acid Composition of Backfat and Intramuscular Fat as well as Backfat Firmness

Forty Large White pigs were fed from 30kg to 103kg body mass on diets supplemented with 6% of pure high-oleic sunflower oil (HO) or HO plus increasing amounts of partially hydrogenated rape seed oil (HR; 1.85%, 3.70%, 5.55%), containing high levels of j 6 to j 11 C 18:1 trans fatty acid isomers. Increasing dietary C 18: trans fatty acids resulted in a linear increase in C 18:1 trans fatty acids and conjugated linoleic acid (cis-9, trans-11 CLA) in backfat (BF) as well as in neutral lipids (NL) and phospholipids (PL) of M. long. dorsi. Thus, the rate of bioconversion of trans vaccenic acid (TVA) into CLA and incorporation of C 18:1 trans and CLA into pig adipose tissue was not limited up to 25g total C 18:1 trans fatty acids including 3.3g of TVA perkg feed. BF was higher in C 18:1 trans fatty acids and CLA than M. long. dorsi NL and PL. In BF and NL the sum of saturated fatty acids (SFA) increased with increasing dietary amounts of HR, while in PL SFA were reduced. Thus, according to their physical properties, C 18:1 trans fatty acids partly replaced SFA in PL. Firmness of backfat was also significantly increased (P<0.05) with increasing amounts of HR in feed.     

亚麻荠FUS3转录因子的鉴定及功能分析北大核心CSCD

FUS3转录因子是调控植物种子油脂合成的关键因子。为探讨亚麻荠CsFUS 3基因在脂质合成和积累过程中的作用,该研究对CsFUS 3基因家族进行全基因组鉴定,分析CsFUS 3基因的时空表达模式,并解析CsFUS 3-1和CsFUS 3-2基因在植物油脂合成中的功能,为深入解析CsFUS 3基因在亚麻荠油脂合成中的功能及亚麻荠高油品种选育提供理论基础。结果表明:(1)利用AtFUS3蛋白序列,在亚麻荠基因组数据库中鉴定出2条完整的CsFUS3蛋白序列,分别命名为CsFUS3-1和CsFUS3-2,亚细胞定位发现2个CsFUS3蛋白均位于细胞核。(2)亚麻荠CsFUS3-1和CsFUS3-2蛋白与拟南芥AtFUS3蛋白的亲缘关系最近,具有与拟南芥AtFUS3蛋白相似的理化性质、高级结构以及完整的B3功能域。(3)qRT-PCR结果显示,CsFUS 3-1和CsFUS 3-2基因仅在种子中表达,且随着种子的发育成熟,2个CsFUS 3基因的表达量均呈先增高后降低的变化趋势,并在花后30 d时表达量达到最高。(4)CsFUS3和CsWRI1蛋白互作以及CsFUS 3对OLE和ABI 3基因的转录调控可能是亚麻荠高油性状的关键调控途径。(5)烟草瞬时表达分析表明,与野生型相比,转CsFUS 3-1和CsFUS 3-2基因的烟草叶片总油脂含量分别提高了0.95%和1.12%,表明亚麻荠CsFUS 3基因能够提高烟叶总油脂的合成积累。     

Metabolic engineering of Schizosaccharomyces pombe to produce punicic acid,a conjugated fatty acid with nutraceutic properties

Punicic acid (PuA) is a conjugated linolenic acid (C18:3Δ^9c,11t,13c) with a wide range of nutraceutic effects with the potential to reduce the incidence of a number of health disorders including diabetes, obesity, and cancer. It is the main component of seed oil from Punica granatum and Trichosanthes kirilowii. Previously, production of relatively high levels of this unusual fatty acid in the seed oil of transgenic Arabidopsis thaliana plant was accomplished by the use of A. thaliana fad3/fae1 mutant high in linoleic acid (18:2∆^9c,12c) and by co-expression of P. granatum FATTY ACID CONJUGASE (PgFADX) with Δ12-DESATURASE (FAD2). In the current study, P. granatum cDNAs governing PuA production were introduced into the yeast Schizosaccharomyces pombe. Expression of PgFADX alone resulted in production of PuA at the level of 19.6% of total fatty acids. Co-expression PgFADX with PgFAD2, however, further enhanced PuA content to 25.1% of total fatty acids, the highest level reported to date for heterologous expression. Therefore, microbial systems can be considered as a potential alternative to plant sources for a source of PuA for nutraceutic applications.

     

Epistatic interaction among loci controlling the palmitic and the stearic acid levels in the seed oil of sunflower

Two sunflower (Helianthus annuus L.) mutants with high concentrations of saturated fatty acids in their seed oil have been identified and studied extensively. The mutant line CAS-5 has high concentrations of palmitic acid (C16:0) (>25% compared with 7% in standard sunflower seed oil) and low-C18:0 values (3%). CAS-3 is characterized by its high levels of stearic acid (C18:0) (>22% compared with 4% in standard sunflower seed oil) and a low-C16:0 content (5%). CAS-5 also possesses elevated levels of palmitoleic acid (C16:1) (>5%), which is absent in standard sunflower seed oil. The objective of this study was to determine the relationships between the loci controlling the high-C16:0 and the high-C18:0 traits in these mutants. Plants of both mutants were reciprocally crossed. Gas chromatographic analyses of fatty acids from the seed oil of F₁, F₂, F₃ and the BC₁F₁ to CAS-5 generations indicated that the loci controlling the high-C16:0 trait exerted an epistatic effect over the loci responsible for the high-C18:0 character. As a result, the phenotypic combination containing both the high-C16:0 levels of CAS-5 and the high-C18:0 levels of CAS-3 was not possible. However, phenotypes with a saturated fatty acid content of 44% (34.5% C16:0+9.5% C18:0) were identified in the F₃ generation. These are the highest saturated (C16:0 and C18:0) levels reported so far in sunflower seed oil. When F₃ C16:0 segregating generations in both a high- and a low-C18:0 background were compared, the high-C16:1 levels were not expressed as expected in the high-C18:0 background (CAS-3 background). In this case, the C16:1 content decreased to values below 1.5%, compared with >5% in a low-C18:0 background. As the stearoyl-ACP desaturase has been reported to catalyze the desaturation from C16:0-ACP to C16:1-ACP, these results suggested that a decrease in its activity was involved in the accumulation of C18:0 in the high-C18:0 mutant CAS-3. Received: 10 March 1999 / Accepted: 16 June 1999     

Sunflower (Helianthus annuus) long‐chain acyl‐coenzyme A synthetases expressed at high levels in developing seeds

Long chain fatty acid synthetases (LACSs) activate the fatty acid chains produced by plastidial de novo biosynthesis to generate acyl‐CoA derivatives, important intermediates in lipid metabolism. Oilseeds, like sunflower, accumulate high levels of triacylglycerols (TAGs) in their seeds to nourish the embryo during germination. This requires that sunflower seed endosperm supports very active glycerolipid synthesis during development. Sunflower seed plastids produce large amounts of fatty acids, which must be activated through the action of LACSs, in order to be incorporated into TAGs. We cloned two different LACS genes from developing sunflower endosperm, HaLACS1 and HaLACS2, which displayed sequence homology with Arabidopsis LACS9 and LACS8 genes, respectively. These genes were expressed at high levels in developing seeds and exhibited distinct subcellular distributions. We generated constructs in which these proteins were fused to green fluorescent protein and performed transient expression experiments in tobacco cells. The HaLACS1 protein associated with the external envelope of tobacco chloroplasts, whereas HaLACS2 was strongly bound to the endoplasmic reticulum. Finally, both proteins were overexpressed in Escherichia coli and recovered as active enzymes in the bacterial membranes. Both enzymes displayed similar substrate specificities, with a very high preference for oleic acid and weaker activity toward stearic acid. On the basis of our findings, we discuss the role of these enzymes in sunflower oil synthesis.     

Feedback inhibition of fatty acid synthesis in tobacco suspension cells

The flux through many metabolic pathways is regulated through feedback inhibition on regulatory enzymes by endproducts of the pathway. Whether feedback inhibition occurs in fatty acid synthesis in plants has been investigated. The addition of exogenous oleic acid, in the form of oleoyl-Tween (Tween-18:1) caused a three- to fivefold decrease in the rate of [1-¹⁴C]acetate incorporation into tobacco suspension cell fatty acids. The decrease in acetate incorporation occurred rapidly upon addition of Tween-18:1 and appeared to be specific for fatty acid synthesis. In order to elucidate possible regulatory steps involved in the feedback regulation of fatty acid synthesis in plant cells, tobacco cell acyl-ACP intermediates were analyzed using a combination of [1-¹⁴C]acetate labeling and immunoblot analysis. Within 30 min of exogenous lipid addition, acetyl-ACP increased and long chain acyl-ACP decreased, whereas medium chain acyl-ACP levels remained constant. These acyl-ACP profiles observed during the feedback inhibition were those predicted to occur under conditions where the flux through fatty acid synthesis is decreased due to limiting levels of malonyl-CoA and therefore indicated that acetyl-CoA carboxylase (ACCase) was centrally involved in the feedback regulation of fatty acid synthesis. Immunoblot analysis showed that ACCase protein levels did not change during the feedback inhibition, indicating that the feedback inhibition of fatty acid synthesis in plant cells occurs through biochemical or post-translational modification of ACCase and possibly other fatty acid synthesis enzymes.     

牡丹DGAT基因的克隆及表达分析

利用RT-PCR和RACE技术,从牡丹种子中克隆得到1个二酰甘油酰基转移酶基因(DGAT),命名为PaDGAT1(GenBank登录号为MG214258)。PaDGAT1基因cDNA全长为2 028bp,包含1 554bp开放阅读框,编码517个氨基酸。PaDGAT1蛋白属于疏水性碱性蛋白,分子量为58.86kD,理论等电点为8.62,二级结构预测表明,无规则卷曲和延伸链是该蛋白的主要结构元件。氨基酸序列对比分析表明,PaDGAT1基因编码的蛋白属于DGAT1亚家族,与油橄榄(Olea europaea)的DGAT1蛋白亲缘关系最近。实时荧光定量分析结果表明,PaDGAT1基因在花芽中表达水平较高,在叶、茎和未发育子房中表达水平较低;在种子发育过程中,PaDGAT1基因表达水平呈现出升高-降低-升高的趋势,其中在发育28d时表达水平最高,随后其表达水平逐渐减低,在种子发育70d时又升高,至发育末期的85d时表达水平升高至较高水平;在种子收获后,常温存放7d时,PaDGAT1基因表达水平最高,随后其表达水平逐渐下降。结果推测,DGAT基因在牡丹种子的油脂合成中起重要的调控作用。     

Comparative evaluation of rumen‐protected fat,coconut oil and various oilseeds supplemented to fattening bulls

The effects of five different dietary fat supplements on fatty acid composition and oxidative stability of subcutaneous and kidney fat were evaluated in 36 Brown Swiss bulls and compared to a low fat diet in a monofactorial design. The following fat supplements were provided as additional fat at 30 g per kg feed dry matter: crystalline rumen‐protected fat, coconut oil, and three types of crushed whole oilseeds (rapeseed, sunflower seed and linseed). Adipose tissues reflected differences (P < 0.05) in dietary fatty acid composition although to a lower extent. Using protected fat, which contained elevated levels of trans fatty acids, and sunflower seed, containing a high proportion of linoleic acid, significantly increased C18:1 trans fatty acid proportion in the adipose tissues. The use of sunflower seed increased conjugated linoleic acid. The oilseeds resulted in lower amounts of C16:0 in favour of C18:0. Except for linseed, all fat supplemented groups improved oxidative stability of adipose tissues as compared with control. This was explained by lower proportions of unsaturated fatty acids in adipose tissue (protected fat), by elevated α‐tocopherol contents (rapeseed, sunflower seed) or by a combination of both (coconut oil). Fat colour remained unaffected by treatments. Compared to other fat supplements oilseeds, especially sunflower seed and rapeseed, can therefore be recommended to be fed to bulls in order to increase the proportions of C18 unsaturated fatty acids in adipose tissues and to maintain or improve oxidative stability.     

Mapping minor QTL for increased stearic acid content in sunflower seed oil

Increased stearic acid (C18:0) content in the seed oil of sunflower would improve the oil quality for some edible uses. The sunflower line CAS-20 (C18:0 genotype Es1Es1es2es2), developed from the high C18:0 mutant line CAS-3 (C18:0 genotype es1es1es2es2; 25% C18:0), shows increased C18:0 levels in its seed oil (8.6%). The objective of this research was to map quantitative trait loci (QTL) conferring increased C18:0 content in CAS-20 in an F₂ mapping population developed from crosses between HA-89 (wild type Es1Es1Es2Es2; low C18:0) and CAS-20, which segregates independently of the macromutation Es1 controlling high C18:0 content in CAS-3. Seed oil fatty acid composition was measured in the F₂ population by gas-liquid chromatography. A genetic linkage map of 17 linkage groups (LGs) comprising 80 RFLP and 19 SSR marker loci from this population was used to identify QTL controlling fatty acid composition. Three QTL affecting C18:0 content were identified on LG3, LG11, and LG13, with all alleles for increased C18:0 content inherited from CAS-20. In total, these QTL explained 43.6% of the C18:0 phenotypic variation. Additionally, four candidate genes (two stearate desaturase genes, SAD6 and SAD17, and a FatA and a FatB thioesterase gene) were placed on the QTL map. On the basis of positional information, QTL on LG11 was suggested to be a SAD6 locus. The results presented show that increased C18:0 content in sunflower seed oil is not a simple trait, and the markers flanking these QTL constitute a powerful tool for plant breeding programs.